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armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1	// Copyright 2013, ARM Limited
				2	// All rights reserved.
				3	//
				4	// Redistribution and use in source and binary forms, with or without
				5	// modification, are permitted provided that the following conditions are met:
				6	//
				7	// * Redistributions of source code must retain the above copyright notice,
				8	// this list of conditions and the following disclaimer.
				9	// * Redistributions in binary form must reproduce the above copyright notice,
				10	// this list of conditions and the following disclaimer in the documentation
				11	// and/or other materials provided with the distribution.
				12	// * Neither the name of ARM Limited nor the names of its contributors may be
				13	// used to endorse or promote products derived from this software without
				14	// specific prior written permission.
				15	//
				16	// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS CONTRIBUTORS "AS IS" AND
				17	// ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
				18	// WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
				19	// DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE
				20	// FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
				21	// DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
				22	// SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
				23	// CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
				24	// OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
				25	// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
				26
				27	#include <stdio.h>
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	28	#include <stdlib.h>
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	29	#include <string.h>
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	30	#include <math.h>
				31	#include <float.h>
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	32
				33	#include "cctest.h"
				34	#include "test-utils-a64.h"
				35	#include "a64/macro-assembler-a64.h"
				36	#include "a64/simulator-a64.h"
				37	#include "a64/debugger-a64.h"
				38	#include "a64/disasm-a64.h"
				39	#include "a64/cpu-a64.h"
				40
				41	namespace vixl {
				42
				43	// Test infrastructure.
				44	//
				45	// Tests are functions which accept no parameters and have no return values.
				46	// The testing code should not perform an explicit return once completed. For
				47	// example to test the mov immediate instruction a very simple test would be:
				48	//
				49	// TEST(mov_x0_one) {
				50	// SETUP();
				51	//
				52	// START();
				53	// __ mov(x0, Operand(1));
				54	// END();
				55	//
				56	// RUN();
				57	//
				58	// ASSERT_EQUAL_64(1, x0);
				59	//
				60	// TEARDOWN();
				61	// }
				62	//
				63	// Within a START ... END block all registers but sp can be modified. sp has to
				64	// be explicitly saved/restored. The END() macro replaces the function return
				65	// so it may appear multiple times in a test if the test has multiple exit
				66	// points.
				67	//
				68	// Once the test has been run all integer and floating point registers as well
				69	// as flags are accessible through a RegisterDump instance, see
				70	// utils-a64.cc for more info on RegisterDump.
				71	//
				72	// We provide some helper assert to handle common cases:
				73	//
				74	// ASSERT_EQUAL_32(int32_t, int_32t)
				75	// ASSERT_EQUAL_FP32(float, float)
				76	// ASSERT_EQUAL_32(int32_t, W register)
				77	// ASSERT_EQUAL_FP32(float, S register)
				78	// ASSERT_EQUAL_64(int64_t, int_64t)
				79	// ASSERT_EQUAL_FP64(double, double)
				80	// ASSERT_EQUAL_64(int64_t, X register)
				81	// ASSERT_EQUAL_64(X register, X register)
				82	// ASSERT_EQUAL_FP64(double, D register)
				83	//
				84	// e.g. ASSERT_EQUAL_64(0.5, d30);
				85	//
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	86	// If more advanced computation is required before the assert then access the
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	87	// RegisterDump named core directly:
				88	//
				89	// ASSERT_EQUAL_64(0x1234, core->reg_x0() & 0xffff);
				90
				91
				92	#define __ masm.
				93	#define TEST(name) TEST_(ASM_##name)
				94
				95	#define BUF_SIZE (4096)
				96
				97	#define SETUP() SETUP_SIZE(BUF_SIZE)
				98
				99	#ifdef USE_SIMULATOR
				100
				101	// Run tests with the simulator.
				102	#define SETUP_SIZE(buf_size) \
				103	byte* buf = new byte[buf_size]; \
				104	MacroAssembler masm(buf, buf_size); \
				105	Decoder decoder; \
				106	Simulator* simulator = NULL; \
				107	if (Cctest::run_debugger()) { \
				108	simulator = new Debugger(&decoder); \
				109	} else { \
				110	simulator = new Simulator(&decoder); \
				111	simulator->set_disasm_trace(Cctest::trace_sim()); \
				112	} \
				113	simulator->set_coloured_trace(Cctest::coloured_trace()); \
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	114	simulator->set_instruction_stats(Cctest::instruction_stats()); \
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	115	RegisterDump core
				116
				117	#define START() \
				118	masm.Reset(); \
				119	simulator->ResetState(); \
				120	__ PushCalleeSavedRegisters(); \
				121	if (Cctest::run_debugger()) { \
				122	if (Cctest::trace_reg()) { \
				123	__ Trace(LOG_STATE, TRACE_ENABLE); \
				124	} \
				125	if (Cctest::trace_sim()) { \
				126	__ Trace(LOG_DISASM, TRACE_ENABLE); \
				127	} \
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	128	} \
				129	if (Cctest::instruction_stats()) { \
				130	__ EnableInstrumentation(); \
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	131	}
				132
				133	#define END() \
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	134	if (Cctest::instruction_stats()) { \
				135	__ DisableInstrumentation(); \
				136	} \
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	137	if (Cctest::run_debugger()) { \
				138	__ Trace(LOG_ALL, TRACE_DISABLE); \
				139	} \
				140	core.Dump(&masm); \
				141	__ PopCalleeSavedRegisters(); \
				142	__ Ret(); \
				143	masm.FinalizeCode()
				144
				145	#define RUN() \
				146	simulator->RunFrom(reinterpret_cast<Instruction*>(buf))
				147
				148	#define TEARDOWN() \
				149	delete simulator; \
				150	delete[] buf;
				151
				152	#else // ifdef USE_SIMULATOR.
				153	// Run the test on real hardware or models.
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	154	#define SETUP_SIZE(size) \
				155	size_t buf_size = size; \
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	156	byte* buf = new byte[buf_size]; \
				157	MacroAssembler masm(buf, buf_size); \
				158	RegisterDump core; \
				159	CPU::SetUp()
				160
				161	#define START() \
				162	masm.Reset(); \
				163	__ PushCalleeSavedRegisters()
				164
				165	#define END() \
				166	core.Dump(&masm); \
				167	__ PopCalleeSavedRegisters(); \
				168	__ Ret(); \
				169	masm.FinalizeCode()
				170
				171	#define RUN() \
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	172	CPU::EnsureIAndDCacheCoherency(buf, buf_size); \
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	173	{ \
				174	void (*test_function)(void); \
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	175	VIXL_ASSERT(sizeof(buf) == sizeof(test_function)); \
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	176	memcpy(&test_function, &buf, sizeof(buf)); \
				177	test_function(); \
				178	}
				179
				180	#define TEARDOWN() \
				181	delete[] buf;
				182
				183	#endif // ifdef USE_SIMULATOR.
				184
				185	#define ASSERT_EQUAL_NZCV(expected) \
				186	assert(EqualNzcv(expected, core.flags_nzcv()))
				187
				188	#define ASSERT_EQUAL_REGISTERS(expected) \
				189	assert(EqualRegisters(&expected, &core))
				190
				191	#define ASSERT_EQUAL_32(expected, result) \
				192	assert(Equal32(static_cast<uint32_t>(expected), &core, result))
				193
				194	#define ASSERT_EQUAL_FP32(expected, result) \
				195	assert(EqualFP32(expected, &core, result))
				196
				197	#define ASSERT_EQUAL_64(expected, result) \
				198	assert(Equal64(expected, &core, result))
				199
				200	#define ASSERT_EQUAL_FP64(expected, result) \
				201	assert(EqualFP64(expected, &core, result))
				202
				203	#define ASSERT_LITERAL_POOL_SIZE(expected) \
				204	assert((expected) == (__ LiteralPoolSize()))
				205
				206
				207	TEST(stack_ops) {
				208	SETUP();
				209
				210	START();
				211	// save sp.
				212	__ Mov(x29, sp);
				213
				214	// Set the sp to a known value.
				215	__ Mov(sp, 0x1004);
				216	__ Mov(x0, sp);
				217
				218	// Add immediate to the sp, and move the result to a normal register.
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	219	__ Add(sp, sp, 0x50);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	220	__ Mov(x1, sp);
				221
				222	// Add extended to the sp, and move the result to a normal register.
				223	__ Mov(x17, 0xfff);
				224	__ Add(sp, sp, Operand(x17, SXTB));
				225	__ Mov(x2, sp);
				226
				227	// Create an sp using a logical instruction, and move to normal register.
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	228	__ Orr(sp, xzr, 0x1fff);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	229	__ Mov(x3, sp);
				230
				231	// Write wsp using a logical instruction.
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	232	__ Orr(wsp, wzr, 0xfffffff8);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	233	__ Mov(x4, sp);
				234
				235	// Write sp, and read back wsp.
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	236	__ Orr(sp, xzr, 0xfffffff8);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	237	__ Mov(w5, wsp);
				238
				239	// restore sp.
				240	__ Mov(sp, x29);
				241	END();
				242
				243	RUN();
				244
				245	ASSERT_EQUAL_64(0x1004, x0);
				246	ASSERT_EQUAL_64(0x1054, x1);
				247	ASSERT_EQUAL_64(0x1053, x2);
				248	ASSERT_EQUAL_64(0x1fff, x3);
				249	ASSERT_EQUAL_64(0xfffffff8, x4);
				250	ASSERT_EQUAL_64(0xfffffff8, x5);
				251
				252	TEARDOWN();
				253	}
				254
				255
				256	TEST(mvn) {
				257	SETUP();
				258
				259	START();
				260	__ Mvn(w0, 0xfff);
				261	__ Mvn(x1, 0xfff);
				262	__ Mvn(w2, Operand(w0, LSL, 1));
				263	__ Mvn(x3, Operand(x1, LSL, 2));
				264	__ Mvn(w4, Operand(w0, LSR, 3));
				265	__ Mvn(x5, Operand(x1, LSR, 4));
				266	__ Mvn(w6, Operand(w0, ASR, 11));
				267	__ Mvn(x7, Operand(x1, ASR, 12));
				268	__ Mvn(w8, Operand(w0, ROR, 13));
				269	__ Mvn(x9, Operand(x1, ROR, 14));
				270	__ Mvn(w10, Operand(w2, UXTB));
				271	__ Mvn(x11, Operand(x2, SXTB, 1));
				272	__ Mvn(w12, Operand(w2, UXTH, 2));
				273	__ Mvn(x13, Operand(x2, SXTH, 3));
				274	__ Mvn(x14, Operand(w2, UXTW, 4));
				275	__ Mvn(x15, Operand(w2, SXTW, 4));
				276	END();
				277
				278	RUN();
				279
				280	ASSERT_EQUAL_64(0xfffff000, x0);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	281	ASSERT_EQUAL_64(0xfffffffffffff000, x1);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	282	ASSERT_EQUAL_64(0x00001fff, x2);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	283	ASSERT_EQUAL_64(0x0000000000003fff, x3);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	284	ASSERT_EQUAL_64(0xe00001ff, x4);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	285	ASSERT_EQUAL_64(0xf0000000000000ff, x5);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	286	ASSERT_EQUAL_64(0x00000001, x6);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	287	ASSERT_EQUAL_64(0x0000000000000000, x7);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	288	ASSERT_EQUAL_64(0x7ff80000, x8);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	289	ASSERT_EQUAL_64(0x3ffc000000000000, x9);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	290	ASSERT_EQUAL_64(0xffffff00, x10);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	291	ASSERT_EQUAL_64(0x0000000000000001, x11);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	292	ASSERT_EQUAL_64(0xffff8003, x12);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	293	ASSERT_EQUAL_64(0xffffffffffff0007, x13);
				294	ASSERT_EQUAL_64(0xfffffffffffe000f, x14);
				295	ASSERT_EQUAL_64(0xfffffffffffe000f, x15);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	296
				297	TEARDOWN();
				298	}
				299
				300
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	301	TEST(mov_imm_w) {
				302	SETUP();
				303
				304	START();
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	305	__ Mov(w0, 0xffffffff);
				306	__ Mov(w1, 0xffff1234);
				307	__ Mov(w2, 0x1234ffff);
				308	__ Mov(w3, 0x00000000);
				309	__ Mov(w4, 0x00001234);
				310	__ Mov(w5, 0x12340000);
				311	__ Mov(w6, 0x12345678);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	312	END();
				313
				314	RUN();
				315
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	316	ASSERT_EQUAL_64(0xffffffff, x0);
				317	ASSERT_EQUAL_64(0xffff1234, x1);
				318	ASSERT_EQUAL_64(0x1234ffff, x2);
				319	ASSERT_EQUAL_64(0x00000000, x3);
				320	ASSERT_EQUAL_64(0x00001234, x4);
				321	ASSERT_EQUAL_64(0x12340000, x5);
				322	ASSERT_EQUAL_64(0x12345678, x6);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	323
				324	TEARDOWN();
				325	}
				326
				327
				328	TEST(mov_imm_x) {
				329	SETUP();
				330
				331	START();
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	332	__ Mov(x0, 0xffffffffffffffff);
				333	__ Mov(x1, 0xffffffffffff1234);
				334	__ Mov(x2, 0xffffffff12345678);
				335	__ Mov(x3, 0xffff1234ffff5678);
				336	__ Mov(x4, 0x1234ffffffff5678);
				337	__ Mov(x5, 0x1234ffff5678ffff);
				338	__ Mov(x6, 0x12345678ffffffff);
				339	__ Mov(x7, 0x1234ffffffffffff);
				340	__ Mov(x8, 0x123456789abcffff);
				341	__ Mov(x9, 0x12345678ffff9abc);
				342	__ Mov(x10, 0x1234ffff56789abc);
				343	__ Mov(x11, 0xffff123456789abc);
				344	__ Mov(x12, 0x0000000000000000);
				345	__ Mov(x13, 0x0000000000001234);
				346	__ Mov(x14, 0x0000000012345678);
				347	__ Mov(x15, 0x0000123400005678);
				348	__ Mov(x18, 0x1234000000005678);
				349	__ Mov(x19, 0x1234000056780000);
				350	__ Mov(x20, 0x1234567800000000);
				351	__ Mov(x21, 0x1234000000000000);
				352	__ Mov(x22, 0x123456789abc0000);
				353	__ Mov(x23, 0x1234567800009abc);
				354	__ Mov(x24, 0x1234000056789abc);
				355	__ Mov(x25, 0x0000123456789abc);
				356	__ Mov(x26, 0x123456789abcdef0);
				357	__ Mov(x27, 0xffff000000000001);
				358	__ Mov(x28, 0x8000ffff00000000);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	359	END();
				360
				361	RUN();
				362
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	363	ASSERT_EQUAL_64(0xffffffffffff1234, x1);
				364	ASSERT_EQUAL_64(0xffffffff12345678, x2);
				365	ASSERT_EQUAL_64(0xffff1234ffff5678, x3);
				366	ASSERT_EQUAL_64(0x1234ffffffff5678, x4);
				367	ASSERT_EQUAL_64(0x1234ffff5678ffff, x5);
				368	ASSERT_EQUAL_64(0x12345678ffffffff, x6);
				369	ASSERT_EQUAL_64(0x1234ffffffffffff, x7);
				370	ASSERT_EQUAL_64(0x123456789abcffff, x8);
				371	ASSERT_EQUAL_64(0x12345678ffff9abc, x9);
				372	ASSERT_EQUAL_64(0x1234ffff56789abc, x10);
				373	ASSERT_EQUAL_64(0xffff123456789abc, x11);
				374	ASSERT_EQUAL_64(0x0000000000000000, x12);
				375	ASSERT_EQUAL_64(0x0000000000001234, x13);
				376	ASSERT_EQUAL_64(0x0000000012345678, x14);
				377	ASSERT_EQUAL_64(0x0000123400005678, x15);
				378	ASSERT_EQUAL_64(0x1234000000005678, x18);
				379	ASSERT_EQUAL_64(0x1234000056780000, x19);
				380	ASSERT_EQUAL_64(0x1234567800000000, x20);
				381	ASSERT_EQUAL_64(0x1234000000000000, x21);
				382	ASSERT_EQUAL_64(0x123456789abc0000, x22);
				383	ASSERT_EQUAL_64(0x1234567800009abc, x23);
				384	ASSERT_EQUAL_64(0x1234000056789abc, x24);
				385	ASSERT_EQUAL_64(0x0000123456789abc, x25);
				386	ASSERT_EQUAL_64(0x123456789abcdef0, x26);
				387	ASSERT_EQUAL_64(0xffff000000000001, x27);
				388	ASSERT_EQUAL_64(0x8000ffff00000000, x28);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	389
				390
				391	TEARDOWN();
				392	}
				393
				394
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	395	TEST(mov) {
				396	SETUP();
				397
				398	START();
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	399	__ Mov(x0, 0xffffffffffffffff);
				400	__ Mov(x1, 0xffffffffffffffff);
				401	__ Mov(x2, 0xffffffffffffffff);
				402	__ Mov(x3, 0xffffffffffffffff);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	403
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	404	__ Mov(x0, 0x0123456789abcdef);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	405
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	406	__ movz(x1, UINT64_C(0xabcd) << 16);
				407	__ movk(x2, UINT64_C(0xabcd) << 32);
				408	__ movn(x3, UINT64_C(0xabcd) << 48);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	409
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	410	__ Mov(x4, 0x0123456789abcdef);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	411	__ Mov(x5, x4);
				412
				413	__ Mov(w6, -1);
				414
				415	// Test that moves back to the same register have the desired effect. This
				416	// is a no-op for X registers, and a truncation for W registers.
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	417	__ Mov(x7, 0x0123456789abcdef);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	418	__ Mov(x7, x7);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	419	__ Mov(x8, 0x0123456789abcdef);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	420	__ Mov(w8, w8);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	421	__ Mov(x9, 0x0123456789abcdef);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	422	__ Mov(x9, Operand(x9));
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	423	__ Mov(x10, 0x0123456789abcdef);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	424	__ Mov(w10, Operand(w10));
				425
				426	__ Mov(w11, 0xfff);
				427	__ Mov(x12, 0xfff);
				428	__ Mov(w13, Operand(w11, LSL, 1));
				429	__ Mov(x14, Operand(x12, LSL, 2));
				430	__ Mov(w15, Operand(w11, LSR, 3));
				431	__ Mov(x18, Operand(x12, LSR, 4));
				432	__ Mov(w19, Operand(w11, ASR, 11));
				433	__ Mov(x20, Operand(x12, ASR, 12));
				434	__ Mov(w21, Operand(w11, ROR, 13));
				435	__ Mov(x22, Operand(x12, ROR, 14));
				436	__ Mov(w23, Operand(w13, UXTB));
				437	__ Mov(x24, Operand(x13, SXTB, 1));
				438	__ Mov(w25, Operand(w13, UXTH, 2));
				439	__ Mov(x26, Operand(x13, SXTH, 3));
				440	__ Mov(x27, Operand(w13, UXTW, 4));
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	441
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	442	__ Mov(x28, 0x0123456789abcdef);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	443	__ Mov(w28, w28, kDiscardForSameWReg);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	444	END();
				445
				446	RUN();
				447
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	448	ASSERT_EQUAL_64(0x0123456789abcdef, x0);
				449	ASSERT_EQUAL_64(0x00000000abcd0000, x1);
				450	ASSERT_EQUAL_64(0xffffabcdffffffff, x2);
				451	ASSERT_EQUAL_64(0x5432ffffffffffff, x3);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	452	ASSERT_EQUAL_64(x4, x5);
				453	ASSERT_EQUAL_32(-1, w6);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	454	ASSERT_EQUAL_64(0x0123456789abcdef, x7);
				455	ASSERT_EQUAL_32(0x89abcdef, w8);
				456	ASSERT_EQUAL_64(0x0123456789abcdef, x9);
				457	ASSERT_EQUAL_32(0x89abcdef, w10);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	458	ASSERT_EQUAL_64(0x00000fff, x11);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	459	ASSERT_EQUAL_64(0x0000000000000fff, x12);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	460	ASSERT_EQUAL_64(0x00001ffe, x13);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	461	ASSERT_EQUAL_64(0x0000000000003ffc, x14);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	462	ASSERT_EQUAL_64(0x000001ff, x15);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	463	ASSERT_EQUAL_64(0x00000000000000ff, x18);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	464	ASSERT_EQUAL_64(0x00000001, x19);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	465	ASSERT_EQUAL_64(0x0000000000000000, x20);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	466	ASSERT_EQUAL_64(0x7ff80000, x21);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	467	ASSERT_EQUAL_64(0x3ffc000000000000, x22);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	468	ASSERT_EQUAL_64(0x000000fe, x23);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	469	ASSERT_EQUAL_64(0xfffffffffffffffc, x24);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	470	ASSERT_EQUAL_64(0x00007ff8, x25);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	471	ASSERT_EQUAL_64(0x000000000000fff0, x26);
				472	ASSERT_EQUAL_64(0x000000000001ffe0, x27);
				473	ASSERT_EQUAL_64(0x0123456789abcdef, x28);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	474
				475	TEARDOWN();
				476	}
				477
				478
				479	TEST(orr) {
				480	SETUP();
				481
				482	START();
				483	__ Mov(x0, 0xf0f0);
				484	__ Mov(x1, 0xf00000ff);
				485
				486	__ Orr(x2, x0, Operand(x1));
				487	__ Orr(w3, w0, Operand(w1, LSL, 28));
				488	__ Orr(x4, x0, Operand(x1, LSL, 32));
				489	__ Orr(x5, x0, Operand(x1, LSR, 4));
				490	__ Orr(w6, w0, Operand(w1, ASR, 4));
				491	__ Orr(x7, x0, Operand(x1, ASR, 4));
				492	__ Orr(w8, w0, Operand(w1, ROR, 12));
				493	__ Orr(x9, x0, Operand(x1, ROR, 12));
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	494	__ Orr(w10, w0, 0xf);
				495	__ Orr(x11, x0, 0xf0000000f0000000);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	496	END();
				497
				498	RUN();
				499
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	500	ASSERT_EQUAL_64(0x00000000f000f0ff, x2);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	501	ASSERT_EQUAL_64(0xf000f0f0, x3);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	502	ASSERT_EQUAL_64(0xf00000ff0000f0f0, x4);
				503	ASSERT_EQUAL_64(0x000000000f00f0ff, x5);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	504	ASSERT_EQUAL_64(0xff00f0ff, x6);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	505	ASSERT_EQUAL_64(0x000000000f00f0ff, x7);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	506	ASSERT_EQUAL_64(0x0ffff0f0, x8);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	507	ASSERT_EQUAL_64(0x0ff00000000ff0f0, x9);
				508	ASSERT_EQUAL_64(0x0000f0ff, x10);
				509	ASSERT_EQUAL_64(0xf0000000f000f0f0, x11);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	510
				511	TEARDOWN();
				512	}
				513
				514
				515	TEST(orr_extend) {
				516	SETUP();
				517
				518	START();
				519	__ Mov(x0, 1);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	520	__ Mov(x1, 0x8000000080008080);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	521	__ Orr(w6, w0, Operand(w1, UXTB));
				522	__ Orr(x7, x0, Operand(x1, UXTH, 1));
				523	__ Orr(w8, w0, Operand(w1, UXTW, 2));
				524	__ Orr(x9, x0, Operand(x1, UXTX, 3));
				525	__ Orr(w10, w0, Operand(w1, SXTB));
				526	__ Orr(x11, x0, Operand(x1, SXTH, 1));
				527	__ Orr(x12, x0, Operand(x1, SXTW, 2));
				528	__ Orr(x13, x0, Operand(x1, SXTX, 3));
				529	END();
				530
				531	RUN();
				532
				533	ASSERT_EQUAL_64(0x00000081, x6);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	534	ASSERT_EQUAL_64(0x0000000000010101, x7);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	535	ASSERT_EQUAL_64(0x00020201, x8);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	536	ASSERT_EQUAL_64(0x0000000400040401, x9);
				537	ASSERT_EQUAL_64(0xffffff81, x10);
				538	ASSERT_EQUAL_64(0xffffffffffff0101, x11);
				539	ASSERT_EQUAL_64(0xfffffffe00020201, x12);
				540	ASSERT_EQUAL_64(0x0000000400040401, x13);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	541
				542	TEARDOWN();
				543	}
				544
				545
				546	TEST(bitwise_wide_imm) {
				547	SETUP();
				548
				549	START();
				550	__ Mov(x0, 0);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	551	__ Mov(x1, 0xf0f0f0f0f0f0f0f0);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	552
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	553	__ Orr(x10, x0, 0x1234567890abcdef);
				554	__ Orr(w11, w1, 0x90abcdef);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	555	END();
				556
				557	RUN();
				558
				559	ASSERT_EQUAL_64(0, x0);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	560	ASSERT_EQUAL_64(0xf0f0f0f0f0f0f0f0, x1);
				561	ASSERT_EQUAL_64(0x1234567890abcdef, x10);
				562	ASSERT_EQUAL_64(0x00000000f0fbfdff, x11);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	563
				564	TEARDOWN();
				565	}
				566
				567
				568	TEST(orn) {
				569	SETUP();
				570
				571	START();
				572	__ Mov(x0, 0xf0f0);
				573	__ Mov(x1, 0xf00000ff);
				574
				575	__ Orn(x2, x0, Operand(x1));
				576	__ Orn(w3, w0, Operand(w1, LSL, 4));
				577	__ Orn(x4, x0, Operand(x1, LSL, 4));
				578	__ Orn(x5, x0, Operand(x1, LSR, 1));
				579	__ Orn(w6, w0, Operand(w1, ASR, 1));
				580	__ Orn(x7, x0, Operand(x1, ASR, 1));
				581	__ Orn(w8, w0, Operand(w1, ROR, 16));
				582	__ Orn(x9, x0, Operand(x1, ROR, 16));
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	583	__ Orn(w10, w0, 0x0000ffff);
				584	__ Orn(x11, x0, 0x0000ffff0000ffff);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	585	END();
				586
				587	RUN();
				588
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	589	ASSERT_EQUAL_64(0xffffffff0ffffff0, x2);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	590	ASSERT_EQUAL_64(0xfffff0ff, x3);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	591	ASSERT_EQUAL_64(0xfffffff0fffff0ff, x4);
				592	ASSERT_EQUAL_64(0xffffffff87fffff0, x5);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	593	ASSERT_EQUAL_64(0x07fffff0, x6);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	594	ASSERT_EQUAL_64(0xffffffff87fffff0, x7);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	595	ASSERT_EQUAL_64(0xff00ffff, x8);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	596	ASSERT_EQUAL_64(0xff00ffffffffffff, x9);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	597	ASSERT_EQUAL_64(0xfffff0f0, x10);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	598	ASSERT_EQUAL_64(0xffff0000fffff0f0, x11);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	599
				600	TEARDOWN();
				601	}
				602
				603
				604	TEST(orn_extend) {
				605	SETUP();
				606
				607	START();
				608	__ Mov(x0, 1);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	609	__ Mov(x1, 0x8000000080008081);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	610	__ Orn(w6, w0, Operand(w1, UXTB));
				611	__ Orn(x7, x0, Operand(x1, UXTH, 1));
				612	__ Orn(w8, w0, Operand(w1, UXTW, 2));
				613	__ Orn(x9, x0, Operand(x1, UXTX, 3));
				614	__ Orn(w10, w0, Operand(w1, SXTB));
				615	__ Orn(x11, x0, Operand(x1, SXTH, 1));
				616	__ Orn(x12, x0, Operand(x1, SXTW, 2));
				617	__ Orn(x13, x0, Operand(x1, SXTX, 3));
				618	END();
				619
				620	RUN();
				621
				622	ASSERT_EQUAL_64(0xffffff7f, x6);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	623	ASSERT_EQUAL_64(0xfffffffffffefefd, x7);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	624	ASSERT_EQUAL_64(0xfffdfdfb, x8);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	625	ASSERT_EQUAL_64(0xfffffffbfffbfbf7, x9);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	626	ASSERT_EQUAL_64(0x0000007f, x10);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	627	ASSERT_EQUAL_64(0x000000000000fefd, x11);
				628	ASSERT_EQUAL_64(0x00000001fffdfdfb, x12);
				629	ASSERT_EQUAL_64(0xfffffffbfffbfbf7, x13);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	630
				631	TEARDOWN();
				632	}
				633
				634
				635	TEST(and_) {
				636	SETUP();
				637
				638	START();
				639	__ Mov(x0, 0xfff0);
				640	__ Mov(x1, 0xf00000ff);
				641
				642	__ And(x2, x0, Operand(x1));
				643	__ And(w3, w0, Operand(w1, LSL, 4));
				644	__ And(x4, x0, Operand(x1, LSL, 4));
				645	__ And(x5, x0, Operand(x1, LSR, 1));
				646	__ And(w6, w0, Operand(w1, ASR, 20));
				647	__ And(x7, x0, Operand(x1, ASR, 20));
				648	__ And(w8, w0, Operand(w1, ROR, 28));
				649	__ And(x9, x0, Operand(x1, ROR, 28));
				650	__ And(w10, w0, Operand(0xff00));
				651	__ And(x11, x0, Operand(0xff));
				652	END();
				653
				654	RUN();
				655
				656	ASSERT_EQUAL_64(0x000000f0, x2);
				657	ASSERT_EQUAL_64(0x00000ff0, x3);
				658	ASSERT_EQUAL_64(0x00000ff0, x4);
				659	ASSERT_EQUAL_64(0x00000070, x5);
				660	ASSERT_EQUAL_64(0x0000ff00, x6);
				661	ASSERT_EQUAL_64(0x00000f00, x7);
				662	ASSERT_EQUAL_64(0x00000ff0, x8);
				663	ASSERT_EQUAL_64(0x00000000, x9);
				664	ASSERT_EQUAL_64(0x0000ff00, x10);
				665	ASSERT_EQUAL_64(0x000000f0, x11);
				666
				667	TEARDOWN();
				668	}
				669
				670
				671	TEST(and_extend) {
				672	SETUP();
				673
				674	START();
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	675	__ Mov(x0, 0xffffffffffffffff);
				676	__ Mov(x1, 0x8000000080008081);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	677	__ And(w6, w0, Operand(w1, UXTB));
				678	__ And(x7, x0, Operand(x1, UXTH, 1));
				679	__ And(w8, w0, Operand(w1, UXTW, 2));
				680	__ And(x9, x0, Operand(x1, UXTX, 3));
				681	__ And(w10, w0, Operand(w1, SXTB));
				682	__ And(x11, x0, Operand(x1, SXTH, 1));
				683	__ And(x12, x0, Operand(x1, SXTW, 2));
				684	__ And(x13, x0, Operand(x1, SXTX, 3));
				685	END();
				686
				687	RUN();
				688
				689	ASSERT_EQUAL_64(0x00000081, x6);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	690	ASSERT_EQUAL_64(0x0000000000010102, x7);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	691	ASSERT_EQUAL_64(0x00020204, x8);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	692	ASSERT_EQUAL_64(0x0000000400040408, x9);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	693	ASSERT_EQUAL_64(0xffffff81, x10);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	694	ASSERT_EQUAL_64(0xffffffffffff0102, x11);
				695	ASSERT_EQUAL_64(0xfffffffe00020204, x12);
				696	ASSERT_EQUAL_64(0x0000000400040408, x13);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	697
				698	TEARDOWN();
				699	}
				700
				701
				702	TEST(ands) {
				703	SETUP();
				704
				705	START();
				706	__ Mov(x1, 0xf00000ff);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	707	__ Ands(w0, w1, Operand(w1));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	708	END();
				709
				710	RUN();
				711
				712	ASSERT_EQUAL_NZCV(NFlag);
				713	ASSERT_EQUAL_64(0xf00000ff, x0);
				714
				715	START();
				716	__ Mov(x0, 0xfff0);
				717	__ Mov(x1, 0xf00000ff);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	718	__ Ands(w0, w0, Operand(w1, LSR, 4));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	719	END();
				720
				721	RUN();
				722
				723	ASSERT_EQUAL_NZCV(ZFlag);
				724	ASSERT_EQUAL_64(0x00000000, x0);
				725
				726	START();
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	727	__ Mov(x0, 0x8000000000000000);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	728	__ Mov(x1, 0x00000001);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	729	__ Ands(x0, x0, Operand(x1, ROR, 1));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	730	END();
				731
				732	RUN();
				733
				734	ASSERT_EQUAL_NZCV(NFlag);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	735	ASSERT_EQUAL_64(0x8000000000000000, x0);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	736
				737	START();
				738	__ Mov(x0, 0xfff0);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	739	__ Ands(w0, w0, Operand(0xf));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	740	END();
				741
				742	RUN();
				743
				744	ASSERT_EQUAL_NZCV(ZFlag);
				745	ASSERT_EQUAL_64(0x00000000, x0);
				746
				747	START();
				748	__ Mov(x0, 0xff000000);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	749	__ Ands(w0, w0, Operand(0x80000000));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	750	END();
				751
				752	RUN();
				753
				754	ASSERT_EQUAL_NZCV(NFlag);
				755	ASSERT_EQUAL_64(0x80000000, x0);
				756
				757	TEARDOWN();
				758	}
				759
				760
				761	TEST(bic) {
				762	SETUP();
				763
				764	START();
				765	__ Mov(x0, 0xfff0);
				766	__ Mov(x1, 0xf00000ff);
				767
				768	__ Bic(x2, x0, Operand(x1));
				769	__ Bic(w3, w0, Operand(w1, LSL, 4));
				770	__ Bic(x4, x0, Operand(x1, LSL, 4));
				771	__ Bic(x5, x0, Operand(x1, LSR, 1));
				772	__ Bic(w6, w0, Operand(w1, ASR, 20));
				773	__ Bic(x7, x0, Operand(x1, ASR, 20));
				774	__ Bic(w8, w0, Operand(w1, ROR, 28));
				775	__ Bic(x9, x0, Operand(x1, ROR, 24));
				776	__ Bic(x10, x0, Operand(0x1f));
				777	__ Bic(x11, x0, Operand(0x100));
				778
				779	// Test bic into sp when the constant cannot be encoded in the immediate
				780	// field.
				781	// Use x20 to preserve sp. We check for the result via x21 because the
				782	// test infrastructure requires that sp be restored to its original value.
				783	__ Mov(x20, sp);
				784	__ Mov(x0, 0xffffff);
				785	__ Bic(sp, x0, Operand(0xabcdef));
				786	__ Mov(x21, sp);
				787	__ Mov(sp, x20);
				788	END();
				789
				790	RUN();
				791
				792	ASSERT_EQUAL_64(0x0000ff00, x2);
				793	ASSERT_EQUAL_64(0x0000f000, x3);
				794	ASSERT_EQUAL_64(0x0000f000, x4);
				795	ASSERT_EQUAL_64(0x0000ff80, x5);
				796	ASSERT_EQUAL_64(0x000000f0, x6);
				797	ASSERT_EQUAL_64(0x0000f0f0, x7);
				798	ASSERT_EQUAL_64(0x0000f000, x8);
				799	ASSERT_EQUAL_64(0x0000ff00, x9);
				800	ASSERT_EQUAL_64(0x0000ffe0, x10);
				801	ASSERT_EQUAL_64(0x0000fef0, x11);
				802
				803	ASSERT_EQUAL_64(0x543210, x21);
				804
				805	TEARDOWN();
				806	}
				807
				808
				809	TEST(bic_extend) {
				810	SETUP();
				811
				812	START();
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	813	__ Mov(x0, 0xffffffffffffffff);
				814	__ Mov(x1, 0x8000000080008081);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	815	__ Bic(w6, w0, Operand(w1, UXTB));
				816	__ Bic(x7, x0, Operand(x1, UXTH, 1));
				817	__ Bic(w8, w0, Operand(w1, UXTW, 2));
				818	__ Bic(x9, x0, Operand(x1, UXTX, 3));
				819	__ Bic(w10, w0, Operand(w1, SXTB));
				820	__ Bic(x11, x0, Operand(x1, SXTH, 1));
				821	__ Bic(x12, x0, Operand(x1, SXTW, 2));
				822	__ Bic(x13, x0, Operand(x1, SXTX, 3));
				823	END();
				824
				825	RUN();
				826
				827	ASSERT_EQUAL_64(0xffffff7e, x6);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	828	ASSERT_EQUAL_64(0xfffffffffffefefd, x7);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	829	ASSERT_EQUAL_64(0xfffdfdfb, x8);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	830	ASSERT_EQUAL_64(0xfffffffbfffbfbf7, x9);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	831	ASSERT_EQUAL_64(0x0000007e, x10);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	832	ASSERT_EQUAL_64(0x000000000000fefd, x11);
				833	ASSERT_EQUAL_64(0x00000001fffdfdfb, x12);
				834	ASSERT_EQUAL_64(0xfffffffbfffbfbf7, x13);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	835
				836	TEARDOWN();
				837	}
				838
				839
				840	TEST(bics) {
				841	SETUP();
				842
				843	START();
				844	__ Mov(x1, 0xffff);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	845	__ Bics(w0, w1, Operand(w1));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	846	END();
				847
				848	RUN();
				849
				850	ASSERT_EQUAL_NZCV(ZFlag);
				851	ASSERT_EQUAL_64(0x00000000, x0);
				852
				853	START();
				854	__ Mov(x0, 0xffffffff);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	855	__ Bics(w0, w0, Operand(w0, LSR, 1));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	856	END();
				857
				858	RUN();
				859
				860	ASSERT_EQUAL_NZCV(NFlag);
				861	ASSERT_EQUAL_64(0x80000000, x0);
				862
				863	START();
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	864	__ Mov(x0, 0x8000000000000000);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	865	__ Mov(x1, 0x00000001);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	866	__ Bics(x0, x0, Operand(x1, ROR, 1));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	867	END();
				868
				869	RUN();
				870
				871	ASSERT_EQUAL_NZCV(ZFlag);
				872	ASSERT_EQUAL_64(0x00000000, x0);
				873
				874	START();
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	875	__ Mov(x0, 0xffffffffffffffff);
				876	__ Bics(x0, x0, 0x7fffffffffffffff);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	877	END();
				878
				879	RUN();
				880
				881	ASSERT_EQUAL_NZCV(NFlag);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	882	ASSERT_EQUAL_64(0x8000000000000000, x0);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	883
				884	START();
				885	__ Mov(w0, 0xffff0000);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	886	__ Bics(w0, w0, 0xfffffff0);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	887	END();
				888
				889	RUN();
				890
				891	ASSERT_EQUAL_NZCV(ZFlag);
				892	ASSERT_EQUAL_64(0x00000000, x0);
				893
				894	TEARDOWN();
				895	}
				896
				897
				898	TEST(eor) {
				899	SETUP();
				900
				901	START();
				902	__ Mov(x0, 0xfff0);
				903	__ Mov(x1, 0xf00000ff);
				904
				905	__ Eor(x2, x0, Operand(x1));
				906	__ Eor(w3, w0, Operand(w1, LSL, 4));
				907	__ Eor(x4, x0, Operand(x1, LSL, 4));
				908	__ Eor(x5, x0, Operand(x1, LSR, 1));
				909	__ Eor(w6, w0, Operand(w1, ASR, 20));
				910	__ Eor(x7, x0, Operand(x1, ASR, 20));
				911	__ Eor(w8, w0, Operand(w1, ROR, 28));
				912	__ Eor(x9, x0, Operand(x1, ROR, 28));
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	913	__ Eor(w10, w0, 0xff00ff00);
				914	__ Eor(x11, x0, 0xff00ff00ff00ff00);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	915	END();
				916
				917	RUN();
				918
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	919	ASSERT_EQUAL_64(0x00000000f000ff0f, x2);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	920	ASSERT_EQUAL_64(0x0000f000, x3);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	921	ASSERT_EQUAL_64(0x0000000f0000f000, x4);
				922	ASSERT_EQUAL_64(0x000000007800ff8f, x5);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	923	ASSERT_EQUAL_64(0xffff00f0, x6);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	924	ASSERT_EQUAL_64(0x000000000000f0f0, x7);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	925	ASSERT_EQUAL_64(0x0000f00f, x8);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	926	ASSERT_EQUAL_64(0x00000ff00000ffff, x9);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	927	ASSERT_EQUAL_64(0xff0000f0, x10);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	928	ASSERT_EQUAL_64(0xff00ff00ff0000f0, x11);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	929
				930	TEARDOWN();
				931	}
				932
				933	TEST(eor_extend) {
				934	SETUP();
				935
				936	START();
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	937	__ Mov(x0, 0x1111111111111111);
				938	__ Mov(x1, 0x8000000080008081);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	939	__ Eor(w6, w0, Operand(w1, UXTB));
				940	__ Eor(x7, x0, Operand(x1, UXTH, 1));
				941	__ Eor(w8, w0, Operand(w1, UXTW, 2));
				942	__ Eor(x9, x0, Operand(x1, UXTX, 3));
				943	__ Eor(w10, w0, Operand(w1, SXTB));
				944	__ Eor(x11, x0, Operand(x1, SXTH, 1));
				945	__ Eor(x12, x0, Operand(x1, SXTW, 2));
				946	__ Eor(x13, x0, Operand(x1, SXTX, 3));
				947	END();
				948
				949	RUN();
				950
				951	ASSERT_EQUAL_64(0x11111190, x6);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	952	ASSERT_EQUAL_64(0x1111111111101013, x7);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	953	ASSERT_EQUAL_64(0x11131315, x8);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	954	ASSERT_EQUAL_64(0x1111111511151519, x9);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	955	ASSERT_EQUAL_64(0xeeeeee90, x10);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	956	ASSERT_EQUAL_64(0xeeeeeeeeeeee1013, x11);
				957	ASSERT_EQUAL_64(0xeeeeeeef11131315, x12);
				958	ASSERT_EQUAL_64(0x1111111511151519, x13);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	959
				960	TEARDOWN();
				961	}
				962
				963
				964	TEST(eon) {
				965	SETUP();
				966
				967	START();
				968	__ Mov(x0, 0xfff0);
				969	__ Mov(x1, 0xf00000ff);
				970
				971	__ Eon(x2, x0, Operand(x1));
				972	__ Eon(w3, w0, Operand(w1, LSL, 4));
				973	__ Eon(x4, x0, Operand(x1, LSL, 4));
				974	__ Eon(x5, x0, Operand(x1, LSR, 1));
				975	__ Eon(w6, w0, Operand(w1, ASR, 20));
				976	__ Eon(x7, x0, Operand(x1, ASR, 20));
				977	__ Eon(w8, w0, Operand(w1, ROR, 28));
				978	__ Eon(x9, x0, Operand(x1, ROR, 28));
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	979	__ Eon(w10, w0, 0x03c003c0);
				980	__ Eon(x11, x0, 0x0000100000001000);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	981	END();
				982
				983	RUN();
				984
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	985	ASSERT_EQUAL_64(0xffffffff0fff00f0, x2);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	986	ASSERT_EQUAL_64(0xffff0fff, x3);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	987	ASSERT_EQUAL_64(0xfffffff0ffff0fff, x4);
				988	ASSERT_EQUAL_64(0xffffffff87ff0070, x5);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	989	ASSERT_EQUAL_64(0x0000ff0f, x6);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	990	ASSERT_EQUAL_64(0xffffffffffff0f0f, x7);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	991	ASSERT_EQUAL_64(0xffff0ff0, x8);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	992	ASSERT_EQUAL_64(0xfffff00fffff0000, x9);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	993	ASSERT_EQUAL_64(0xfc3f03cf, x10);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	994	ASSERT_EQUAL_64(0xffffefffffff100f, x11);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	995
				996	TEARDOWN();
				997	}
				998
				999
				1000	TEST(eon_extend) {
				1001	SETUP();
				1002
				1003	START();
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1004	__ Mov(x0, 0x1111111111111111);
				1005	__ Mov(x1, 0x8000000080008081);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1006	__ Eon(w6, w0, Operand(w1, UXTB));
				1007	__ Eon(x7, x0, Operand(x1, UXTH, 1));
				1008	__ Eon(w8, w0, Operand(w1, UXTW, 2));
				1009	__ Eon(x9, x0, Operand(x1, UXTX, 3));
				1010	__ Eon(w10, w0, Operand(w1, SXTB));
				1011	__ Eon(x11, x0, Operand(x1, SXTH, 1));
				1012	__ Eon(x12, x0, Operand(x1, SXTW, 2));
				1013	__ Eon(x13, x0, Operand(x1, SXTX, 3));
				1014	END();
				1015
				1016	RUN();
				1017
				1018	ASSERT_EQUAL_64(0xeeeeee6f, x6);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1019	ASSERT_EQUAL_64(0xeeeeeeeeeeefefec, x7);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1020	ASSERT_EQUAL_64(0xeeececea, x8);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1021	ASSERT_EQUAL_64(0xeeeeeeeaeeeaeae6, x9);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1022	ASSERT_EQUAL_64(0x1111116f, x10);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1023	ASSERT_EQUAL_64(0x111111111111efec, x11);
				1024	ASSERT_EQUAL_64(0x11111110eeececea, x12);
				1025	ASSERT_EQUAL_64(0xeeeeeeeaeeeaeae6, x13);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1026
				1027	TEARDOWN();
				1028	}
				1029
				1030
				1031	TEST(mul) {
				1032	SETUP();
				1033
				1034	START();
				1035	__ Mov(x16, 0);
				1036	__ Mov(x17, 1);
				1037	__ Mov(x18, 0xffffffff);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1038	__ Mov(x19, 0xffffffffffffffff);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1039
				1040	__ Mul(w0, w16, w16);
				1041	__ Mul(w1, w16, w17);
				1042	__ Mul(w2, w17, w18);
				1043	__ Mul(w3, w18, w19);
				1044	__ Mul(x4, x16, x16);
				1045	__ Mul(x5, x17, x18);
				1046	__ Mul(x6, x18, x19);
				1047	__ Mul(x7, x19, x19);
				1048	__ Smull(x8, w17, w18);
				1049	__ Smull(x9, w18, w18);
				1050	__ Smull(x10, w19, w19);
				1051	__ Mneg(w11, w16, w16);
				1052	__ Mneg(w12, w16, w17);
				1053	__ Mneg(w13, w17, w18);
				1054	__ Mneg(w14, w18, w19);
				1055	__ Mneg(x20, x16, x16);
				1056	__ Mneg(x21, x17, x18);
				1057	__ Mneg(x22, x18, x19);
				1058	__ Mneg(x23, x19, x19);
				1059	END();
				1060
				1061	RUN();
				1062
				1063	ASSERT_EQUAL_64(0, x0);
				1064	ASSERT_EQUAL_64(0, x1);
				1065	ASSERT_EQUAL_64(0xffffffff, x2);
				1066	ASSERT_EQUAL_64(1, x3);
				1067	ASSERT_EQUAL_64(0, x4);
				1068	ASSERT_EQUAL_64(0xffffffff, x5);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1069	ASSERT_EQUAL_64(0xffffffff00000001, x6);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1070	ASSERT_EQUAL_64(1, x7);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1071	ASSERT_EQUAL_64(0xffffffffffffffff, x8);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1072	ASSERT_EQUAL_64(1, x9);
				1073	ASSERT_EQUAL_64(1, x10);
				1074	ASSERT_EQUAL_64(0, x11);
				1075	ASSERT_EQUAL_64(0, x12);
				1076	ASSERT_EQUAL_64(1, x13);
				1077	ASSERT_EQUAL_64(0xffffffff, x14);
				1078	ASSERT_EQUAL_64(0, x20);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1079	ASSERT_EQUAL_64(0xffffffff00000001, x21);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1080	ASSERT_EQUAL_64(0xffffffff, x22);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1081	ASSERT_EQUAL_64(0xffffffffffffffff, x23);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1082
				1083	TEARDOWN();
				1084	}
				1085
				1086
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	1087	static void SmullHelper(int64_t expected, int64_t a, int64_t b) {
				1088	SETUP();
				1089	START();
				1090	__ Mov(w0, a);
				1091	__ Mov(w1, b);
				1092	__ Smull(x2, w0, w1);
				1093	END();
				1094	RUN();
				1095	ASSERT_EQUAL_64(expected, x2);
				1096	TEARDOWN();
				1097	}
				1098
				1099
				1100	TEST(smull) {
				1101	SmullHelper(0, 0, 0);
				1102	SmullHelper(1, 1, 1);
				1103	SmullHelper(-1, -1, 1);
				1104	SmullHelper(1, -1, -1);
				1105	SmullHelper(0xffffffff80000000, 0x80000000, 1);
				1106	SmullHelper(0x0000000080000000, 0x00010000, 0x00008000);
				1107	}
				1108
				1109
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1110	TEST(madd) {
				1111	SETUP();
				1112
				1113	START();
				1114	__ Mov(x16, 0);
				1115	__ Mov(x17, 1);
				1116	__ Mov(x18, 0xffffffff);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1117	__ Mov(x19, 0xffffffffffffffff);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1118
				1119	__ Madd(w0, w16, w16, w16);
				1120	__ Madd(w1, w16, w16, w17);
				1121	__ Madd(w2, w16, w16, w18);
				1122	__ Madd(w3, w16, w16, w19);
				1123	__ Madd(w4, w16, w17, w17);
				1124	__ Madd(w5, w17, w17, w18);
				1125	__ Madd(w6, w17, w17, w19);
				1126	__ Madd(w7, w17, w18, w16);
				1127	__ Madd(w8, w17, w18, w18);
				1128	__ Madd(w9, w18, w18, w17);
				1129	__ Madd(w10, w18, w19, w18);
				1130	__ Madd(w11, w19, w19, w19);
				1131
				1132	__ Madd(x12, x16, x16, x16);
				1133	__ Madd(x13, x16, x16, x17);
				1134	__ Madd(x14, x16, x16, x18);
				1135	__ Madd(x15, x16, x16, x19);
				1136	__ Madd(x20, x16, x17, x17);
				1137	__ Madd(x21, x17, x17, x18);
				1138	__ Madd(x22, x17, x17, x19);
				1139	__ Madd(x23, x17, x18, x16);
				1140	__ Madd(x24, x17, x18, x18);
				1141	__ Madd(x25, x18, x18, x17);
				1142	__ Madd(x26, x18, x19, x18);
				1143	__ Madd(x27, x19, x19, x19);
				1144
				1145	END();
				1146
				1147	RUN();
				1148
				1149	ASSERT_EQUAL_64(0, x0);
				1150	ASSERT_EQUAL_64(1, x1);
				1151	ASSERT_EQUAL_64(0xffffffff, x2);
				1152	ASSERT_EQUAL_64(0xffffffff, x3);
				1153	ASSERT_EQUAL_64(1, x4);
				1154	ASSERT_EQUAL_64(0, x5);
				1155	ASSERT_EQUAL_64(0, x6);
				1156	ASSERT_EQUAL_64(0xffffffff, x7);
				1157	ASSERT_EQUAL_64(0xfffffffe, x8);
				1158	ASSERT_EQUAL_64(2, x9);
				1159	ASSERT_EQUAL_64(0, x10);
				1160	ASSERT_EQUAL_64(0, x11);
				1161
				1162	ASSERT_EQUAL_64(0, x12);
				1163	ASSERT_EQUAL_64(1, x13);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1164	ASSERT_EQUAL_64(0x00000000ffffffff, x14);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1165	ASSERT_EQUAL_64(0xffffffffffffffff, x15);
				1166	ASSERT_EQUAL_64(1, x20);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1167	ASSERT_EQUAL_64(0x0000000100000000, x21);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1168	ASSERT_EQUAL_64(0, x22);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1169	ASSERT_EQUAL_64(0x00000000ffffffff, x23);
				1170	ASSERT_EQUAL_64(0x00000001fffffffe, x24);
				1171	ASSERT_EQUAL_64(0xfffffffe00000002, x25);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1172	ASSERT_EQUAL_64(0, x26);
				1173	ASSERT_EQUAL_64(0, x27);
				1174
				1175	TEARDOWN();
				1176	}
				1177
				1178
				1179	TEST(msub) {
				1180	SETUP();
				1181
				1182	START();
				1183	__ Mov(x16, 0);
				1184	__ Mov(x17, 1);
				1185	__ Mov(x18, 0xffffffff);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1186	__ Mov(x19, 0xffffffffffffffff);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1187
				1188	__ Msub(w0, w16, w16, w16);
				1189	__ Msub(w1, w16, w16, w17);
				1190	__ Msub(w2, w16, w16, w18);
				1191	__ Msub(w3, w16, w16, w19);
				1192	__ Msub(w4, w16, w17, w17);
				1193	__ Msub(w5, w17, w17, w18);
				1194	__ Msub(w6, w17, w17, w19);
				1195	__ Msub(w7, w17, w18, w16);
				1196	__ Msub(w8, w17, w18, w18);
				1197	__ Msub(w9, w18, w18, w17);
				1198	__ Msub(w10, w18, w19, w18);
				1199	__ Msub(w11, w19, w19, w19);
				1200
				1201	__ Msub(x12, x16, x16, x16);
				1202	__ Msub(x13, x16, x16, x17);
				1203	__ Msub(x14, x16, x16, x18);
				1204	__ Msub(x15, x16, x16, x19);
				1205	__ Msub(x20, x16, x17, x17);
				1206	__ Msub(x21, x17, x17, x18);
				1207	__ Msub(x22, x17, x17, x19);
				1208	__ Msub(x23, x17, x18, x16);
				1209	__ Msub(x24, x17, x18, x18);
				1210	__ Msub(x25, x18, x18, x17);
				1211	__ Msub(x26, x18, x19, x18);
				1212	__ Msub(x27, x19, x19, x19);
				1213
				1214	END();
				1215
				1216	RUN();
				1217
				1218	ASSERT_EQUAL_64(0, x0);
				1219	ASSERT_EQUAL_64(1, x1);
				1220	ASSERT_EQUAL_64(0xffffffff, x2);
				1221	ASSERT_EQUAL_64(0xffffffff, x3);
				1222	ASSERT_EQUAL_64(1, x4);
				1223	ASSERT_EQUAL_64(0xfffffffe, x5);
				1224	ASSERT_EQUAL_64(0xfffffffe, x6);
				1225	ASSERT_EQUAL_64(1, x7);
				1226	ASSERT_EQUAL_64(0, x8);
				1227	ASSERT_EQUAL_64(0, x9);
				1228	ASSERT_EQUAL_64(0xfffffffe, x10);
				1229	ASSERT_EQUAL_64(0xfffffffe, x11);
				1230
				1231	ASSERT_EQUAL_64(0, x12);
				1232	ASSERT_EQUAL_64(1, x13);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1233	ASSERT_EQUAL_64(0x00000000ffffffff, x14);
				1234	ASSERT_EQUAL_64(0xffffffffffffffff, x15);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1235	ASSERT_EQUAL_64(1, x20);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1236	ASSERT_EQUAL_64(0x00000000fffffffe, x21);
				1237	ASSERT_EQUAL_64(0xfffffffffffffffe, x22);
				1238	ASSERT_EQUAL_64(0xffffffff00000001, x23);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1239	ASSERT_EQUAL_64(0, x24);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1240	ASSERT_EQUAL_64(0x0000000200000000, x25);
				1241	ASSERT_EQUAL_64(0x00000001fffffffe, x26);
				1242	ASSERT_EQUAL_64(0xfffffffffffffffe, x27);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1243
				1244	TEARDOWN();
				1245	}
				1246
				1247
				1248	TEST(smulh) {
				1249	SETUP();
				1250
				1251	START();
				1252	__ Mov(x20, 0);
				1253	__ Mov(x21, 1);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1254	__ Mov(x22, 0x0000000100000000);
				1255	__ Mov(x23, 0x0000000012345678);
				1256	__ Mov(x24, 0x0123456789abcdef);
				1257	__ Mov(x25, 0x0000000200000000);
				1258	__ Mov(x26, 0x8000000000000000);
				1259	__ Mov(x27, 0xffffffffffffffff);
				1260	__ Mov(x28, 0x5555555555555555);
				1261	__ Mov(x29, 0xaaaaaaaaaaaaaaaa);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1262
				1263	__ Smulh(x0, x20, x24);
				1264	__ Smulh(x1, x21, x24);
				1265	__ Smulh(x2, x22, x23);
				1266	__ Smulh(x3, x22, x24);
				1267	__ Smulh(x4, x24, x25);
				1268	__ Smulh(x5, x23, x27);
				1269	__ Smulh(x6, x26, x26);
				1270	__ Smulh(x7, x26, x27);
				1271	__ Smulh(x8, x27, x27);
				1272	__ Smulh(x9, x28, x28);
				1273	__ Smulh(x10, x28, x29);
				1274	__ Smulh(x11, x29, x29);
				1275	END();
				1276
				1277	RUN();
				1278
				1279	ASSERT_EQUAL_64(0, x0);
				1280	ASSERT_EQUAL_64(0, x1);
				1281	ASSERT_EQUAL_64(0, x2);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1282	ASSERT_EQUAL_64(0x0000000001234567, x3);
				1283	ASSERT_EQUAL_64(0x0000000002468acf, x4);
				1284	ASSERT_EQUAL_64(0xffffffffffffffff, x5);
				1285	ASSERT_EQUAL_64(0x4000000000000000, x6);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1286	ASSERT_EQUAL_64(0, x7);
				1287	ASSERT_EQUAL_64(0, x8);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1288	ASSERT_EQUAL_64(0x1c71c71c71c71c71, x9);
				1289	ASSERT_EQUAL_64(0xe38e38e38e38e38e, x10);
				1290	ASSERT_EQUAL_64(0x1c71c71c71c71c72, x11);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1291
				1292	TEARDOWN();
				1293	}
				1294
				1295
				1296	TEST(smaddl_umaddl) {
				1297	SETUP();
				1298
				1299	START();
				1300	__ Mov(x17, 1);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1301	__ Mov(x18, 0x00000000ffffffff);
				1302	__ Mov(x19, 0xffffffffffffffff);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1303	__ Mov(x20, 4);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1304	__ Mov(x21, 0x0000000200000000);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1305
				1306	__ Smaddl(x9, w17, w18, x20);
				1307	__ Smaddl(x10, w18, w18, x20);
				1308	__ Smaddl(x11, w19, w19, x20);
				1309	__ Smaddl(x12, w19, w19, x21);
				1310	__ Umaddl(x13, w17, w18, x20);
				1311	__ Umaddl(x14, w18, w18, x20);
				1312	__ Umaddl(x15, w19, w19, x20);
				1313	__ Umaddl(x22, w19, w19, x21);
				1314	END();
				1315
				1316	RUN();
				1317
				1318	ASSERT_EQUAL_64(3, x9);
				1319	ASSERT_EQUAL_64(5, x10);
				1320	ASSERT_EQUAL_64(5, x11);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1321	ASSERT_EQUAL_64(0x0000000200000001, x12);
				1322	ASSERT_EQUAL_64(0x0000000100000003, x13);
				1323	ASSERT_EQUAL_64(0xfffffffe00000005, x14);
				1324	ASSERT_EQUAL_64(0xfffffffe00000005, x15);
				1325	ASSERT_EQUAL_64(1, x22);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1326
				1327	TEARDOWN();
				1328	}
				1329
				1330
				1331	TEST(smsubl_umsubl) {
				1332	SETUP();
				1333
				1334	START();
				1335	__ Mov(x17, 1);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1336	__ Mov(x18, 0x00000000ffffffff);
				1337	__ Mov(x19, 0xffffffffffffffff);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1338	__ Mov(x20, 4);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1339	__ Mov(x21, 0x0000000200000000);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1340
				1341	__ Smsubl(x9, w17, w18, x20);
				1342	__ Smsubl(x10, w18, w18, x20);
				1343	__ Smsubl(x11, w19, w19, x20);
				1344	__ Smsubl(x12, w19, w19, x21);
				1345	__ Umsubl(x13, w17, w18, x20);
				1346	__ Umsubl(x14, w18, w18, x20);
				1347	__ Umsubl(x15, w19, w19, x20);
				1348	__ Umsubl(x22, w19, w19, x21);
				1349	END();
				1350
				1351	RUN();
				1352
				1353	ASSERT_EQUAL_64(5, x9);
				1354	ASSERT_EQUAL_64(3, x10);
				1355	ASSERT_EQUAL_64(3, x11);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1356	ASSERT_EQUAL_64(0x00000001ffffffff, x12);
				1357	ASSERT_EQUAL_64(0xffffffff00000005, x13);
				1358	ASSERT_EQUAL_64(0x0000000200000003, x14);
				1359	ASSERT_EQUAL_64(0x0000000200000003, x15);
				1360	ASSERT_EQUAL_64(0x00000003ffffffff, x22);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1361
				1362	TEARDOWN();
				1363	}
				1364
				1365
				1366	TEST(div) {
				1367	SETUP();
				1368
				1369	START();
				1370	__ Mov(x16, 1);
				1371	__ Mov(x17, 0xffffffff);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1372	__ Mov(x18, 0xffffffffffffffff);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1373	__ Mov(x19, 0x80000000);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1374	__ Mov(x20, 0x8000000000000000);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1375	__ Mov(x21, 2);
				1376
				1377	__ Udiv(w0, w16, w16);
				1378	__ Udiv(w1, w17, w16);
				1379	__ Sdiv(w2, w16, w16);
				1380	__ Sdiv(w3, w16, w17);
				1381	__ Sdiv(w4, w17, w18);
				1382
				1383	__ Udiv(x5, x16, x16);
				1384	__ Udiv(x6, x17, x18);
				1385	__ Sdiv(x7, x16, x16);
				1386	__ Sdiv(x8, x16, x17);
				1387	__ Sdiv(x9, x17, x18);
				1388
				1389	__ Udiv(w10, w19, w21);
				1390	__ Sdiv(w11, w19, w21);
				1391	__ Udiv(x12, x19, x21);
				1392	__ Sdiv(x13, x19, x21);
				1393	__ Udiv(x14, x20, x21);
				1394	__ Sdiv(x15, x20, x21);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	1395
				1396	__ Udiv(w22, w19, w17);
				1397	__ Sdiv(w23, w19, w17);
				1398	__ Udiv(x24, x20, x18);
				1399	__ Sdiv(x25, x20, x18);
				1400
				1401	__ Udiv(x26, x16, x21);
				1402	__ Sdiv(x27, x16, x21);
				1403	__ Udiv(x28, x18, x21);
				1404	__ Sdiv(x29, x18, x21);
				1405
				1406	__ Mov(x17, 0);
				1407	__ Udiv(w18, w16, w17);
				1408	__ Sdiv(w19, w16, w17);
				1409	__ Udiv(x20, x16, x17);
				1410	__ Sdiv(x21, x16, x17);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1411	END();
				1412
				1413	RUN();
				1414
				1415	ASSERT_EQUAL_64(1, x0);
				1416	ASSERT_EQUAL_64(0xffffffff, x1);
				1417	ASSERT_EQUAL_64(1, x2);
				1418	ASSERT_EQUAL_64(0xffffffff, x3);
				1419	ASSERT_EQUAL_64(1, x4);
				1420	ASSERT_EQUAL_64(1, x5);
				1421	ASSERT_EQUAL_64(0, x6);
				1422	ASSERT_EQUAL_64(1, x7);
				1423	ASSERT_EQUAL_64(0, x8);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1424	ASSERT_EQUAL_64(0xffffffff00000001, x9);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1425	ASSERT_EQUAL_64(0x40000000, x10);
				1426	ASSERT_EQUAL_64(0xC0000000, x11);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1427	ASSERT_EQUAL_64(0x0000000040000000, x12);
				1428	ASSERT_EQUAL_64(0x0000000040000000, x13);
				1429	ASSERT_EQUAL_64(0x4000000000000000, x14);
				1430	ASSERT_EQUAL_64(0xC000000000000000, x15);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	1431	ASSERT_EQUAL_64(0, x22);
				1432	ASSERT_EQUAL_64(0x80000000, x23);
				1433	ASSERT_EQUAL_64(0, x24);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1434	ASSERT_EQUAL_64(0x8000000000000000, x25);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	1435	ASSERT_EQUAL_64(0, x26);
				1436	ASSERT_EQUAL_64(0, x27);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1437	ASSERT_EQUAL_64(0x7fffffffffffffff, x28);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	1438	ASSERT_EQUAL_64(0, x29);
				1439	ASSERT_EQUAL_64(0, x18);
				1440	ASSERT_EQUAL_64(0, x19);
				1441	ASSERT_EQUAL_64(0, x20);
				1442	ASSERT_EQUAL_64(0, x21);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1443
				1444	TEARDOWN();
				1445	}
				1446
				1447
				1448	TEST(rbit_rev) {
				1449	SETUP();
				1450
				1451	START();
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1452	__ Mov(x24, 0xfedcba9876543210);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1453	__ Rbit(w0, w24);
				1454	__ Rbit(x1, x24);
				1455	__ Rev16(w2, w24);
				1456	__ Rev16(x3, x24);
				1457	__ Rev(w4, w24);
				1458	__ Rev32(x5, x24);
				1459	__ Rev(x6, x24);
				1460	END();
				1461
				1462	RUN();
				1463
				1464	ASSERT_EQUAL_64(0x084c2a6e, x0);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1465	ASSERT_EQUAL_64(0x084c2a6e195d3b7f, x1);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1466	ASSERT_EQUAL_64(0x54761032, x2);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1467	ASSERT_EQUAL_64(0xdcfe98ba54761032, x3);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1468	ASSERT_EQUAL_64(0x10325476, x4);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1469	ASSERT_EQUAL_64(0x98badcfe10325476, x5);
				1470	ASSERT_EQUAL_64(0x1032547698badcfe, x6);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1471
				1472	TEARDOWN();
				1473	}
				1474
				1475
				1476	TEST(clz_cls) {
				1477	SETUP();
				1478
				1479	START();
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1480	__ Mov(x24, 0x0008000000800000);
				1481	__ Mov(x25, 0xff800000fff80000);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1482	__ Mov(x26, 0);
				1483	__ Clz(w0, w24);
				1484	__ Clz(x1, x24);
				1485	__ Clz(w2, w25);
				1486	__ Clz(x3, x25);
				1487	__ Clz(w4, w26);
				1488	__ Clz(x5, x26);
				1489	__ Cls(w6, w24);
				1490	__ Cls(x7, x24);
				1491	__ Cls(w8, w25);
				1492	__ Cls(x9, x25);
				1493	__ Cls(w10, w26);
				1494	__ Cls(x11, x26);
				1495	END();
				1496
				1497	RUN();
				1498
				1499	ASSERT_EQUAL_64(8, x0);
				1500	ASSERT_EQUAL_64(12, x1);
				1501	ASSERT_EQUAL_64(0, x2);
				1502	ASSERT_EQUAL_64(0, x3);
				1503	ASSERT_EQUAL_64(32, x4);
				1504	ASSERT_EQUAL_64(64, x5);
				1505	ASSERT_EQUAL_64(7, x6);
				1506	ASSERT_EQUAL_64(11, x7);
				1507	ASSERT_EQUAL_64(12, x8);
				1508	ASSERT_EQUAL_64(8, x9);
				1509	ASSERT_EQUAL_64(31, x10);
				1510	ASSERT_EQUAL_64(63, x11);
				1511
				1512	TEARDOWN();
				1513	}
				1514
				1515
				1516	TEST(label) {
				1517	SETUP();
				1518
				1519	Label label_1, label_2, label_3, label_4;
				1520
				1521	START();
				1522	__ Mov(x0, 0x1);
				1523	__ Mov(x1, 0x0);
				1524	__ Mov(x22, lr); // Save lr.
				1525
				1526	__ B(&label_1);
				1527	__ B(&label_1);
				1528	__ B(&label_1); // Multiple branches to the same label.
				1529	__ Mov(x0, 0x0);
				1530	__ Bind(&label_2);
				1531	__ B(&label_3); // Forward branch.
				1532	__ Mov(x0, 0x0);
				1533	__ Bind(&label_1);
				1534	__ B(&label_2); // Backward branch.
				1535	__ Mov(x0, 0x0);
				1536	__ Bind(&label_3);
				1537	__ Bl(&label_4);
				1538	END();
				1539
				1540	__ Bind(&label_4);
				1541	__ Mov(x1, 0x1);
				1542	__ Mov(lr, x22);
				1543	END();
				1544
				1545	RUN();
				1546
				1547	ASSERT_EQUAL_64(0x1, x0);
				1548	ASSERT_EQUAL_64(0x1, x1);
				1549
				1550	TEARDOWN();
				1551	}
				1552
				1553
				1554	TEST(adr) {
				1555	SETUP();
				1556
				1557	Label label_1, label_2, label_3, label_4;
				1558
				1559	START();
				1560	__ Mov(x0, 0x0); // Set to non-zero to indicate failure.
				1561	__ Adr(x1, &label_3); // Set to zero to indicate success.
				1562
				1563	__ Adr(x2, &label_1); // Multiple forward references to the same label.
				1564	__ Adr(x3, &label_1);
				1565	__ Adr(x4, &label_1);
				1566
				1567	__ Bind(&label_2);
				1568	__ Eor(x5, x2, Operand(x3)); // Ensure that x2,x3 and x4 are identical.
				1569	__ Eor(x6, x2, Operand(x4));
				1570	__ Orr(x0, x0, Operand(x5));
				1571	__ Orr(x0, x0, Operand(x6));
				1572	__ Br(x2); // label_1, label_3
				1573
				1574	__ Bind(&label_3);
				1575	__ Adr(x2, &label_3); // Self-reference (offset 0).
				1576	__ Eor(x1, x1, Operand(x2));
				1577	__ Adr(x2, &label_4); // Simple forward reference.
				1578	__ Br(x2); // label_4
				1579
				1580	__ Bind(&label_1);
				1581	__ Adr(x2, &label_3); // Multiple reverse references to the same label.
				1582	__ Adr(x3, &label_3);
				1583	__ Adr(x4, &label_3);
				1584	__ Adr(x5, &label_2); // Simple reverse reference.
				1585	__ Br(x5); // label_2
				1586
				1587	__ Bind(&label_4);
				1588	END();
				1589
				1590	RUN();
				1591
				1592	ASSERT_EQUAL_64(0x0, x0);
				1593	ASSERT_EQUAL_64(0x0, x1);
				1594
				1595	TEARDOWN();
				1596	}
				1597
				1598
				1599	TEST(branch_cond) {
				1600	SETUP();
				1601
				1602	Label wrong;
				1603
				1604	START();
				1605	__ Mov(x0, 0x1);
				1606	__ Mov(x1, 0x1);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1607	__ Mov(x2, 0x8000000000000000);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1608
				1609	// For each 'cmp' instruction below, condition codes other than the ones
				1610	// following it would branch.
				1611
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	1612	__ Cmp(x1, 0);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1613	__ B(&wrong, eq);
				1614	__ B(&wrong, lo);
				1615	__ B(&wrong, mi);
				1616	__ B(&wrong, vs);
				1617	__ B(&wrong, ls);
				1618	__ B(&wrong, lt);
				1619	__ B(&wrong, le);
				1620	Label ok_1;
				1621	__ B(&ok_1, ne);
				1622	__ Mov(x0, 0x0);
				1623	__ Bind(&ok_1);
				1624
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	1625	__ Cmp(x1, 1);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1626	__ B(&wrong, ne);
				1627	__ B(&wrong, lo);
				1628	__ B(&wrong, mi);
				1629	__ B(&wrong, vs);
				1630	__ B(&wrong, hi);
				1631	__ B(&wrong, lt);
				1632	__ B(&wrong, gt);
				1633	Label ok_2;
				1634	__ B(&ok_2, pl);
				1635	__ Mov(x0, 0x0);
				1636	__ Bind(&ok_2);
				1637
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	1638	__ Cmp(x1, 2);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1639	__ B(&wrong, eq);
				1640	__ B(&wrong, hs);
				1641	__ B(&wrong, pl);
				1642	__ B(&wrong, vs);
				1643	__ B(&wrong, hi);
				1644	__ B(&wrong, ge);
				1645	__ B(&wrong, gt);
				1646	Label ok_3;
				1647	__ B(&ok_3, vc);
				1648	__ Mov(x0, 0x0);
				1649	__ Bind(&ok_3);
				1650
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	1651	__ Cmp(x2, 1);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1652	__ B(&wrong, eq);
				1653	__ B(&wrong, lo);
				1654	__ B(&wrong, mi);
				1655	__ B(&wrong, vc);
				1656	__ B(&wrong, ls);
				1657	__ B(&wrong, ge);
				1658	__ B(&wrong, gt);
				1659	Label ok_4;
				1660	__ B(&ok_4, le);
				1661	__ Mov(x0, 0x0);
				1662	__ Bind(&ok_4);
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	1663
				1664	Label ok_5;
				1665	__ b(&ok_5, al);
				1666	__ Mov(x0, 0x0);
				1667	__ Bind(&ok_5);
				1668
				1669	Label ok_6;
				1670	__ b(&ok_6, nv);
				1671	__ Mov(x0, 0x0);
				1672	__ Bind(&ok_6);
				1673
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1674	END();
				1675
				1676	__ Bind(&wrong);
				1677	__ Mov(x0, 0x0);
				1678	END();
				1679
				1680	RUN();
				1681
				1682	ASSERT_EQUAL_64(0x1, x0);
				1683
				1684	TEARDOWN();
				1685	}
				1686
				1687
				1688	TEST(branch_to_reg) {
				1689	SETUP();
				1690
				1691	// Test br.
				1692	Label fn1, after_fn1;
				1693
				1694	START();
				1695	__ Mov(x29, lr);
				1696
				1697	__ Mov(x1, 0);
				1698	__ B(&after_fn1);
				1699
				1700	__ Bind(&fn1);
				1701	__ Mov(x0, lr);
				1702	__ Mov(x1, 42);
				1703	__ Br(x0);
				1704
				1705	__ Bind(&after_fn1);
				1706	__ Bl(&fn1);
				1707
				1708	// Test blr.
				1709	Label fn2, after_fn2;
				1710
				1711	__ Mov(x2, 0);
				1712	__ B(&after_fn2);
				1713
				1714	__ Bind(&fn2);
				1715	__ Mov(x0, lr);
				1716	__ Mov(x2, 84);
				1717	__ Blr(x0);
				1718
				1719	__ Bind(&after_fn2);
				1720	__ Bl(&fn2);
				1721	__ Mov(x3, lr);
				1722
				1723	__ Mov(lr, x29);
				1724	END();
				1725
				1726	RUN();
				1727
				1728	ASSERT_EQUAL_64(core.xreg(3) + kInstructionSize, x0);
				1729	ASSERT_EQUAL_64(42, x1);
				1730	ASSERT_EQUAL_64(84, x2);
				1731
				1732	TEARDOWN();
				1733	}
				1734
				1735
				1736	TEST(compare_branch) {
				1737	SETUP();
				1738
				1739	START();
				1740	__ Mov(x0, 0);
				1741	__ Mov(x1, 0);
				1742	__ Mov(x2, 0);
				1743	__ Mov(x3, 0);
				1744	__ Mov(x4, 0);
				1745	__ Mov(x5, 0);
				1746	__ Mov(x16, 0);
				1747	__ Mov(x17, 42);
				1748
				1749	Label zt, zt_end;
				1750	__ Cbz(w16, &zt);
				1751	__ B(&zt_end);
				1752	__ Bind(&zt);
				1753	__ Mov(x0, 1);
				1754	__ Bind(&zt_end);
				1755
				1756	Label zf, zf_end;
				1757	__ Cbz(x17, &zf);
				1758	__ B(&zf_end);
				1759	__ Bind(&zf);
				1760	__ Mov(x1, 1);
				1761	__ Bind(&zf_end);
				1762
				1763	Label nzt, nzt_end;
				1764	__ Cbnz(w17, &nzt);
				1765	__ B(&nzt_end);
				1766	__ Bind(&nzt);
				1767	__ Mov(x2, 1);
				1768	__ Bind(&nzt_end);
				1769
				1770	Label nzf, nzf_end;
				1771	__ Cbnz(x16, &nzf);
				1772	__ B(&nzf_end);
				1773	__ Bind(&nzf);
				1774	__ Mov(x3, 1);
				1775	__ Bind(&nzf_end);
				1776
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1777	__ Mov(x18, 0xffffffff00000000);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1778
				1779	Label a, a_end;
				1780	__ Cbz(w18, &a);
				1781	__ B(&a_end);
				1782	__ Bind(&a);
				1783	__ Mov(x4, 1);
				1784	__ Bind(&a_end);
				1785
				1786	Label b, b_end;
				1787	__ Cbnz(w18, &b);
				1788	__ B(&b_end);
				1789	__ Bind(&b);
				1790	__ Mov(x5, 1);
				1791	__ Bind(&b_end);
				1792
				1793	END();
				1794
				1795	RUN();
				1796
				1797	ASSERT_EQUAL_64(1, x0);
				1798	ASSERT_EQUAL_64(0, x1);
				1799	ASSERT_EQUAL_64(1, x2);
				1800	ASSERT_EQUAL_64(0, x3);
				1801	ASSERT_EQUAL_64(1, x4);
				1802	ASSERT_EQUAL_64(0, x5);
				1803
				1804	TEARDOWN();
				1805	}
				1806
				1807
				1808	TEST(test_branch) {
				1809	SETUP();
				1810
				1811	START();
				1812	__ Mov(x0, 0);
				1813	__ Mov(x1, 0);
				1814	__ Mov(x2, 0);
				1815	__ Mov(x3, 0);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1816	__ Mov(x16, 0xaaaaaaaaaaaaaaaa);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1817
				1818	Label bz, bz_end;
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	1819	__ Tbz(w16, 0, &bz);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1820	__ B(&bz_end);
				1821	__ Bind(&bz);
				1822	__ Mov(x0, 1);
				1823	__ Bind(&bz_end);
				1824
				1825	Label bo, bo_end;
				1826	__ Tbz(x16, 63, &bo);
				1827	__ B(&bo_end);
				1828	__ Bind(&bo);
				1829	__ Mov(x1, 1);
				1830	__ Bind(&bo_end);
				1831
				1832	Label nbz, nbz_end;
				1833	__ Tbnz(x16, 61, &nbz);
				1834	__ B(&nbz_end);
				1835	__ Bind(&nbz);
				1836	__ Mov(x2, 1);
				1837	__ Bind(&nbz_end);
				1838
				1839	Label nbo, nbo_end;
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	1840	__ Tbnz(w16, 2, &nbo);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1841	__ B(&nbo_end);
				1842	__ Bind(&nbo);
				1843	__ Mov(x3, 1);
				1844	__ Bind(&nbo_end);
				1845	END();
				1846
				1847	RUN();
				1848
				1849	ASSERT_EQUAL_64(1, x0);
				1850	ASSERT_EQUAL_64(0, x1);
				1851	ASSERT_EQUAL_64(1, x2);
				1852	ASSERT_EQUAL_64(0, x3);
				1853
				1854	TEARDOWN();
				1855	}
				1856
				1857
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1858	TEST(branch_type) {
				1859	SETUP();
				1860
				1861	Label fail, done;
				1862
				1863	START();
				1864	__ Mov(x0, 0x0);
				1865	__ Mov(x10, 0x7);
				1866	__ Mov(x11, 0x0);
				1867
				1868	// Test non taken branches.
				1869	__ Cmp(x10, 0x7);
				1870	__ B(&fail, ne);
				1871	__ B(&fail, never);
				1872	__ B(&fail, reg_zero, x10);
				1873	__ B(&fail, reg_not_zero, x11);
				1874	__ B(&fail, reg_bit_clear, x10, 0);
				1875	__ B(&fail, reg_bit_set, x10, 3);
				1876
				1877	// Test taken branches.
				1878	Label l1, l2, l3, l4, l5;
				1879	__ Cmp(x10, 0x7);
				1880	__ B(&l1, eq);
				1881	__ B(&fail);
				1882	__ Bind(&l1);
				1883	__ B(&l2, always);
				1884	__ B(&fail);
				1885	__ Bind(&l2);
				1886	__ B(&l3, reg_not_zero, x10);
				1887	__ B(&fail);
				1888	__ Bind(&l3);
				1889	__ B(&l4, reg_bit_clear, x10, 15);
				1890	__ B(&fail);
				1891	__ Bind(&l4);
				1892	__ B(&l5, reg_bit_set, x10, 1);
				1893	__ B(&fail);
				1894	__ Bind(&l5);
				1895
				1896	__ B(&done);
				1897
				1898	__ Bind(&fail);
				1899	__ Mov(x0, 0x1);
				1900
				1901	__ Bind(&done);
				1902
				1903	END();
				1904
				1905	RUN();
				1906
				1907	ASSERT_EQUAL_64(0x0, x0);
				1908
				1909	TEARDOWN();
				1910	}
				1911
				1912
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1913	TEST(ldr_str_offset) {
				1914	SETUP();
				1915
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1916	uint64_t src[2] = {0xfedcba9876543210, 0x0123456789abcdef};
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1917	uint64_t dst[5] = {0, 0, 0, 0, 0};
				1918	uintptr_t src_base = reinterpret_cast<uintptr_t>(src);
				1919	uintptr_t dst_base = reinterpret_cast<uintptr_t>(dst);
				1920
				1921	START();
				1922	__ Mov(x17, src_base);
				1923	__ Mov(x18, dst_base);
				1924	__ Ldr(w0, MemOperand(x17));
				1925	__ Str(w0, MemOperand(x18));
				1926	__ Ldr(w1, MemOperand(x17, 4));
				1927	__ Str(w1, MemOperand(x18, 12));
				1928	__ Ldr(x2, MemOperand(x17, 8));
				1929	__ Str(x2, MemOperand(x18, 16));
				1930	__ Ldrb(w3, MemOperand(x17, 1));
				1931	__ Strb(w3, MemOperand(x18, 25));
				1932	__ Ldrh(w4, MemOperand(x17, 2));
				1933	__ Strh(w4, MemOperand(x18, 33));
				1934	END();
				1935
				1936	RUN();
				1937
				1938	ASSERT_EQUAL_64(0x76543210, x0);
				1939	ASSERT_EQUAL_64(0x76543210, dst[0]);
				1940	ASSERT_EQUAL_64(0xfedcba98, x1);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	1941	ASSERT_EQUAL_64(0xfedcba9800000000, dst[1]);
				1942	ASSERT_EQUAL_64(0x0123456789abcdef, x2);
				1943	ASSERT_EQUAL_64(0x0123456789abcdef, dst[2]);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	1944	ASSERT_EQUAL_64(0x32, x3);
				1945	ASSERT_EQUAL_64(0x3200, dst[3]);
				1946	ASSERT_EQUAL_64(0x7654, x4);
				1947	ASSERT_EQUAL_64(0x765400, dst[4]);
				1948	ASSERT_EQUAL_64(src_base, x17);
				1949	ASSERT_EQUAL_64(dst_base, x18);
				1950
				1951	TEARDOWN();
				1952	}
				1953
				1954
				1955	TEST(ldr_str_wide) {
				1956	SETUP();
				1957
				1958	uint32_t src[8192];
				1959	uint32_t dst[8192];
				1960	uintptr_t src_base = reinterpret_cast<uintptr_t>(src);
				1961	uintptr_t dst_base = reinterpret_cast<uintptr_t>(dst);
				1962	memset(src, 0xaa, 8192 * sizeof(src[0]));
				1963	memset(dst, 0xaa, 8192 * sizeof(dst[0]));
				1964	src[0] = 0;
				1965	src[6144] = 6144;
				1966	src[8191] = 8191;
				1967
				1968	START();
				1969	__ Mov(x22, src_base);
				1970	__ Mov(x23, dst_base);
				1971	__ Mov(x24, src_base);
				1972	__ Mov(x25, dst_base);
				1973	__ Mov(x26, src_base);
				1974	__ Mov(x27, dst_base);
				1975
				1976	__ Ldr(w0, MemOperand(x22, 8191 * sizeof(src[0])));
				1977	__ Str(w0, MemOperand(x23, 8191 * sizeof(dst[0])));
				1978	__ Ldr(w1, MemOperand(x24, 4096 * sizeof(src[0]), PostIndex));
				1979	__ Str(w1, MemOperand(x25, 4096 * sizeof(dst[0]), PostIndex));
				1980	__ Ldr(w2, MemOperand(x26, 6144 * sizeof(src[0]), PreIndex));
				1981	__ Str(w2, MemOperand(x27, 6144 * sizeof(dst[0]), PreIndex));
				1982	END();
				1983
				1984	RUN();
				1985
				1986	ASSERT_EQUAL_32(8191, w0);
				1987	ASSERT_EQUAL_32(8191, dst[8191]);
				1988	ASSERT_EQUAL_64(src_base, x22);
				1989	ASSERT_EQUAL_64(dst_base, x23);
				1990	ASSERT_EQUAL_32(0, w1);
				1991	ASSERT_EQUAL_32(0, dst[0]);
				1992	ASSERT_EQUAL_64(src_base + 4096 * sizeof(src[0]), x24);
				1993	ASSERT_EQUAL_64(dst_base + 4096 * sizeof(dst[0]), x25);
				1994	ASSERT_EQUAL_32(6144, w2);
				1995	ASSERT_EQUAL_32(6144, dst[6144]);
				1996	ASSERT_EQUAL_64(src_base + 6144 * sizeof(src[0]), x26);
				1997	ASSERT_EQUAL_64(dst_base + 6144 * sizeof(dst[0]), x27);
				1998
				1999	TEARDOWN();
				2000	}
				2001
				2002
				2003	TEST(ldr_str_preindex) {
				2004	SETUP();
				2005
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2006	uint64_t src[2] = {0xfedcba9876543210, 0x0123456789abcdef};
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2007	uint64_t dst[6] = {0, 0, 0, 0, 0, 0};
				2008	uintptr_t src_base = reinterpret_cast<uintptr_t>(src);
				2009	uintptr_t dst_base = reinterpret_cast<uintptr_t>(dst);
				2010
				2011	START();
				2012	__ Mov(x17, src_base);
				2013	__ Mov(x18, dst_base);
				2014	__ Mov(x19, src_base);
				2015	__ Mov(x20, dst_base);
				2016	__ Mov(x21, src_base + 16);
				2017	__ Mov(x22, dst_base + 40);
				2018	__ Mov(x23, src_base);
				2019	__ Mov(x24, dst_base);
				2020	__ Mov(x25, src_base);
				2021	__ Mov(x26, dst_base);
				2022	__ Ldr(w0, MemOperand(x17, 4, PreIndex));
				2023	__ Str(w0, MemOperand(x18, 12, PreIndex));
				2024	__ Ldr(x1, MemOperand(x19, 8, PreIndex));
				2025	__ Str(x1, MemOperand(x20, 16, PreIndex));
				2026	__ Ldr(w2, MemOperand(x21, -4, PreIndex));
				2027	__ Str(w2, MemOperand(x22, -4, PreIndex));
				2028	__ Ldrb(w3, MemOperand(x23, 1, PreIndex));
				2029	__ Strb(w3, MemOperand(x24, 25, PreIndex));
				2030	__ Ldrh(w4, MemOperand(x25, 3, PreIndex));
				2031	__ Strh(w4, MemOperand(x26, 41, PreIndex));
				2032	END();
				2033
				2034	RUN();
				2035
				2036	ASSERT_EQUAL_64(0xfedcba98, x0);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2037	ASSERT_EQUAL_64(0xfedcba9800000000, dst[1]);
				2038	ASSERT_EQUAL_64(0x0123456789abcdef, x1);
				2039	ASSERT_EQUAL_64(0x0123456789abcdef, dst[2]);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2040	ASSERT_EQUAL_64(0x01234567, x2);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2041	ASSERT_EQUAL_64(0x0123456700000000, dst[4]);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2042	ASSERT_EQUAL_64(0x32, x3);
				2043	ASSERT_EQUAL_64(0x3200, dst[3]);
				2044	ASSERT_EQUAL_64(0x9876, x4);
				2045	ASSERT_EQUAL_64(0x987600, dst[5]);
				2046	ASSERT_EQUAL_64(src_base + 4, x17);
				2047	ASSERT_EQUAL_64(dst_base + 12, x18);
				2048	ASSERT_EQUAL_64(src_base + 8, x19);
				2049	ASSERT_EQUAL_64(dst_base + 16, x20);
				2050	ASSERT_EQUAL_64(src_base + 12, x21);
				2051	ASSERT_EQUAL_64(dst_base + 36, x22);
				2052	ASSERT_EQUAL_64(src_base + 1, x23);
				2053	ASSERT_EQUAL_64(dst_base + 25, x24);
				2054	ASSERT_EQUAL_64(src_base + 3, x25);
				2055	ASSERT_EQUAL_64(dst_base + 41, x26);
				2056
				2057	TEARDOWN();
				2058	}
				2059
				2060
				2061	TEST(ldr_str_postindex) {
				2062	SETUP();
				2063
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2064	uint64_t src[2] = {0xfedcba9876543210, 0x0123456789abcdef};
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2065	uint64_t dst[6] = {0, 0, 0, 0, 0, 0};
				2066	uintptr_t src_base = reinterpret_cast<uintptr_t>(src);
				2067	uintptr_t dst_base = reinterpret_cast<uintptr_t>(dst);
				2068
				2069	START();
				2070	__ Mov(x17, src_base + 4);
				2071	__ Mov(x18, dst_base + 12);
				2072	__ Mov(x19, src_base + 8);
				2073	__ Mov(x20, dst_base + 16);
				2074	__ Mov(x21, src_base + 8);
				2075	__ Mov(x22, dst_base + 32);
				2076	__ Mov(x23, src_base + 1);
				2077	__ Mov(x24, dst_base + 25);
				2078	__ Mov(x25, src_base + 3);
				2079	__ Mov(x26, dst_base + 41);
				2080	__ Ldr(w0, MemOperand(x17, 4, PostIndex));
				2081	__ Str(w0, MemOperand(x18, 12, PostIndex));
				2082	__ Ldr(x1, MemOperand(x19, 8, PostIndex));
				2083	__ Str(x1, MemOperand(x20, 16, PostIndex));
				2084	__ Ldr(x2, MemOperand(x21, -8, PostIndex));
				2085	__ Str(x2, MemOperand(x22, -32, PostIndex));
				2086	__ Ldrb(w3, MemOperand(x23, 1, PostIndex));
				2087	__ Strb(w3, MemOperand(x24, 5, PostIndex));
				2088	__ Ldrh(w4, MemOperand(x25, -3, PostIndex));
				2089	__ Strh(w4, MemOperand(x26, -41, PostIndex));
				2090	END();
				2091
				2092	RUN();
				2093
				2094	ASSERT_EQUAL_64(0xfedcba98, x0);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2095	ASSERT_EQUAL_64(0xfedcba9800000000, dst[1]);
				2096	ASSERT_EQUAL_64(0x0123456789abcdef, x1);
				2097	ASSERT_EQUAL_64(0x0123456789abcdef, dst[2]);
				2098	ASSERT_EQUAL_64(0x0123456789abcdef, x2);
				2099	ASSERT_EQUAL_64(0x0123456789abcdef, dst[4]);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2100	ASSERT_EQUAL_64(0x32, x3);
				2101	ASSERT_EQUAL_64(0x3200, dst[3]);
				2102	ASSERT_EQUAL_64(0x9876, x4);
				2103	ASSERT_EQUAL_64(0x987600, dst[5]);
				2104	ASSERT_EQUAL_64(src_base + 8, x17);
				2105	ASSERT_EQUAL_64(dst_base + 24, x18);
				2106	ASSERT_EQUAL_64(src_base + 16, x19);
				2107	ASSERT_EQUAL_64(dst_base + 32, x20);
				2108	ASSERT_EQUAL_64(src_base, x21);
				2109	ASSERT_EQUAL_64(dst_base, x22);
				2110	ASSERT_EQUAL_64(src_base + 2, x23);
				2111	ASSERT_EQUAL_64(dst_base + 30, x24);
				2112	ASSERT_EQUAL_64(src_base, x25);
				2113	ASSERT_EQUAL_64(dst_base, x26);
				2114
				2115	TEARDOWN();
				2116	}
				2117
				2118
				2119	TEST(ldr_str_largeindex) {
				2120	SETUP();
				2121
				2122	// This value won't fit in the immediate offset field of ldr/str instructions.
				2123	int largeoffset = 0xabcdef;
				2124
				2125	int64_t data[3] = { 0x1122334455667788, 0, 0 };
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2126	uint64_t base_addr = reinterpret_cast<uintptr_t>(data);
				2127	uint64_t drifted_addr = base_addr - largeoffset;
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2128
				2129	// This test checks that we we can use large immediate offsets when
				2130	// using PreIndex or PostIndex addressing mode of the MacroAssembler
				2131	// Ldr/Str instructions.
				2132
				2133	START();
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2134	__ Mov(x19, drifted_addr);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2135	__ Ldr(x0, MemOperand(x19, largeoffset, PreIndex));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2136
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2137	__ Mov(x20, base_addr);
				2138	__ Ldr(x1, MemOperand(x20, largeoffset, PostIndex));
				2139
				2140	__ Mov(x21, drifted_addr);
				2141	__ Str(x0, MemOperand(x21, largeoffset + 8, PreIndex));
				2142
				2143	__ Mov(x22, base_addr + 16);
				2144	__ Str(x0, MemOperand(x22, largeoffset, PostIndex));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2145	END();
				2146
				2147	RUN();
				2148
				2149	ASSERT_EQUAL_64(0x1122334455667788, data[0]);
				2150	ASSERT_EQUAL_64(0x1122334455667788, data[1]);
				2151	ASSERT_EQUAL_64(0x1122334455667788, data[2]);
				2152	ASSERT_EQUAL_64(0x1122334455667788, x0);
				2153	ASSERT_EQUAL_64(0x1122334455667788, x1);
				2154
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2155	ASSERT_EQUAL_64(base_addr, x19);
				2156	ASSERT_EQUAL_64(base_addr + largeoffset, x20);
				2157	ASSERT_EQUAL_64(base_addr + 8, x21);
				2158	ASSERT_EQUAL_64(base_addr + 16 + largeoffset, x22);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2159
				2160	TEARDOWN();
				2161	}
				2162
				2163
				2164	TEST(load_signed) {
				2165	SETUP();
				2166
				2167	uint32_t src[2] = {0x80008080, 0x7fff7f7f};
				2168	uintptr_t src_base = reinterpret_cast<uintptr_t>(src);
				2169
				2170	START();
				2171	__ Mov(x24, src_base);
				2172	__ Ldrsb(w0, MemOperand(x24));
				2173	__ Ldrsb(w1, MemOperand(x24, 4));
				2174	__ Ldrsh(w2, MemOperand(x24));
				2175	__ Ldrsh(w3, MemOperand(x24, 4));
				2176	__ Ldrsb(x4, MemOperand(x24));
				2177	__ Ldrsb(x5, MemOperand(x24, 4));
				2178	__ Ldrsh(x6, MemOperand(x24));
				2179	__ Ldrsh(x7, MemOperand(x24, 4));
				2180	__ Ldrsw(x8, MemOperand(x24));
				2181	__ Ldrsw(x9, MemOperand(x24, 4));
				2182	END();
				2183
				2184	RUN();
				2185
				2186	ASSERT_EQUAL_64(0xffffff80, x0);
				2187	ASSERT_EQUAL_64(0x0000007f, x1);
				2188	ASSERT_EQUAL_64(0xffff8080, x2);
				2189	ASSERT_EQUAL_64(0x00007f7f, x3);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2190	ASSERT_EQUAL_64(0xffffffffffffff80, x4);
				2191	ASSERT_EQUAL_64(0x000000000000007f, x5);
				2192	ASSERT_EQUAL_64(0xffffffffffff8080, x6);
				2193	ASSERT_EQUAL_64(0x0000000000007f7f, x7);
				2194	ASSERT_EQUAL_64(0xffffffff80008080, x8);
				2195	ASSERT_EQUAL_64(0x000000007fff7f7f, x9);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2196
				2197	TEARDOWN();
				2198	}
				2199
				2200
				2201	TEST(load_store_regoffset) {
				2202	SETUP();
				2203
				2204	uint32_t src[3] = {1, 2, 3};
				2205	uint32_t dst[4] = {0, 0, 0, 0};
				2206	uintptr_t src_base = reinterpret_cast<uintptr_t>(src);
				2207	uintptr_t dst_base = reinterpret_cast<uintptr_t>(dst);
				2208
				2209	START();
				2210	__ Mov(x16, src_base);
				2211	__ Mov(x17, dst_base);
				2212	__ Mov(x18, src_base + 3 * sizeof(src[0]));
				2213	__ Mov(x19, dst_base + 3 * sizeof(dst[0]));
				2214	__ Mov(x20, dst_base + 4 * sizeof(dst[0]));
				2215	__ Mov(x24, 0);
				2216	__ Mov(x25, 4);
				2217	__ Mov(x26, -4);
				2218	__ Mov(x27, 0xfffffffc); // 32-bit -4.
				2219	__ Mov(x28, 0xfffffffe); // 32-bit -2.
				2220	__ Mov(x29, 0xffffffff); // 32-bit -1.
				2221
				2222	__ Ldr(w0, MemOperand(x16, x24));
				2223	__ Ldr(x1, MemOperand(x16, x25));
				2224	__ Ldr(w2, MemOperand(x18, x26));
				2225	__ Ldr(w3, MemOperand(x18, x27, SXTW));
				2226	__ Ldr(w4, MemOperand(x18, x28, SXTW, 2));
				2227	__ Str(w0, MemOperand(x17, x24));
				2228	__ Str(x1, MemOperand(x17, x25));
				2229	__ Str(w2, MemOperand(x20, x29, SXTW, 2));
				2230	END();
				2231
				2232	RUN();
				2233
				2234	ASSERT_EQUAL_64(1, x0);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2235	ASSERT_EQUAL_64(0x0000000300000002, x1);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2236	ASSERT_EQUAL_64(3, x2);
				2237	ASSERT_EQUAL_64(3, x3);
				2238	ASSERT_EQUAL_64(2, x4);
				2239	ASSERT_EQUAL_32(1, dst[0]);
				2240	ASSERT_EQUAL_32(2, dst[1]);
				2241	ASSERT_EQUAL_32(3, dst[2]);
				2242	ASSERT_EQUAL_32(3, dst[3]);
				2243
				2244	TEARDOWN();
				2245	}
				2246
				2247
				2248	TEST(load_store_float) {
				2249	SETUP();
				2250
				2251	float src[3] = {1.0, 2.0, 3.0};
				2252	float dst[3] = {0.0, 0.0, 0.0};
				2253	uintptr_t src_base = reinterpret_cast<uintptr_t>(src);
				2254	uintptr_t dst_base = reinterpret_cast<uintptr_t>(dst);
				2255
				2256	START();
				2257	__ Mov(x17, src_base);
				2258	__ Mov(x18, dst_base);
				2259	__ Mov(x19, src_base);
				2260	__ Mov(x20, dst_base);
				2261	__ Mov(x21, src_base);
				2262	__ Mov(x22, dst_base);
				2263	__ Ldr(s0, MemOperand(x17, sizeof(src[0])));
				2264	__ Str(s0, MemOperand(x18, sizeof(dst[0]), PostIndex));
				2265	__ Ldr(s1, MemOperand(x19, sizeof(src[0]), PostIndex));
				2266	__ Str(s1, MemOperand(x20, 2 * sizeof(dst[0]), PreIndex));
				2267	__ Ldr(s2, MemOperand(x21, 2 * sizeof(src[0]), PreIndex));
				2268	__ Str(s2, MemOperand(x22, sizeof(dst[0])));
				2269	END();
				2270
				2271	RUN();
				2272
				2273	ASSERT_EQUAL_FP32(2.0, s0);
				2274	ASSERT_EQUAL_FP32(2.0, dst[0]);
				2275	ASSERT_EQUAL_FP32(1.0, s1);
				2276	ASSERT_EQUAL_FP32(1.0, dst[2]);
				2277	ASSERT_EQUAL_FP32(3.0, s2);
				2278	ASSERT_EQUAL_FP32(3.0, dst[1]);
				2279	ASSERT_EQUAL_64(src_base, x17);
				2280	ASSERT_EQUAL_64(dst_base + sizeof(dst[0]), x18);
				2281	ASSERT_EQUAL_64(src_base + sizeof(src[0]), x19);
				2282	ASSERT_EQUAL_64(dst_base + 2 * sizeof(dst[0]), x20);
				2283	ASSERT_EQUAL_64(src_base + 2 * sizeof(src[0]), x21);
				2284	ASSERT_EQUAL_64(dst_base, x22);
				2285
				2286	TEARDOWN();
				2287	}
				2288
				2289
				2290	TEST(load_store_double) {
				2291	SETUP();
				2292
				2293	double src[3] = {1.0, 2.0, 3.0};
				2294	double dst[3] = {0.0, 0.0, 0.0};
				2295	uintptr_t src_base = reinterpret_cast<uintptr_t>(src);
				2296	uintptr_t dst_base = reinterpret_cast<uintptr_t>(dst);
				2297
				2298	START();
				2299	__ Mov(x17, src_base);
				2300	__ Mov(x18, dst_base);
				2301	__ Mov(x19, src_base);
				2302	__ Mov(x20, dst_base);
				2303	__ Mov(x21, src_base);
				2304	__ Mov(x22, dst_base);
				2305	__ Ldr(d0, MemOperand(x17, sizeof(src[0])));
				2306	__ Str(d0, MemOperand(x18, sizeof(dst[0]), PostIndex));
				2307	__ Ldr(d1, MemOperand(x19, sizeof(src[0]), PostIndex));
				2308	__ Str(d1, MemOperand(x20, 2 * sizeof(dst[0]), PreIndex));
				2309	__ Ldr(d2, MemOperand(x21, 2 * sizeof(src[0]), PreIndex));
				2310	__ Str(d2, MemOperand(x22, sizeof(dst[0])));
				2311	END();
				2312
				2313	RUN();
				2314
				2315	ASSERT_EQUAL_FP64(2.0, d0);
				2316	ASSERT_EQUAL_FP64(2.0, dst[0]);
				2317	ASSERT_EQUAL_FP64(1.0, d1);
				2318	ASSERT_EQUAL_FP64(1.0, dst[2]);
				2319	ASSERT_EQUAL_FP64(3.0, d2);
				2320	ASSERT_EQUAL_FP64(3.0, dst[1]);
				2321	ASSERT_EQUAL_64(src_base, x17);
				2322	ASSERT_EQUAL_64(dst_base + sizeof(dst[0]), x18);
				2323	ASSERT_EQUAL_64(src_base + sizeof(src[0]), x19);
				2324	ASSERT_EQUAL_64(dst_base + 2 * sizeof(dst[0]), x20);
				2325	ASSERT_EQUAL_64(src_base + 2 * sizeof(src[0]), x21);
				2326	ASSERT_EQUAL_64(dst_base, x22);
				2327
				2328	TEARDOWN();
				2329	}
				2330
				2331
				2332	TEST(ldp_stp_float) {
				2333	SETUP();
				2334
				2335	float src[2] = {1.0, 2.0};
				2336	float dst[3] = {0.0, 0.0, 0.0};
				2337	uintptr_t src_base = reinterpret_cast<uintptr_t>(src);
				2338	uintptr_t dst_base = reinterpret_cast<uintptr_t>(dst);
				2339
				2340	START();
				2341	__ Mov(x16, src_base);
				2342	__ Mov(x17, dst_base);
				2343	__ Ldp(s31, s0, MemOperand(x16, 2 * sizeof(src[0]), PostIndex));
				2344	__ Stp(s0, s31, MemOperand(x17, sizeof(dst[1]), PreIndex));
				2345	END();
				2346
				2347	RUN();
				2348
				2349	ASSERT_EQUAL_FP32(1.0, s31);
				2350	ASSERT_EQUAL_FP32(2.0, s0);
				2351	ASSERT_EQUAL_FP32(0.0, dst[0]);
				2352	ASSERT_EQUAL_FP32(2.0, dst[1]);
				2353	ASSERT_EQUAL_FP32(1.0, dst[2]);
				2354	ASSERT_EQUAL_64(src_base + 2 * sizeof(src[0]), x16);
				2355	ASSERT_EQUAL_64(dst_base + sizeof(dst[1]), x17);
				2356
				2357	TEARDOWN();
				2358	}
				2359
				2360
				2361	TEST(ldp_stp_double) {
				2362	SETUP();
				2363
				2364	double src[2] = {1.0, 2.0};
				2365	double dst[3] = {0.0, 0.0, 0.0};
				2366	uintptr_t src_base = reinterpret_cast<uintptr_t>(src);
				2367	uintptr_t dst_base = reinterpret_cast<uintptr_t>(dst);
				2368
				2369	START();
				2370	__ Mov(x16, src_base);
				2371	__ Mov(x17, dst_base);
				2372	__ Ldp(d31, d0, MemOperand(x16, 2 * sizeof(src[0]), PostIndex));
				2373	__ Stp(d0, d31, MemOperand(x17, sizeof(dst[1]), PreIndex));
				2374	END();
				2375
				2376	RUN();
				2377
				2378	ASSERT_EQUAL_FP64(1.0, d31);
				2379	ASSERT_EQUAL_FP64(2.0, d0);
				2380	ASSERT_EQUAL_FP64(0.0, dst[0]);
				2381	ASSERT_EQUAL_FP64(2.0, dst[1]);
				2382	ASSERT_EQUAL_FP64(1.0, dst[2]);
				2383	ASSERT_EQUAL_64(src_base + 2 * sizeof(src[0]), x16);
				2384	ASSERT_EQUAL_64(dst_base + sizeof(dst[1]), x17);
				2385
				2386	TEARDOWN();
				2387	}
				2388
				2389
				2390	TEST(ldp_stp_offset) {
				2391	SETUP();
				2392
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2393	uint64_t src[3] = {0x0011223344556677, 0x8899aabbccddeeff,
				2394	0xffeeddccbbaa9988};
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2395	uint64_t dst[7] = {0, 0, 0, 0, 0, 0, 0};
				2396	uintptr_t src_base = reinterpret_cast<uintptr_t>(src);
				2397	uintptr_t dst_base = reinterpret_cast<uintptr_t>(dst);
				2398
				2399	START();
				2400	__ Mov(x16, src_base);
				2401	__ Mov(x17, dst_base);
				2402	__ Mov(x18, src_base + 24);
				2403	__ Mov(x19, dst_base + 56);
				2404	__ Ldp(w0, w1, MemOperand(x16));
				2405	__ Ldp(w2, w3, MemOperand(x16, 4));
				2406	__ Ldp(x4, x5, MemOperand(x16, 8));
				2407	__ Ldp(w6, w7, MemOperand(x18, -12));
				2408	__ Ldp(x8, x9, MemOperand(x18, -16));
				2409	__ Stp(w0, w1, MemOperand(x17));
				2410	__ Stp(w2, w3, MemOperand(x17, 8));
				2411	__ Stp(x4, x5, MemOperand(x17, 16));
				2412	__ Stp(w6, w7, MemOperand(x19, -24));
				2413	__ Stp(x8, x9, MemOperand(x19, -16));
				2414	END();
				2415
				2416	RUN();
				2417
				2418	ASSERT_EQUAL_64(0x44556677, x0);
				2419	ASSERT_EQUAL_64(0x00112233, x1);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2420	ASSERT_EQUAL_64(0x0011223344556677, dst[0]);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2421	ASSERT_EQUAL_64(0x00112233, x2);
				2422	ASSERT_EQUAL_64(0xccddeeff, x3);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2423	ASSERT_EQUAL_64(0xccddeeff00112233, dst[1]);
				2424	ASSERT_EQUAL_64(0x8899aabbccddeeff, x4);
				2425	ASSERT_EQUAL_64(0x8899aabbccddeeff, dst[2]);
				2426	ASSERT_EQUAL_64(0xffeeddccbbaa9988, x5);
				2427	ASSERT_EQUAL_64(0xffeeddccbbaa9988, dst[3]);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2428	ASSERT_EQUAL_64(0x8899aabb, x6);
				2429	ASSERT_EQUAL_64(0xbbaa9988, x7);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2430	ASSERT_EQUAL_64(0xbbaa99888899aabb, dst[4]);
				2431	ASSERT_EQUAL_64(0x8899aabbccddeeff, x8);
				2432	ASSERT_EQUAL_64(0x8899aabbccddeeff, dst[5]);
				2433	ASSERT_EQUAL_64(0xffeeddccbbaa9988, x9);
				2434	ASSERT_EQUAL_64(0xffeeddccbbaa9988, dst[6]);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2435	ASSERT_EQUAL_64(src_base, x16);
				2436	ASSERT_EQUAL_64(dst_base, x17);
				2437	ASSERT_EQUAL_64(src_base + 24, x18);
				2438	ASSERT_EQUAL_64(dst_base + 56, x19);
				2439
				2440	TEARDOWN();
				2441	}
				2442
				2443
				2444	TEST(ldnp_stnp_offset) {
				2445	SETUP();
				2446
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2447	uint64_t src[3] = {0x0011223344556677, 0x8899aabbccddeeff,
				2448	0xffeeddccbbaa9988};
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2449	uint64_t dst[7] = {0, 0, 0, 0, 0, 0, 0};
				2450	uintptr_t src_base = reinterpret_cast<uintptr_t>(src);
				2451	uintptr_t dst_base = reinterpret_cast<uintptr_t>(dst);
				2452
				2453	START();
				2454	__ Mov(x16, src_base);
				2455	__ Mov(x17, dst_base);
				2456	__ Mov(x18, src_base + 24);
				2457	__ Mov(x19, dst_base + 56);
				2458	__ Ldnp(w0, w1, MemOperand(x16));
				2459	__ Ldnp(w2, w3, MemOperand(x16, 4));
				2460	__ Ldnp(x4, x5, MemOperand(x16, 8));
				2461	__ Ldnp(w6, w7, MemOperand(x18, -12));
				2462	__ Ldnp(x8, x9, MemOperand(x18, -16));
				2463	__ Stnp(w0, w1, MemOperand(x17));
				2464	__ Stnp(w2, w3, MemOperand(x17, 8));
				2465	__ Stnp(x4, x5, MemOperand(x17, 16));
				2466	__ Stnp(w6, w7, MemOperand(x19, -24));
				2467	__ Stnp(x8, x9, MemOperand(x19, -16));
				2468	END();
				2469
				2470	RUN();
				2471
				2472	ASSERT_EQUAL_64(0x44556677, x0);
				2473	ASSERT_EQUAL_64(0x00112233, x1);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2474	ASSERT_EQUAL_64(0x0011223344556677, dst[0]);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2475	ASSERT_EQUAL_64(0x00112233, x2);
				2476	ASSERT_EQUAL_64(0xccddeeff, x3);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2477	ASSERT_EQUAL_64(0xccddeeff00112233, dst[1]);
				2478	ASSERT_EQUAL_64(0x8899aabbccddeeff, x4);
				2479	ASSERT_EQUAL_64(0x8899aabbccddeeff, dst[2]);
				2480	ASSERT_EQUAL_64(0xffeeddccbbaa9988, x5);
				2481	ASSERT_EQUAL_64(0xffeeddccbbaa9988, dst[3]);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2482	ASSERT_EQUAL_64(0x8899aabb, x6);
				2483	ASSERT_EQUAL_64(0xbbaa9988, x7);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2484	ASSERT_EQUAL_64(0xbbaa99888899aabb, dst[4]);
				2485	ASSERT_EQUAL_64(0x8899aabbccddeeff, x8);
				2486	ASSERT_EQUAL_64(0x8899aabbccddeeff, dst[5]);
				2487	ASSERT_EQUAL_64(0xffeeddccbbaa9988, x9);
				2488	ASSERT_EQUAL_64(0xffeeddccbbaa9988, dst[6]);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2489	ASSERT_EQUAL_64(src_base, x16);
				2490	ASSERT_EQUAL_64(dst_base, x17);
				2491	ASSERT_EQUAL_64(src_base + 24, x18);
				2492	ASSERT_EQUAL_64(dst_base + 56, x19);
				2493
				2494	TEARDOWN();
				2495	}
				2496
				2497
				2498	TEST(ldp_stp_preindex) {
				2499	SETUP();
				2500
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2501	uint64_t src[3] = {0x0011223344556677, 0x8899aabbccddeeff,
				2502	0xffeeddccbbaa9988};
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2503	uint64_t dst[5] = {0, 0, 0, 0, 0};
				2504	uintptr_t src_base = reinterpret_cast<uintptr_t>(src);
				2505	uintptr_t dst_base = reinterpret_cast<uintptr_t>(dst);
				2506
				2507	START();
				2508	__ Mov(x16, src_base);
				2509	__ Mov(x17, dst_base);
				2510	__ Mov(x18, dst_base + 16);
				2511	__ Ldp(w0, w1, MemOperand(x16, 4, PreIndex));
				2512	__ Mov(x19, x16);
				2513	__ Ldp(w2, w3, MemOperand(x16, -4, PreIndex));
				2514	__ Stp(w2, w3, MemOperand(x17, 4, PreIndex));
				2515	__ Mov(x20, x17);
				2516	__ Stp(w0, w1, MemOperand(x17, -4, PreIndex));
				2517	__ Ldp(x4, x5, MemOperand(x16, 8, PreIndex));
				2518	__ Mov(x21, x16);
				2519	__ Ldp(x6, x7, MemOperand(x16, -8, PreIndex));
				2520	__ Stp(x7, x6, MemOperand(x18, 8, PreIndex));
				2521	__ Mov(x22, x18);
				2522	__ Stp(x5, x4, MemOperand(x18, -8, PreIndex));
				2523	END();
				2524
				2525	RUN();
				2526
				2527	ASSERT_EQUAL_64(0x00112233, x0);
				2528	ASSERT_EQUAL_64(0xccddeeff, x1);
				2529	ASSERT_EQUAL_64(0x44556677, x2);
				2530	ASSERT_EQUAL_64(0x00112233, x3);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2531	ASSERT_EQUAL_64(0xccddeeff00112233, dst[0]);
				2532	ASSERT_EQUAL_64(0x0000000000112233, dst[1]);
				2533	ASSERT_EQUAL_64(0x8899aabbccddeeff, x4);
				2534	ASSERT_EQUAL_64(0xffeeddccbbaa9988, x5);
				2535	ASSERT_EQUAL_64(0x0011223344556677, x6);
				2536	ASSERT_EQUAL_64(0x8899aabbccddeeff, x7);
				2537	ASSERT_EQUAL_64(0xffeeddccbbaa9988, dst[2]);
				2538	ASSERT_EQUAL_64(0x8899aabbccddeeff, dst[3]);
				2539	ASSERT_EQUAL_64(0x0011223344556677, dst[4]);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2540	ASSERT_EQUAL_64(src_base, x16);
				2541	ASSERT_EQUAL_64(dst_base, x17);
				2542	ASSERT_EQUAL_64(dst_base + 16, x18);
				2543	ASSERT_EQUAL_64(src_base + 4, x19);
				2544	ASSERT_EQUAL_64(dst_base + 4, x20);
				2545	ASSERT_EQUAL_64(src_base + 8, x21);
				2546	ASSERT_EQUAL_64(dst_base + 24, x22);
				2547
				2548	TEARDOWN();
				2549	}
				2550
				2551
				2552	TEST(ldp_stp_postindex) {
				2553	SETUP();
				2554
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2555	uint64_t src[4] = {0x0011223344556677, 0x8899aabbccddeeff,
				2556	0xffeeddccbbaa9988, 0x7766554433221100};
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2557	uint64_t dst[5] = {0, 0, 0, 0, 0};
				2558	uintptr_t src_base = reinterpret_cast<uintptr_t>(src);
				2559	uintptr_t dst_base = reinterpret_cast<uintptr_t>(dst);
				2560
				2561	START();
				2562	__ Mov(x16, src_base);
				2563	__ Mov(x17, dst_base);
				2564	__ Mov(x18, dst_base + 16);
				2565	__ Ldp(w0, w1, MemOperand(x16, 4, PostIndex));
				2566	__ Mov(x19, x16);
				2567	__ Ldp(w2, w3, MemOperand(x16, -4, PostIndex));
				2568	__ Stp(w2, w3, MemOperand(x17, 4, PostIndex));
				2569	__ Mov(x20, x17);
				2570	__ Stp(w0, w1, MemOperand(x17, -4, PostIndex));
				2571	__ Ldp(x4, x5, MemOperand(x16, 8, PostIndex));
				2572	__ Mov(x21, x16);
				2573	__ Ldp(x6, x7, MemOperand(x16, -8, PostIndex));
				2574	__ Stp(x7, x6, MemOperand(x18, 8, PostIndex));
				2575	__ Mov(x22, x18);
				2576	__ Stp(x5, x4, MemOperand(x18, -8, PostIndex));
				2577	END();
				2578
				2579	RUN();
				2580
				2581	ASSERT_EQUAL_64(0x44556677, x0);
				2582	ASSERT_EQUAL_64(0x00112233, x1);
				2583	ASSERT_EQUAL_64(0x00112233, x2);
				2584	ASSERT_EQUAL_64(0xccddeeff, x3);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2585	ASSERT_EQUAL_64(0x4455667700112233, dst[0]);
				2586	ASSERT_EQUAL_64(0x0000000000112233, dst[1]);
				2587	ASSERT_EQUAL_64(0x0011223344556677, x4);
				2588	ASSERT_EQUAL_64(0x8899aabbccddeeff, x5);
				2589	ASSERT_EQUAL_64(0x8899aabbccddeeff, x6);
				2590	ASSERT_EQUAL_64(0xffeeddccbbaa9988, x7);
				2591	ASSERT_EQUAL_64(0xffeeddccbbaa9988, dst[2]);
				2592	ASSERT_EQUAL_64(0x8899aabbccddeeff, dst[3]);
				2593	ASSERT_EQUAL_64(0x0011223344556677, dst[4]);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2594	ASSERT_EQUAL_64(src_base, x16);
				2595	ASSERT_EQUAL_64(dst_base, x17);
				2596	ASSERT_EQUAL_64(dst_base + 16, x18);
				2597	ASSERT_EQUAL_64(src_base + 4, x19);
				2598	ASSERT_EQUAL_64(dst_base + 4, x20);
				2599	ASSERT_EQUAL_64(src_base + 8, x21);
				2600	ASSERT_EQUAL_64(dst_base + 24, x22);
				2601
				2602	TEARDOWN();
				2603	}
				2604
				2605
				2606	TEST(ldp_sign_extend) {
				2607	SETUP();
				2608
				2609	uint32_t src[2] = {0x80000000, 0x7fffffff};
				2610	uintptr_t src_base = reinterpret_cast<uintptr_t>(src);
				2611
				2612	START();
				2613	__ Mov(x24, src_base);
				2614	__ Ldpsw(x0, x1, MemOperand(x24));
				2615	END();
				2616
				2617	RUN();
				2618
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2619	ASSERT_EQUAL_64(0xffffffff80000000, x0);
				2620	ASSERT_EQUAL_64(0x000000007fffffff, x1);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2621
				2622	TEARDOWN();
				2623	}
				2624
				2625
				2626	TEST(ldur_stur) {
				2627	SETUP();
				2628
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2629	int64_t src[2] = {0x0123456789abcdef, 0x0123456789abcdef};
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2630	int64_t dst[5] = {0, 0, 0, 0, 0};
				2631	uintptr_t src_base = reinterpret_cast<uintptr_t>(src);
				2632	uintptr_t dst_base = reinterpret_cast<uintptr_t>(dst);
				2633
				2634	START();
				2635	__ Mov(x17, src_base);
				2636	__ Mov(x18, dst_base);
				2637	__ Mov(x19, src_base + 16);
				2638	__ Mov(x20, dst_base + 32);
				2639	__ Mov(x21, dst_base + 40);
				2640	__ Ldr(w0, MemOperand(x17, 1));
				2641	__ Str(w0, MemOperand(x18, 2));
				2642	__ Ldr(x1, MemOperand(x17, 3));
				2643	__ Str(x1, MemOperand(x18, 9));
				2644	__ Ldr(w2, MemOperand(x19, -9));
				2645	__ Str(w2, MemOperand(x20, -5));
				2646	__ Ldrb(w3, MemOperand(x19, -1));
				2647	__ Strb(w3, MemOperand(x21, -1));
				2648	END();
				2649
				2650	RUN();
				2651
				2652	ASSERT_EQUAL_64(0x6789abcd, x0);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2653	ASSERT_EQUAL_64(0x00006789abcd0000, dst[0]);
				2654	ASSERT_EQUAL_64(0xabcdef0123456789, x1);
				2655	ASSERT_EQUAL_64(0xcdef012345678900, dst[1]);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2656	ASSERT_EQUAL_64(0x000000ab, dst[2]);
				2657	ASSERT_EQUAL_64(0xabcdef01, x2);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2658	ASSERT_EQUAL_64(0x00abcdef01000000, dst[3]);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2659	ASSERT_EQUAL_64(0x00000001, x3);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2660	ASSERT_EQUAL_64(0x0100000000000000, dst[4]);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2661	ASSERT_EQUAL_64(src_base, x17);
				2662	ASSERT_EQUAL_64(dst_base, x18);
				2663	ASSERT_EQUAL_64(src_base + 16, x19);
				2664	ASSERT_EQUAL_64(dst_base + 32, x20);
				2665
				2666	TEARDOWN();
				2667	}
				2668
				2669
				2670	TEST(ldr_literal) {
				2671	SETUP();
				2672
				2673	START();
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2674	__ Ldr(x2, 0x1234567890abcdef);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2675	__ Ldr(w3, 0xfedcba09);
				2676	__ Ldr(d13, 1.234);
				2677	__ Ldr(s25, 2.5);
				2678	END();
				2679
				2680	RUN();
				2681
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2682	ASSERT_EQUAL_64(0x1234567890abcdef, x2);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2683	ASSERT_EQUAL_64(0xfedcba09, x3);
				2684	ASSERT_EQUAL_FP64(1.234, d13);
				2685	ASSERT_EQUAL_FP32(2.5, s25);
				2686
				2687	TEARDOWN();
				2688	}
				2689
				2690
				2691	static void LdrLiteralRangeHelper(ptrdiff_t range_,
				2692	LiteralPoolEmitOption option,
				2693	bool expect_dump) {
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2694	VIXL_ASSERT(range_ > 0);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2695	SETUP_SIZE(range_ + 1024);
				2696
				2697	Label label_1, label_2;
				2698
				2699	size_t range = static_cast<size_t>(range_);
				2700	size_t code_size = 0;
				2701	size_t pool_guard_size;
				2702
				2703	if (option == NoJumpRequired) {
				2704	// Space for an explicit branch.
				2705	pool_guard_size = sizeof(Instr);
				2706	} else {
				2707	pool_guard_size = 0;
				2708	}
				2709
				2710	START();
				2711	// Force a pool dump so the pool starts off empty.
				2712	__ EmitLiteralPool(JumpRequired);
				2713	ASSERT_LITERAL_POOL_SIZE(0);
				2714
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2715	__ Ldr(x0, 0x1234567890abcdef);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2716	__ Ldr(w1, 0xfedcba09);
				2717	__ Ldr(d0, 1.234);
				2718	__ Ldr(s1, 2.5);
				2719	ASSERT_LITERAL_POOL_SIZE(24);
				2720
				2721	code_size += 4 * sizeof(Instr);
				2722
				2723	// Check that the requested range (allowing space for a branch over the pool)
				2724	// can be handled by this test.
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2725	VIXL_ASSERT((code_size + pool_guard_size) <= range);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2726
				2727	// Emit NOPs up to 'range', leaving space for the pool guard.
				2728	while ((code_size + pool_guard_size) < range) {
				2729	__ Nop();
				2730	code_size += sizeof(Instr);
				2731	}
				2732
				2733	// Emit the guard sequence before the literal pool.
				2734	if (option == NoJumpRequired) {
				2735	__ B(&label_1);
				2736	code_size += sizeof(Instr);
				2737	}
				2738
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2739	VIXL_ASSERT(code_size == range);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2740	ASSERT_LITERAL_POOL_SIZE(24);
				2741
				2742	// Possibly generate a literal pool.
				2743	__ CheckLiteralPool(option);
				2744	__ Bind(&label_1);
				2745	if (expect_dump) {
				2746	ASSERT_LITERAL_POOL_SIZE(0);
				2747	} else {
				2748	ASSERT_LITERAL_POOL_SIZE(24);
				2749	}
				2750
				2751	// Force a pool flush to check that a second pool functions correctly.
				2752	__ EmitLiteralPool(JumpRequired);
				2753	ASSERT_LITERAL_POOL_SIZE(0);
				2754
				2755	// These loads should be after the pool (and will require a new one).
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2756	__ Ldr(x4, 0x34567890abcdef12);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2757	__ Ldr(w5, 0xdcba09fe);
				2758	__ Ldr(d4, 123.4);
				2759	__ Ldr(s5, 250.0);
				2760	ASSERT_LITERAL_POOL_SIZE(24);
				2761	END();
				2762
				2763	RUN();
				2764
				2765	// Check that the literals loaded correctly.
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2766	ASSERT_EQUAL_64(0x1234567890abcdef, x0);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2767	ASSERT_EQUAL_64(0xfedcba09, x1);
				2768	ASSERT_EQUAL_FP64(1.234, d0);
				2769	ASSERT_EQUAL_FP32(2.5, s1);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2770	ASSERT_EQUAL_64(0x34567890abcdef12, x4);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2771	ASSERT_EQUAL_64(0xdcba09fe, x5);
				2772	ASSERT_EQUAL_FP64(123.4, d4);
				2773	ASSERT_EQUAL_FP32(250.0, s5);
				2774
				2775	TEARDOWN();
				2776	}
				2777
				2778
				2779	TEST(ldr_literal_range_1) {
				2780	LdrLiteralRangeHelper(kRecommendedLiteralPoolRange,
				2781	NoJumpRequired,
				2782	true);
				2783	}
				2784
				2785
				2786	TEST(ldr_literal_range_2) {
				2787	LdrLiteralRangeHelper(kRecommendedLiteralPoolRange-sizeof(Instr),
				2788	NoJumpRequired,
				2789	false);
				2790	}
				2791
				2792
				2793	TEST(ldr_literal_range_3) {
				2794	LdrLiteralRangeHelper(2 * kRecommendedLiteralPoolRange,
				2795	JumpRequired,
				2796	true);
				2797	}
				2798
				2799
				2800	TEST(ldr_literal_range_4) {
				2801	LdrLiteralRangeHelper(2 * kRecommendedLiteralPoolRange-sizeof(Instr),
				2802	JumpRequired,
				2803	false);
				2804	}
				2805
				2806
				2807	TEST(ldr_literal_range_5) {
				2808	LdrLiteralRangeHelper(kLiteralPoolCheckInterval,
				2809	JumpRequired,
				2810	false);
				2811	}
				2812
				2813
				2814	TEST(ldr_literal_range_6) {
				2815	LdrLiteralRangeHelper(kLiteralPoolCheckInterval-sizeof(Instr),
				2816	JumpRequired,
				2817	false);
				2818	}
				2819
				2820
				2821	TEST(add_sub_imm) {
				2822	SETUP();
				2823
				2824	START();
				2825	__ Mov(x0, 0x0);
				2826	__ Mov(x1, 0x1111);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2827	__ Mov(x2, 0xffffffffffffffff);
				2828	__ Mov(x3, 0x8000000000000000);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2829
				2830	__ Add(x10, x0, Operand(0x123));
				2831	__ Add(x11, x1, Operand(0x122000));
				2832	__ Add(x12, x0, Operand(0xabc << 12));
				2833	__ Add(x13, x2, Operand(1));
				2834
				2835	__ Add(w14, w0, Operand(0x123));
				2836	__ Add(w15, w1, Operand(0x122000));
				2837	__ Add(w16, w0, Operand(0xabc << 12));
				2838	__ Add(w17, w2, Operand(1));
				2839
				2840	__ Sub(x20, x0, Operand(0x1));
				2841	__ Sub(x21, x1, Operand(0x111));
				2842	__ Sub(x22, x1, Operand(0x1 << 12));
				2843	__ Sub(x23, x3, Operand(1));
				2844
				2845	__ Sub(w24, w0, Operand(0x1));
				2846	__ Sub(w25, w1, Operand(0x111));
				2847	__ Sub(w26, w1, Operand(0x1 << 12));
				2848	__ Sub(w27, w3, Operand(1));
				2849	END();
				2850
				2851	RUN();
				2852
				2853	ASSERT_EQUAL_64(0x123, x10);
				2854	ASSERT_EQUAL_64(0x123111, x11);
				2855	ASSERT_EQUAL_64(0xabc000, x12);
				2856	ASSERT_EQUAL_64(0x0, x13);
				2857
				2858	ASSERT_EQUAL_32(0x123, w14);
				2859	ASSERT_EQUAL_32(0x123111, w15);
				2860	ASSERT_EQUAL_32(0xabc000, w16);
				2861	ASSERT_EQUAL_32(0x0, w17);
				2862
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2863	ASSERT_EQUAL_64(0xffffffffffffffff, x20);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2864	ASSERT_EQUAL_64(0x1000, x21);
				2865	ASSERT_EQUAL_64(0x111, x22);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2866	ASSERT_EQUAL_64(0x7fffffffffffffff, x23);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2867
				2868	ASSERT_EQUAL_32(0xffffffff, w24);
				2869	ASSERT_EQUAL_32(0x1000, w25);
				2870	ASSERT_EQUAL_32(0x111, w26);
				2871	ASSERT_EQUAL_32(0xffffffff, w27);
				2872
				2873	TEARDOWN();
				2874	}
				2875
				2876
				2877	TEST(add_sub_wide_imm) {
				2878	SETUP();
				2879
				2880	START();
				2881	__ Mov(x0, 0x0);
				2882	__ Mov(x1, 0x1);
				2883
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2884	__ Add(x10, x0, Operand(0x1234567890abcdef));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2885	__ Add(x11, x1, Operand(0xffffffff));
				2886
				2887	__ Add(w12, w0, Operand(0x12345678));
				2888	__ Add(w13, w1, Operand(0xffffffff));
				2889
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2890	__ Sub(x20, x0, Operand(0x1234567890abcdef));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2891
				2892	__ Sub(w21, w0, Operand(0x12345678));
				2893	END();
				2894
				2895	RUN();
				2896
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2897	ASSERT_EQUAL_64(0x1234567890abcdef, x10);
				2898	ASSERT_EQUAL_64(0x100000000, x11);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2899
				2900	ASSERT_EQUAL_32(0x12345678, w12);
				2901	ASSERT_EQUAL_64(0x0, x13);
				2902
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2903	ASSERT_EQUAL_64(-0x1234567890abcdef, x20);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2904
				2905	ASSERT_EQUAL_32(-0x12345678, w21);
				2906
				2907	TEARDOWN();
				2908	}
				2909
				2910
				2911	TEST(add_sub_shifted) {
				2912	SETUP();
				2913
				2914	START();
				2915	__ Mov(x0, 0);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2916	__ Mov(x1, 0x0123456789abcdef);
				2917	__ Mov(x2, 0xfedcba9876543210);
				2918	__ Mov(x3, 0xffffffffffffffff);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2919
				2920	__ Add(x10, x1, Operand(x2));
				2921	__ Add(x11, x0, Operand(x1, LSL, 8));
				2922	__ Add(x12, x0, Operand(x1, LSR, 8));
				2923	__ Add(x13, x0, Operand(x1, ASR, 8));
				2924	__ Add(x14, x0, Operand(x2, ASR, 8));
				2925	__ Add(w15, w0, Operand(w1, ASR, 8));
				2926	__ Add(w18, w3, Operand(w1, ROR, 8));
				2927	__ Add(x19, x3, Operand(x1, ROR, 8));
				2928
				2929	__ Sub(x20, x3, Operand(x2));
				2930	__ Sub(x21, x3, Operand(x1, LSL, 8));
				2931	__ Sub(x22, x3, Operand(x1, LSR, 8));
				2932	__ Sub(x23, x3, Operand(x1, ASR, 8));
				2933	__ Sub(x24, x3, Operand(x2, ASR, 8));
				2934	__ Sub(w25, w3, Operand(w1, ASR, 8));
				2935	__ Sub(w26, w3, Operand(w1, ROR, 8));
				2936	__ Sub(x27, x3, Operand(x1, ROR, 8));
				2937	END();
				2938
				2939	RUN();
				2940
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2941	ASSERT_EQUAL_64(0xffffffffffffffff, x10);
				2942	ASSERT_EQUAL_64(0x23456789abcdef00, x11);
				2943	ASSERT_EQUAL_64(0x000123456789abcd, x12);
				2944	ASSERT_EQUAL_64(0x000123456789abcd, x13);
				2945	ASSERT_EQUAL_64(0xfffedcba98765432, x14);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2946	ASSERT_EQUAL_64(0xff89abcd, x15);
				2947	ASSERT_EQUAL_64(0xef89abcc, x18);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2948	ASSERT_EQUAL_64(0xef0123456789abcc, x19);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2949
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2950	ASSERT_EQUAL_64(0x0123456789abcdef, x20);
				2951	ASSERT_EQUAL_64(0xdcba9876543210ff, x21);
				2952	ASSERT_EQUAL_64(0xfffedcba98765432, x22);
				2953	ASSERT_EQUAL_64(0xfffedcba98765432, x23);
				2954	ASSERT_EQUAL_64(0x000123456789abcd, x24);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2955	ASSERT_EQUAL_64(0x00765432, x25);
				2956	ASSERT_EQUAL_64(0x10765432, x26);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2957	ASSERT_EQUAL_64(0x10fedcba98765432, x27);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2958
				2959	TEARDOWN();
				2960	}
				2961
				2962
				2963	TEST(add_sub_extended) {
				2964	SETUP();
				2965
				2966	START();
				2967	__ Mov(x0, 0);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	2968	__ Mov(x1, 0x0123456789abcdef);
				2969	__ Mov(x2, 0xfedcba9876543210);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	2970	__ Mov(w3, 0x80);
				2971
				2972	__ Add(x10, x0, Operand(x1, UXTB, 0));
				2973	__ Add(x11, x0, Operand(x1, UXTB, 1));
				2974	__ Add(x12, x0, Operand(x1, UXTH, 2));
				2975	__ Add(x13, x0, Operand(x1, UXTW, 4));
				2976
				2977	__ Add(x14, x0, Operand(x1, SXTB, 0));
				2978	__ Add(x15, x0, Operand(x1, SXTB, 1));
				2979	__ Add(x16, x0, Operand(x1, SXTH, 2));
				2980	__ Add(x17, x0, Operand(x1, SXTW, 3));
				2981	__ Add(x18, x0, Operand(x2, SXTB, 0));
				2982	__ Add(x19, x0, Operand(x2, SXTB, 1));
				2983	__ Add(x20, x0, Operand(x2, SXTH, 2));
				2984	__ Add(x21, x0, Operand(x2, SXTW, 3));
				2985
				2986	__ Add(x22, x1, Operand(x2, SXTB, 1));
				2987	__ Sub(x23, x1, Operand(x2, SXTB, 1));
				2988
				2989	__ Add(w24, w1, Operand(w2, UXTB, 2));
				2990	__ Add(w25, w0, Operand(w1, SXTB, 0));
				2991	__ Add(w26, w0, Operand(w1, SXTB, 1));
				2992	__ Add(w27, w2, Operand(w1, SXTW, 3));
				2993
				2994	__ Add(w28, w0, Operand(w1, SXTW, 3));
				2995	__ Add(x29, x0, Operand(w1, SXTW, 3));
				2996
				2997	__ Sub(x30, x0, Operand(w3, SXTB, 1));
				2998	END();
				2999
				3000	RUN();
				3001
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3002	ASSERT_EQUAL_64(0xef, x10);
				3003	ASSERT_EQUAL_64(0x1de, x11);
				3004	ASSERT_EQUAL_64(0x337bc, x12);
				3005	ASSERT_EQUAL_64(0x89abcdef0, x13);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3006
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3007	ASSERT_EQUAL_64(0xffffffffffffffef, x14);
				3008	ASSERT_EQUAL_64(0xffffffffffffffde, x15);
				3009	ASSERT_EQUAL_64(0xffffffffffff37bc, x16);
				3010	ASSERT_EQUAL_64(0xfffffffc4d5e6f78, x17);
				3011	ASSERT_EQUAL_64(0x10, x18);
				3012	ASSERT_EQUAL_64(0x20, x19);
				3013	ASSERT_EQUAL_64(0xc840, x20);
				3014	ASSERT_EQUAL_64(0x3b2a19080, x21);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3015
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3016	ASSERT_EQUAL_64(0x0123456789abce0f, x22);
				3017	ASSERT_EQUAL_64(0x0123456789abcdcf, x23);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3018
				3019	ASSERT_EQUAL_32(0x89abce2f, w24);
				3020	ASSERT_EQUAL_32(0xffffffef, w25);
				3021	ASSERT_EQUAL_32(0xffffffde, w26);
				3022	ASSERT_EQUAL_32(0xc3b2a188, w27);
				3023
				3024	ASSERT_EQUAL_32(0x4d5e6f78, w28);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3025	ASSERT_EQUAL_64(0xfffffffc4d5e6f78, x29);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3026
				3027	ASSERT_EQUAL_64(256, x30);
				3028
				3029	TEARDOWN();
				3030	}
				3031
				3032
				3033	TEST(add_sub_negative) {
				3034	SETUP();
				3035
				3036	START();
				3037	__ Mov(x0, 0);
				3038	__ Mov(x1, 4687);
				3039	__ Mov(x2, 0x1122334455667788);
				3040	__ Mov(w3, 0x11223344);
				3041	__ Mov(w4, 400000);
				3042
				3043	__ Add(x10, x0, -42);
				3044	__ Add(x11, x1, -687);
				3045	__ Add(x12, x2, -0x88);
				3046
				3047	__ Sub(x13, x0, -600);
				3048	__ Sub(x14, x1, -313);
				3049	__ Sub(x15, x2, -0x555);
				3050
				3051	__ Add(w19, w3, -0x344);
				3052	__ Add(w20, w4, -2000);
				3053
				3054	__ Sub(w21, w3, -0xbc);
				3055	__ Sub(w22, w4, -2000);
				3056	END();
				3057
				3058	RUN();
				3059
				3060	ASSERT_EQUAL_64(-42, x10);
				3061	ASSERT_EQUAL_64(4000, x11);
				3062	ASSERT_EQUAL_64(0x1122334455667700, x12);
				3063
				3064	ASSERT_EQUAL_64(600, x13);
				3065	ASSERT_EQUAL_64(5000, x14);
				3066	ASSERT_EQUAL_64(0x1122334455667cdd, x15);
				3067
				3068	ASSERT_EQUAL_32(0x11223000, w19);
				3069	ASSERT_EQUAL_32(398000, w20);
				3070
				3071	ASSERT_EQUAL_32(0x11223400, w21);
				3072	ASSERT_EQUAL_32(402000, w22);
				3073
				3074	TEARDOWN();
				3075	}
				3076
				3077
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3078	TEST(add_sub_zero) {
				3079	SETUP();
				3080
				3081	START();
				3082	__ Mov(x0, 0);
				3083	__ Mov(x1, 0);
				3084	__ Mov(x2, 0);
				3085
				3086	Label blob1;
				3087	__ Bind(&blob1);
				3088	__ Add(x0, x0, 0);
				3089	__ Sub(x1, x1, 0);
				3090	__ Sub(x2, x2, xzr);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3091	VIXL_CHECK(__ SizeOfCodeGeneratedSince(&blob1) == 0);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3092
				3093	Label blob2;
				3094	__ Bind(&blob2);
				3095	__ Add(w3, w3, 0);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3096	VIXL_CHECK(__ SizeOfCodeGeneratedSince(&blob2) != 0);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3097
				3098	Label blob3;
				3099	__ Bind(&blob3);
				3100	__ Sub(w3, w3, wzr);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3101	VIXL_CHECK(__ SizeOfCodeGeneratedSince(&blob3) != 0);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3102
				3103	END();
				3104
				3105	RUN();
				3106
				3107	ASSERT_EQUAL_64(0, x0);
				3108	ASSERT_EQUAL_64(0, x1);
				3109	ASSERT_EQUAL_64(0, x2);
				3110
				3111	TEARDOWN();
				3112	}
				3113
				3114
				3115	TEST(claim_drop_zero) {
				3116	SETUP();
				3117
				3118	START();
				3119
				3120	Label start;
				3121	__ Bind(&start);
				3122	__ Claim(Operand(0));
				3123	__ Drop(Operand(0));
				3124	__ Claim(Operand(xzr));
				3125	__ Drop(Operand(xzr));
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3126	VIXL_CHECK(__ SizeOfCodeGeneratedSince(&start) == 0);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3127
				3128	END();
				3129
				3130	RUN();
				3131
				3132	TEARDOWN();
				3133	}
				3134
				3135
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3136	TEST(neg) {
				3137	SETUP();
				3138
				3139	START();
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3140	__ Mov(x0, 0xf123456789abcdef);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3141
				3142	// Immediate.
				3143	__ Neg(x1, 0x123);
				3144	__ Neg(w2, 0x123);
				3145
				3146	// Shifted.
				3147	__ Neg(x3, Operand(x0, LSL, 1));
				3148	__ Neg(w4, Operand(w0, LSL, 2));
				3149	__ Neg(x5, Operand(x0, LSR, 3));
				3150	__ Neg(w6, Operand(w0, LSR, 4));
				3151	__ Neg(x7, Operand(x0, ASR, 5));
				3152	__ Neg(w8, Operand(w0, ASR, 6));
				3153
				3154	// Extended.
				3155	__ Neg(w9, Operand(w0, UXTB));
				3156	__ Neg(x10, Operand(x0, SXTB, 1));
				3157	__ Neg(w11, Operand(w0, UXTH, 2));
				3158	__ Neg(x12, Operand(x0, SXTH, 3));
				3159	__ Neg(w13, Operand(w0, UXTW, 4));
				3160	__ Neg(x14, Operand(x0, SXTW, 4));
				3161	END();
				3162
				3163	RUN();
				3164
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3165	ASSERT_EQUAL_64(0xfffffffffffffedd, x1);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3166	ASSERT_EQUAL_64(0xfffffedd, x2);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3167	ASSERT_EQUAL_64(0x1db97530eca86422, x3);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3168	ASSERT_EQUAL_64(0xd950c844, x4);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3169	ASSERT_EQUAL_64(0xe1db97530eca8643, x5);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3170	ASSERT_EQUAL_64(0xf7654322, x6);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3171	ASSERT_EQUAL_64(0x0076e5d4c3b2a191, x7);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3172	ASSERT_EQUAL_64(0x01d950c9, x8);
				3173	ASSERT_EQUAL_64(0xffffff11, x9);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3174	ASSERT_EQUAL_64(0x0000000000000022, x10);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3175	ASSERT_EQUAL_64(0xfffcc844, x11);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3176	ASSERT_EQUAL_64(0x0000000000019088, x12);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3177	ASSERT_EQUAL_64(0x65432110, x13);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3178	ASSERT_EQUAL_64(0x0000000765432110, x14);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3179
				3180	TEARDOWN();
				3181	}
				3182
				3183
				3184	TEST(adc_sbc_shift) {
				3185	SETUP();
				3186
				3187	START();
				3188	__ Mov(x0, 0);
				3189	__ Mov(x1, 1);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3190	__ Mov(x2, 0x0123456789abcdef);
				3191	__ Mov(x3, 0xfedcba9876543210);
				3192	__ Mov(x4, 0xffffffffffffffff);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3193
				3194	// Clear the C flag.
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3195	__ Adds(x0, x0, Operand(0));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3196
				3197	__ Adc(x5, x2, Operand(x3));
				3198	__ Adc(x6, x0, Operand(x1, LSL, 60));
				3199	__ Sbc(x7, x4, Operand(x3, LSR, 4));
				3200	__ Adc(x8, x2, Operand(x3, ASR, 4));
				3201	__ Adc(x9, x2, Operand(x3, ROR, 8));
				3202
				3203	__ Adc(w10, w2, Operand(w3));
				3204	__ Adc(w11, w0, Operand(w1, LSL, 30));
				3205	__ Sbc(w12, w4, Operand(w3, LSR, 4));
				3206	__ Adc(w13, w2, Operand(w3, ASR, 4));
				3207	__ Adc(w14, w2, Operand(w3, ROR, 8));
				3208
				3209	// Set the C flag.
				3210	__ Cmp(w0, Operand(w0));
				3211
				3212	__ Adc(x18, x2, Operand(x3));
				3213	__ Adc(x19, x0, Operand(x1, LSL, 60));
				3214	__ Sbc(x20, x4, Operand(x3, LSR, 4));
				3215	__ Adc(x21, x2, Operand(x3, ASR, 4));
				3216	__ Adc(x22, x2, Operand(x3, ROR, 8));
				3217
				3218	__ Adc(w23, w2, Operand(w3));
				3219	__ Adc(w24, w0, Operand(w1, LSL, 30));
				3220	__ Sbc(w25, w4, Operand(w3, LSR, 4));
				3221	__ Adc(w26, w2, Operand(w3, ASR, 4));
				3222	__ Adc(w27, w2, Operand(w3, ROR, 8));
				3223	END();
				3224
				3225	RUN();
				3226
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3227	ASSERT_EQUAL_64(0xffffffffffffffff, x5);
				3228	ASSERT_EQUAL_64(INT64_C(1) << 60, x6);
				3229	ASSERT_EQUAL_64(0xf0123456789abcdd, x7);
				3230	ASSERT_EQUAL_64(0x0111111111111110, x8);
				3231	ASSERT_EQUAL_64(0x1222222222222221, x9);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3232
				3233	ASSERT_EQUAL_32(0xffffffff, w10);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3234	ASSERT_EQUAL_32(INT32_C(1) << 30, w11);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3235	ASSERT_EQUAL_32(0xf89abcdd, w12);
				3236	ASSERT_EQUAL_32(0x91111110, w13);
				3237	ASSERT_EQUAL_32(0x9a222221, w14);
				3238
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3239	ASSERT_EQUAL_64(0xffffffffffffffff + 1, x18);
				3240	ASSERT_EQUAL_64((INT64_C(1) << 60) + 1, x19);
				3241	ASSERT_EQUAL_64(0xf0123456789abcdd + 1, x20);
				3242	ASSERT_EQUAL_64(0x0111111111111110 + 1, x21);
				3243	ASSERT_EQUAL_64(0x1222222222222221 + 1, x22);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3244
				3245	ASSERT_EQUAL_32(0xffffffff + 1, w23);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3246	ASSERT_EQUAL_32((INT32_C(1) << 30) + 1, w24);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3247	ASSERT_EQUAL_32(0xf89abcdd + 1, w25);
				3248	ASSERT_EQUAL_32(0x91111110 + 1, w26);
				3249	ASSERT_EQUAL_32(0x9a222221 + 1, w27);
				3250
				3251	// Check that adc correctly sets the condition flags.
				3252	START();
				3253	__ Mov(x0, 1);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3254	__ Mov(x1, 0xffffffffffffffff);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3255	// Clear the C flag.
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3256	__ Adds(x0, x0, Operand(0));
				3257	__ Adcs(x10, x0, Operand(x1));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3258	END();
				3259
				3260	RUN();
				3261
				3262	ASSERT_EQUAL_NZCV(ZCFlag);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3263	ASSERT_EQUAL_64(0, x10);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3264
				3265	START();
				3266	__ Mov(x0, 1);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3267	__ Mov(x1, 0x8000000000000000);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3268	// Clear the C flag.
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3269	__ Adds(x0, x0, Operand(0));
				3270	__ Adcs(x10, x0, Operand(x1, ASR, 63));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3271	END();
				3272
				3273	RUN();
				3274
				3275	ASSERT_EQUAL_NZCV(ZCFlag);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3276	ASSERT_EQUAL_64(0, x10);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3277
				3278	START();
				3279	__ Mov(x0, 0x10);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3280	__ Mov(x1, 0x07ffffffffffffff);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3281	// Clear the C flag.
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3282	__ Adds(x0, x0, Operand(0));
				3283	__ Adcs(x10, x0, Operand(x1, LSL, 4));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3284	END();
				3285
				3286	RUN();
				3287
				3288	ASSERT_EQUAL_NZCV(NVFlag);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3289	ASSERT_EQUAL_64(0x8000000000000000, x10);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3290
				3291	// Check that sbc correctly sets the condition flags.
				3292	START();
				3293	__ Mov(x0, 0);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3294	__ Mov(x1, 0xffffffffffffffff);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3295	// Clear the C flag.
				3296	__ Adds(x0, x0, Operand(0));
				3297	__ Sbcs(x10, x0, Operand(x1));
				3298	END();
				3299
				3300	RUN();
				3301
				3302	ASSERT_EQUAL_NZCV(ZFlag);
				3303	ASSERT_EQUAL_64(0, x10);
				3304
				3305	START();
				3306	__ Mov(x0, 1);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3307	__ Mov(x1, 0xffffffffffffffff);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3308	// Clear the C flag.
				3309	__ Adds(x0, x0, Operand(0));
				3310	__ Sbcs(x10, x0, Operand(x1, LSR, 1));
				3311	END();
				3312
				3313	RUN();
				3314
				3315	ASSERT_EQUAL_NZCV(NFlag);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3316	ASSERT_EQUAL_64(0x8000000000000001, x10);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3317
				3318	START();
				3319	__ Mov(x0, 0);
				3320	// Clear the C flag.
				3321	__ Adds(x0, x0, Operand(0));
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3322	__ Sbcs(x10, x0, Operand(0xffffffffffffffff));
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3323	END();
				3324
				3325	RUN();
				3326
				3327	ASSERT_EQUAL_NZCV(ZFlag);
				3328	ASSERT_EQUAL_64(0, x10);
				3329
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3330	START();
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3331	__ Mov(w0, 0x7fffffff);
				3332	// Clear the C flag.
				3333	__ Adds(x0, x0, Operand(0));
				3334	__ Ngcs(w10, w0);
				3335	END();
				3336
				3337	RUN();
				3338
				3339	ASSERT_EQUAL_NZCV(NFlag);
				3340	ASSERT_EQUAL_64(0x80000000, x10);
				3341
				3342	START();
				3343	// Clear the C flag.
				3344	__ Adds(x0, x0, Operand(0));
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3345	__ Ngcs(x10, 0x7fffffffffffffff);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3346	END();
				3347
				3348	RUN();
				3349
				3350	ASSERT_EQUAL_NZCV(NFlag);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3351	ASSERT_EQUAL_64(0x8000000000000000, x10);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3352
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3353	START();
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3354	__ Mov(x0, 0);
				3355	// Set the C flag.
				3356	__ Cmp(x0, Operand(x0));
				3357	__ Sbcs(x10, x0, Operand(1));
				3358	END();
				3359
				3360	RUN();
				3361
				3362	ASSERT_EQUAL_NZCV(NFlag);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3363	ASSERT_EQUAL_64(0xffffffffffffffff, x10);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3364
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3365	START();
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3366	__ Mov(x0, 0);
				3367	// Set the C flag.
				3368	__ Cmp(x0, Operand(x0));
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3369	__ Ngcs(x10, 0x7fffffffffffffff);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3370	END();
				3371
				3372	RUN();
				3373
				3374	ASSERT_EQUAL_NZCV(NFlag);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3375	ASSERT_EQUAL_64(0x8000000000000001, x10);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3376
				3377	TEARDOWN();
				3378	}
				3379
				3380
				3381	TEST(adc_sbc_extend) {
				3382	SETUP();
				3383
				3384	START();
				3385	// Clear the C flag.
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3386	__ Adds(x0, x0, Operand(0));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3387
				3388	__ Mov(x0, 0);
				3389	__ Mov(x1, 1);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3390	__ Mov(x2, 0x0123456789abcdef);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3391
				3392	__ Adc(x10, x1, Operand(w2, UXTB, 1));
				3393	__ Adc(x11, x1, Operand(x2, SXTH, 2));
				3394	__ Sbc(x12, x1, Operand(w2, UXTW, 4));
				3395	__ Adc(x13, x1, Operand(x2, UXTX, 4));
				3396
				3397	__ Adc(w14, w1, Operand(w2, UXTB, 1));
				3398	__ Adc(w15, w1, Operand(w2, SXTH, 2));
				3399	__ Adc(w9, w1, Operand(w2, UXTW, 4));
				3400
				3401	// Set the C flag.
				3402	__ Cmp(w0, Operand(w0));
				3403
				3404	__ Adc(x20, x1, Operand(w2, UXTB, 1));
				3405	__ Adc(x21, x1, Operand(x2, SXTH, 2));
				3406	__ Sbc(x22, x1, Operand(w2, UXTW, 4));
				3407	__ Adc(x23, x1, Operand(x2, UXTX, 4));
				3408
				3409	__ Adc(w24, w1, Operand(w2, UXTB, 1));
				3410	__ Adc(w25, w1, Operand(w2, SXTH, 2));
				3411	__ Adc(w26, w1, Operand(w2, UXTW, 4));
				3412	END();
				3413
				3414	RUN();
				3415
				3416	ASSERT_EQUAL_64(0x1df, x10);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3417	ASSERT_EQUAL_64(0xffffffffffff37bd, x11);
				3418	ASSERT_EQUAL_64(0xfffffff765432110, x12);
				3419	ASSERT_EQUAL_64(0x123456789abcdef1, x13);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3420
				3421	ASSERT_EQUAL_32(0x1df, w14);
				3422	ASSERT_EQUAL_32(0xffff37bd, w15);
				3423	ASSERT_EQUAL_32(0x9abcdef1, w9);
				3424
				3425	ASSERT_EQUAL_64(0x1df + 1, x20);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3426	ASSERT_EQUAL_64(0xffffffffffff37bd + 1, x21);
				3427	ASSERT_EQUAL_64(0xfffffff765432110 + 1, x22);
				3428	ASSERT_EQUAL_64(0x123456789abcdef1 + 1, x23);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3429
				3430	ASSERT_EQUAL_32(0x1df + 1, w24);
				3431	ASSERT_EQUAL_32(0xffff37bd + 1, w25);
				3432	ASSERT_EQUAL_32(0x9abcdef1 + 1, w26);
				3433
				3434	// Check that adc correctly sets the condition flags.
				3435	START();
				3436	__ Mov(x0, 0xff);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3437	__ Mov(x1, 0xffffffffffffffff);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3438	// Clear the C flag.
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3439	__ Adds(x0, x0, Operand(0));
				3440	__ Adcs(x10, x0, Operand(x1, SXTX, 1));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3441	END();
				3442
				3443	RUN();
				3444
				3445	ASSERT_EQUAL_NZCV(CFlag);
				3446
				3447	START();
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3448	__ Mov(x0, 0x7fffffffffffffff);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3449	__ Mov(x1, 1);
				3450	// Clear the C flag.
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3451	__ Adds(x0, x0, Operand(0));
				3452	__ Adcs(x10, x0, Operand(x1, UXTB, 2));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3453	END();
				3454
				3455	RUN();
				3456
				3457	ASSERT_EQUAL_NZCV(NVFlag);
				3458
				3459	START();
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3460	__ Mov(x0, 0x7fffffffffffffff);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3461	// Clear the C flag.
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3462	__ Adds(x0, x0, Operand(0));
				3463	__ Adcs(x10, x0, Operand(1));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3464	END();
				3465
				3466	RUN();
				3467
				3468	ASSERT_EQUAL_NZCV(NVFlag);
				3469
				3470	TEARDOWN();
				3471	}
				3472
				3473
				3474	TEST(adc_sbc_wide_imm) {
				3475	SETUP();
				3476
				3477	START();
				3478	__ Mov(x0, 0);
				3479
				3480	// Clear the C flag.
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3481	__ Adds(x0, x0, Operand(0));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3482
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3483	__ Adc(x7, x0, Operand(0x1234567890abcdef));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3484	__ Adc(w8, w0, Operand(0xffffffff));
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3485	__ Sbc(x9, x0, Operand(0x1234567890abcdef));
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3486	__ Sbc(w10, w0, Operand(0xffffffff));
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3487	__ Ngc(x11, Operand(0xffffffff00000000));
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3488	__ Ngc(w12, Operand(0xffff0000));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3489
				3490	// Set the C flag.
				3491	__ Cmp(w0, Operand(w0));
				3492
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3493	__ Adc(x18, x0, Operand(0x1234567890abcdef));
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3494	__ Adc(w19, w0, Operand(0xffffffff));
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3495	__ Sbc(x20, x0, Operand(0x1234567890abcdef));
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3496	__ Sbc(w21, w0, Operand(0xffffffff));
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3497	__ Ngc(x22, Operand(0xffffffff00000000));
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3498	__ Ngc(w23, Operand(0xffff0000));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3499	END();
				3500
				3501	RUN();
				3502
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3503	ASSERT_EQUAL_64(0x1234567890abcdef, x7);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3504	ASSERT_EQUAL_64(0xffffffff, x8);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3505	ASSERT_EQUAL_64(0xedcba9876f543210, x9);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3506	ASSERT_EQUAL_64(0, x10);
				3507	ASSERT_EQUAL_64(0xffffffff, x11);
				3508	ASSERT_EQUAL_64(0xffff, x12);
				3509
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3510	ASSERT_EQUAL_64(0x1234567890abcdef + 1, x18);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3511	ASSERT_EQUAL_64(0, x19);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3512	ASSERT_EQUAL_64(0xedcba9876f543211, x20);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3513	ASSERT_EQUAL_64(1, x21);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3514	ASSERT_EQUAL_64(0x0000000100000000, x22);
				3515	ASSERT_EQUAL_64(0x0000000000010000, x23);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3516
				3517	TEARDOWN();
				3518	}
				3519
				3520	TEST(flags) {
				3521	SETUP();
				3522
				3523	START();
				3524	__ Mov(x0, 0);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3525	__ Mov(x1, 0x1111111111111111);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3526	__ Neg(x10, Operand(x0));
				3527	__ Neg(x11, Operand(x1));
				3528	__ Neg(w12, Operand(w1));
				3529	// Clear the C flag.
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3530	__ Adds(x0, x0, Operand(0));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3531	__ Ngc(x13, Operand(x0));
				3532	// Set the C flag.
				3533	__ Cmp(x0, Operand(x0));
				3534	__ Ngc(w14, Operand(w0));
				3535	END();
				3536
				3537	RUN();
				3538
				3539	ASSERT_EQUAL_64(0, x10);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3540	ASSERT_EQUAL_64(-0x1111111111111111, x11);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3541	ASSERT_EQUAL_32(-0x11111111, w12);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3542	ASSERT_EQUAL_64(-1, x13);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3543	ASSERT_EQUAL_32(0, w14);
				3544
				3545	START();
				3546	__ Mov(x0, 0);
				3547	__ Cmp(x0, Operand(x0));
				3548	END();
				3549
				3550	RUN();
				3551
				3552	ASSERT_EQUAL_NZCV(ZCFlag);
				3553
				3554	START();
				3555	__ Mov(w0, 0);
				3556	__ Cmp(w0, Operand(w0));
				3557	END();
				3558
				3559	RUN();
				3560
				3561	ASSERT_EQUAL_NZCV(ZCFlag);
				3562
				3563	START();
				3564	__ Mov(x0, 0);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3565	__ Mov(x1, 0x1111111111111111);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3566	__ Cmp(x0, Operand(x1));
				3567	END();
				3568
				3569	RUN();
				3570
				3571	ASSERT_EQUAL_NZCV(NFlag);
				3572
				3573	START();
				3574	__ Mov(w0, 0);
				3575	__ Mov(w1, 0x11111111);
				3576	__ Cmp(w0, Operand(w1));
				3577	END();
				3578
				3579	RUN();
				3580
				3581	ASSERT_EQUAL_NZCV(NFlag);
				3582
				3583	START();
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3584	__ Mov(x1, 0x1111111111111111);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3585	__ Cmp(x1, Operand(0));
				3586	END();
				3587
				3588	RUN();
				3589
				3590	ASSERT_EQUAL_NZCV(CFlag);
				3591
				3592	START();
				3593	__ Mov(w1, 0x11111111);
				3594	__ Cmp(w1, Operand(0));
				3595	END();
				3596
				3597	RUN();
				3598
				3599	ASSERT_EQUAL_NZCV(CFlag);
				3600
				3601	START();
				3602	__ Mov(x0, 1);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3603	__ Mov(x1, 0x7fffffffffffffff);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3604	__ Cmn(x1, Operand(x0));
				3605	END();
				3606
				3607	RUN();
				3608
				3609	ASSERT_EQUAL_NZCV(NVFlag);
				3610
				3611	START();
				3612	__ Mov(w0, 1);
				3613	__ Mov(w1, 0x7fffffff);
				3614	__ Cmn(w1, Operand(w0));
				3615	END();
				3616
				3617	RUN();
				3618
				3619	ASSERT_EQUAL_NZCV(NVFlag);
				3620
				3621	START();
				3622	__ Mov(x0, 1);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3623	__ Mov(x1, 0xffffffffffffffff);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3624	__ Cmn(x1, Operand(x0));
				3625	END();
				3626
				3627	RUN();
				3628
				3629	ASSERT_EQUAL_NZCV(ZCFlag);
				3630
				3631	START();
				3632	__ Mov(w0, 1);
				3633	__ Mov(w1, 0xffffffff);
				3634	__ Cmn(w1, Operand(w0));
				3635	END();
				3636
				3637	RUN();
				3638
				3639	ASSERT_EQUAL_NZCV(ZCFlag);
				3640
				3641	START();
				3642	__ Mov(w0, 0);
				3643	__ Mov(w1, 1);
				3644	// Clear the C flag.
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3645	__ Adds(w0, w0, Operand(0));
				3646	__ Ngcs(w0, Operand(w1));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3647	END();
				3648
				3649	RUN();
				3650
				3651	ASSERT_EQUAL_NZCV(NFlag);
				3652
				3653	START();
				3654	__ Mov(w0, 0);
				3655	__ Mov(w1, 0);
				3656	// Set the C flag.
				3657	__ Cmp(w0, Operand(w0));
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3658	__ Ngcs(w0, Operand(w1));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3659	END();
				3660
				3661	RUN();
				3662
				3663	ASSERT_EQUAL_NZCV(ZCFlag);
				3664
				3665	TEARDOWN();
				3666	}
				3667
				3668
				3669	TEST(cmp_shift) {
				3670	SETUP();
				3671
				3672	START();
				3673	__ Mov(x18, 0xf0000000);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3674	__ Mov(x19, 0xf000000010000000);
				3675	__ Mov(x20, 0xf0000000f0000000);
				3676	__ Mov(x21, 0x7800000078000000);
				3677	__ Mov(x22, 0x3c0000003c000000);
				3678	__ Mov(x23, 0x8000000780000000);
				3679	__ Mov(x24, 0x0000000f00000000);
				3680	__ Mov(x25, 0x00000003c0000000);
				3681	__ Mov(x26, 0x8000000780000000);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3682	__ Mov(x27, 0xc0000003);
				3683
				3684	__ Cmp(w20, Operand(w21, LSL, 1));
				3685	__ Mrs(x0, NZCV);
				3686
				3687	__ Cmp(x20, Operand(x22, LSL, 2));
				3688	__ Mrs(x1, NZCV);
				3689
				3690	__ Cmp(w19, Operand(w23, LSR, 3));
				3691	__ Mrs(x2, NZCV);
				3692
				3693	__ Cmp(x18, Operand(x24, LSR, 4));
				3694	__ Mrs(x3, NZCV);
				3695
				3696	__ Cmp(w20, Operand(w25, ASR, 2));
				3697	__ Mrs(x4, NZCV);
				3698
				3699	__ Cmp(x20, Operand(x26, ASR, 3));
				3700	__ Mrs(x5, NZCV);
				3701
				3702	__ Cmp(w27, Operand(w22, ROR, 28));
				3703	__ Mrs(x6, NZCV);
				3704
				3705	__ Cmp(x20, Operand(x21, ROR, 31));
				3706	__ Mrs(x7, NZCV);
				3707	END();
				3708
				3709	RUN();
				3710
				3711	ASSERT_EQUAL_32(ZCFlag, w0);
				3712	ASSERT_EQUAL_32(ZCFlag, w1);
				3713	ASSERT_EQUAL_32(ZCFlag, w2);
				3714	ASSERT_EQUAL_32(ZCFlag, w3);
				3715	ASSERT_EQUAL_32(ZCFlag, w4);
				3716	ASSERT_EQUAL_32(ZCFlag, w5);
				3717	ASSERT_EQUAL_32(ZCFlag, w6);
				3718	ASSERT_EQUAL_32(ZCFlag, w7);
				3719
				3720	TEARDOWN();
				3721	}
				3722
				3723
				3724	TEST(cmp_extend) {
				3725	SETUP();
				3726
				3727	START();
				3728	__ Mov(w20, 0x2);
				3729	__ Mov(w21, 0x1);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3730	__ Mov(x22, 0xffffffffffffffff);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3731	__ Mov(x23, 0xff);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3732	__ Mov(x24, 0xfffffffffffffffe);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3733	__ Mov(x25, 0xffff);
				3734	__ Mov(x26, 0xffffffff);
				3735
				3736	__ Cmp(w20, Operand(w21, LSL, 1));
				3737	__ Mrs(x0, NZCV);
				3738
				3739	__ Cmp(x22, Operand(x23, SXTB, 0));
				3740	__ Mrs(x1, NZCV);
				3741
				3742	__ Cmp(x24, Operand(x23, SXTB, 1));
				3743	__ Mrs(x2, NZCV);
				3744
				3745	__ Cmp(x24, Operand(x23, UXTB, 1));
				3746	__ Mrs(x3, NZCV);
				3747
				3748	__ Cmp(w22, Operand(w25, UXTH));
				3749	__ Mrs(x4, NZCV);
				3750
				3751	__ Cmp(x22, Operand(x25, SXTH));
				3752	__ Mrs(x5, NZCV);
				3753
				3754	__ Cmp(x22, Operand(x26, UXTW));
				3755	__ Mrs(x6, NZCV);
				3756
				3757	__ Cmp(x24, Operand(x26, SXTW, 1));
				3758	__ Mrs(x7, NZCV);
				3759	END();
				3760
				3761	RUN();
				3762
				3763	ASSERT_EQUAL_32(ZCFlag, w0);
				3764	ASSERT_EQUAL_32(ZCFlag, w1);
				3765	ASSERT_EQUAL_32(ZCFlag, w2);
				3766	ASSERT_EQUAL_32(NCFlag, w3);
				3767	ASSERT_EQUAL_32(NCFlag, w4);
				3768	ASSERT_EQUAL_32(ZCFlag, w5);
				3769	ASSERT_EQUAL_32(NCFlag, w6);
				3770	ASSERT_EQUAL_32(ZCFlag, w7);
				3771
				3772	TEARDOWN();
				3773	}
				3774
				3775
				3776	TEST(ccmp) {
				3777	SETUP();
				3778
				3779	START();
				3780	__ Mov(w16, 0);
				3781	__ Mov(w17, 1);
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	3782	__ Cmp(w16, w16);
				3783	__ Ccmp(w16, w17, NCFlag, eq);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3784	__ Mrs(x0, NZCV);
				3785
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	3786	__ Cmp(w16, w16);
				3787	__ Ccmp(w16, w17, NCFlag, ne);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3788	__ Mrs(x1, NZCV);
				3789
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	3790	__ Cmp(x16, x16);
				3791	__ Ccmn(x16, 2, NZCVFlag, eq);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3792	__ Mrs(x2, NZCV);
				3793
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	3794	__ Cmp(x16, x16);
				3795	__ Ccmn(x16, 2, NZCVFlag, ne);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3796	__ Mrs(x3, NZCV);
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	3797
				3798	__ ccmp(x16, x16, NZCVFlag, al);
				3799	__ Mrs(x4, NZCV);
				3800
				3801	__ ccmp(x16, x16, NZCVFlag, nv);
				3802	__ Mrs(x5, NZCV);
				3803
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3804	END();
				3805
				3806	RUN();
				3807
				3808	ASSERT_EQUAL_32(NFlag, w0);
				3809	ASSERT_EQUAL_32(NCFlag, w1);
				3810	ASSERT_EQUAL_32(NoFlag, w2);
				3811	ASSERT_EQUAL_32(NZCVFlag, w3);
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	3812	ASSERT_EQUAL_32(ZCFlag, w4);
				3813	ASSERT_EQUAL_32(ZCFlag, w5);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3814
				3815	TEARDOWN();
				3816	}
				3817
				3818
				3819	TEST(ccmp_wide_imm) {
				3820	SETUP();
				3821
				3822	START();
				3823	__ Mov(w20, 0);
				3824
				3825	__ Cmp(w20, Operand(w20));
				3826	__ Ccmp(w20, Operand(0x12345678), NZCVFlag, eq);
				3827	__ Mrs(x0, NZCV);
				3828
				3829	__ Cmp(w20, Operand(w20));
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3830	__ Ccmp(x20, Operand(0xffffffffffffffff), NZCVFlag, eq);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3831	__ Mrs(x1, NZCV);
				3832	END();
				3833
				3834	RUN();
				3835
				3836	ASSERT_EQUAL_32(NFlag, w0);
				3837	ASSERT_EQUAL_32(NoFlag, w1);
				3838
				3839	TEARDOWN();
				3840	}
				3841
				3842
				3843	TEST(ccmp_shift_extend) {
				3844	SETUP();
				3845
				3846	START();
				3847	__ Mov(w20, 0x2);
				3848	__ Mov(w21, 0x1);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3849	__ Mov(x22, 0xffffffffffffffff);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3850	__ Mov(x23, 0xff);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3851	__ Mov(x24, 0xfffffffffffffffe);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3852
				3853	__ Cmp(w20, Operand(w20));
				3854	__ Ccmp(w20, Operand(w21, LSL, 1), NZCVFlag, eq);
				3855	__ Mrs(x0, NZCV);
				3856
				3857	__ Cmp(w20, Operand(w20));
				3858	__ Ccmp(x22, Operand(x23, SXTB, 0), NZCVFlag, eq);
				3859	__ Mrs(x1, NZCV);
				3860
				3861	__ Cmp(w20, Operand(w20));
				3862	__ Ccmp(x24, Operand(x23, SXTB, 1), NZCVFlag, eq);
				3863	__ Mrs(x2, NZCV);
				3864
				3865	__ Cmp(w20, Operand(w20));
				3866	__ Ccmp(x24, Operand(x23, UXTB, 1), NZCVFlag, eq);
				3867	__ Mrs(x3, NZCV);
				3868
				3869	__ Cmp(w20, Operand(w20));
				3870	__ Ccmp(x24, Operand(x23, UXTB, 1), NZCVFlag, ne);
				3871	__ Mrs(x4, NZCV);
				3872	END();
				3873
				3874	RUN();
				3875
				3876	ASSERT_EQUAL_32(ZCFlag, w0);
				3877	ASSERT_EQUAL_32(ZCFlag, w1);
				3878	ASSERT_EQUAL_32(ZCFlag, w2);
				3879	ASSERT_EQUAL_32(NCFlag, w3);
				3880	ASSERT_EQUAL_32(NZCVFlag, w4);
				3881
				3882	TEARDOWN();
				3883	}
				3884
				3885
				3886	TEST(csel) {
				3887	SETUP();
				3888
				3889	START();
				3890	__ Mov(x16, 0);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3891	__ Mov(x24, 0x0000000f0000000f);
				3892	__ Mov(x25, 0x0000001f0000001f);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3893
				3894	__ Cmp(w16, Operand(0));
				3895	__ Csel(w0, w24, w25, eq);
				3896	__ Csel(w1, w24, w25, ne);
				3897	__ Csinc(w2, w24, w25, mi);
				3898	__ Csinc(w3, w24, w25, pl);
				3899
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	3900	__ csel(w13, w24, w25, al);
				3901	__ csel(x14, x24, x25, nv);
				3902
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3903	__ Cmp(x16, Operand(1));
				3904	__ Csinv(x4, x24, x25, gt);
				3905	__ Csinv(x5, x24, x25, le);
				3906	__ Csneg(x6, x24, x25, hs);
				3907	__ Csneg(x7, x24, x25, lo);
				3908
				3909	__ Cset(w8, ne);
				3910	__ Csetm(w9, ne);
				3911	__ Cinc(x10, x25, ne);
				3912	__ Cinv(x11, x24, ne);
				3913	__ Cneg(x12, x24, ne);
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	3914
				3915	__ csel(w15, w24, w25, al);
				3916	__ csel(x17, x24, x25, nv);
				3917
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3918	END();
				3919
				3920	RUN();
				3921
				3922	ASSERT_EQUAL_64(0x0000000f, x0);
				3923	ASSERT_EQUAL_64(0x0000001f, x1);
				3924	ASSERT_EQUAL_64(0x00000020, x2);
				3925	ASSERT_EQUAL_64(0x0000000f, x3);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3926	ASSERT_EQUAL_64(0xffffffe0ffffffe0, x4);
				3927	ASSERT_EQUAL_64(0x0000000f0000000f, x5);
				3928	ASSERT_EQUAL_64(0xffffffe0ffffffe1, x6);
				3929	ASSERT_EQUAL_64(0x0000000f0000000f, x7);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3930	ASSERT_EQUAL_64(0x00000001, x8);
				3931	ASSERT_EQUAL_64(0xffffffff, x9);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3932	ASSERT_EQUAL_64(0x0000001f00000020, x10);
				3933	ASSERT_EQUAL_64(0xfffffff0fffffff0, x11);
				3934	ASSERT_EQUAL_64(0xfffffff0fffffff1, x12);
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	3935	ASSERT_EQUAL_64(0x0000000f, x13);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3936	ASSERT_EQUAL_64(0x0000000f0000000f, x14);
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	3937	ASSERT_EQUAL_64(0x0000000f, x15);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3938	ASSERT_EQUAL_64(0x0000000f0000000f, x17);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3939
				3940	TEARDOWN();
				3941	}
				3942
				3943
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3944	TEST(csel_imm) {
				3945	SETUP();
				3946
				3947	START();
				3948	__ Mov(x18, 0);
				3949	__ Mov(x19, 0x80000000);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3950	__ Mov(x20, 0x8000000000000000);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3951
				3952	__ Cmp(x18, Operand(0));
				3953	__ Csel(w0, w19, -2, ne);
				3954	__ Csel(w1, w19, -1, ne);
				3955	__ Csel(w2, w19, 0, ne);
				3956	__ Csel(w3, w19, 1, ne);
				3957	__ Csel(w4, w19, 2, ne);
				3958	__ Csel(w5, w19, Operand(w19, ASR, 31), ne);
				3959	__ Csel(w6, w19, Operand(w19, ROR, 1), ne);
				3960	__ Csel(w7, w19, 3, eq);
				3961
				3962	__ Csel(x8, x20, -2, ne);
				3963	__ Csel(x9, x20, -1, ne);
				3964	__ Csel(x10, x20, 0, ne);
				3965	__ Csel(x11, x20, 1, ne);
				3966	__ Csel(x12, x20, 2, ne);
				3967	__ Csel(x13, x20, Operand(x20, ASR, 63), ne);
				3968	__ Csel(x14, x20, Operand(x20, ROR, 1), ne);
				3969	__ Csel(x15, x20, 3, eq);
				3970
				3971	END();
				3972
				3973	RUN();
				3974
				3975	ASSERT_EQUAL_32(-2, w0);
				3976	ASSERT_EQUAL_32(-1, w1);
				3977	ASSERT_EQUAL_32(0, w2);
				3978	ASSERT_EQUAL_32(1, w3);
				3979	ASSERT_EQUAL_32(2, w4);
				3980	ASSERT_EQUAL_32(-1, w5);
				3981	ASSERT_EQUAL_32(0x40000000, w6);
				3982	ASSERT_EQUAL_32(0x80000000, w7);
				3983
				3984	ASSERT_EQUAL_64(-2, x8);
				3985	ASSERT_EQUAL_64(-1, x9);
				3986	ASSERT_EQUAL_64(0, x10);
				3987	ASSERT_EQUAL_64(1, x11);
				3988	ASSERT_EQUAL_64(2, x12);
				3989	ASSERT_EQUAL_64(-1, x13);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	3990	ASSERT_EQUAL_64(0x4000000000000000, x14);
				3991	ASSERT_EQUAL_64(0x8000000000000000, x15);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	3992
				3993	TEARDOWN();
				3994	}
				3995
				3996
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	3997	TEST(lslv) {
				3998	SETUP();
				3999
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4000	uint64_t value = 0x0123456789abcdef;
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4001	int shift[] = {1, 3, 5, 9, 17, 33};
				4002
				4003	START();
				4004	__ Mov(x0, value);
				4005	__ Mov(w1, shift[0]);
				4006	__ Mov(w2, shift[1]);
				4007	__ Mov(w3, shift[2]);
				4008	__ Mov(w4, shift[3]);
				4009	__ Mov(w5, shift[4]);
				4010	__ Mov(w6, shift[5]);
				4011
				4012	__ lslv(x0, x0, xzr);
				4013
				4014	__ Lsl(x16, x0, x1);
				4015	__ Lsl(x17, x0, x2);
				4016	__ Lsl(x18, x0, x3);
				4017	__ Lsl(x19, x0, x4);
				4018	__ Lsl(x20, x0, x5);
				4019	__ Lsl(x21, x0, x6);
				4020
				4021	__ Lsl(w22, w0, w1);
				4022	__ Lsl(w23, w0, w2);
				4023	__ Lsl(w24, w0, w3);
				4024	__ Lsl(w25, w0, w4);
				4025	__ Lsl(w26, w0, w5);
				4026	__ Lsl(w27, w0, w6);
				4027	END();
				4028
				4029	RUN();
				4030
				4031	ASSERT_EQUAL_64(value, x0);
				4032	ASSERT_EQUAL_64(value << (shift[0] & 63), x16);
				4033	ASSERT_EQUAL_64(value << (shift[1] & 63), x17);
				4034	ASSERT_EQUAL_64(value << (shift[2] & 63), x18);
				4035	ASSERT_EQUAL_64(value << (shift[3] & 63), x19);
				4036	ASSERT_EQUAL_64(value << (shift[4] & 63), x20);
				4037	ASSERT_EQUAL_64(value << (shift[5] & 63), x21);
				4038	ASSERT_EQUAL_32(value << (shift[0] & 31), w22);
				4039	ASSERT_EQUAL_32(value << (shift[1] & 31), w23);
				4040	ASSERT_EQUAL_32(value << (shift[2] & 31), w24);
				4041	ASSERT_EQUAL_32(value << (shift[3] & 31), w25);
				4042	ASSERT_EQUAL_32(value << (shift[4] & 31), w26);
				4043	ASSERT_EQUAL_32(value << (shift[5] & 31), w27);
				4044
				4045	TEARDOWN();
				4046	}
				4047
				4048
				4049	TEST(lsrv) {
				4050	SETUP();
				4051
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4052	uint64_t value = 0x0123456789abcdef;
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4053	int shift[] = {1, 3, 5, 9, 17, 33};
				4054
				4055	START();
				4056	__ Mov(x0, value);
				4057	__ Mov(w1, shift[0]);
				4058	__ Mov(w2, shift[1]);
				4059	__ Mov(w3, shift[2]);
				4060	__ Mov(w4, shift[3]);
				4061	__ Mov(w5, shift[4]);
				4062	__ Mov(w6, shift[5]);
				4063
				4064	__ lsrv(x0, x0, xzr);
				4065
				4066	__ Lsr(x16, x0, x1);
				4067	__ Lsr(x17, x0, x2);
				4068	__ Lsr(x18, x0, x3);
				4069	__ Lsr(x19, x0, x4);
				4070	__ Lsr(x20, x0, x5);
				4071	__ Lsr(x21, x0, x6);
				4072
				4073	__ Lsr(w22, w0, w1);
				4074	__ Lsr(w23, w0, w2);
				4075	__ Lsr(w24, w0, w3);
				4076	__ Lsr(w25, w0, w4);
				4077	__ Lsr(w26, w0, w5);
				4078	__ Lsr(w27, w0, w6);
				4079	END();
				4080
				4081	RUN();
				4082
				4083	ASSERT_EQUAL_64(value, x0);
				4084	ASSERT_EQUAL_64(value >> (shift[0] & 63), x16);
				4085	ASSERT_EQUAL_64(value >> (shift[1] & 63), x17);
				4086	ASSERT_EQUAL_64(value >> (shift[2] & 63), x18);
				4087	ASSERT_EQUAL_64(value >> (shift[3] & 63), x19);
				4088	ASSERT_EQUAL_64(value >> (shift[4] & 63), x20);
				4089	ASSERT_EQUAL_64(value >> (shift[5] & 63), x21);
				4090
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4091	value &= 0xffffffff;
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4092	ASSERT_EQUAL_32(value >> (shift[0] & 31), w22);
				4093	ASSERT_EQUAL_32(value >> (shift[1] & 31), w23);
				4094	ASSERT_EQUAL_32(value >> (shift[2] & 31), w24);
				4095	ASSERT_EQUAL_32(value >> (shift[3] & 31), w25);
				4096	ASSERT_EQUAL_32(value >> (shift[4] & 31), w26);
				4097	ASSERT_EQUAL_32(value >> (shift[5] & 31), w27);
				4098
				4099	TEARDOWN();
				4100	}
				4101
				4102
				4103	TEST(asrv) {
				4104	SETUP();
				4105
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4106	int64_t value = 0xfedcba98fedcba98;
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4107	int shift[] = {1, 3, 5, 9, 17, 33};
				4108
				4109	START();
				4110	__ Mov(x0, value);
				4111	__ Mov(w1, shift[0]);
				4112	__ Mov(w2, shift[1]);
				4113	__ Mov(w3, shift[2]);
				4114	__ Mov(w4, shift[3]);
				4115	__ Mov(w5, shift[4]);
				4116	__ Mov(w6, shift[5]);
				4117
				4118	__ asrv(x0, x0, xzr);
				4119
				4120	__ Asr(x16, x0, x1);
				4121	__ Asr(x17, x0, x2);
				4122	__ Asr(x18, x0, x3);
				4123	__ Asr(x19, x0, x4);
				4124	__ Asr(x20, x0, x5);
				4125	__ Asr(x21, x0, x6);
				4126
				4127	__ Asr(w22, w0, w1);
				4128	__ Asr(w23, w0, w2);
				4129	__ Asr(w24, w0, w3);
				4130	__ Asr(w25, w0, w4);
				4131	__ Asr(w26, w0, w5);
				4132	__ Asr(w27, w0, w6);
				4133	END();
				4134
				4135	RUN();
				4136
				4137	ASSERT_EQUAL_64(value, x0);
				4138	ASSERT_EQUAL_64(value >> (shift[0] & 63), x16);
				4139	ASSERT_EQUAL_64(value >> (shift[1] & 63), x17);
				4140	ASSERT_EQUAL_64(value >> (shift[2] & 63), x18);
				4141	ASSERT_EQUAL_64(value >> (shift[3] & 63), x19);
				4142	ASSERT_EQUAL_64(value >> (shift[4] & 63), x20);
				4143	ASSERT_EQUAL_64(value >> (shift[5] & 63), x21);
				4144
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4145	int32_t value32 = static_cast<int32_t>(value & 0xffffffff);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4146	ASSERT_EQUAL_32(value32 >> (shift[0] & 31), w22);
				4147	ASSERT_EQUAL_32(value32 >> (shift[1] & 31), w23);
				4148	ASSERT_EQUAL_32(value32 >> (shift[2] & 31), w24);
				4149	ASSERT_EQUAL_32(value32 >> (shift[3] & 31), w25);
				4150	ASSERT_EQUAL_32(value32 >> (shift[4] & 31), w26);
				4151	ASSERT_EQUAL_32(value32 >> (shift[5] & 31), w27);
				4152
				4153	TEARDOWN();
				4154	}
				4155
				4156
				4157	TEST(rorv) {
				4158	SETUP();
				4159
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4160	uint64_t value = 0x0123456789abcdef;
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4161	int shift[] = {4, 8, 12, 16, 24, 36};
				4162
				4163	START();
				4164	__ Mov(x0, value);
				4165	__ Mov(w1, shift[0]);
				4166	__ Mov(w2, shift[1]);
				4167	__ Mov(w3, shift[2]);
				4168	__ Mov(w4, shift[3]);
				4169	__ Mov(w5, shift[4]);
				4170	__ Mov(w6, shift[5]);
				4171
				4172	__ rorv(x0, x0, xzr);
				4173
				4174	__ Ror(x16, x0, x1);
				4175	__ Ror(x17, x0, x2);
				4176	__ Ror(x18, x0, x3);
				4177	__ Ror(x19, x0, x4);
				4178	__ Ror(x20, x0, x5);
				4179	__ Ror(x21, x0, x6);
				4180
				4181	__ Ror(w22, w0, w1);
				4182	__ Ror(w23, w0, w2);
				4183	__ Ror(w24, w0, w3);
				4184	__ Ror(w25, w0, w4);
				4185	__ Ror(w26, w0, w5);
				4186	__ Ror(w27, w0, w6);
				4187	END();
				4188
				4189	RUN();
				4190
				4191	ASSERT_EQUAL_64(value, x0);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4192	ASSERT_EQUAL_64(0xf0123456789abcde, x16);
				4193	ASSERT_EQUAL_64(0xef0123456789abcd, x17);
				4194	ASSERT_EQUAL_64(0xdef0123456789abc, x18);
				4195	ASSERT_EQUAL_64(0xcdef0123456789ab, x19);
				4196	ASSERT_EQUAL_64(0xabcdef0123456789, x20);
				4197	ASSERT_EQUAL_64(0x789abcdef0123456, x21);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4198	ASSERT_EQUAL_32(0xf89abcde, w22);
				4199	ASSERT_EQUAL_32(0xef89abcd, w23);
				4200	ASSERT_EQUAL_32(0xdef89abc, w24);
				4201	ASSERT_EQUAL_32(0xcdef89ab, w25);
				4202	ASSERT_EQUAL_32(0xabcdef89, w26);
				4203	ASSERT_EQUAL_32(0xf89abcde, w27);
				4204
				4205	TEARDOWN();
				4206	}
				4207
				4208
				4209	TEST(bfm) {
				4210	SETUP();
				4211
				4212	START();
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4213	__ Mov(x1, 0x0123456789abcdef);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4214
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4215	__ Mov(x10, 0x8888888888888888);
				4216	__ Mov(x11, 0x8888888888888888);
				4217	__ Mov(x12, 0x8888888888888888);
				4218	__ Mov(x13, 0x8888888888888888);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4219	__ Mov(w20, 0x88888888);
				4220	__ Mov(w21, 0x88888888);
				4221
				4222	__ bfm(x10, x1, 16, 31);
				4223	__ bfm(x11, x1, 32, 15);
				4224
				4225	__ bfm(w20, w1, 16, 23);
				4226	__ bfm(w21, w1, 24, 15);
				4227
				4228	// Aliases.
				4229	__ Bfi(x12, x1, 16, 8);
				4230	__ Bfxil(x13, x1, 16, 8);
				4231	END();
				4232
				4233	RUN();
				4234
				4235
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4236	ASSERT_EQUAL_64(0x88888888888889ab, x10);
				4237	ASSERT_EQUAL_64(0x8888cdef88888888, x11);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4238
				4239	ASSERT_EQUAL_32(0x888888ab, w20);
				4240	ASSERT_EQUAL_32(0x88cdef88, w21);
				4241
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4242	ASSERT_EQUAL_64(0x8888888888ef8888, x12);
				4243	ASSERT_EQUAL_64(0x88888888888888ab, x13);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4244
				4245	TEARDOWN();
				4246	}
				4247
				4248
				4249	TEST(sbfm) {
				4250	SETUP();
				4251
				4252	START();
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4253	__ Mov(x1, 0x0123456789abcdef);
				4254	__ Mov(x2, 0xfedcba9876543210);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4255
				4256	__ sbfm(x10, x1, 16, 31);
				4257	__ sbfm(x11, x1, 32, 15);
				4258	__ sbfm(x12, x1, 32, 47);
				4259	__ sbfm(x13, x1, 48, 35);
				4260
				4261	__ sbfm(w14, w1, 16, 23);
				4262	__ sbfm(w15, w1, 24, 15);
				4263	__ sbfm(w16, w2, 16, 23);
				4264	__ sbfm(w17, w2, 24, 15);
				4265
				4266	// Aliases.
				4267	__ Asr(x18, x1, 32);
				4268	__ Asr(x19, x2, 32);
				4269	__ Sbfiz(x20, x1, 8, 16);
				4270	__ Sbfiz(x21, x2, 8, 16);
				4271	__ Sbfx(x22, x1, 8, 16);
				4272	__ Sbfx(x23, x2, 8, 16);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	4273	__ Sxtb(x24, w1);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4274	__ Sxtb(x25, x2);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	4275	__ Sxth(x26, w1);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4276	__ Sxth(x27, x2);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	4277	__ Sxtw(x28, w1);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4278	__ Sxtw(x29, x2);
				4279	END();
				4280
				4281	RUN();
				4282
				4283
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4284	ASSERT_EQUAL_64(0xffffffffffff89ab, x10);
				4285	ASSERT_EQUAL_64(0xffffcdef00000000, x11);
				4286	ASSERT_EQUAL_64(0x0000000000004567, x12);
				4287	ASSERT_EQUAL_64(0x000789abcdef0000, x13);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4288
				4289	ASSERT_EQUAL_32(0xffffffab, w14);
				4290	ASSERT_EQUAL_32(0xffcdef00, w15);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4291	ASSERT_EQUAL_32(0x00000054, w16);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4292	ASSERT_EQUAL_32(0x00321000, w17);
				4293
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4294	ASSERT_EQUAL_64(0x0000000001234567, x18);
				4295	ASSERT_EQUAL_64(0xfffffffffedcba98, x19);
				4296	ASSERT_EQUAL_64(0xffffffffffcdef00, x20);
				4297	ASSERT_EQUAL_64(0x0000000000321000, x21);
				4298	ASSERT_EQUAL_64(0xffffffffffffabcd, x22);
				4299	ASSERT_EQUAL_64(0x0000000000005432, x23);
				4300	ASSERT_EQUAL_64(0xffffffffffffffef, x24);
				4301	ASSERT_EQUAL_64(0x0000000000000010, x25);
				4302	ASSERT_EQUAL_64(0xffffffffffffcdef, x26);
				4303	ASSERT_EQUAL_64(0x0000000000003210, x27);
				4304	ASSERT_EQUAL_64(0xffffffff89abcdef, x28);
				4305	ASSERT_EQUAL_64(0x0000000076543210, x29);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4306
				4307	TEARDOWN();
				4308	}
				4309
				4310
				4311	TEST(ubfm) {
				4312	SETUP();
				4313
				4314	START();
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4315	__ Mov(x1, 0x0123456789abcdef);
				4316	__ Mov(x2, 0xfedcba9876543210);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4317
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4318	__ Mov(x10, 0x8888888888888888);
				4319	__ Mov(x11, 0x8888888888888888);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4320
				4321	__ ubfm(x10, x1, 16, 31);
				4322	__ ubfm(x11, x1, 32, 15);
				4323	__ ubfm(x12, x1, 32, 47);
				4324	__ ubfm(x13, x1, 48, 35);
				4325
				4326	__ ubfm(w25, w1, 16, 23);
				4327	__ ubfm(w26, w1, 24, 15);
				4328	__ ubfm(w27, w2, 16, 23);
				4329	__ ubfm(w28, w2, 24, 15);
				4330
				4331	// Aliases
				4332	__ Lsl(x15, x1, 63);
				4333	__ Lsl(x16, x1, 0);
				4334	__ Lsr(x17, x1, 32);
				4335	__ Ubfiz(x18, x1, 8, 16);
				4336	__ Ubfx(x19, x1, 8, 16);
				4337	__ Uxtb(x20, x1);
				4338	__ Uxth(x21, x1);
				4339	__ Uxtw(x22, x1);
				4340	END();
				4341
				4342	RUN();
				4343
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4344	ASSERT_EQUAL_64(0x00000000000089ab, x10);
				4345	ASSERT_EQUAL_64(0x0000cdef00000000, x11);
				4346	ASSERT_EQUAL_64(0x0000000000004567, x12);
				4347	ASSERT_EQUAL_64(0x000789abcdef0000, x13);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4348
				4349	ASSERT_EQUAL_32(0x000000ab, w25);
				4350	ASSERT_EQUAL_32(0x00cdef00, w26);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4351	ASSERT_EQUAL_32(0x00000054, w27);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4352	ASSERT_EQUAL_32(0x00321000, w28);
				4353
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4354	ASSERT_EQUAL_64(0x8000000000000000, x15);
				4355	ASSERT_EQUAL_64(0x0123456789abcdef, x16);
				4356	ASSERT_EQUAL_64(0x0000000001234567, x17);
				4357	ASSERT_EQUAL_64(0x0000000000cdef00, x18);
				4358	ASSERT_EQUAL_64(0x000000000000abcd, x19);
				4359	ASSERT_EQUAL_64(0x00000000000000ef, x20);
				4360	ASSERT_EQUAL_64(0x000000000000cdef, x21);
				4361	ASSERT_EQUAL_64(0x0000000089abcdef, x22);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4362
				4363	TEARDOWN();
				4364	}
				4365
				4366
				4367	TEST(extr) {
				4368	SETUP();
				4369
				4370	START();
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4371	__ Mov(x1, 0x0123456789abcdef);
				4372	__ Mov(x2, 0xfedcba9876543210);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4373
				4374	__ Extr(w10, w1, w2, 0);
				4375	__ Extr(w11, w1, w2, 1);
				4376	__ Extr(x12, x2, x1, 2);
				4377
				4378	__ Ror(w13, w1, 0);
				4379	__ Ror(w14, w2, 17);
				4380	__ Ror(w15, w1, 31);
				4381	__ Ror(x18, x2, 1);
				4382	__ Ror(x19, x1, 63);
				4383	END();
				4384
				4385	RUN();
				4386
				4387	ASSERT_EQUAL_64(0x76543210, x10);
				4388	ASSERT_EQUAL_64(0xbb2a1908, x11);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4389	ASSERT_EQUAL_64(0x0048d159e26af37b, x12);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4390	ASSERT_EQUAL_64(0x89abcdef, x13);
				4391	ASSERT_EQUAL_64(0x19083b2a, x14);
				4392	ASSERT_EQUAL_64(0x13579bdf, x15);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4393	ASSERT_EQUAL_64(0x7f6e5d4c3b2a1908, x18);
				4394	ASSERT_EQUAL_64(0x02468acf13579bde, x19);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4395
				4396	TEARDOWN();
				4397	}
				4398
				4399
				4400	TEST(fmov_imm) {
				4401	SETUP();
				4402
				4403	START();
				4404	__ Fmov(s11, 1.0);
				4405	__ Fmov(d22, -13.0);
				4406	__ Fmov(s1, 255.0);
				4407	__ Fmov(d2, 12.34567);
				4408	__ Fmov(s3, 0.0);
				4409	__ Fmov(d4, 0.0);
				4410	__ Fmov(s5, kFP32PositiveInfinity);
				4411	__ Fmov(d6, kFP64NegativeInfinity);
				4412	END();
				4413
				4414	RUN();
				4415
				4416	ASSERT_EQUAL_FP32(1.0, s11);
				4417	ASSERT_EQUAL_FP64(-13.0, d22);
				4418	ASSERT_EQUAL_FP32(255.0, s1);
				4419	ASSERT_EQUAL_FP64(12.34567, d2);
				4420	ASSERT_EQUAL_FP32(0.0, s3);
				4421	ASSERT_EQUAL_FP64(0.0, d4);
				4422	ASSERT_EQUAL_FP32(kFP32PositiveInfinity, s5);
				4423	ASSERT_EQUAL_FP64(kFP64NegativeInfinity, d6);
				4424
				4425	TEARDOWN();
				4426	}
				4427
				4428
				4429	TEST(fmov_reg) {
				4430	SETUP();
				4431
				4432	START();
				4433	__ Fmov(s20, 1.0);
				4434	__ Fmov(w10, s20);
				4435	__ Fmov(s30, w10);
				4436	__ Fmov(s5, s20);
				4437	__ Fmov(d1, -13.0);
				4438	__ Fmov(x1, d1);
				4439	__ Fmov(d2, x1);
				4440	__ Fmov(d4, d1);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4441	__ Fmov(d6, rawbits_to_double(0x0123456789abcdef));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4442	__ Fmov(s6, s6);
				4443	END();
				4444
				4445	RUN();
				4446
				4447	ASSERT_EQUAL_32(float_to_rawbits(1.0), w10);
				4448	ASSERT_EQUAL_FP32(1.0, s30);
				4449	ASSERT_EQUAL_FP32(1.0, s5);
				4450	ASSERT_EQUAL_64(double_to_rawbits(-13.0), x1);
				4451	ASSERT_EQUAL_FP64(-13.0, d2);
				4452	ASSERT_EQUAL_FP64(-13.0, d4);
				4453	ASSERT_EQUAL_FP32(rawbits_to_float(0x89abcdef), s6);
				4454
				4455	TEARDOWN();
				4456	}
				4457
				4458
				4459	TEST(fadd) {
				4460	SETUP();
				4461
				4462	START();
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4463	__ Fmov(s14, -0.0f);
				4464	__ Fmov(s15, kFP32PositiveInfinity);
				4465	__ Fmov(s16, kFP32NegativeInfinity);
				4466	__ Fmov(s17, 3.25f);
				4467	__ Fmov(s18, 1.0f);
				4468	__ Fmov(s19, 0.0f);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4469
				4470	__ Fmov(d26, -0.0);
				4471	__ Fmov(d27, kFP64PositiveInfinity);
				4472	__ Fmov(d28, kFP64NegativeInfinity);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4473	__ Fmov(d29, 0.0);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4474	__ Fmov(d30, -2.0);
				4475	__ Fmov(d31, 2.25);
				4476
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4477	__ Fadd(s0, s17, s18);
				4478	__ Fadd(s1, s18, s19);
				4479	__ Fadd(s2, s14, s18);
				4480	__ Fadd(s3, s15, s18);
				4481	__ Fadd(s4, s16, s18);
				4482	__ Fadd(s5, s15, s16);
				4483	__ Fadd(s6, s16, s15);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4484
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4485	__ Fadd(d7, d30, d31);
				4486	__ Fadd(d8, d29, d31);
				4487	__ Fadd(d9, d26, d31);
				4488	__ Fadd(d10, d27, d31);
				4489	__ Fadd(d11, d28, d31);
				4490	__ Fadd(d12, d27, d28);
				4491	__ Fadd(d13, d28, d27);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4492	END();
				4493
				4494	RUN();
				4495
				4496	ASSERT_EQUAL_FP32(4.25, s0);
				4497	ASSERT_EQUAL_FP32(1.0, s1);
				4498	ASSERT_EQUAL_FP32(1.0, s2);
				4499	ASSERT_EQUAL_FP32(kFP32PositiveInfinity, s3);
				4500	ASSERT_EQUAL_FP32(kFP32NegativeInfinity, s4);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4501	ASSERT_EQUAL_FP32(kFP32DefaultNaN, s5);
				4502	ASSERT_EQUAL_FP32(kFP32DefaultNaN, s6);
				4503	ASSERT_EQUAL_FP64(0.25, d7);
				4504	ASSERT_EQUAL_FP64(2.25, d8);
				4505	ASSERT_EQUAL_FP64(2.25, d9);
				4506	ASSERT_EQUAL_FP64(kFP64PositiveInfinity, d10);
				4507	ASSERT_EQUAL_FP64(kFP64NegativeInfinity, d11);
				4508	ASSERT_EQUAL_FP64(kFP64DefaultNaN, d12);
				4509	ASSERT_EQUAL_FP64(kFP64DefaultNaN, d13);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4510
				4511	TEARDOWN();
				4512	}
				4513
				4514
				4515	TEST(fsub) {
				4516	SETUP();
				4517
				4518	START();
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4519	__ Fmov(s14, -0.0f);
				4520	__ Fmov(s15, kFP32PositiveInfinity);
				4521	__ Fmov(s16, kFP32NegativeInfinity);
				4522	__ Fmov(s17, 3.25f);
				4523	__ Fmov(s18, 1.0f);
				4524	__ Fmov(s19, 0.0f);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4525
				4526	__ Fmov(d26, -0.0);
				4527	__ Fmov(d27, kFP64PositiveInfinity);
				4528	__ Fmov(d28, kFP64NegativeInfinity);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4529	__ Fmov(d29, 0.0);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4530	__ Fmov(d30, -2.0);
				4531	__ Fmov(d31, 2.25);
				4532
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4533	__ Fsub(s0, s17, s18);
				4534	__ Fsub(s1, s18, s19);
				4535	__ Fsub(s2, s14, s18);
				4536	__ Fsub(s3, s18, s15);
				4537	__ Fsub(s4, s18, s16);
				4538	__ Fsub(s5, s15, s15);
				4539	__ Fsub(s6, s16, s16);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4540
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4541	__ Fsub(d7, d30, d31);
				4542	__ Fsub(d8, d29, d31);
				4543	__ Fsub(d9, d26, d31);
				4544	__ Fsub(d10, d31, d27);
				4545	__ Fsub(d11, d31, d28);
				4546	__ Fsub(d12, d27, d27);
				4547	__ Fsub(d13, d28, d28);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4548	END();
				4549
				4550	RUN();
				4551
				4552	ASSERT_EQUAL_FP32(2.25, s0);
				4553	ASSERT_EQUAL_FP32(1.0, s1);
				4554	ASSERT_EQUAL_FP32(-1.0, s2);
				4555	ASSERT_EQUAL_FP32(kFP32NegativeInfinity, s3);
				4556	ASSERT_EQUAL_FP32(kFP32PositiveInfinity, s4);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4557	ASSERT_EQUAL_FP32(kFP32DefaultNaN, s5);
				4558	ASSERT_EQUAL_FP32(kFP32DefaultNaN, s6);
				4559	ASSERT_EQUAL_FP64(-4.25, d7);
				4560	ASSERT_EQUAL_FP64(-2.25, d8);
				4561	ASSERT_EQUAL_FP64(-2.25, d9);
				4562	ASSERT_EQUAL_FP64(kFP64NegativeInfinity, d10);
				4563	ASSERT_EQUAL_FP64(kFP64PositiveInfinity, d11);
				4564	ASSERT_EQUAL_FP64(kFP64DefaultNaN, d12);
				4565	ASSERT_EQUAL_FP64(kFP64DefaultNaN, d13);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4566
				4567	TEARDOWN();
				4568	}
				4569
				4570
				4571	TEST(fmul) {
				4572	SETUP();
				4573
				4574	START();
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4575	__ Fmov(s14, -0.0f);
				4576	__ Fmov(s15, kFP32PositiveInfinity);
				4577	__ Fmov(s16, kFP32NegativeInfinity);
				4578	__ Fmov(s17, 3.25f);
				4579	__ Fmov(s18, 2.0f);
				4580	__ Fmov(s19, 0.0f);
				4581	__ Fmov(s20, -2.0f);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4582
				4583	__ Fmov(d26, -0.0);
				4584	__ Fmov(d27, kFP64PositiveInfinity);
				4585	__ Fmov(d28, kFP64NegativeInfinity);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4586	__ Fmov(d29, 0.0);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4587	__ Fmov(d30, -2.0);
				4588	__ Fmov(d31, 2.25);
				4589
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4590	__ Fmul(s0, s17, s18);
				4591	__ Fmul(s1, s18, s19);
				4592	__ Fmul(s2, s14, s14);
				4593	__ Fmul(s3, s15, s20);
				4594	__ Fmul(s4, s16, s20);
				4595	__ Fmul(s5, s15, s19);
				4596	__ Fmul(s6, s19, s16);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4597
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4598	__ Fmul(d7, d30, d31);
				4599	__ Fmul(d8, d29, d31);
				4600	__ Fmul(d9, d26, d26);
				4601	__ Fmul(d10, d27, d30);
				4602	__ Fmul(d11, d28, d30);
				4603	__ Fmul(d12, d27, d29);
				4604	__ Fmul(d13, d29, d28);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4605	END();
				4606
				4607	RUN();
				4608
				4609	ASSERT_EQUAL_FP32(6.5, s0);
				4610	ASSERT_EQUAL_FP32(0.0, s1);
				4611	ASSERT_EQUAL_FP32(0.0, s2);
				4612	ASSERT_EQUAL_FP32(kFP32NegativeInfinity, s3);
				4613	ASSERT_EQUAL_FP32(kFP32PositiveInfinity, s4);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4614	ASSERT_EQUAL_FP32(kFP32DefaultNaN, s5);
				4615	ASSERT_EQUAL_FP32(kFP32DefaultNaN, s6);
				4616	ASSERT_EQUAL_FP64(-4.5, d7);
				4617	ASSERT_EQUAL_FP64(0.0, d8);
				4618	ASSERT_EQUAL_FP64(0.0, d9);
				4619	ASSERT_EQUAL_FP64(kFP64NegativeInfinity, d10);
				4620	ASSERT_EQUAL_FP64(kFP64PositiveInfinity, d11);
				4621	ASSERT_EQUAL_FP64(kFP64DefaultNaN, d12);
				4622	ASSERT_EQUAL_FP64(kFP64DefaultNaN, d13);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4623
				4624	TEARDOWN();
				4625	}
				4626
				4627
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4628	static void FmaddFmsubHelper(double n, double m, double a,
				4629	double fmadd, double fmsub,
				4630	double fnmadd, double fnmsub) {
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4631	SETUP();
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4632	START();
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4633
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	4634	__ Fmov(d0, n);
				4635	__ Fmov(d1, m);
				4636	__ Fmov(d2, a);
				4637	__ Fmadd(d28, d0, d1, d2);
				4638	__ Fmsub(d29, d0, d1, d2);
				4639	__ Fnmadd(d30, d0, d1, d2);
				4640	__ Fnmsub(d31, d0, d1, d2);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4641
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4642	END();
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4643	RUN();
				4644
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	4645	ASSERT_EQUAL_FP64(fmadd, d28);
				4646	ASSERT_EQUAL_FP64(fmsub, d29);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4647	ASSERT_EQUAL_FP64(fnmadd, d30);
				4648	ASSERT_EQUAL_FP64(fnmsub, d31);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4649
				4650	TEARDOWN();
				4651	}
				4652
				4653
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	4654	TEST(fmadd_fmsub_double) {
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4655	// It's hard to check the result of fused operations because the only way to
				4656	// calculate the result is using fma, which is what the simulator uses anyway.
				4657	// TODO(jbramley): Add tests to check behaviour against a hardware trace.
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	4658
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4659	// Basic operation.
				4660	FmaddFmsubHelper(1.0, 2.0, 3.0, 5.0, 1.0, -5.0, -1.0);
				4661	FmaddFmsubHelper(-1.0, 2.0, 3.0, 1.0, 5.0, -1.0, -5.0);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	4662
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4663	// Check the sign of exact zeroes.
				4664	// n m a fmadd fmsub fnmadd fnmsub
				4665	FmaddFmsubHelper(-0.0, +0.0, -0.0, -0.0, +0.0, +0.0, +0.0);
				4666	FmaddFmsubHelper(+0.0, +0.0, -0.0, +0.0, -0.0, +0.0, +0.0);
				4667	FmaddFmsubHelper(+0.0, +0.0, +0.0, +0.0, +0.0, -0.0, +0.0);
				4668	FmaddFmsubHelper(-0.0, +0.0, +0.0, +0.0, +0.0, +0.0, -0.0);
				4669	FmaddFmsubHelper(+0.0, -0.0, -0.0, -0.0, +0.0, +0.0, +0.0);
				4670	FmaddFmsubHelper(-0.0, -0.0, -0.0, +0.0, -0.0, +0.0, +0.0);
				4671	FmaddFmsubHelper(-0.0, -0.0, +0.0, +0.0, +0.0, -0.0, +0.0);
				4672	FmaddFmsubHelper(+0.0, -0.0, +0.0, +0.0, +0.0, +0.0, -0.0);
				4673
				4674	// Check NaN generation.
				4675	FmaddFmsubHelper(kFP64PositiveInfinity, 0.0, 42.0,
				4676	kFP64DefaultNaN, kFP64DefaultNaN,
				4677	kFP64DefaultNaN, kFP64DefaultNaN);
				4678	FmaddFmsubHelper(0.0, kFP64PositiveInfinity, 42.0,
				4679	kFP64DefaultNaN, kFP64DefaultNaN,
				4680	kFP64DefaultNaN, kFP64DefaultNaN);
				4681	FmaddFmsubHelper(kFP64PositiveInfinity, 1.0, kFP64PositiveInfinity,
				4682	kFP64PositiveInfinity, // inf + ( inf * 1) = inf
				4683	kFP64DefaultNaN, // inf + (-inf * 1) = NaN
				4684	kFP64NegativeInfinity, // -inf + (-inf * 1) = -inf
				4685	kFP64DefaultNaN); // -inf + ( inf * 1) = NaN
				4686	FmaddFmsubHelper(kFP64NegativeInfinity, 1.0, kFP64PositiveInfinity,
				4687	kFP64DefaultNaN, // inf + (-inf * 1) = NaN
				4688	kFP64PositiveInfinity, // inf + ( inf * 1) = inf
				4689	kFP64DefaultNaN, // -inf + ( inf * 1) = NaN
				4690	kFP64NegativeInfinity); // -inf + (-inf * 1) = -inf
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	4691	}
				4692
				4693
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4694	static void FmaddFmsubHelper(float n, float m, float a,
				4695	float fmadd, float fmsub,
				4696	float fnmadd, float fnmsub) {
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	4697	SETUP();
				4698	START();
				4699
				4700	__ Fmov(s0, n);
				4701	__ Fmov(s1, m);
				4702	__ Fmov(s2, a);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4703	__ Fmadd(s28, s0, s1, s2);
				4704	__ Fmsub(s29, s0, s1, s2);
				4705	__ Fnmadd(s30, s0, s1, s2);
				4706	__ Fnmsub(s31, s0, s1, s2);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	4707
				4708	END();
				4709	RUN();
				4710
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4711	ASSERT_EQUAL_FP32(fmadd, s28);
				4712	ASSERT_EQUAL_FP32(fmsub, s29);
				4713	ASSERT_EQUAL_FP32(fnmadd, s30);
				4714	ASSERT_EQUAL_FP32(fnmsub, s31);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	4715
				4716	TEARDOWN();
				4717	}
				4718
				4719
				4720	TEST(fmadd_fmsub_float) {
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4721	// It's hard to check the result of fused operations because the only way to
				4722	// calculate the result is using fma, which is what the simulator uses anyway.
				4723	// TODO(jbramley): Add tests to check behaviour against a hardware trace.
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	4724
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4725	// Basic operation.
				4726	FmaddFmsubHelper(1.0f, 2.0f, 3.0f, 5.0f, 1.0f, -5.0f, -1.0f);
				4727	FmaddFmsubHelper(-1.0f, 2.0f, 3.0f, 1.0f, 5.0f, -1.0f, -5.0f);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	4728
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4729	// Check the sign of exact zeroes.
				4730	// n m a fmadd fmsub fnmadd fnmsub
				4731	FmaddFmsubHelper(-0.0f, +0.0f, -0.0f, -0.0f, +0.0f, +0.0f, +0.0f);
				4732	FmaddFmsubHelper(+0.0f, +0.0f, -0.0f, +0.0f, -0.0f, +0.0f, +0.0f);
				4733	FmaddFmsubHelper(+0.0f, +0.0f, +0.0f, +0.0f, +0.0f, -0.0f, +0.0f);
				4734	FmaddFmsubHelper(-0.0f, +0.0f, +0.0f, +0.0f, +0.0f, +0.0f, -0.0f);
				4735	FmaddFmsubHelper(+0.0f, -0.0f, -0.0f, -0.0f, +0.0f, +0.0f, +0.0f);
				4736	FmaddFmsubHelper(-0.0f, -0.0f, -0.0f, +0.0f, -0.0f, +0.0f, +0.0f);
				4737	FmaddFmsubHelper(-0.0f, -0.0f, +0.0f, +0.0f, +0.0f, -0.0f, +0.0f);
				4738	FmaddFmsubHelper(+0.0f, -0.0f, +0.0f, +0.0f, +0.0f, +0.0f, -0.0f);
				4739
				4740	// Check NaN generation.
				4741	FmaddFmsubHelper(kFP32PositiveInfinity, 0.0f, 42.0f,
				4742	kFP32DefaultNaN, kFP32DefaultNaN,
				4743	kFP32DefaultNaN, kFP32DefaultNaN);
				4744	FmaddFmsubHelper(0.0f, kFP32PositiveInfinity, 42.0f,
				4745	kFP32DefaultNaN, kFP32DefaultNaN,
				4746	kFP32DefaultNaN, kFP32DefaultNaN);
				4747	FmaddFmsubHelper(kFP32PositiveInfinity, 1.0f, kFP32PositiveInfinity,
				4748	kFP32PositiveInfinity, // inf + ( inf * 1) = inf
				4749	kFP32DefaultNaN, // inf + (-inf * 1) = NaN
				4750	kFP32NegativeInfinity, // -inf + (-inf * 1) = -inf
				4751	kFP32DefaultNaN); // -inf + ( inf * 1) = NaN
				4752	FmaddFmsubHelper(kFP32NegativeInfinity, 1.0f, kFP32PositiveInfinity,
				4753	kFP32DefaultNaN, // inf + (-inf * 1) = NaN
				4754	kFP32PositiveInfinity, // inf + ( inf * 1) = inf
				4755	kFP32DefaultNaN, // -inf + ( inf * 1) = NaN
				4756	kFP32NegativeInfinity); // -inf + (-inf * 1) = -inf
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	4757	}
				4758
				4759
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4760	TEST(fmadd_fmsub_double_nans) {
				4761	// Make sure that NaN propagation works correctly.
				4762	double s1 = rawbits_to_double(0x7ff5555511111111);
				4763	double s2 = rawbits_to_double(0x7ff5555522222222);
				4764	double sa = rawbits_to_double(0x7ff55555aaaaaaaa);
				4765	double q1 = rawbits_to_double(0x7ffaaaaa11111111);
				4766	double q2 = rawbits_to_double(0x7ffaaaaa22222222);
				4767	double qa = rawbits_to_double(0x7ffaaaaaaaaaaaaa);
				4768	VIXL_ASSERT(IsSignallingNaN(s1));
				4769	VIXL_ASSERT(IsSignallingNaN(s2));
				4770	VIXL_ASSERT(IsSignallingNaN(sa));
				4771	VIXL_ASSERT(IsQuietNaN(q1));
				4772	VIXL_ASSERT(IsQuietNaN(q2));
				4773	VIXL_ASSERT(IsQuietNaN(qa));
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	4774
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4775	// The input NaNs after passing through ProcessNaN.
				4776	double s1_proc = rawbits_to_double(0x7ffd555511111111);
				4777	double s2_proc = rawbits_to_double(0x7ffd555522222222);
				4778	double sa_proc = rawbits_to_double(0x7ffd5555aaaaaaaa);
				4779	double q1_proc = q1;
				4780	double q2_proc = q2;
				4781	double qa_proc = qa;
				4782	VIXL_ASSERT(IsQuietNaN(s1_proc));
				4783	VIXL_ASSERT(IsQuietNaN(s2_proc));
				4784	VIXL_ASSERT(IsQuietNaN(sa_proc));
				4785	VIXL_ASSERT(IsQuietNaN(q1_proc));
				4786	VIXL_ASSERT(IsQuietNaN(q2_proc));
				4787	VIXL_ASSERT(IsQuietNaN(qa_proc));
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	4788
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	4789	// Negated NaNs as it would be done on ARMv8 hardware.
				4790	double s1_proc_neg = rawbits_to_double(0xfffd555511111111);
				4791	double sa_proc_neg = rawbits_to_double(0xfffd5555aaaaaaaa);
				4792	double q1_proc_neg = rawbits_to_double(0xfffaaaaa11111111);
				4793	double qa_proc_neg = rawbits_to_double(0xfffaaaaaaaaaaaaa);
				4794	VIXL_ASSERT(IsQuietNaN(s1_proc_neg));
				4795	VIXL_ASSERT(IsQuietNaN(sa_proc_neg));
				4796	VIXL_ASSERT(IsQuietNaN(q1_proc_neg));
				4797	VIXL_ASSERT(IsQuietNaN(qa_proc_neg));
				4798
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4799	// Quiet NaNs are propagated.
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	4800	FmaddFmsubHelper(q1, 0, 0, q1_proc, q1_proc_neg, q1_proc_neg, q1_proc);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4801	FmaddFmsubHelper(0, q2, 0, q2_proc, q2_proc, q2_proc, q2_proc);
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	4802	FmaddFmsubHelper(0, 0, qa, qa_proc, qa_proc, qa_proc_neg, qa_proc_neg);
				4803	FmaddFmsubHelper(q1, q2, 0, q1_proc, q1_proc_neg, q1_proc_neg, q1_proc);
				4804	FmaddFmsubHelper(0, q2, qa, qa_proc, qa_proc, qa_proc_neg, qa_proc_neg);
				4805	FmaddFmsubHelper(q1, 0, qa, qa_proc, qa_proc, qa_proc_neg, qa_proc_neg);
				4806	FmaddFmsubHelper(q1, q2, qa, qa_proc, qa_proc, qa_proc_neg, qa_proc_neg);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	4807
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4808	// Signalling NaNs are propagated, and made quiet.
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	4809	FmaddFmsubHelper(s1, 0, 0, s1_proc, s1_proc_neg, s1_proc_neg, s1_proc);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4810	FmaddFmsubHelper(0, s2, 0, s2_proc, s2_proc, s2_proc, s2_proc);
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	4811	FmaddFmsubHelper(0, 0, sa, sa_proc, sa_proc, sa_proc_neg, sa_proc_neg);
				4812	FmaddFmsubHelper(s1, s2, 0, s1_proc, s1_proc_neg, s1_proc_neg, s1_proc);
				4813	FmaddFmsubHelper(0, s2, sa, sa_proc, sa_proc, sa_proc_neg, sa_proc_neg);
				4814	FmaddFmsubHelper(s1, 0, sa, sa_proc, sa_proc, sa_proc_neg, sa_proc_neg);
				4815	FmaddFmsubHelper(s1, s2, sa, sa_proc, sa_proc, sa_proc_neg, sa_proc_neg);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	4816
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4817	// Signalling NaNs take precedence over quiet NaNs.
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	4818	FmaddFmsubHelper(s1, q2, qa, s1_proc, s1_proc_neg, s1_proc_neg, s1_proc);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4819	FmaddFmsubHelper(q1, s2, qa, s2_proc, s2_proc, s2_proc, s2_proc);
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	4820	FmaddFmsubHelper(q1, q2, sa, sa_proc, sa_proc, sa_proc_neg, sa_proc_neg);
				4821	FmaddFmsubHelper(s1, s2, qa, s1_proc, s1_proc_neg, s1_proc_neg, s1_proc);
				4822	FmaddFmsubHelper(q1, s2, sa, sa_proc, sa_proc, sa_proc_neg, sa_proc_neg);
				4823	FmaddFmsubHelper(s1, q2, sa, sa_proc, sa_proc, sa_proc_neg, sa_proc_neg);
				4824	FmaddFmsubHelper(s1, s2, sa, sa_proc, sa_proc, sa_proc_neg, sa_proc_neg);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	4825
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4826	// A NaN generated by the intermediate op1 * op2 overrides a quiet NaN in a.
				4827	FmaddFmsubHelper(0, kFP64PositiveInfinity, qa,
				4828	kFP64DefaultNaN, kFP64DefaultNaN,
				4829	kFP64DefaultNaN, kFP64DefaultNaN);
				4830	FmaddFmsubHelper(kFP64PositiveInfinity, 0, qa,
				4831	kFP64DefaultNaN, kFP64DefaultNaN,
				4832	kFP64DefaultNaN, kFP64DefaultNaN);
				4833	FmaddFmsubHelper(0, kFP64NegativeInfinity, qa,
				4834	kFP64DefaultNaN, kFP64DefaultNaN,
				4835	kFP64DefaultNaN, kFP64DefaultNaN);
				4836	FmaddFmsubHelper(kFP64NegativeInfinity, 0, qa,
				4837	kFP64DefaultNaN, kFP64DefaultNaN,
				4838	kFP64DefaultNaN, kFP64DefaultNaN);
				4839	}
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	4840
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	4841
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4842	TEST(fmadd_fmsub_float_nans) {
				4843	// Make sure that NaN propagation works correctly.
				4844	float s1 = rawbits_to_float(0x7f951111);
				4845	float s2 = rawbits_to_float(0x7f952222);
				4846	float sa = rawbits_to_float(0x7f95aaaa);
				4847	float q1 = rawbits_to_float(0x7fea1111);
				4848	float q2 = rawbits_to_float(0x7fea2222);
				4849	float qa = rawbits_to_float(0x7feaaaaa);
				4850	VIXL_ASSERT(IsSignallingNaN(s1));
				4851	VIXL_ASSERT(IsSignallingNaN(s2));
				4852	VIXL_ASSERT(IsSignallingNaN(sa));
				4853	VIXL_ASSERT(IsQuietNaN(q1));
				4854	VIXL_ASSERT(IsQuietNaN(q2));
				4855	VIXL_ASSERT(IsQuietNaN(qa));
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	4856
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4857	// The input NaNs after passing through ProcessNaN.
				4858	float s1_proc = rawbits_to_float(0x7fd51111);
				4859	float s2_proc = rawbits_to_float(0x7fd52222);
				4860	float sa_proc = rawbits_to_float(0x7fd5aaaa);
				4861	float q1_proc = q1;
				4862	float q2_proc = q2;
				4863	float qa_proc = qa;
				4864	VIXL_ASSERT(IsQuietNaN(s1_proc));
				4865	VIXL_ASSERT(IsQuietNaN(s2_proc));
				4866	VIXL_ASSERT(IsQuietNaN(sa_proc));
				4867	VIXL_ASSERT(IsQuietNaN(q1_proc));
				4868	VIXL_ASSERT(IsQuietNaN(q2_proc));
				4869	VIXL_ASSERT(IsQuietNaN(qa_proc));
				4870
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	4871	// Negated NaNs as it would be done on ARMv8 hardware.
				4872	float s1_proc_neg = rawbits_to_float(0xffd51111);
				4873	float sa_proc_neg = rawbits_to_float(0xffd5aaaa);
				4874	float q1_proc_neg = rawbits_to_float(0xffea1111);
				4875	float qa_proc_neg = rawbits_to_float(0xffeaaaaa);
				4876	VIXL_ASSERT(IsQuietNaN(s1_proc_neg));
				4877	VIXL_ASSERT(IsQuietNaN(sa_proc_neg));
				4878	VIXL_ASSERT(IsQuietNaN(q1_proc_neg));
				4879	VIXL_ASSERT(IsQuietNaN(qa_proc_neg));
				4880
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4881	// Quiet NaNs are propagated.
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	4882	FmaddFmsubHelper(q1, 0, 0, q1_proc, q1_proc_neg, q1_proc_neg, q1_proc);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4883	FmaddFmsubHelper(0, q2, 0, q2_proc, q2_proc, q2_proc, q2_proc);
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	4884	FmaddFmsubHelper(0, 0, qa, qa_proc, qa_proc, qa_proc_neg, qa_proc_neg);
				4885	FmaddFmsubHelper(q1, q2, 0, q1_proc, q1_proc_neg, q1_proc_neg, q1_proc);
				4886	FmaddFmsubHelper(0, q2, qa, qa_proc, qa_proc, qa_proc_neg, qa_proc_neg);
				4887	FmaddFmsubHelper(q1, 0, qa, qa_proc, qa_proc, qa_proc_neg, qa_proc_neg);
				4888	FmaddFmsubHelper(q1, q2, qa, qa_proc, qa_proc, qa_proc_neg, qa_proc_neg);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4889
				4890	// Signalling NaNs are propagated, and made quiet.
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	4891	FmaddFmsubHelper(s1, 0, 0, s1_proc, s1_proc_neg, s1_proc_neg, s1_proc);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4892	FmaddFmsubHelper(0, s2, 0, s2_proc, s2_proc, s2_proc, s2_proc);
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	4893	FmaddFmsubHelper(0, 0, sa, sa_proc, sa_proc, sa_proc_neg, sa_proc_neg);
				4894	FmaddFmsubHelper(s1, s2, 0, s1_proc, s1_proc_neg, s1_proc_neg, s1_proc);
				4895	FmaddFmsubHelper(0, s2, sa, sa_proc, sa_proc, sa_proc_neg, sa_proc_neg);
				4896	FmaddFmsubHelper(s1, 0, sa, sa_proc, sa_proc, sa_proc_neg, sa_proc_neg);
				4897	FmaddFmsubHelper(s1, s2, sa, sa_proc, sa_proc, sa_proc_neg, sa_proc_neg);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4898
				4899	// Signalling NaNs take precedence over quiet NaNs.
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	4900	FmaddFmsubHelper(s1, q2, qa, s1_proc, s1_proc_neg, s1_proc_neg, s1_proc);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4901	FmaddFmsubHelper(q1, s2, qa, s2_proc, s2_proc, s2_proc, s2_proc);
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	4902	FmaddFmsubHelper(q1, q2, sa, sa_proc, sa_proc, sa_proc_neg, sa_proc_neg);
				4903	FmaddFmsubHelper(s1, s2, qa, s1_proc, s1_proc_neg, s1_proc_neg, s1_proc);
				4904	FmaddFmsubHelper(q1, s2, sa, sa_proc, sa_proc, sa_proc_neg, sa_proc_neg);
				4905	FmaddFmsubHelper(s1, q2, sa, sa_proc, sa_proc, sa_proc_neg, sa_proc_neg);
				4906	FmaddFmsubHelper(s1, s2, sa, sa_proc, sa_proc, sa_proc_neg, sa_proc_neg);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4907
				4908	// A NaN generated by the intermediate op1 * op2 overrides a quiet NaN in a.
				4909	FmaddFmsubHelper(0, kFP32PositiveInfinity, qa,
				4910	kFP32DefaultNaN, kFP32DefaultNaN,
				4911	kFP32DefaultNaN, kFP32DefaultNaN);
				4912	FmaddFmsubHelper(kFP32PositiveInfinity, 0, qa,
				4913	kFP32DefaultNaN, kFP32DefaultNaN,
				4914	kFP32DefaultNaN, kFP32DefaultNaN);
				4915	FmaddFmsubHelper(0, kFP32NegativeInfinity, qa,
				4916	kFP32DefaultNaN, kFP32DefaultNaN,
				4917	kFP32DefaultNaN, kFP32DefaultNaN);
				4918	FmaddFmsubHelper(kFP32NegativeInfinity, 0, qa,
				4919	kFP32DefaultNaN, kFP32DefaultNaN,
				4920	kFP32DefaultNaN, kFP32DefaultNaN);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	4921	}
				4922
				4923
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4924	TEST(fdiv) {
				4925	SETUP();
				4926
				4927	START();
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4928	__ Fmov(s14, -0.0f);
				4929	__ Fmov(s15, kFP32PositiveInfinity);
				4930	__ Fmov(s16, kFP32NegativeInfinity);
				4931	__ Fmov(s17, 3.25f);
				4932	__ Fmov(s18, 2.0f);
				4933	__ Fmov(s19, 2.0f);
				4934	__ Fmov(s20, -2.0f);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4935
				4936	__ Fmov(d26, -0.0);
				4937	__ Fmov(d27, kFP64PositiveInfinity);
				4938	__ Fmov(d28, kFP64NegativeInfinity);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4939	__ Fmov(d29, 0.0);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4940	__ Fmov(d30, -2.0);
				4941	__ Fmov(d31, 2.25);
				4942
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4943	__ Fdiv(s0, s17, s18);
				4944	__ Fdiv(s1, s18, s19);
				4945	__ Fdiv(s2, s14, s18);
				4946	__ Fdiv(s3, s18, s15);
				4947	__ Fdiv(s4, s18, s16);
				4948	__ Fdiv(s5, s15, s16);
				4949	__ Fdiv(s6, s14, s14);
				4950
				4951	__ Fdiv(d7, d31, d30);
				4952	__ Fdiv(d8, d29, d31);
				4953	__ Fdiv(d9, d26, d31);
				4954	__ Fdiv(d10, d31, d27);
				4955	__ Fdiv(d11, d31, d28);
				4956	__ Fdiv(d12, d28, d27);
				4957	__ Fdiv(d13, d29, d29);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4958	END();
				4959
				4960	RUN();
				4961
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4962	ASSERT_EQUAL_FP32(1.625f, s0);
				4963	ASSERT_EQUAL_FP32(1.0f, s1);
				4964	ASSERT_EQUAL_FP32(-0.0f, s2);
				4965	ASSERT_EQUAL_FP32(0.0f, s3);
				4966	ASSERT_EQUAL_FP32(-0.0f, s4);
				4967	ASSERT_EQUAL_FP32(kFP32DefaultNaN, s5);
				4968	ASSERT_EQUAL_FP32(kFP32DefaultNaN, s6);
				4969	ASSERT_EQUAL_FP64(-1.125, d7);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4970	ASSERT_EQUAL_FP64(0.0, d8);
				4971	ASSERT_EQUAL_FP64(-0.0, d9);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4972	ASSERT_EQUAL_FP64(0.0, d10);
				4973	ASSERT_EQUAL_FP64(-0.0, d11);
				4974	ASSERT_EQUAL_FP64(kFP64DefaultNaN, d12);
				4975	ASSERT_EQUAL_FP64(kFP64DefaultNaN, d13);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4976
				4977	TEARDOWN();
				4978	}
				4979
				4980
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	4981	static float MinMaxHelper(float n,
				4982	float m,
				4983	bool min,
				4984	float quiet_nan_substitute = 0.0) {
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4985	const uint64_t kFP32QuietNaNMask = 0x00400000;
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	4986	uint32_t raw_n = float_to_rawbits(n);
				4987	uint32_t raw_m = float_to_rawbits(m);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	4988
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	4989	if (isnan(n) && ((raw_n & kFP32QuietNaNMask) == 0)) {
				4990	// n is signalling NaN.
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4991	return rawbits_to_float(raw_n \| kFP32QuietNaNMask);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	4992	} else if (isnan(m) && ((raw_m & kFP32QuietNaNMask) == 0)) {
				4993	// m is signalling NaN.
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	4994	return rawbits_to_float(raw_m \| kFP32QuietNaNMask);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	4995	} else if (quiet_nan_substitute == 0.0) {
				4996	if (isnan(n)) {
				4997	// n is quiet NaN.
				4998	return n;
				4999	} else if (isnan(m)) {
				5000	// m is quiet NaN.
				5001	return m;
				5002	}
				5003	} else {
				5004	// Substitute n or m if one is quiet, but not both.
				5005	if (isnan(n) && !isnan(m)) {
				5006	// n is quiet NaN: replace with substitute.
				5007	n = quiet_nan_substitute;
				5008	} else if (!isnan(n) && isnan(m)) {
				5009	// m is quiet NaN: replace with substitute.
				5010	m = quiet_nan_substitute;
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5011	}
				5012	}
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5013
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	5014	if ((n == 0.0) && (m == 0.0) &&
				5015	(copysign(1.0, n) != copysign(1.0, m))) {
				5016	return min ? -0.0 : 0.0;
				5017	}
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5018
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	5019	return min ? fminf(n, m) : fmaxf(n, m);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5020	}
				5021
				5022
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	5023	static double MinMaxHelper(double n,
				5024	double m,
				5025	bool min,
				5026	double quiet_nan_substitute = 0.0) {
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	5027	const uint64_t kFP64QuietNaNMask = 0x0008000000000000;
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	5028	uint64_t raw_n = double_to_rawbits(n);
				5029	uint64_t raw_m = double_to_rawbits(m);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5030
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	5031	if (isnan(n) && ((raw_n & kFP64QuietNaNMask) == 0)) {
				5032	// n is signalling NaN.
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	5033	return rawbits_to_double(raw_n \| kFP64QuietNaNMask);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	5034	} else if (isnan(m) && ((raw_m & kFP64QuietNaNMask) == 0)) {
				5035	// m is signalling NaN.
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	5036	return rawbits_to_double(raw_m \| kFP64QuietNaNMask);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	5037	} else if (quiet_nan_substitute == 0.0) {
				5038	if (isnan(n)) {
				5039	// n is quiet NaN.
				5040	return n;
				5041	} else if (isnan(m)) {
				5042	// m is quiet NaN.
				5043	return m;
				5044	}
				5045	} else {
				5046	// Substitute n or m if one is quiet, but not both.
				5047	if (isnan(n) && !isnan(m)) {
				5048	// n is quiet NaN: replace with substitute.
				5049	n = quiet_nan_substitute;
				5050	} else if (!isnan(n) && isnan(m)) {
				5051	// m is quiet NaN: replace with substitute.
				5052	m = quiet_nan_substitute;
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5053	}
				5054	}
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	5055
				5056	if ((n == 0.0) && (m == 0.0) &&
				5057	(copysign(1.0, n) != copysign(1.0, m))) {
				5058	return min ? -0.0 : 0.0;
				5059	}
				5060
				5061	return min ? fmin(n, m) : fmax(n, m);
				5062	}
				5063
				5064
				5065	static void FminFmaxDoubleHelper(double n, double m, double min, double max,
				5066	double minnm, double maxnm) {
				5067	SETUP();
				5068
				5069	START();
				5070	__ Fmov(d0, n);
				5071	__ Fmov(d1, m);
				5072	__ Fmin(d28, d0, d1);
				5073	__ Fmax(d29, d0, d1);
				5074	__ Fminnm(d30, d0, d1);
				5075	__ Fmaxnm(d31, d0, d1);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5076	END();
				5077
				5078	RUN();
				5079
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	5080	ASSERT_EQUAL_FP64(min, d28);
				5081	ASSERT_EQUAL_FP64(max, d29);
				5082	ASSERT_EQUAL_FP64(minnm, d30);
				5083	ASSERT_EQUAL_FP64(maxnm, d31);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5084
				5085	TEARDOWN();
				5086	}
				5087
				5088
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	5089	TEST(fmax_fmin_d) {
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	5090	// Use non-standard NaNs to check that the payload bits are preserved.
				5091	double snan = rawbits_to_double(0x7ff5555512345678);
				5092	double qnan = rawbits_to_double(0x7ffaaaaa87654321);
				5093
				5094	double snan_processed = rawbits_to_double(0x7ffd555512345678);
				5095	double qnan_processed = qnan;
				5096
				5097	VIXL_ASSERT(IsSignallingNaN(snan));
				5098	VIXL_ASSERT(IsQuietNaN(qnan));
				5099	VIXL_ASSERT(IsQuietNaN(snan_processed));
				5100	VIXL_ASSERT(IsQuietNaN(qnan_processed));
				5101
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	5102	// Bootstrap tests.
				5103	FminFmaxDoubleHelper(0, 0, 0, 0, 0, 0);
				5104	FminFmaxDoubleHelper(0, 1, 0, 1, 0, 1);
				5105	FminFmaxDoubleHelper(kFP64PositiveInfinity, kFP64NegativeInfinity,
				5106	kFP64NegativeInfinity, kFP64PositiveInfinity,
				5107	kFP64NegativeInfinity, kFP64PositiveInfinity);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	5108	FminFmaxDoubleHelper(snan, 0,
				5109	snan_processed, snan_processed,
				5110	snan_processed, snan_processed);
				5111	FminFmaxDoubleHelper(0, snan,
				5112	snan_processed, snan_processed,
				5113	snan_processed, snan_processed);
				5114	FminFmaxDoubleHelper(qnan, 0,
				5115	qnan_processed, qnan_processed,
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	5116	0, 0);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	5117	FminFmaxDoubleHelper(0, qnan,
				5118	qnan_processed, qnan_processed,
				5119	0, 0);
				5120	FminFmaxDoubleHelper(qnan, snan,
				5121	snan_processed, snan_processed,
				5122	snan_processed, snan_processed);
				5123	FminFmaxDoubleHelper(snan, qnan,
				5124	snan_processed, snan_processed,
				5125	snan_processed, snan_processed);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	5126
				5127	// Iterate over all combinations of inputs.
				5128	double inputs[] = { DBL_MAX, DBL_MIN, 1.0, 0.0,
				5129	-DBL_MAX, -DBL_MIN, -1.0, -0.0,
				5130	kFP64PositiveInfinity, kFP64NegativeInfinity,
				5131	kFP64QuietNaN, kFP64SignallingNaN };
				5132
				5133	const int count = sizeof(inputs) / sizeof(inputs[0]);
				5134
				5135	for (int in = 0; in < count; in++) {
				5136	double n = inputs[in];
				5137	for (int im = 0; im < count; im++) {
				5138	double m = inputs[im];
				5139	FminFmaxDoubleHelper(n, m,
				5140	MinMaxHelper(n, m, true),
				5141	MinMaxHelper(n, m, false),
				5142	MinMaxHelper(n, m, true, kFP64PositiveInfinity),
				5143	MinMaxHelper(n, m, false, kFP64NegativeInfinity));
				5144	}
				5145	}
				5146	}
				5147
				5148
				5149	static void FminFmaxFloatHelper(float n, float m, float min, float max,
				5150	float minnm, float maxnm) {
				5151	SETUP();
				5152
				5153	START();
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	5154	__ Fmov(s0, n);
				5155	__ Fmov(s1, m);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	5156	__ Fmin(s28, s0, s1);
				5157	__ Fmax(s29, s0, s1);
				5158	__ Fminnm(s30, s0, s1);
				5159	__ Fmaxnm(s31, s0, s1);
				5160	END();
				5161
				5162	RUN();
				5163
				5164	ASSERT_EQUAL_FP32(min, s28);
				5165	ASSERT_EQUAL_FP32(max, s29);
				5166	ASSERT_EQUAL_FP32(minnm, s30);
				5167	ASSERT_EQUAL_FP32(maxnm, s31);
				5168
				5169	TEARDOWN();
				5170	}
				5171
				5172
				5173	TEST(fmax_fmin_s) {
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	5174	// Use non-standard NaNs to check that the payload bits are preserved.
				5175	float snan = rawbits_to_float(0x7f951234);
				5176	float qnan = rawbits_to_float(0x7fea8765);
				5177
				5178	float snan_processed = rawbits_to_float(0x7fd51234);
				5179	float qnan_processed = qnan;
				5180
				5181	VIXL_ASSERT(IsSignallingNaN(snan));
				5182	VIXL_ASSERT(IsQuietNaN(qnan));
				5183	VIXL_ASSERT(IsQuietNaN(snan_processed));
				5184	VIXL_ASSERT(IsQuietNaN(qnan_processed));
				5185
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	5186	// Bootstrap tests.
				5187	FminFmaxFloatHelper(0, 0, 0, 0, 0, 0);
				5188	FminFmaxFloatHelper(0, 1, 0, 1, 0, 1);
				5189	FminFmaxFloatHelper(kFP32PositiveInfinity, kFP32NegativeInfinity,
				5190	kFP32NegativeInfinity, kFP32PositiveInfinity,
				5191	kFP32NegativeInfinity, kFP32PositiveInfinity);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	5192	FminFmaxFloatHelper(snan, 0,
				5193	snan_processed, snan_processed,
				5194	snan_processed, snan_processed);
				5195	FminFmaxFloatHelper(0, snan,
				5196	snan_processed, snan_processed,
				5197	snan_processed, snan_processed);
				5198	FminFmaxFloatHelper(qnan, 0,
				5199	qnan_processed, qnan_processed,
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	5200	0, 0);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	5201	FminFmaxFloatHelper(0, qnan,
				5202	qnan_processed, qnan_processed,
				5203	0, 0);
				5204	FminFmaxFloatHelper(qnan, snan,
				5205	snan_processed, snan_processed,
				5206	snan_processed, snan_processed);
				5207	FminFmaxFloatHelper(snan, qnan,
				5208	snan_processed, snan_processed,
				5209	snan_processed, snan_processed);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	5210
				5211	// Iterate over all combinations of inputs.
				5212	float inputs[] = { FLT_MAX, FLT_MIN, 1.0, 0.0,
				5213	-FLT_MAX, -FLT_MIN, -1.0, -0.0,
				5214	kFP32PositiveInfinity, kFP32NegativeInfinity,
				5215	kFP32QuietNaN, kFP32SignallingNaN };
				5216
				5217	const int count = sizeof(inputs) / sizeof(inputs[0]);
				5218
				5219	for (int in = 0; in < count; in++) {
				5220	float n = inputs[in];
				5221	for (int im = 0; im < count; im++) {
				5222	float m = inputs[im];
				5223	FminFmaxFloatHelper(n, m,
				5224	MinMaxHelper(n, m, true),
				5225	MinMaxHelper(n, m, false),
				5226	MinMaxHelper(n, m, true, kFP32PositiveInfinity),
				5227	MinMaxHelper(n, m, false, kFP32NegativeInfinity));
				5228	}
				5229	}
				5230	}
				5231
				5232
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5233	TEST(fccmp) {
				5234	SETUP();
				5235
				5236	START();
				5237	__ Fmov(s16, 0.0);
				5238	__ Fmov(s17, 0.5);
				5239	__ Fmov(d18, -0.5);
				5240	__ Fmov(d19, -1.0);
				5241	__ Mov(x20, 0);
				5242
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	5243	__ Cmp(x20, 0);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5244	__ Fccmp(s16, s16, NoFlag, eq);
				5245	__ Mrs(x0, NZCV);
				5246
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	5247	__ Cmp(x20, 0);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5248	__ Fccmp(s16, s16, VFlag, ne);
				5249	__ Mrs(x1, NZCV);
				5250
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	5251	__ Cmp(x20, 0);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5252	__ Fccmp(s16, s17, CFlag, ge);
				5253	__ Mrs(x2, NZCV);
				5254
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	5255	__ Cmp(x20, 0);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5256	__ Fccmp(s16, s17, CVFlag, lt);
				5257	__ Mrs(x3, NZCV);
				5258
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	5259	__ Cmp(x20, 0);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5260	__ Fccmp(d18, d18, ZFlag, le);
				5261	__ Mrs(x4, NZCV);
				5262
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	5263	__ Cmp(x20, 0);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5264	__ Fccmp(d18, d18, ZVFlag, gt);
				5265	__ Mrs(x5, NZCV);
				5266
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	5267	__ Cmp(x20, 0);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5268	__ Fccmp(d18, d19, ZCVFlag, ls);
				5269	__ Mrs(x6, NZCV);
				5270
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	5271	__ Cmp(x20, 0);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5272	__ Fccmp(d18, d19, NFlag, hi);
				5273	__ Mrs(x7, NZCV);
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	5274
				5275	__ fccmp(s16, s16, NFlag, al);
				5276	__ Mrs(x8, NZCV);
				5277
				5278	__ fccmp(d18, d18, NFlag, nv);
				5279	__ Mrs(x9, NZCV);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5280	END();
				5281
				5282	RUN();
				5283
				5284	ASSERT_EQUAL_32(ZCFlag, w0);
				5285	ASSERT_EQUAL_32(VFlag, w1);
				5286	ASSERT_EQUAL_32(NFlag, w2);
				5287	ASSERT_EQUAL_32(CVFlag, w3);
				5288	ASSERT_EQUAL_32(ZCFlag, w4);
				5289	ASSERT_EQUAL_32(ZVFlag, w5);
				5290	ASSERT_EQUAL_32(CFlag, w6);
				5291	ASSERT_EQUAL_32(NFlag, w7);
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	5292	ASSERT_EQUAL_32(ZCFlag, w8);
				5293	ASSERT_EQUAL_32(ZCFlag, w9);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5294
				5295	TEARDOWN();
				5296	}
				5297
				5298
				5299	TEST(fcmp) {
				5300	SETUP();
				5301
				5302	START();
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	5303
				5304	// Some of these tests require a floating-point scratch register assigned to
				5305	// the macro assembler, but most do not.
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	5306	{
				5307	UseScratchRegisterScope temps(&masm);
				5308	temps.ExcludeAll();
				5309	temps.Include(ip0, ip1);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	5310
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	5311	__ Fmov(s8, 0.0);
				5312	__ Fmov(s9, 0.5);
				5313	__ Mov(w18, 0x7f800001); // Single precision NaN.
				5314	__ Fmov(s18, w18);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5315
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	5316	__ Fcmp(s8, s8);
				5317	__ Mrs(x0, NZCV);
				5318	__ Fcmp(s8, s9);
				5319	__ Mrs(x1, NZCV);
				5320	__ Fcmp(s9, s8);
				5321	__ Mrs(x2, NZCV);
				5322	__ Fcmp(s8, s18);
				5323	__ Mrs(x3, NZCV);
				5324	__ Fcmp(s18, s18);
				5325	__ Mrs(x4, NZCV);
				5326	__ Fcmp(s8, 0.0);
				5327	__ Mrs(x5, NZCV);
				5328	temps.Include(d0);
				5329	__ Fcmp(s8, 255.0);
				5330	temps.Exclude(d0);
				5331	__ Mrs(x6, NZCV);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5332
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	5333	__ Fmov(d19, 0.0);
				5334	__ Fmov(d20, 0.5);
				5335	__ Mov(x21, 0x7ff0000000000001); // Double precision NaN.
				5336	__ Fmov(d21, x21);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5337
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	5338	__ Fcmp(d19, d19);
				5339	__ Mrs(x10, NZCV);
				5340	__ Fcmp(d19, d20);
				5341	__ Mrs(x11, NZCV);
				5342	__ Fcmp(d20, d19);
				5343	__ Mrs(x12, NZCV);
				5344	__ Fcmp(d19, d21);
				5345	__ Mrs(x13, NZCV);
				5346	__ Fcmp(d21, d21);
				5347	__ Mrs(x14, NZCV);
				5348	__ Fcmp(d19, 0.0);
				5349	__ Mrs(x15, NZCV);
				5350	temps.Include(d0);
				5351	__ Fcmp(d19, 12.3456);
				5352	temps.Exclude(d0);
				5353	__ Mrs(x16, NZCV);
				5354	}
				5355
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5356	END();
				5357
				5358	RUN();
				5359
				5360	ASSERT_EQUAL_32(ZCFlag, w0);
				5361	ASSERT_EQUAL_32(NFlag, w1);
				5362	ASSERT_EQUAL_32(CFlag, w2);
				5363	ASSERT_EQUAL_32(CVFlag, w3);
				5364	ASSERT_EQUAL_32(CVFlag, w4);
				5365	ASSERT_EQUAL_32(ZCFlag, w5);
				5366	ASSERT_EQUAL_32(NFlag, w6);
				5367	ASSERT_EQUAL_32(ZCFlag, w10);
				5368	ASSERT_EQUAL_32(NFlag, w11);
				5369	ASSERT_EQUAL_32(CFlag, w12);
				5370	ASSERT_EQUAL_32(CVFlag, w13);
				5371	ASSERT_EQUAL_32(CVFlag, w14);
				5372	ASSERT_EQUAL_32(ZCFlag, w15);
				5373	ASSERT_EQUAL_32(NFlag, w16);
				5374
				5375	TEARDOWN();
				5376	}
				5377
				5378
				5379	TEST(fcsel) {
				5380	SETUP();
				5381
				5382	START();
				5383	__ Mov(x16, 0);
				5384	__ Fmov(s16, 1.0);
				5385	__ Fmov(s17, 2.0);
				5386	__ Fmov(d18, 3.0);
				5387	__ Fmov(d19, 4.0);
				5388
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	5389	__ Cmp(x16, 0);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5390	__ Fcsel(s0, s16, s17, eq);
				5391	__ Fcsel(s1, s16, s17, ne);
				5392	__ Fcsel(d2, d18, d19, eq);
				5393	__ Fcsel(d3, d18, d19, ne);
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	5394	__ fcsel(s4, s16, s17, al);
				5395	__ fcsel(d5, d18, d19, nv);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5396	END();
				5397
				5398	RUN();
				5399
				5400	ASSERT_EQUAL_FP32(1.0, s0);
				5401	ASSERT_EQUAL_FP32(2.0, s1);
				5402	ASSERT_EQUAL_FP64(3.0, d2);
				5403	ASSERT_EQUAL_FP64(4.0, d3);
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	5404	ASSERT_EQUAL_FP32(1.0, s4);
				5405	ASSERT_EQUAL_FP64(3.0, d5);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5406
				5407	TEARDOWN();
				5408	}
				5409
				5410
				5411	TEST(fneg) {
				5412	SETUP();
				5413
				5414	START();
				5415	__ Fmov(s16, 1.0);
				5416	__ Fmov(s17, 0.0);
				5417	__ Fmov(s18, kFP32PositiveInfinity);
				5418	__ Fmov(d19, 1.0);
				5419	__ Fmov(d20, 0.0);
				5420	__ Fmov(d21, kFP64PositiveInfinity);
				5421
				5422	__ Fneg(s0, s16);
				5423	__ Fneg(s1, s0);
				5424	__ Fneg(s2, s17);
				5425	__ Fneg(s3, s2);
				5426	__ Fneg(s4, s18);
				5427	__ Fneg(s5, s4);
				5428	__ Fneg(d6, d19);
				5429	__ Fneg(d7, d6);
				5430	__ Fneg(d8, d20);
				5431	__ Fneg(d9, d8);
				5432	__ Fneg(d10, d21);
				5433	__ Fneg(d11, d10);
				5434	END();
				5435
				5436	RUN();
				5437
				5438	ASSERT_EQUAL_FP32(-1.0, s0);
				5439	ASSERT_EQUAL_FP32(1.0, s1);
				5440	ASSERT_EQUAL_FP32(-0.0, s2);
				5441	ASSERT_EQUAL_FP32(0.0, s3);
				5442	ASSERT_EQUAL_FP32(kFP32NegativeInfinity, s4);
				5443	ASSERT_EQUAL_FP32(kFP32PositiveInfinity, s5);
				5444	ASSERT_EQUAL_FP64(-1.0, d6);
				5445	ASSERT_EQUAL_FP64(1.0, d7);
				5446	ASSERT_EQUAL_FP64(-0.0, d8);
				5447	ASSERT_EQUAL_FP64(0.0, d9);
				5448	ASSERT_EQUAL_FP64(kFP64NegativeInfinity, d10);
				5449	ASSERT_EQUAL_FP64(kFP64PositiveInfinity, d11);
				5450
				5451	TEARDOWN();
				5452	}
				5453
				5454
				5455	TEST(fabs) {
				5456	SETUP();
				5457
				5458	START();
				5459	__ Fmov(s16, -1.0);
				5460	__ Fmov(s17, -0.0);
				5461	__ Fmov(s18, kFP32NegativeInfinity);
				5462	__ Fmov(d19, -1.0);
				5463	__ Fmov(d20, -0.0);
				5464	__ Fmov(d21, kFP64NegativeInfinity);
				5465
				5466	__ Fabs(s0, s16);
				5467	__ Fabs(s1, s0);
				5468	__ Fabs(s2, s17);
				5469	__ Fabs(s3, s18);
				5470	__ Fabs(d4, d19);
				5471	__ Fabs(d5, d4);
				5472	__ Fabs(d6, d20);
				5473	__ Fabs(d7, d21);
				5474	END();
				5475
				5476	RUN();
				5477
				5478	ASSERT_EQUAL_FP32(1.0, s0);
				5479	ASSERT_EQUAL_FP32(1.0, s1);
				5480	ASSERT_EQUAL_FP32(0.0, s2);
				5481	ASSERT_EQUAL_FP32(kFP32PositiveInfinity, s3);
				5482	ASSERT_EQUAL_FP64(1.0, d4);
				5483	ASSERT_EQUAL_FP64(1.0, d5);
				5484	ASSERT_EQUAL_FP64(0.0, d6);
				5485	ASSERT_EQUAL_FP64(kFP64PositiveInfinity, d7);
				5486
				5487	TEARDOWN();
				5488	}
				5489
				5490
				5491	TEST(fsqrt) {
				5492	SETUP();
				5493
				5494	START();
				5495	__ Fmov(s16, 0.0);
				5496	__ Fmov(s17, 1.0);
				5497	__ Fmov(s18, 0.25);
				5498	__ Fmov(s19, 65536.0);
				5499	__ Fmov(s20, -0.0);
				5500	__ Fmov(s21, kFP32PositiveInfinity);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	5501	__ Fmov(s22, -1.0);
				5502	__ Fmov(d23, 0.0);
				5503	__ Fmov(d24, 1.0);
				5504	__ Fmov(d25, 0.25);
				5505	__ Fmov(d26, 4294967296.0);
				5506	__ Fmov(d27, -0.0);
				5507	__ Fmov(d28, kFP64PositiveInfinity);
				5508	__ Fmov(d29, -1.0);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5509
				5510	__ Fsqrt(s0, s16);
				5511	__ Fsqrt(s1, s17);
				5512	__ Fsqrt(s2, s18);
				5513	__ Fsqrt(s3, s19);
				5514	__ Fsqrt(s4, s20);
				5515	__ Fsqrt(s5, s21);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	5516	__ Fsqrt(s6, s22);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5517	__ Fsqrt(d7, d23);
				5518	__ Fsqrt(d8, d24);
				5519	__ Fsqrt(d9, d25);
				5520	__ Fsqrt(d10, d26);
				5521	__ Fsqrt(d11, d27);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	5522	__ Fsqrt(d12, d28);
				5523	__ Fsqrt(d13, d29);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5524	END();
				5525
				5526	RUN();
				5527
				5528	ASSERT_EQUAL_FP32(0.0, s0);
				5529	ASSERT_EQUAL_FP32(1.0, s1);
				5530	ASSERT_EQUAL_FP32(0.5, s2);
				5531	ASSERT_EQUAL_FP32(256.0, s3);
				5532	ASSERT_EQUAL_FP32(-0.0, s4);
				5533	ASSERT_EQUAL_FP32(kFP32PositiveInfinity, s5);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	5534	ASSERT_EQUAL_FP32(kFP32DefaultNaN, s6);
				5535	ASSERT_EQUAL_FP64(0.0, d7);
				5536	ASSERT_EQUAL_FP64(1.0, d8);
				5537	ASSERT_EQUAL_FP64(0.5, d9);
				5538	ASSERT_EQUAL_FP64(65536.0, d10);
				5539	ASSERT_EQUAL_FP64(-0.0, d11);
				5540	ASSERT_EQUAL_FP64(kFP32PositiveInfinity, d12);
				5541	ASSERT_EQUAL_FP64(kFP64DefaultNaN, d13);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5542
				5543	TEARDOWN();
				5544	}
				5545
				5546
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	5547	TEST(frinta) {
				5548	SETUP();
				5549
				5550	START();
				5551	__ Fmov(s16, 1.0);
				5552	__ Fmov(s17, 1.1);
				5553	__ Fmov(s18, 1.5);
				5554	__ Fmov(s19, 1.9);
				5555	__ Fmov(s20, 2.5);
				5556	__ Fmov(s21, -1.5);
				5557	__ Fmov(s22, -2.5);
				5558	__ Fmov(s23, kFP32PositiveInfinity);
				5559	__ Fmov(s24, kFP32NegativeInfinity);
				5560	__ Fmov(s25, 0.0);
				5561	__ Fmov(s26, -0.0);
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	5562	__ Fmov(s27, -0.2);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	5563
				5564	__ Frinta(s0, s16);
				5565	__ Frinta(s1, s17);
				5566	__ Frinta(s2, s18);
				5567	__ Frinta(s3, s19);
				5568	__ Frinta(s4, s20);
				5569	__ Frinta(s5, s21);
				5570	__ Frinta(s6, s22);
				5571	__ Frinta(s7, s23);
				5572	__ Frinta(s8, s24);
				5573	__ Frinta(s9, s25);
				5574	__ Frinta(s10, s26);
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	5575	__ Frinta(s11, s27);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	5576
				5577	__ Fmov(d16, 1.0);
				5578	__ Fmov(d17, 1.1);
				5579	__ Fmov(d18, 1.5);
				5580	__ Fmov(d19, 1.9);
				5581	__ Fmov(d20, 2.5);
				5582	__ Fmov(d21, -1.5);
				5583	__ Fmov(d22, -2.5);
				5584	__ Fmov(d23, kFP32PositiveInfinity);
				5585	__ Fmov(d24, kFP32NegativeInfinity);
				5586	__ Fmov(d25, 0.0);
				5587	__ Fmov(d26, -0.0);
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	5588	__ Fmov(d27, -0.2);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	5589
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	5590	__ Frinta(d12, d16);
				5591	__ Frinta(d13, d17);
				5592	__ Frinta(d14, d18);
				5593	__ Frinta(d15, d19);
				5594	__ Frinta(d16, d20);
				5595	__ Frinta(d17, d21);
				5596	__ Frinta(d18, d22);
				5597	__ Frinta(d19, d23);
				5598	__ Frinta(d20, d24);
				5599	__ Frinta(d21, d25);
				5600	__ Frinta(d22, d26);
				5601	__ Frinta(d23, d27);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	5602	END();
				5603
				5604	RUN();
				5605
				5606	ASSERT_EQUAL_FP32(1.0, s0);
				5607	ASSERT_EQUAL_FP32(1.0, s1);
				5608	ASSERT_EQUAL_FP32(2.0, s2);
				5609	ASSERT_EQUAL_FP32(2.0, s3);
				5610	ASSERT_EQUAL_FP32(3.0, s4);
				5611	ASSERT_EQUAL_FP32(-2.0, s5);
				5612	ASSERT_EQUAL_FP32(-3.0, s6);
				5613	ASSERT_EQUAL_FP32(kFP32PositiveInfinity, s7);
				5614	ASSERT_EQUAL_FP32(kFP32NegativeInfinity, s8);
				5615	ASSERT_EQUAL_FP32(0.0, s9);
				5616	ASSERT_EQUAL_FP32(-0.0, s10);
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	5617	ASSERT_EQUAL_FP32(-0.0, s11);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	5618	ASSERT_EQUAL_FP64(1.0, d12);
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	5619	ASSERT_EQUAL_FP64(1.0, d13);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	5620	ASSERT_EQUAL_FP64(2.0, d14);
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	5621	ASSERT_EQUAL_FP64(2.0, d15);
				5622	ASSERT_EQUAL_FP64(3.0, d16);
				5623	ASSERT_EQUAL_FP64(-2.0, d17);
				5624	ASSERT_EQUAL_FP64(-3.0, d18);
				5625	ASSERT_EQUAL_FP64(kFP64PositiveInfinity, d19);
				5626	ASSERT_EQUAL_FP64(kFP64NegativeInfinity, d20);
				5627	ASSERT_EQUAL_FP64(0.0, d21);
				5628	ASSERT_EQUAL_FP64(-0.0, d22);
				5629	ASSERT_EQUAL_FP64(-0.0, d23);
				5630
				5631	TEARDOWN();
				5632	}
				5633
				5634
				5635	TEST(frintm) {
				5636	SETUP();
				5637
				5638	START();
				5639	__ Fmov(s16, 1.0);
				5640	__ Fmov(s17, 1.1);
				5641	__ Fmov(s18, 1.5);
				5642	__ Fmov(s19, 1.9);
				5643	__ Fmov(s20, 2.5);
				5644	__ Fmov(s21, -1.5);
				5645	__ Fmov(s22, -2.5);
				5646	__ Fmov(s23, kFP32PositiveInfinity);
				5647	__ Fmov(s24, kFP32NegativeInfinity);
				5648	__ Fmov(s25, 0.0);
				5649	__ Fmov(s26, -0.0);
				5650	__ Fmov(s27, -0.2);
				5651
				5652	__ Frintm(s0, s16);
				5653	__ Frintm(s1, s17);
				5654	__ Frintm(s2, s18);
				5655	__ Frintm(s3, s19);
				5656	__ Frintm(s4, s20);
				5657	__ Frintm(s5, s21);
				5658	__ Frintm(s6, s22);
				5659	__ Frintm(s7, s23);
				5660	__ Frintm(s8, s24);
				5661	__ Frintm(s9, s25);
				5662	__ Frintm(s10, s26);
				5663	__ Frintm(s11, s27);
				5664
				5665	__ Fmov(d16, 1.0);
				5666	__ Fmov(d17, 1.1);
				5667	__ Fmov(d18, 1.5);
				5668	__ Fmov(d19, 1.9);
				5669	__ Fmov(d20, 2.5);
				5670	__ Fmov(d21, -1.5);
				5671	__ Fmov(d22, -2.5);
				5672	__ Fmov(d23, kFP32PositiveInfinity);
				5673	__ Fmov(d24, kFP32NegativeInfinity);
				5674	__ Fmov(d25, 0.0);
				5675	__ Fmov(d26, -0.0);
				5676	__ Fmov(d27, -0.2);
				5677
				5678	__ Frintm(d12, d16);
				5679	__ Frintm(d13, d17);
				5680	__ Frintm(d14, d18);
				5681	__ Frintm(d15, d19);
				5682	__ Frintm(d16, d20);
				5683	__ Frintm(d17, d21);
				5684	__ Frintm(d18, d22);
				5685	__ Frintm(d19, d23);
				5686	__ Frintm(d20, d24);
				5687	__ Frintm(d21, d25);
				5688	__ Frintm(d22, d26);
				5689	__ Frintm(d23, d27);
				5690	END();
				5691
				5692	RUN();
				5693
				5694	ASSERT_EQUAL_FP32(1.0, s0);
				5695	ASSERT_EQUAL_FP32(1.0, s1);
				5696	ASSERT_EQUAL_FP32(1.0, s2);
				5697	ASSERT_EQUAL_FP32(1.0, s3);
				5698	ASSERT_EQUAL_FP32(2.0, s4);
				5699	ASSERT_EQUAL_FP32(-2.0, s5);
				5700	ASSERT_EQUAL_FP32(-3.0, s6);
				5701	ASSERT_EQUAL_FP32(kFP32PositiveInfinity, s7);
				5702	ASSERT_EQUAL_FP32(kFP32NegativeInfinity, s8);
				5703	ASSERT_EQUAL_FP32(0.0, s9);
				5704	ASSERT_EQUAL_FP32(-0.0, s10);
				5705	ASSERT_EQUAL_FP32(-1.0, s11);
				5706	ASSERT_EQUAL_FP64(1.0, d12);
				5707	ASSERT_EQUAL_FP64(1.0, d13);
				5708	ASSERT_EQUAL_FP64(1.0, d14);
				5709	ASSERT_EQUAL_FP64(1.0, d15);
				5710	ASSERT_EQUAL_FP64(2.0, d16);
				5711	ASSERT_EQUAL_FP64(-2.0, d17);
				5712	ASSERT_EQUAL_FP64(-3.0, d18);
				5713	ASSERT_EQUAL_FP64(kFP64PositiveInfinity, d19);
				5714	ASSERT_EQUAL_FP64(kFP64NegativeInfinity, d20);
				5715	ASSERT_EQUAL_FP64(0.0, d21);
				5716	ASSERT_EQUAL_FP64(-0.0, d22);
				5717	ASSERT_EQUAL_FP64(-1.0, d23);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	5718
				5719	TEARDOWN();
				5720	}
				5721
				5722
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5723	TEST(frintn) {
				5724	SETUP();
				5725
				5726	START();
				5727	__ Fmov(s16, 1.0);
				5728	__ Fmov(s17, 1.1);
				5729	__ Fmov(s18, 1.5);
				5730	__ Fmov(s19, 1.9);
				5731	__ Fmov(s20, 2.5);
				5732	__ Fmov(s21, -1.5);
				5733	__ Fmov(s22, -2.5);
				5734	__ Fmov(s23, kFP32PositiveInfinity);
				5735	__ Fmov(s24, kFP32NegativeInfinity);
				5736	__ Fmov(s25, 0.0);
				5737	__ Fmov(s26, -0.0);
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	5738	__ Fmov(s27, -0.2);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5739
				5740	__ Frintn(s0, s16);
				5741	__ Frintn(s1, s17);
				5742	__ Frintn(s2, s18);
				5743	__ Frintn(s3, s19);
				5744	__ Frintn(s4, s20);
				5745	__ Frintn(s5, s21);
				5746	__ Frintn(s6, s22);
				5747	__ Frintn(s7, s23);
				5748	__ Frintn(s8, s24);
				5749	__ Frintn(s9, s25);
				5750	__ Frintn(s10, s26);
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	5751	__ Frintn(s11, s27);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5752
				5753	__ Fmov(d16, 1.0);
				5754	__ Fmov(d17, 1.1);
				5755	__ Fmov(d18, 1.5);
				5756	__ Fmov(d19, 1.9);
				5757	__ Fmov(d20, 2.5);
				5758	__ Fmov(d21, -1.5);
				5759	__ Fmov(d22, -2.5);
				5760	__ Fmov(d23, kFP32PositiveInfinity);
				5761	__ Fmov(d24, kFP32NegativeInfinity);
				5762	__ Fmov(d25, 0.0);
				5763	__ Fmov(d26, -0.0);
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	5764	__ Fmov(d27, -0.2);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5765
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	5766	__ Frintn(d12, d16);
				5767	__ Frintn(d13, d17);
				5768	__ Frintn(d14, d18);
				5769	__ Frintn(d15, d19);
				5770	__ Frintn(d16, d20);
				5771	__ Frintn(d17, d21);
				5772	__ Frintn(d18, d22);
				5773	__ Frintn(d19, d23);
				5774	__ Frintn(d20, d24);
				5775	__ Frintn(d21, d25);
				5776	__ Frintn(d22, d26);
				5777	__ Frintn(d23, d27);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5778	END();
				5779
				5780	RUN();
				5781
				5782	ASSERT_EQUAL_FP32(1.0, s0);
				5783	ASSERT_EQUAL_FP32(1.0, s1);
				5784	ASSERT_EQUAL_FP32(2.0, s2);
				5785	ASSERT_EQUAL_FP32(2.0, s3);
				5786	ASSERT_EQUAL_FP32(2.0, s4);
				5787	ASSERT_EQUAL_FP32(-2.0, s5);
				5788	ASSERT_EQUAL_FP32(-2.0, s6);
				5789	ASSERT_EQUAL_FP32(kFP32PositiveInfinity, s7);
				5790	ASSERT_EQUAL_FP32(kFP32NegativeInfinity, s8);
				5791	ASSERT_EQUAL_FP32(0.0, s9);
				5792	ASSERT_EQUAL_FP32(-0.0, s10);
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	5793	ASSERT_EQUAL_FP32(-0.0, s11);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5794	ASSERT_EQUAL_FP64(1.0, d12);
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	5795	ASSERT_EQUAL_FP64(1.0, d13);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5796	ASSERT_EQUAL_FP64(2.0, d14);
				5797	ASSERT_EQUAL_FP64(2.0, d15);
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	5798	ASSERT_EQUAL_FP64(2.0, d16);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5799	ASSERT_EQUAL_FP64(-2.0, d17);
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	5800	ASSERT_EQUAL_FP64(-2.0, d18);
				5801	ASSERT_EQUAL_FP64(kFP64PositiveInfinity, d19);
				5802	ASSERT_EQUAL_FP64(kFP64NegativeInfinity, d20);
				5803	ASSERT_EQUAL_FP64(0.0, d21);
				5804	ASSERT_EQUAL_FP64(-0.0, d22);
				5805	ASSERT_EQUAL_FP64(-0.0, d23);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5806
				5807	TEARDOWN();
				5808	}
				5809
				5810
				5811	TEST(frintz) {
				5812	SETUP();
				5813
				5814	START();
				5815	__ Fmov(s16, 1.0);
				5816	__ Fmov(s17, 1.1);
				5817	__ Fmov(s18, 1.5);
				5818	__ Fmov(s19, 1.9);
				5819	__ Fmov(s20, 2.5);
				5820	__ Fmov(s21, -1.5);
				5821	__ Fmov(s22, -2.5);
				5822	__ Fmov(s23, kFP32PositiveInfinity);
				5823	__ Fmov(s24, kFP32NegativeInfinity);
				5824	__ Fmov(s25, 0.0);
				5825	__ Fmov(s26, -0.0);
				5826
				5827	__ Frintz(s0, s16);
				5828	__ Frintz(s1, s17);
				5829	__ Frintz(s2, s18);
				5830	__ Frintz(s3, s19);
				5831	__ Frintz(s4, s20);
				5832	__ Frintz(s5, s21);
				5833	__ Frintz(s6, s22);
				5834	__ Frintz(s7, s23);
				5835	__ Frintz(s8, s24);
				5836	__ Frintz(s9, s25);
				5837	__ Frintz(s10, s26);
				5838
				5839	__ Fmov(d16, 1.0);
				5840	__ Fmov(d17, 1.1);
				5841	__ Fmov(d18, 1.5);
				5842	__ Fmov(d19, 1.9);
				5843	__ Fmov(d20, 2.5);
				5844	__ Fmov(d21, -1.5);
				5845	__ Fmov(d22, -2.5);
				5846	__ Fmov(d23, kFP32PositiveInfinity);
				5847	__ Fmov(d24, kFP32NegativeInfinity);
				5848	__ Fmov(d25, 0.0);
				5849	__ Fmov(d26, -0.0);
				5850
				5851	__ Frintz(d11, d16);
				5852	__ Frintz(d12, d17);
				5853	__ Frintz(d13, d18);
				5854	__ Frintz(d14, d19);
				5855	__ Frintz(d15, d20);
				5856	__ Frintz(d16, d21);
				5857	__ Frintz(d17, d22);
				5858	__ Frintz(d18, d23);
				5859	__ Frintz(d19, d24);
				5860	__ Frintz(d20, d25);
				5861	__ Frintz(d21, d26);
				5862	END();
				5863
				5864	RUN();
				5865
				5866	ASSERT_EQUAL_FP32(1.0, s0);
				5867	ASSERT_EQUAL_FP32(1.0, s1);
				5868	ASSERT_EQUAL_FP32(1.0, s2);
				5869	ASSERT_EQUAL_FP32(1.0, s3);
				5870	ASSERT_EQUAL_FP32(2.0, s4);
				5871	ASSERT_EQUAL_FP32(-1.0, s5);
				5872	ASSERT_EQUAL_FP32(-2.0, s6);
				5873	ASSERT_EQUAL_FP32(kFP32PositiveInfinity, s7);
				5874	ASSERT_EQUAL_FP32(kFP32NegativeInfinity, s8);
				5875	ASSERT_EQUAL_FP32(0.0, s9);
				5876	ASSERT_EQUAL_FP32(-0.0, s10);
				5877	ASSERT_EQUAL_FP64(1.0, d11);
				5878	ASSERT_EQUAL_FP64(1.0, d12);
				5879	ASSERT_EQUAL_FP64(1.0, d13);
				5880	ASSERT_EQUAL_FP64(1.0, d14);
				5881	ASSERT_EQUAL_FP64(2.0, d15);
				5882	ASSERT_EQUAL_FP64(-1.0, d16);
				5883	ASSERT_EQUAL_FP64(-2.0, d17);
				5884	ASSERT_EQUAL_FP64(kFP64PositiveInfinity, d18);
				5885	ASSERT_EQUAL_FP64(kFP64NegativeInfinity, d19);
				5886	ASSERT_EQUAL_FP64(0.0, d20);
				5887	ASSERT_EQUAL_FP64(-0.0, d21);
				5888
				5889	TEARDOWN();
				5890	}
				5891
				5892
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	5893	TEST(fcvt_ds) {
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5894	SETUP();
				5895
				5896	START();
				5897	__ Fmov(s16, 1.0);
				5898	__ Fmov(s17, 1.1);
				5899	__ Fmov(s18, 1.5);
				5900	__ Fmov(s19, 1.9);
				5901	__ Fmov(s20, 2.5);
				5902	__ Fmov(s21, -1.5);
				5903	__ Fmov(s22, -2.5);
				5904	__ Fmov(s23, kFP32PositiveInfinity);
				5905	__ Fmov(s24, kFP32NegativeInfinity);
				5906	__ Fmov(s25, 0.0);
				5907	__ Fmov(s26, -0.0);
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	5908	__ Fmov(s27, FLT_MAX);
				5909	__ Fmov(s28, FLT_MIN);
				5910	__ Fmov(s29, rawbits_to_float(0x7fc12345)); // Quiet NaN.
				5911	__ Fmov(s30, rawbits_to_float(0x7f812345)); // Signalling NaN.
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5912
				5913	__ Fcvt(d0, s16);
				5914	__ Fcvt(d1, s17);
				5915	__ Fcvt(d2, s18);
				5916	__ Fcvt(d3, s19);
				5917	__ Fcvt(d4, s20);
				5918	__ Fcvt(d5, s21);
				5919	__ Fcvt(d6, s22);
				5920	__ Fcvt(d7, s23);
				5921	__ Fcvt(d8, s24);
				5922	__ Fcvt(d9, s25);
				5923	__ Fcvt(d10, s26);
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	5924	__ Fcvt(d11, s27);
				5925	__ Fcvt(d12, s28);
				5926	__ Fcvt(d13, s29);
				5927	__ Fcvt(d14, s30);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5928	END();
				5929
				5930	RUN();
				5931
				5932	ASSERT_EQUAL_FP64(1.0f, d0);
				5933	ASSERT_EQUAL_FP64(1.1f, d1);
				5934	ASSERT_EQUAL_FP64(1.5f, d2);
				5935	ASSERT_EQUAL_FP64(1.9f, d3);
				5936	ASSERT_EQUAL_FP64(2.5f, d4);
				5937	ASSERT_EQUAL_FP64(-1.5f, d5);
				5938	ASSERT_EQUAL_FP64(-2.5f, d6);
				5939	ASSERT_EQUAL_FP64(kFP64PositiveInfinity, d7);
				5940	ASSERT_EQUAL_FP64(kFP64NegativeInfinity, d8);
				5941	ASSERT_EQUAL_FP64(0.0f, d9);
				5942	ASSERT_EQUAL_FP64(-0.0f, d10);
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	5943	ASSERT_EQUAL_FP64(FLT_MAX, d11);
				5944	ASSERT_EQUAL_FP64(FLT_MIN, d12);
				5945
				5946	// Check that the NaN payload is preserved according to A64 conversion rules:
				5947	// - The sign bit is preserved.
				5948	// - The top bit of the mantissa is forced to 1 (making it a quiet NaN).
				5949	// - The remaining mantissa bits are copied until they run out.
				5950	// - The low-order bits that haven't already been assigned are set to 0.
				5951	ASSERT_EQUAL_FP64(rawbits_to_double(0x7ff82468a0000000), d13);
				5952	ASSERT_EQUAL_FP64(rawbits_to_double(0x7ff82468a0000000), d14);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	5953
				5954	TEARDOWN();
				5955	}
				5956
				5957
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	5958	TEST(fcvt_sd) {
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	5959	// Test simple conversions here. Complex behaviour (such as rounding
				5960	// specifics) are tested in the simulator tests.
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	5961
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	5962	SETUP();
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	5963
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	5964	START();
				5965	__ Fmov(d16, 1.0);
				5966	__ Fmov(d17, 1.1);
				5967	__ Fmov(d18, 1.5);
				5968	__ Fmov(d19, 1.9);
				5969	__ Fmov(d20, 2.5);
				5970	__ Fmov(d21, -1.5);
				5971	__ Fmov(d22, -2.5);
				5972	__ Fmov(d23, kFP32PositiveInfinity);
				5973	__ Fmov(d24, kFP32NegativeInfinity);
				5974	__ Fmov(d25, 0.0);
				5975	__ Fmov(d26, -0.0);
				5976	__ Fmov(d27, FLT_MAX);
				5977	__ Fmov(d28, FLT_MIN);
				5978	__ Fmov(d29, rawbits_to_double(0x7ff82468a0000000)); // Quiet NaN.
				5979	__ Fmov(d30, rawbits_to_double(0x7ff02468a0000000)); // Signalling NaN.
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	5980
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	5981	__ Fcvt(s0, d16);
				5982	__ Fcvt(s1, d17);
				5983	__ Fcvt(s2, d18);
				5984	__ Fcvt(s3, d19);
				5985	__ Fcvt(s4, d20);
				5986	__ Fcvt(s5, d21);
				5987	__ Fcvt(s6, d22);
				5988	__ Fcvt(s7, d23);
				5989	__ Fcvt(s8, d24);
				5990	__ Fcvt(s9, d25);
				5991	__ Fcvt(s10, d26);
				5992	__ Fcvt(s11, d27);
				5993	__ Fcvt(s12, d28);
				5994	__ Fcvt(s13, d29);
				5995	__ Fcvt(s14, d30);
				5996	END();
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	5997
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	5998	RUN();
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	5999
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	6000	ASSERT_EQUAL_FP32(1.0f, s0);
				6001	ASSERT_EQUAL_FP32(1.1f, s1);
				6002	ASSERT_EQUAL_FP32(1.5f, s2);
				6003	ASSERT_EQUAL_FP32(1.9f, s3);
				6004	ASSERT_EQUAL_FP32(2.5f, s4);
				6005	ASSERT_EQUAL_FP32(-1.5f, s5);
				6006	ASSERT_EQUAL_FP32(-2.5f, s6);
				6007	ASSERT_EQUAL_FP32(kFP32PositiveInfinity, s7);
				6008	ASSERT_EQUAL_FP32(kFP32NegativeInfinity, s8);
				6009	ASSERT_EQUAL_FP32(0.0f, s9);
				6010	ASSERT_EQUAL_FP32(-0.0f, s10);
				6011	ASSERT_EQUAL_FP32(FLT_MAX, s11);
				6012	ASSERT_EQUAL_FP32(FLT_MIN, s12);
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	6013
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	6014	// Check that the NaN payload is preserved according to A64 conversion rules:
				6015	// - The sign bit is preserved.
				6016	// - The top bit of the mantissa is forced to 1 (making it a quiet NaN).
				6017	// - The remaining mantissa bits are copied until they run out.
				6018	// - The low-order bits that haven't already been assigned are set to 0.
				6019	ASSERT_EQUAL_FP32(rawbits_to_float(0x7fc12345), s13);
				6020	ASSERT_EQUAL_FP32(rawbits_to_float(0x7fc12345), s14);
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	6021
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	6022	TEARDOWN();
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	6023	}
				6024
				6025
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	6026	TEST(fcvtas) {
				6027	SETUP();
				6028
				6029	START();
				6030	__ Fmov(s0, 1.0);
				6031	__ Fmov(s1, 1.1);
				6032	__ Fmov(s2, 2.5);
				6033	__ Fmov(s3, -2.5);
				6034	__ Fmov(s4, kFP32PositiveInfinity);
				6035	__ Fmov(s5, kFP32NegativeInfinity);
				6036	__ Fmov(s6, 0x7fffff80); // Largest float < INT32_MAX.
				6037	__ Fneg(s7, s6); // Smallest float > INT32_MIN.
				6038	__ Fmov(d8, 1.0);
				6039	__ Fmov(d9, 1.1);
				6040	__ Fmov(d10, 2.5);
				6041	__ Fmov(d11, -2.5);
				6042	__ Fmov(d12, kFP64PositiveInfinity);
				6043	__ Fmov(d13, kFP64NegativeInfinity);
				6044	__ Fmov(d14, kWMaxInt - 1);
				6045	__ Fmov(d15, kWMinInt + 1);
				6046	__ Fmov(s17, 1.1);
				6047	__ Fmov(s18, 2.5);
				6048	__ Fmov(s19, -2.5);
				6049	__ Fmov(s20, kFP32PositiveInfinity);
				6050	__ Fmov(s21, kFP32NegativeInfinity);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6051	__ Fmov(s22, 0x7fffff8000000000); // Largest float < INT64_MAX.
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	6052	__ Fneg(s23, s22); // Smallest float > INT64_MIN.
				6053	__ Fmov(d24, 1.1);
				6054	__ Fmov(d25, 2.5);
				6055	__ Fmov(d26, -2.5);
				6056	__ Fmov(d27, kFP64PositiveInfinity);
				6057	__ Fmov(d28, kFP64NegativeInfinity);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6058	__ Fmov(d29, 0x7ffffffffffffc00); // Largest double < INT64_MAX.
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	6059	__ Fneg(d30, d29); // Smallest double > INT64_MIN.
				6060
				6061	__ Fcvtas(w0, s0);
				6062	__ Fcvtas(w1, s1);
				6063	__ Fcvtas(w2, s2);
				6064	__ Fcvtas(w3, s3);
				6065	__ Fcvtas(w4, s4);
				6066	__ Fcvtas(w5, s5);
				6067	__ Fcvtas(w6, s6);
				6068	__ Fcvtas(w7, s7);
				6069	__ Fcvtas(w8, d8);
				6070	__ Fcvtas(w9, d9);
				6071	__ Fcvtas(w10, d10);
				6072	__ Fcvtas(w11, d11);
				6073	__ Fcvtas(w12, d12);
				6074	__ Fcvtas(w13, d13);
				6075	__ Fcvtas(w14, d14);
				6076	__ Fcvtas(w15, d15);
				6077	__ Fcvtas(x17, s17);
				6078	__ Fcvtas(x18, s18);
				6079	__ Fcvtas(x19, s19);
				6080	__ Fcvtas(x20, s20);
				6081	__ Fcvtas(x21, s21);
				6082	__ Fcvtas(x22, s22);
				6083	__ Fcvtas(x23, s23);
				6084	__ Fcvtas(x24, d24);
				6085	__ Fcvtas(x25, d25);
				6086	__ Fcvtas(x26, d26);
				6087	__ Fcvtas(x27, d27);
				6088	__ Fcvtas(x28, d28);
				6089	__ Fcvtas(x29, d29);
				6090	__ Fcvtas(x30, d30);
				6091	END();
				6092
				6093	RUN();
				6094
				6095	ASSERT_EQUAL_64(1, x0);
				6096	ASSERT_EQUAL_64(1, x1);
				6097	ASSERT_EQUAL_64(3, x2);
				6098	ASSERT_EQUAL_64(0xfffffffd, x3);
				6099	ASSERT_EQUAL_64(0x7fffffff, x4);
				6100	ASSERT_EQUAL_64(0x80000000, x5);
				6101	ASSERT_EQUAL_64(0x7fffff80, x6);
				6102	ASSERT_EQUAL_64(0x80000080, x7);
				6103	ASSERT_EQUAL_64(1, x8);
				6104	ASSERT_EQUAL_64(1, x9);
				6105	ASSERT_EQUAL_64(3, x10);
				6106	ASSERT_EQUAL_64(0xfffffffd, x11);
				6107	ASSERT_EQUAL_64(0x7fffffff, x12);
				6108	ASSERT_EQUAL_64(0x80000000, x13);
				6109	ASSERT_EQUAL_64(0x7ffffffe, x14);
				6110	ASSERT_EQUAL_64(0x80000001, x15);
				6111	ASSERT_EQUAL_64(1, x17);
				6112	ASSERT_EQUAL_64(3, x18);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6113	ASSERT_EQUAL_64(0xfffffffffffffffd, x19);
				6114	ASSERT_EQUAL_64(0x7fffffffffffffff, x20);
				6115	ASSERT_EQUAL_64(0x8000000000000000, x21);
				6116	ASSERT_EQUAL_64(0x7fffff8000000000, x22);
				6117	ASSERT_EQUAL_64(0x8000008000000000, x23);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	6118	ASSERT_EQUAL_64(1, x24);
				6119	ASSERT_EQUAL_64(3, x25);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6120	ASSERT_EQUAL_64(0xfffffffffffffffd, x26);
				6121	ASSERT_EQUAL_64(0x7fffffffffffffff, x27);
				6122	ASSERT_EQUAL_64(0x8000000000000000, x28);
				6123	ASSERT_EQUAL_64(0x7ffffffffffffc00, x29);
				6124	ASSERT_EQUAL_64(0x8000000000000400, x30);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	6125
				6126	TEARDOWN();
				6127	}
				6128
				6129
				6130	TEST(fcvtau) {
				6131	SETUP();
				6132
				6133	START();
				6134	__ Fmov(s0, 1.0);
				6135	__ Fmov(s1, 1.1);
				6136	__ Fmov(s2, 2.5);
				6137	__ Fmov(s3, -2.5);
				6138	__ Fmov(s4, kFP32PositiveInfinity);
				6139	__ Fmov(s5, kFP32NegativeInfinity);
				6140	__ Fmov(s6, 0xffffff00); // Largest float < UINT32_MAX.
				6141	__ Fmov(d8, 1.0);
				6142	__ Fmov(d9, 1.1);
				6143	__ Fmov(d10, 2.5);
				6144	__ Fmov(d11, -2.5);
				6145	__ Fmov(d12, kFP64PositiveInfinity);
				6146	__ Fmov(d13, kFP64NegativeInfinity);
				6147	__ Fmov(d14, 0xfffffffe);
				6148	__ Fmov(s16, 1.0);
				6149	__ Fmov(s17, 1.1);
				6150	__ Fmov(s18, 2.5);
				6151	__ Fmov(s19, -2.5);
				6152	__ Fmov(s20, kFP32PositiveInfinity);
				6153	__ Fmov(s21, kFP32NegativeInfinity);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6154	__ Fmov(s22, 0xffffff0000000000); // Largest float < UINT64_MAX.
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	6155	__ Fmov(d24, 1.1);
				6156	__ Fmov(d25, 2.5);
				6157	__ Fmov(d26, -2.5);
				6158	__ Fmov(d27, kFP64PositiveInfinity);
				6159	__ Fmov(d28, kFP64NegativeInfinity);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6160	__ Fmov(d29, 0xfffffffffffff800); // Largest double < UINT64_MAX.
				6161	__ Fmov(s30, 0x100000000);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	6162
				6163	__ Fcvtau(w0, s0);
				6164	__ Fcvtau(w1, s1);
				6165	__ Fcvtau(w2, s2);
				6166	__ Fcvtau(w3, s3);
				6167	__ Fcvtau(w4, s4);
				6168	__ Fcvtau(w5, s5);
				6169	__ Fcvtau(w6, s6);
				6170	__ Fcvtau(w8, d8);
				6171	__ Fcvtau(w9, d9);
				6172	__ Fcvtau(w10, d10);
				6173	__ Fcvtau(w11, d11);
				6174	__ Fcvtau(w12, d12);
				6175	__ Fcvtau(w13, d13);
				6176	__ Fcvtau(w14, d14);
				6177	__ Fcvtau(w15, d15);
				6178	__ Fcvtau(x16, s16);
				6179	__ Fcvtau(x17, s17);
				6180	__ Fcvtau(x18, s18);
				6181	__ Fcvtau(x19, s19);
				6182	__ Fcvtau(x20, s20);
				6183	__ Fcvtau(x21, s21);
				6184	__ Fcvtau(x22, s22);
				6185	__ Fcvtau(x24, d24);
				6186	__ Fcvtau(x25, d25);
				6187	__ Fcvtau(x26, d26);
				6188	__ Fcvtau(x27, d27);
				6189	__ Fcvtau(x28, d28);
				6190	__ Fcvtau(x29, d29);
				6191	__ Fcvtau(w30, s30);
				6192	END();
				6193
				6194	RUN();
				6195
				6196	ASSERT_EQUAL_64(1, x0);
				6197	ASSERT_EQUAL_64(1, x1);
				6198	ASSERT_EQUAL_64(3, x2);
				6199	ASSERT_EQUAL_64(0, x3);
				6200	ASSERT_EQUAL_64(0xffffffff, x4);
				6201	ASSERT_EQUAL_64(0, x5);
				6202	ASSERT_EQUAL_64(0xffffff00, x6);
				6203	ASSERT_EQUAL_64(1, x8);
				6204	ASSERT_EQUAL_64(1, x9);
				6205	ASSERT_EQUAL_64(3, x10);
				6206	ASSERT_EQUAL_64(0, x11);
				6207	ASSERT_EQUAL_64(0xffffffff, x12);
				6208	ASSERT_EQUAL_64(0, x13);
				6209	ASSERT_EQUAL_64(0xfffffffe, x14);
				6210	ASSERT_EQUAL_64(1, x16);
				6211	ASSERT_EQUAL_64(1, x17);
				6212	ASSERT_EQUAL_64(3, x18);
				6213	ASSERT_EQUAL_64(0, x19);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6214	ASSERT_EQUAL_64(0xffffffffffffffff, x20);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	6215	ASSERT_EQUAL_64(0, x21);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6216	ASSERT_EQUAL_64(0xffffff0000000000, x22);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	6217	ASSERT_EQUAL_64(1, x24);
				6218	ASSERT_EQUAL_64(3, x25);
				6219	ASSERT_EQUAL_64(0, x26);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6220	ASSERT_EQUAL_64(0xffffffffffffffff, x27);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	6221	ASSERT_EQUAL_64(0, x28);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6222	ASSERT_EQUAL_64(0xfffffffffffff800, x29);
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	6223	ASSERT_EQUAL_64(0xffffffff, x30);
				6224
				6225	TEARDOWN();
				6226	}
				6227
				6228
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6229	TEST(fcvtms) {
				6230	SETUP();
				6231
				6232	START();
				6233	__ Fmov(s0, 1.0);
				6234	__ Fmov(s1, 1.1);
				6235	__ Fmov(s2, 1.5);
				6236	__ Fmov(s3, -1.5);
				6237	__ Fmov(s4, kFP32PositiveInfinity);
				6238	__ Fmov(s5, kFP32NegativeInfinity);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6239	__ Fmov(s6, 0x7fffff80); // Largest float < INT32_MAX.
				6240	__ Fneg(s7, s6); // Smallest float > INT32_MIN.
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6241	__ Fmov(d8, 1.0);
				6242	__ Fmov(d9, 1.1);
				6243	__ Fmov(d10, 1.5);
				6244	__ Fmov(d11, -1.5);
				6245	__ Fmov(d12, kFP64PositiveInfinity);
				6246	__ Fmov(d13, kFP64NegativeInfinity);
				6247	__ Fmov(d14, kWMaxInt - 1);
				6248	__ Fmov(d15, kWMinInt + 1);
				6249	__ Fmov(s17, 1.1);
				6250	__ Fmov(s18, 1.5);
				6251	__ Fmov(s19, -1.5);
				6252	__ Fmov(s20, kFP32PositiveInfinity);
				6253	__ Fmov(s21, kFP32NegativeInfinity);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6254	__ Fmov(s22, 0x7fffff8000000000); // Largest float < INT64_MAX.
				6255	__ Fneg(s23, s22); // Smallest float > INT64_MIN.
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6256	__ Fmov(d24, 1.1);
				6257	__ Fmov(d25, 1.5);
				6258	__ Fmov(d26, -1.5);
				6259	__ Fmov(d27, kFP64PositiveInfinity);
				6260	__ Fmov(d28, kFP64NegativeInfinity);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6261	__ Fmov(d29, 0x7ffffffffffffc00); // Largest double < INT64_MAX.
				6262	__ Fneg(d30, d29); // Smallest double > INT64_MIN.
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6263
				6264	__ Fcvtms(w0, s0);
				6265	__ Fcvtms(w1, s1);
				6266	__ Fcvtms(w2, s2);
				6267	__ Fcvtms(w3, s3);
				6268	__ Fcvtms(w4, s4);
				6269	__ Fcvtms(w5, s5);
				6270	__ Fcvtms(w6, s6);
				6271	__ Fcvtms(w7, s7);
				6272	__ Fcvtms(w8, d8);
				6273	__ Fcvtms(w9, d9);
				6274	__ Fcvtms(w10, d10);
				6275	__ Fcvtms(w11, d11);
				6276	__ Fcvtms(w12, d12);
				6277	__ Fcvtms(w13, d13);
				6278	__ Fcvtms(w14, d14);
				6279	__ Fcvtms(w15, d15);
				6280	__ Fcvtms(x17, s17);
				6281	__ Fcvtms(x18, s18);
				6282	__ Fcvtms(x19, s19);
				6283	__ Fcvtms(x20, s20);
				6284	__ Fcvtms(x21, s21);
				6285	__ Fcvtms(x22, s22);
				6286	__ Fcvtms(x23, s23);
				6287	__ Fcvtms(x24, d24);
				6288	__ Fcvtms(x25, d25);
				6289	__ Fcvtms(x26, d26);
				6290	__ Fcvtms(x27, d27);
				6291	__ Fcvtms(x28, d28);
				6292	__ Fcvtms(x29, d29);
				6293	__ Fcvtms(x30, d30);
				6294	END();
				6295
				6296	RUN();
				6297
				6298	ASSERT_EQUAL_64(1, x0);
				6299	ASSERT_EQUAL_64(1, x1);
				6300	ASSERT_EQUAL_64(1, x2);
				6301	ASSERT_EQUAL_64(0xfffffffe, x3);
				6302	ASSERT_EQUAL_64(0x7fffffff, x4);
				6303	ASSERT_EQUAL_64(0x80000000, x5);
				6304	ASSERT_EQUAL_64(0x7fffff80, x6);
				6305	ASSERT_EQUAL_64(0x80000080, x7);
				6306	ASSERT_EQUAL_64(1, x8);
				6307	ASSERT_EQUAL_64(1, x9);
				6308	ASSERT_EQUAL_64(1, x10);
				6309	ASSERT_EQUAL_64(0xfffffffe, x11);
				6310	ASSERT_EQUAL_64(0x7fffffff, x12);
				6311	ASSERT_EQUAL_64(0x80000000, x13);
				6312	ASSERT_EQUAL_64(0x7ffffffe, x14);
				6313	ASSERT_EQUAL_64(0x80000001, x15);
				6314	ASSERT_EQUAL_64(1, x17);
				6315	ASSERT_EQUAL_64(1, x18);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6316	ASSERT_EQUAL_64(0xfffffffffffffffe, x19);
				6317	ASSERT_EQUAL_64(0x7fffffffffffffff, x20);
				6318	ASSERT_EQUAL_64(0x8000000000000000, x21);
				6319	ASSERT_EQUAL_64(0x7fffff8000000000, x22);
				6320	ASSERT_EQUAL_64(0x8000008000000000, x23);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6321	ASSERT_EQUAL_64(1, x24);
				6322	ASSERT_EQUAL_64(1, x25);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6323	ASSERT_EQUAL_64(0xfffffffffffffffe, x26);
				6324	ASSERT_EQUAL_64(0x7fffffffffffffff, x27);
				6325	ASSERT_EQUAL_64(0x8000000000000000, x28);
				6326	ASSERT_EQUAL_64(0x7ffffffffffffc00, x29);
				6327	ASSERT_EQUAL_64(0x8000000000000400, x30);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6328
				6329	TEARDOWN();
				6330	}
				6331
				6332
				6333	TEST(fcvtmu) {
				6334	SETUP();
				6335
				6336	START();
				6337	__ Fmov(s0, 1.0);
				6338	__ Fmov(s1, 1.1);
				6339	__ Fmov(s2, 1.5);
				6340	__ Fmov(s3, -1.5);
				6341	__ Fmov(s4, kFP32PositiveInfinity);
				6342	__ Fmov(s5, kFP32NegativeInfinity);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6343	__ Fmov(s6, 0x7fffff80); // Largest float < INT32_MAX.
				6344	__ Fneg(s7, s6); // Smallest float > INT32_MIN.
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6345	__ Fmov(d8, 1.0);
				6346	__ Fmov(d9, 1.1);
				6347	__ Fmov(d10, 1.5);
				6348	__ Fmov(d11, -1.5);
				6349	__ Fmov(d12, kFP64PositiveInfinity);
				6350	__ Fmov(d13, kFP64NegativeInfinity);
				6351	__ Fmov(d14, kWMaxInt - 1);
				6352	__ Fmov(d15, kWMinInt + 1);
				6353	__ Fmov(s17, 1.1);
				6354	__ Fmov(s18, 1.5);
				6355	__ Fmov(s19, -1.5);
				6356	__ Fmov(s20, kFP32PositiveInfinity);
				6357	__ Fmov(s21, kFP32NegativeInfinity);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6358	__ Fmov(s22, 0x7fffff8000000000); // Largest float < INT64_MAX.
				6359	__ Fneg(s23, s22); // Smallest float > INT64_MIN.
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6360	__ Fmov(d24, 1.1);
				6361	__ Fmov(d25, 1.5);
				6362	__ Fmov(d26, -1.5);
				6363	__ Fmov(d27, kFP64PositiveInfinity);
				6364	__ Fmov(d28, kFP64NegativeInfinity);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6365	__ Fmov(d29, 0x7ffffffffffffc00); // Largest double < INT64_MAX.
				6366	__ Fneg(d30, d29); // Smallest double > INT64_MIN.
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6367
				6368	__ Fcvtmu(w0, s0);
				6369	__ Fcvtmu(w1, s1);
				6370	__ Fcvtmu(w2, s2);
				6371	__ Fcvtmu(w3, s3);
				6372	__ Fcvtmu(w4, s4);
				6373	__ Fcvtmu(w5, s5);
				6374	__ Fcvtmu(w6, s6);
				6375	__ Fcvtmu(w7, s7);
				6376	__ Fcvtmu(w8, d8);
				6377	__ Fcvtmu(w9, d9);
				6378	__ Fcvtmu(w10, d10);
				6379	__ Fcvtmu(w11, d11);
				6380	__ Fcvtmu(w12, d12);
				6381	__ Fcvtmu(w13, d13);
				6382	__ Fcvtmu(w14, d14);
				6383	__ Fcvtmu(x17, s17);
				6384	__ Fcvtmu(x18, s18);
				6385	__ Fcvtmu(x19, s19);
				6386	__ Fcvtmu(x20, s20);
				6387	__ Fcvtmu(x21, s21);
				6388	__ Fcvtmu(x22, s22);
				6389	__ Fcvtmu(x23, s23);
				6390	__ Fcvtmu(x24, d24);
				6391	__ Fcvtmu(x25, d25);
				6392	__ Fcvtmu(x26, d26);
				6393	__ Fcvtmu(x27, d27);
				6394	__ Fcvtmu(x28, d28);
				6395	__ Fcvtmu(x29, d29);
				6396	__ Fcvtmu(x30, d30);
				6397	END();
				6398
				6399	RUN();
				6400
				6401	ASSERT_EQUAL_64(1, x0);
				6402	ASSERT_EQUAL_64(1, x1);
				6403	ASSERT_EQUAL_64(1, x2);
				6404	ASSERT_EQUAL_64(0, x3);
				6405	ASSERT_EQUAL_64(0xffffffff, x4);
				6406	ASSERT_EQUAL_64(0, x5);
				6407	ASSERT_EQUAL_64(0x7fffff80, x6);
				6408	ASSERT_EQUAL_64(0, x7);
				6409	ASSERT_EQUAL_64(1, x8);
				6410	ASSERT_EQUAL_64(1, x9);
				6411	ASSERT_EQUAL_64(1, x10);
				6412	ASSERT_EQUAL_64(0, x11);
				6413	ASSERT_EQUAL_64(0xffffffff, x12);
				6414	ASSERT_EQUAL_64(0, x13);
				6415	ASSERT_EQUAL_64(0x7ffffffe, x14);
				6416	ASSERT_EQUAL_64(1, x17);
				6417	ASSERT_EQUAL_64(1, x18);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6418	ASSERT_EQUAL_64(0, x19);
				6419	ASSERT_EQUAL_64(0xffffffffffffffff, x20);
				6420	ASSERT_EQUAL_64(0, x21);
				6421	ASSERT_EQUAL_64(0x7fffff8000000000, x22);
				6422	ASSERT_EQUAL_64(0, x23);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6423	ASSERT_EQUAL_64(1, x24);
				6424	ASSERT_EQUAL_64(1, x25);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6425	ASSERT_EQUAL_64(0, x26);
				6426	ASSERT_EQUAL_64(0xffffffffffffffff, x27);
				6427	ASSERT_EQUAL_64(0, x28);
				6428	ASSERT_EQUAL_64(0x7ffffffffffffc00, x29);
				6429	ASSERT_EQUAL_64(0, x30);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6430
				6431	TEARDOWN();
				6432	}
				6433
				6434
				6435	TEST(fcvtns) {
				6436	SETUP();
				6437
				6438	START();
				6439	__ Fmov(s0, 1.0);
				6440	__ Fmov(s1, 1.1);
				6441	__ Fmov(s2, 1.5);
				6442	__ Fmov(s3, -1.5);
				6443	__ Fmov(s4, kFP32PositiveInfinity);
				6444	__ Fmov(s5, kFP32NegativeInfinity);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6445	__ Fmov(s6, 0x7fffff80); // Largest float < INT32_MAX.
				6446	__ Fneg(s7, s6); // Smallest float > INT32_MIN.
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6447	__ Fmov(d8, 1.0);
				6448	__ Fmov(d9, 1.1);
				6449	__ Fmov(d10, 1.5);
				6450	__ Fmov(d11, -1.5);
				6451	__ Fmov(d12, kFP64PositiveInfinity);
				6452	__ Fmov(d13, kFP64NegativeInfinity);
				6453	__ Fmov(d14, kWMaxInt - 1);
				6454	__ Fmov(d15, kWMinInt + 1);
				6455	__ Fmov(s17, 1.1);
				6456	__ Fmov(s18, 1.5);
				6457	__ Fmov(s19, -1.5);
				6458	__ Fmov(s20, kFP32PositiveInfinity);
				6459	__ Fmov(s21, kFP32NegativeInfinity);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6460	__ Fmov(s22, 0x7fffff8000000000); // Largest float < INT64_MAX.
				6461	__ Fneg(s23, s22); // Smallest float > INT64_MIN.
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6462	__ Fmov(d24, 1.1);
				6463	__ Fmov(d25, 1.5);
				6464	__ Fmov(d26, -1.5);
				6465	__ Fmov(d27, kFP64PositiveInfinity);
				6466	__ Fmov(d28, kFP64NegativeInfinity);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6467	__ Fmov(d29, 0x7ffffffffffffc00); // Largest double < INT64_MAX.
				6468	__ Fneg(d30, d29); // Smallest double > INT64_MIN.
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6469
				6470	__ Fcvtns(w0, s0);
				6471	__ Fcvtns(w1, s1);
				6472	__ Fcvtns(w2, s2);
				6473	__ Fcvtns(w3, s3);
				6474	__ Fcvtns(w4, s4);
				6475	__ Fcvtns(w5, s5);
				6476	__ Fcvtns(w6, s6);
				6477	__ Fcvtns(w7, s7);
				6478	__ Fcvtns(w8, d8);
				6479	__ Fcvtns(w9, d9);
				6480	__ Fcvtns(w10, d10);
				6481	__ Fcvtns(w11, d11);
				6482	__ Fcvtns(w12, d12);
				6483	__ Fcvtns(w13, d13);
				6484	__ Fcvtns(w14, d14);
				6485	__ Fcvtns(w15, d15);
				6486	__ Fcvtns(x17, s17);
				6487	__ Fcvtns(x18, s18);
				6488	__ Fcvtns(x19, s19);
				6489	__ Fcvtns(x20, s20);
				6490	__ Fcvtns(x21, s21);
				6491	__ Fcvtns(x22, s22);
				6492	__ Fcvtns(x23, s23);
				6493	__ Fcvtns(x24, d24);
				6494	__ Fcvtns(x25, d25);
				6495	__ Fcvtns(x26, d26);
				6496	__ Fcvtns(x27, d27);
				6497	__ Fcvtns(x28, d28);
				6498	__ Fcvtns(x29, d29);
				6499	__ Fcvtns(x30, d30);
				6500	END();
				6501
				6502	RUN();
				6503
				6504	ASSERT_EQUAL_64(1, x0);
				6505	ASSERT_EQUAL_64(1, x1);
				6506	ASSERT_EQUAL_64(2, x2);
				6507	ASSERT_EQUAL_64(0xfffffffe, x3);
				6508	ASSERT_EQUAL_64(0x7fffffff, x4);
				6509	ASSERT_EQUAL_64(0x80000000, x5);
				6510	ASSERT_EQUAL_64(0x7fffff80, x6);
				6511	ASSERT_EQUAL_64(0x80000080, x7);
				6512	ASSERT_EQUAL_64(1, x8);
				6513	ASSERT_EQUAL_64(1, x9);
				6514	ASSERT_EQUAL_64(2, x10);
				6515	ASSERT_EQUAL_64(0xfffffffe, x11);
				6516	ASSERT_EQUAL_64(0x7fffffff, x12);
				6517	ASSERT_EQUAL_64(0x80000000, x13);
				6518	ASSERT_EQUAL_64(0x7ffffffe, x14);
				6519	ASSERT_EQUAL_64(0x80000001, x15);
				6520	ASSERT_EQUAL_64(1, x17);
				6521	ASSERT_EQUAL_64(2, x18);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6522	ASSERT_EQUAL_64(0xfffffffffffffffe, x19);
				6523	ASSERT_EQUAL_64(0x7fffffffffffffff, x20);
				6524	ASSERT_EQUAL_64(0x8000000000000000, x21);
				6525	ASSERT_EQUAL_64(0x7fffff8000000000, x22);
				6526	ASSERT_EQUAL_64(0x8000008000000000, x23);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6527	ASSERT_EQUAL_64(1, x24);
				6528	ASSERT_EQUAL_64(2, x25);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6529	ASSERT_EQUAL_64(0xfffffffffffffffe, x26);
				6530	ASSERT_EQUAL_64(0x7fffffffffffffff, x27);
				6531	ASSERT_EQUAL_64(0x8000000000000000, x28);
				6532	ASSERT_EQUAL_64(0x7ffffffffffffc00, x29);
				6533	ASSERT_EQUAL_64(0x8000000000000400, x30);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6534
				6535	TEARDOWN();
				6536	}
				6537
				6538
				6539	TEST(fcvtnu) {
				6540	SETUP();
				6541
				6542	START();
				6543	__ Fmov(s0, 1.0);
				6544	__ Fmov(s1, 1.1);
				6545	__ Fmov(s2, 1.5);
				6546	__ Fmov(s3, -1.5);
				6547	__ Fmov(s4, kFP32PositiveInfinity);
				6548	__ Fmov(s5, kFP32NegativeInfinity);
				6549	__ Fmov(s6, 0xffffff00); // Largest float < UINT32_MAX.
				6550	__ Fmov(d8, 1.0);
				6551	__ Fmov(d9, 1.1);
				6552	__ Fmov(d10, 1.5);
				6553	__ Fmov(d11, -1.5);
				6554	__ Fmov(d12, kFP64PositiveInfinity);
				6555	__ Fmov(d13, kFP64NegativeInfinity);
				6556	__ Fmov(d14, 0xfffffffe);
				6557	__ Fmov(s16, 1.0);
				6558	__ Fmov(s17, 1.1);
				6559	__ Fmov(s18, 1.5);
				6560	__ Fmov(s19, -1.5);
				6561	__ Fmov(s20, kFP32PositiveInfinity);
				6562	__ Fmov(s21, kFP32NegativeInfinity);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6563	__ Fmov(s22, 0xffffff0000000000); // Largest float < UINT64_MAX.
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6564	__ Fmov(d24, 1.1);
				6565	__ Fmov(d25, 1.5);
				6566	__ Fmov(d26, -1.5);
				6567	__ Fmov(d27, kFP64PositiveInfinity);
				6568	__ Fmov(d28, kFP64NegativeInfinity);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6569	__ Fmov(d29, 0xfffffffffffff800); // Largest double < UINT64_MAX.
				6570	__ Fmov(s30, 0x100000000);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6571
				6572	__ Fcvtnu(w0, s0);
				6573	__ Fcvtnu(w1, s1);
				6574	__ Fcvtnu(w2, s2);
				6575	__ Fcvtnu(w3, s3);
				6576	__ Fcvtnu(w4, s4);
				6577	__ Fcvtnu(w5, s5);
				6578	__ Fcvtnu(w6, s6);
				6579	__ Fcvtnu(w8, d8);
				6580	__ Fcvtnu(w9, d9);
				6581	__ Fcvtnu(w10, d10);
				6582	__ Fcvtnu(w11, d11);
				6583	__ Fcvtnu(w12, d12);
				6584	__ Fcvtnu(w13, d13);
				6585	__ Fcvtnu(w14, d14);
				6586	__ Fcvtnu(w15, d15);
				6587	__ Fcvtnu(x16, s16);
				6588	__ Fcvtnu(x17, s17);
				6589	__ Fcvtnu(x18, s18);
				6590	__ Fcvtnu(x19, s19);
				6591	__ Fcvtnu(x20, s20);
				6592	__ Fcvtnu(x21, s21);
				6593	__ Fcvtnu(x22, s22);
				6594	__ Fcvtnu(x24, d24);
				6595	__ Fcvtnu(x25, d25);
				6596	__ Fcvtnu(x26, d26);
				6597	__ Fcvtnu(x27, d27);
				6598	__ Fcvtnu(x28, d28);
				6599	__ Fcvtnu(x29, d29);
				6600	__ Fcvtnu(w30, s30);
				6601	END();
				6602
				6603	RUN();
				6604
				6605	ASSERT_EQUAL_64(1, x0);
				6606	ASSERT_EQUAL_64(1, x1);
				6607	ASSERT_EQUAL_64(2, x2);
				6608	ASSERT_EQUAL_64(0, x3);
				6609	ASSERT_EQUAL_64(0xffffffff, x4);
				6610	ASSERT_EQUAL_64(0, x5);
				6611	ASSERT_EQUAL_64(0xffffff00, x6);
				6612	ASSERT_EQUAL_64(1, x8);
				6613	ASSERT_EQUAL_64(1, x9);
				6614	ASSERT_EQUAL_64(2, x10);
				6615	ASSERT_EQUAL_64(0, x11);
				6616	ASSERT_EQUAL_64(0xffffffff, x12);
				6617	ASSERT_EQUAL_64(0, x13);
				6618	ASSERT_EQUAL_64(0xfffffffe, x14);
				6619	ASSERT_EQUAL_64(1, x16);
				6620	ASSERT_EQUAL_64(1, x17);
				6621	ASSERT_EQUAL_64(2, x18);
				6622	ASSERT_EQUAL_64(0, x19);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6623	ASSERT_EQUAL_64(0xffffffffffffffff, x20);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6624	ASSERT_EQUAL_64(0, x21);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6625	ASSERT_EQUAL_64(0xffffff0000000000, x22);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6626	ASSERT_EQUAL_64(1, x24);
				6627	ASSERT_EQUAL_64(2, x25);
				6628	ASSERT_EQUAL_64(0, x26);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6629	ASSERT_EQUAL_64(0xffffffffffffffff, x27);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6630	ASSERT_EQUAL_64(0, x28);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6631	ASSERT_EQUAL_64(0xfffffffffffff800, x29);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6632	ASSERT_EQUAL_64(0xffffffff, x30);
				6633
				6634	TEARDOWN();
				6635	}
				6636
				6637
				6638	TEST(fcvtzs) {
				6639	SETUP();
				6640
				6641	START();
				6642	__ Fmov(s0, 1.0);
				6643	__ Fmov(s1, 1.1);
				6644	__ Fmov(s2, 1.5);
				6645	__ Fmov(s3, -1.5);
				6646	__ Fmov(s4, kFP32PositiveInfinity);
				6647	__ Fmov(s5, kFP32NegativeInfinity);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6648	__ Fmov(s6, 0x7fffff80); // Largest float < INT32_MAX.
				6649	__ Fneg(s7, s6); // Smallest float > INT32_MIN.
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6650	__ Fmov(d8, 1.0);
				6651	__ Fmov(d9, 1.1);
				6652	__ Fmov(d10, 1.5);
				6653	__ Fmov(d11, -1.5);
				6654	__ Fmov(d12, kFP64PositiveInfinity);
				6655	__ Fmov(d13, kFP64NegativeInfinity);
				6656	__ Fmov(d14, kWMaxInt - 1);
				6657	__ Fmov(d15, kWMinInt + 1);
				6658	__ Fmov(s17, 1.1);
				6659	__ Fmov(s18, 1.5);
				6660	__ Fmov(s19, -1.5);
				6661	__ Fmov(s20, kFP32PositiveInfinity);
				6662	__ Fmov(s21, kFP32NegativeInfinity);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6663	__ Fmov(s22, 0x7fffff8000000000); // Largest float < INT64_MAX.
				6664	__ Fneg(s23, s22); // Smallest float > INT64_MIN.
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6665	__ Fmov(d24, 1.1);
				6666	__ Fmov(d25, 1.5);
				6667	__ Fmov(d26, -1.5);
				6668	__ Fmov(d27, kFP64PositiveInfinity);
				6669	__ Fmov(d28, kFP64NegativeInfinity);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6670	__ Fmov(d29, 0x7ffffffffffffc00); // Largest double < INT64_MAX.
				6671	__ Fneg(d30, d29); // Smallest double > INT64_MIN.
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6672
				6673	__ Fcvtzs(w0, s0);
				6674	__ Fcvtzs(w1, s1);
				6675	__ Fcvtzs(w2, s2);
				6676	__ Fcvtzs(w3, s3);
				6677	__ Fcvtzs(w4, s4);
				6678	__ Fcvtzs(w5, s5);
				6679	__ Fcvtzs(w6, s6);
				6680	__ Fcvtzs(w7, s7);
				6681	__ Fcvtzs(w8, d8);
				6682	__ Fcvtzs(w9, d9);
				6683	__ Fcvtzs(w10, d10);
				6684	__ Fcvtzs(w11, d11);
				6685	__ Fcvtzs(w12, d12);
				6686	__ Fcvtzs(w13, d13);
				6687	__ Fcvtzs(w14, d14);
				6688	__ Fcvtzs(w15, d15);
				6689	__ Fcvtzs(x17, s17);
				6690	__ Fcvtzs(x18, s18);
				6691	__ Fcvtzs(x19, s19);
				6692	__ Fcvtzs(x20, s20);
				6693	__ Fcvtzs(x21, s21);
				6694	__ Fcvtzs(x22, s22);
				6695	__ Fcvtzs(x23, s23);
				6696	__ Fcvtzs(x24, d24);
				6697	__ Fcvtzs(x25, d25);
				6698	__ Fcvtzs(x26, d26);
				6699	__ Fcvtzs(x27, d27);
				6700	__ Fcvtzs(x28, d28);
				6701	__ Fcvtzs(x29, d29);
				6702	__ Fcvtzs(x30, d30);
				6703	END();
				6704
				6705	RUN();
				6706
				6707	ASSERT_EQUAL_64(1, x0);
				6708	ASSERT_EQUAL_64(1, x1);
				6709	ASSERT_EQUAL_64(1, x2);
				6710	ASSERT_EQUAL_64(0xffffffff, x3);
				6711	ASSERT_EQUAL_64(0x7fffffff, x4);
				6712	ASSERT_EQUAL_64(0x80000000, x5);
				6713	ASSERT_EQUAL_64(0x7fffff80, x6);
				6714	ASSERT_EQUAL_64(0x80000080, x7);
				6715	ASSERT_EQUAL_64(1, x8);
				6716	ASSERT_EQUAL_64(1, x9);
				6717	ASSERT_EQUAL_64(1, x10);
				6718	ASSERT_EQUAL_64(0xffffffff, x11);
				6719	ASSERT_EQUAL_64(0x7fffffff, x12);
				6720	ASSERT_EQUAL_64(0x80000000, x13);
				6721	ASSERT_EQUAL_64(0x7ffffffe, x14);
				6722	ASSERT_EQUAL_64(0x80000001, x15);
				6723	ASSERT_EQUAL_64(1, x17);
				6724	ASSERT_EQUAL_64(1, x18);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6725	ASSERT_EQUAL_64(0xffffffffffffffff, x19);
				6726	ASSERT_EQUAL_64(0x7fffffffffffffff, x20);
				6727	ASSERT_EQUAL_64(0x8000000000000000, x21);
				6728	ASSERT_EQUAL_64(0x7fffff8000000000, x22);
				6729	ASSERT_EQUAL_64(0x8000008000000000, x23);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6730	ASSERT_EQUAL_64(1, x24);
				6731	ASSERT_EQUAL_64(1, x25);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6732	ASSERT_EQUAL_64(0xffffffffffffffff, x26);
				6733	ASSERT_EQUAL_64(0x7fffffffffffffff, x27);
				6734	ASSERT_EQUAL_64(0x8000000000000000, x28);
				6735	ASSERT_EQUAL_64(0x7ffffffffffffc00, x29);
				6736	ASSERT_EQUAL_64(0x8000000000000400, x30);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6737
				6738	TEARDOWN();
				6739	}
				6740
				6741	TEST(fcvtzu) {
				6742	SETUP();
				6743
				6744	START();
				6745	__ Fmov(s0, 1.0);
				6746	__ Fmov(s1, 1.1);
				6747	__ Fmov(s2, 1.5);
				6748	__ Fmov(s3, -1.5);
				6749	__ Fmov(s4, kFP32PositiveInfinity);
				6750	__ Fmov(s5, kFP32NegativeInfinity);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6751	__ Fmov(s6, 0x7fffff80); // Largest float < INT32_MAX.
				6752	__ Fneg(s7, s6); // Smallest float > INT32_MIN.
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6753	__ Fmov(d8, 1.0);
				6754	__ Fmov(d9, 1.1);
				6755	__ Fmov(d10, 1.5);
				6756	__ Fmov(d11, -1.5);
				6757	__ Fmov(d12, kFP64PositiveInfinity);
				6758	__ Fmov(d13, kFP64NegativeInfinity);
				6759	__ Fmov(d14, kWMaxInt - 1);
				6760	__ Fmov(d15, kWMinInt + 1);
				6761	__ Fmov(s17, 1.1);
				6762	__ Fmov(s18, 1.5);
				6763	__ Fmov(s19, -1.5);
				6764	__ Fmov(s20, kFP32PositiveInfinity);
				6765	__ Fmov(s21, kFP32NegativeInfinity);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6766	__ Fmov(s22, 0x7fffff8000000000); // Largest float < INT64_MAX.
				6767	__ Fneg(s23, s22); // Smallest float > INT64_MIN.
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6768	__ Fmov(d24, 1.1);
				6769	__ Fmov(d25, 1.5);
				6770	__ Fmov(d26, -1.5);
				6771	__ Fmov(d27, kFP64PositiveInfinity);
				6772	__ Fmov(d28, kFP64NegativeInfinity);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6773	__ Fmov(d29, 0x7ffffffffffffc00); // Largest double < INT64_MAX.
				6774	__ Fneg(d30, d29); // Smallest double > INT64_MIN.
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6775
				6776	__ Fcvtzu(w0, s0);
				6777	__ Fcvtzu(w1, s1);
				6778	__ Fcvtzu(w2, s2);
				6779	__ Fcvtzu(w3, s3);
				6780	__ Fcvtzu(w4, s4);
				6781	__ Fcvtzu(w5, s5);
				6782	__ Fcvtzu(w6, s6);
				6783	__ Fcvtzu(w7, s7);
				6784	__ Fcvtzu(w8, d8);
				6785	__ Fcvtzu(w9, d9);
				6786	__ Fcvtzu(w10, d10);
				6787	__ Fcvtzu(w11, d11);
				6788	__ Fcvtzu(w12, d12);
				6789	__ Fcvtzu(w13, d13);
				6790	__ Fcvtzu(w14, d14);
				6791	__ Fcvtzu(x17, s17);
				6792	__ Fcvtzu(x18, s18);
				6793	__ Fcvtzu(x19, s19);
				6794	__ Fcvtzu(x20, s20);
				6795	__ Fcvtzu(x21, s21);
				6796	__ Fcvtzu(x22, s22);
				6797	__ Fcvtzu(x23, s23);
				6798	__ Fcvtzu(x24, d24);
				6799	__ Fcvtzu(x25, d25);
				6800	__ Fcvtzu(x26, d26);
				6801	__ Fcvtzu(x27, d27);
				6802	__ Fcvtzu(x28, d28);
				6803	__ Fcvtzu(x29, d29);
				6804	__ Fcvtzu(x30, d30);
				6805	END();
				6806
				6807	RUN();
				6808
				6809	ASSERT_EQUAL_64(1, x0);
				6810	ASSERT_EQUAL_64(1, x1);
				6811	ASSERT_EQUAL_64(1, x2);
				6812	ASSERT_EQUAL_64(0, x3);
				6813	ASSERT_EQUAL_64(0xffffffff, x4);
				6814	ASSERT_EQUAL_64(0, x5);
				6815	ASSERT_EQUAL_64(0x7fffff80, x6);
				6816	ASSERT_EQUAL_64(0, x7);
				6817	ASSERT_EQUAL_64(1, x8);
				6818	ASSERT_EQUAL_64(1, x9);
				6819	ASSERT_EQUAL_64(1, x10);
				6820	ASSERT_EQUAL_64(0, x11);
				6821	ASSERT_EQUAL_64(0xffffffff, x12);
				6822	ASSERT_EQUAL_64(0, x13);
				6823	ASSERT_EQUAL_64(0x7ffffffe, x14);
				6824	ASSERT_EQUAL_64(1, x17);
				6825	ASSERT_EQUAL_64(1, x18);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6826	ASSERT_EQUAL_64(0, x19);
				6827	ASSERT_EQUAL_64(0xffffffffffffffff, x20);
				6828	ASSERT_EQUAL_64(0, x21);
				6829	ASSERT_EQUAL_64(0x7fffff8000000000, x22);
				6830	ASSERT_EQUAL_64(0, x23);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6831	ASSERT_EQUAL_64(1, x24);
				6832	ASSERT_EQUAL_64(1, x25);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6833	ASSERT_EQUAL_64(0, x26);
				6834	ASSERT_EQUAL_64(0xffffffffffffffff, x27);
				6835	ASSERT_EQUAL_64(0, x28);
				6836	ASSERT_EQUAL_64(0x7ffffffffffffc00, x29);
				6837	ASSERT_EQUAL_64(0, x30);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6838
				6839	TEARDOWN();
				6840	}
				6841
				6842
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	6843	// Test that scvtf and ucvtf can convert the 64-bit input into the expected
				6844	// value. All possible values of 'fbits' are tested. The expected value is
				6845	// modified accordingly in each case.
				6846	//
				6847	// The expected value is specified as the bit encoding of the expected double
				6848	// produced by scvtf (expected_scvtf_bits) as well as ucvtf
				6849	// (expected_ucvtf_bits).
				6850	//
				6851	// Where the input value is representable by int32_t or uint32_t, conversions
				6852	// from W registers will also be tested.
				6853	static void TestUScvtfHelper(uint64_t in,
				6854	uint64_t expected_scvtf_bits,
				6855	uint64_t expected_ucvtf_bits) {
				6856	uint64_t u64 = in;
				6857	uint32_t u32 = u64 & 0xffffffff;
				6858	int64_t s64 = static_cast<int64_t>(in);
				6859	int32_t s32 = s64 & 0x7fffffff;
				6860
				6861	bool cvtf_s32 = (s64 == s32);
				6862	bool cvtf_u32 = (u64 == u32);
				6863
				6864	double results_scvtf_x[65];
				6865	double results_ucvtf_x[65];
				6866	double results_scvtf_w[33];
				6867	double results_ucvtf_w[33];
				6868
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6869	SETUP();
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6870	START();
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6871
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	6872	__ Mov(x0, reinterpret_cast<uintptr_t>(results_scvtf_x));
				6873	__ Mov(x1, reinterpret_cast<uintptr_t>(results_ucvtf_x));
				6874	__ Mov(x2, reinterpret_cast<uintptr_t>(results_scvtf_w));
				6875	__ Mov(x3, reinterpret_cast<uintptr_t>(results_ucvtf_w));
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	6876
				6877	__ Mov(x10, s64);
				6878
				6879	// Corrupt the top word, in case it is accidentally used during W-register
				6880	// conversions.
				6881	__ Mov(x11, 0x5555555555555555);
				6882	__ Bfi(x11, x10, 0, kWRegSize);
				6883
				6884	// Test integer conversions.
				6885	__ Scvtf(d0, x10);
				6886	__ Ucvtf(d1, x10);
				6887	__ Scvtf(d2, w11);
				6888	__ Ucvtf(d3, w11);
				6889	__ Str(d0, MemOperand(x0));
				6890	__ Str(d1, MemOperand(x1));
				6891	__ Str(d2, MemOperand(x2));
				6892	__ Str(d3, MemOperand(x3));
				6893
				6894	// Test all possible values of fbits.
				6895	for (int fbits = 1; fbits <= 32; fbits++) {
				6896	__ Scvtf(d0, x10, fbits);
				6897	__ Ucvtf(d1, x10, fbits);
				6898	__ Scvtf(d2, w11, fbits);
				6899	__ Ucvtf(d3, w11, fbits);
				6900	__ Str(d0, MemOperand(x0, fbits * kDRegSizeInBytes));
				6901	__ Str(d1, MemOperand(x1, fbits * kDRegSizeInBytes));
				6902	__ Str(d2, MemOperand(x2, fbits * kDRegSizeInBytes));
				6903	__ Str(d3, MemOperand(x3, fbits * kDRegSizeInBytes));
				6904	}
				6905
				6906	// Conversions from W registers can only handle fbits values <= 32, so just
				6907	// test conversions from X registers for 32 < fbits <= 64.
				6908	for (int fbits = 33; fbits <= 64; fbits++) {
				6909	__ Scvtf(d0, x10, fbits);
				6910	__ Ucvtf(d1, x10, fbits);
				6911	__ Str(d0, MemOperand(x0, fbits * kDRegSizeInBytes));
				6912	__ Str(d1, MemOperand(x1, fbits * kDRegSizeInBytes));
				6913	}
				6914
				6915	END();
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6916	RUN();
				6917
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	6918	// Check the results.
				6919	double expected_scvtf_base = rawbits_to_double(expected_scvtf_bits);
				6920	double expected_ucvtf_base = rawbits_to_double(expected_ucvtf_bits);
				6921
				6922	for (int fbits = 0; fbits <= 32; fbits++) {
				6923	double expected_scvtf = expected_scvtf_base / pow(2, fbits);
				6924	double expected_ucvtf = expected_ucvtf_base / pow(2, fbits);
				6925	ASSERT_EQUAL_FP64(expected_scvtf, results_scvtf_x[fbits]);
				6926	ASSERT_EQUAL_FP64(expected_ucvtf, results_ucvtf_x[fbits]);
				6927	if (cvtf_s32) ASSERT_EQUAL_FP64(expected_scvtf, results_scvtf_w[fbits]);
				6928	if (cvtf_u32) ASSERT_EQUAL_FP64(expected_ucvtf, results_ucvtf_w[fbits]);
				6929	}
				6930	for (int fbits = 33; fbits <= 64; fbits++) {
				6931	double expected_scvtf = expected_scvtf_base / pow(2, fbits);
				6932	double expected_ucvtf = expected_ucvtf_base / pow(2, fbits);
				6933	ASSERT_EQUAL_FP64(expected_scvtf, results_scvtf_x[fbits]);
				6934	ASSERT_EQUAL_FP64(expected_ucvtf, results_ucvtf_x[fbits]);
				6935	}
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	6936
				6937	TEARDOWN();
				6938	}
				6939
				6940
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	6941	TEST(scvtf_ucvtf_double) {
				6942	// Simple conversions of positive numbers which require no rounding; the
				6943	// results should not depened on the rounding mode, and ucvtf and scvtf should
				6944	// produce the same result.
				6945	TestUScvtfHelper(0x0000000000000000, 0x0000000000000000, 0x0000000000000000);
				6946	TestUScvtfHelper(0x0000000000000001, 0x3ff0000000000000, 0x3ff0000000000000);
				6947	TestUScvtfHelper(0x0000000040000000, 0x41d0000000000000, 0x41d0000000000000);
				6948	TestUScvtfHelper(0x0000000100000000, 0x41f0000000000000, 0x41f0000000000000);
				6949	TestUScvtfHelper(0x4000000000000000, 0x43d0000000000000, 0x43d0000000000000);
				6950	// Test mantissa extremities.
				6951	TestUScvtfHelper(0x4000000000000400, 0x43d0000000000001, 0x43d0000000000001);
				6952	// The largest int32_t that fits in a double.
				6953	TestUScvtfHelper(0x000000007fffffff, 0x41dfffffffc00000, 0x41dfffffffc00000);
				6954	// Values that would be negative if treated as an int32_t.
				6955	TestUScvtfHelper(0x00000000ffffffff, 0x41efffffffe00000, 0x41efffffffe00000);
				6956	TestUScvtfHelper(0x0000000080000000, 0x41e0000000000000, 0x41e0000000000000);
				6957	TestUScvtfHelper(0x0000000080000001, 0x41e0000000200000, 0x41e0000000200000);
				6958	// The largest int64_t that fits in a double.
				6959	TestUScvtfHelper(0x7ffffffffffffc00, 0x43dfffffffffffff, 0x43dfffffffffffff);
				6960	// Check for bit pattern reproduction.
				6961	TestUScvtfHelper(0x0123456789abcde0, 0x43723456789abcde, 0x43723456789abcde);
				6962	TestUScvtfHelper(0x0000000012345678, 0x41b2345678000000, 0x41b2345678000000);
				6963
				6964	// Simple conversions of negative int64_t values. These require no rounding,
				6965	// and the results should not depend on the rounding mode.
				6966	TestUScvtfHelper(0xffffffffc0000000, 0xc1d0000000000000, 0x43effffffff80000);
				6967	TestUScvtfHelper(0xffffffff00000000, 0xc1f0000000000000, 0x43efffffffe00000);
				6968	TestUScvtfHelper(0xc000000000000000, 0xc3d0000000000000, 0x43e8000000000000);
				6969
				6970	// Conversions which require rounding.
				6971	TestUScvtfHelper(0x1000000000000000, 0x43b0000000000000, 0x43b0000000000000);
				6972	TestUScvtfHelper(0x1000000000000001, 0x43b0000000000000, 0x43b0000000000000);
				6973	TestUScvtfHelper(0x1000000000000080, 0x43b0000000000000, 0x43b0000000000000);
				6974	TestUScvtfHelper(0x1000000000000081, 0x43b0000000000001, 0x43b0000000000001);
				6975	TestUScvtfHelper(0x1000000000000100, 0x43b0000000000001, 0x43b0000000000001);
				6976	TestUScvtfHelper(0x1000000000000101, 0x43b0000000000001, 0x43b0000000000001);
				6977	TestUScvtfHelper(0x1000000000000180, 0x43b0000000000002, 0x43b0000000000002);
				6978	TestUScvtfHelper(0x1000000000000181, 0x43b0000000000002, 0x43b0000000000002);
				6979	TestUScvtfHelper(0x1000000000000200, 0x43b0000000000002, 0x43b0000000000002);
				6980	TestUScvtfHelper(0x1000000000000201, 0x43b0000000000002, 0x43b0000000000002);
				6981	TestUScvtfHelper(0x1000000000000280, 0x43b0000000000002, 0x43b0000000000002);
				6982	TestUScvtfHelper(0x1000000000000281, 0x43b0000000000003, 0x43b0000000000003);
				6983	TestUScvtfHelper(0x1000000000000300, 0x43b0000000000003, 0x43b0000000000003);
				6984	// Check rounding of negative int64_t values (and large uint64_t values).
				6985	TestUScvtfHelper(0x8000000000000000, 0xc3e0000000000000, 0x43e0000000000000);
				6986	TestUScvtfHelper(0x8000000000000001, 0xc3e0000000000000, 0x43e0000000000000);
				6987	TestUScvtfHelper(0x8000000000000200, 0xc3e0000000000000, 0x43e0000000000000);
				6988	TestUScvtfHelper(0x8000000000000201, 0xc3dfffffffffffff, 0x43e0000000000000);
				6989	TestUScvtfHelper(0x8000000000000400, 0xc3dfffffffffffff, 0x43e0000000000000);
				6990	TestUScvtfHelper(0x8000000000000401, 0xc3dfffffffffffff, 0x43e0000000000001);
				6991	TestUScvtfHelper(0x8000000000000600, 0xc3dffffffffffffe, 0x43e0000000000001);
				6992	TestUScvtfHelper(0x8000000000000601, 0xc3dffffffffffffe, 0x43e0000000000001);
				6993	TestUScvtfHelper(0x8000000000000800, 0xc3dffffffffffffe, 0x43e0000000000001);
				6994	TestUScvtfHelper(0x8000000000000801, 0xc3dffffffffffffe, 0x43e0000000000001);
				6995	TestUScvtfHelper(0x8000000000000a00, 0xc3dffffffffffffe, 0x43e0000000000001);
				6996	TestUScvtfHelper(0x8000000000000a01, 0xc3dffffffffffffd, 0x43e0000000000001);
				6997	TestUScvtfHelper(0x8000000000000c00, 0xc3dffffffffffffd, 0x43e0000000000002);
				6998	// Round up to produce a result that's too big for the input to represent.
				6999	TestUScvtfHelper(0x7ffffffffffffe00, 0x43e0000000000000, 0x43e0000000000000);
				7000	TestUScvtfHelper(0x7fffffffffffffff, 0x43e0000000000000, 0x43e0000000000000);
				7001	TestUScvtfHelper(0xfffffffffffffc00, 0xc090000000000000, 0x43f0000000000000);
				7002	TestUScvtfHelper(0xffffffffffffffff, 0xbff0000000000000, 0x43f0000000000000);
				7003	}
				7004
				7005
				7006	// The same as TestUScvtfHelper, but convert to floats.
				7007	static void TestUScvtf32Helper(uint64_t in,
				7008	uint32_t expected_scvtf_bits,
				7009	uint32_t expected_ucvtf_bits) {
				7010	uint64_t u64 = in;
				7011	uint32_t u32 = u64 & 0xffffffff;
				7012	int64_t s64 = static_cast<int64_t>(in);
				7013	int32_t s32 = s64 & 0x7fffffff;
				7014
				7015	bool cvtf_s32 = (s64 == s32);
				7016	bool cvtf_u32 = (u64 == u32);
				7017
				7018	float results_scvtf_x[65];
				7019	float results_ucvtf_x[65];
				7020	float results_scvtf_w[33];
				7021	float results_ucvtf_w[33];
				7022
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7023	SETUP();
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7024	START();
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7025
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	7026	__ Mov(x0, reinterpret_cast<uintptr_t>(results_scvtf_x));
				7027	__ Mov(x1, reinterpret_cast<uintptr_t>(results_ucvtf_x));
				7028	__ Mov(x2, reinterpret_cast<uintptr_t>(results_scvtf_w));
				7029	__ Mov(x3, reinterpret_cast<uintptr_t>(results_ucvtf_w));
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	7030
				7031	__ Mov(x10, s64);
				7032
				7033	// Corrupt the top word, in case it is accidentally used during W-register
				7034	// conversions.
				7035	__ Mov(x11, 0x5555555555555555);
				7036	__ Bfi(x11, x10, 0, kWRegSize);
				7037
				7038	// Test integer conversions.
				7039	__ Scvtf(s0, x10);
				7040	__ Ucvtf(s1, x10);
				7041	__ Scvtf(s2, w11);
				7042	__ Ucvtf(s3, w11);
				7043	__ Str(s0, MemOperand(x0));
				7044	__ Str(s1, MemOperand(x1));
				7045	__ Str(s2, MemOperand(x2));
				7046	__ Str(s3, MemOperand(x3));
				7047
				7048	// Test all possible values of fbits.
				7049	for (int fbits = 1; fbits <= 32; fbits++) {
				7050	__ Scvtf(s0, x10, fbits);
				7051	__ Ucvtf(s1, x10, fbits);
				7052	__ Scvtf(s2, w11, fbits);
				7053	__ Ucvtf(s3, w11, fbits);
				7054	__ Str(s0, MemOperand(x0, fbits * kSRegSizeInBytes));
				7055	__ Str(s1, MemOperand(x1, fbits * kSRegSizeInBytes));
				7056	__ Str(s2, MemOperand(x2, fbits * kSRegSizeInBytes));
				7057	__ Str(s3, MemOperand(x3, fbits * kSRegSizeInBytes));
				7058	}
				7059
				7060	// Conversions from W registers can only handle fbits values <= 32, so just
				7061	// test conversions from X registers for 32 < fbits <= 64.
				7062	for (int fbits = 33; fbits <= 64; fbits++) {
				7063	__ Scvtf(s0, x10, fbits);
				7064	__ Ucvtf(s1, x10, fbits);
				7065	__ Str(s0, MemOperand(x0, fbits * kSRegSizeInBytes));
				7066	__ Str(s1, MemOperand(x1, fbits * kSRegSizeInBytes));
				7067	}
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7068
				7069	END();
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7070	RUN();
				7071
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	7072	// Check the results.
				7073	float expected_scvtf_base = rawbits_to_float(expected_scvtf_bits);
				7074	float expected_ucvtf_base = rawbits_to_float(expected_ucvtf_bits);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7075
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	7076	for (int fbits = 0; fbits <= 32; fbits++) {
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	7077	float expected_scvtf = expected_scvtf_base / powf(2, fbits);
				7078	float expected_ucvtf = expected_ucvtf_base / powf(2, fbits);
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	7079	ASSERT_EQUAL_FP32(expected_scvtf, results_scvtf_x[fbits]);
				7080	ASSERT_EQUAL_FP32(expected_ucvtf, results_ucvtf_x[fbits]);
				7081	if (cvtf_s32) ASSERT_EQUAL_FP32(expected_scvtf, results_scvtf_w[fbits]);
				7082	if (cvtf_u32) ASSERT_EQUAL_FP32(expected_ucvtf, results_ucvtf_w[fbits]);
				7083	break;
				7084	}
				7085	for (int fbits = 33; fbits <= 64; fbits++) {
				7086	break;
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	7087	float expected_scvtf = expected_scvtf_base / powf(2, fbits);
				7088	float expected_ucvtf = expected_ucvtf_base / powf(2, fbits);
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	7089	ASSERT_EQUAL_FP32(expected_scvtf, results_scvtf_x[fbits]);
				7090	ASSERT_EQUAL_FP32(expected_ucvtf, results_ucvtf_x[fbits]);
				7091	}
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7092
				7093	TEARDOWN();
				7094	}
				7095
				7096
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	7097	TEST(scvtf_ucvtf_float) {
				7098	// Simple conversions of positive numbers which require no rounding; the
				7099	// results should not depened on the rounding mode, and ucvtf and scvtf should
				7100	// produce the same result.
				7101	TestUScvtf32Helper(0x0000000000000000, 0x00000000, 0x00000000);
				7102	TestUScvtf32Helper(0x0000000000000001, 0x3f800000, 0x3f800000);
				7103	TestUScvtf32Helper(0x0000000040000000, 0x4e800000, 0x4e800000);
				7104	TestUScvtf32Helper(0x0000000100000000, 0x4f800000, 0x4f800000);
				7105	TestUScvtf32Helper(0x4000000000000000, 0x5e800000, 0x5e800000);
				7106	// Test mantissa extremities.
				7107	TestUScvtf32Helper(0x0000000000800001, 0x4b000001, 0x4b000001);
				7108	TestUScvtf32Helper(0x4000008000000000, 0x5e800001, 0x5e800001);
				7109	// The largest int32_t that fits in a float.
				7110	TestUScvtf32Helper(0x000000007fffff80, 0x4effffff, 0x4effffff);
				7111	// Values that would be negative if treated as an int32_t.
				7112	TestUScvtf32Helper(0x00000000ffffff00, 0x4f7fffff, 0x4f7fffff);
				7113	TestUScvtf32Helper(0x0000000080000000, 0x4f000000, 0x4f000000);
				7114	TestUScvtf32Helper(0x0000000080000100, 0x4f000001, 0x4f000001);
				7115	// The largest int64_t that fits in a float.
				7116	TestUScvtf32Helper(0x7fffff8000000000, 0x5effffff, 0x5effffff);
				7117	// Check for bit pattern reproduction.
				7118	TestUScvtf32Helper(0x0000000000876543, 0x4b076543, 0x4b076543);
				7119
				7120	// Simple conversions of negative int64_t values. These require no rounding,
				7121	// and the results should not depend on the rounding mode.
				7122	TestUScvtf32Helper(0xfffffc0000000000, 0xd4800000, 0x5f7ffffc);
				7123	TestUScvtf32Helper(0xc000000000000000, 0xde800000, 0x5f400000);
				7124
				7125	// Conversions which require rounding.
				7126	TestUScvtf32Helper(0x0000800000000000, 0x57000000, 0x57000000);
				7127	TestUScvtf32Helper(0x0000800000000001, 0x57000000, 0x57000000);
				7128	TestUScvtf32Helper(0x0000800000800000, 0x57000000, 0x57000000);
				7129	TestUScvtf32Helper(0x0000800000800001, 0x57000001, 0x57000001);
				7130	TestUScvtf32Helper(0x0000800001000000, 0x57000001, 0x57000001);
				7131	TestUScvtf32Helper(0x0000800001000001, 0x57000001, 0x57000001);
				7132	TestUScvtf32Helper(0x0000800001800000, 0x57000002, 0x57000002);
				7133	TestUScvtf32Helper(0x0000800001800001, 0x57000002, 0x57000002);
				7134	TestUScvtf32Helper(0x0000800002000000, 0x57000002, 0x57000002);
				7135	TestUScvtf32Helper(0x0000800002000001, 0x57000002, 0x57000002);
				7136	TestUScvtf32Helper(0x0000800002800000, 0x57000002, 0x57000002);
				7137	TestUScvtf32Helper(0x0000800002800001, 0x57000003, 0x57000003);
				7138	TestUScvtf32Helper(0x0000800003000000, 0x57000003, 0x57000003);
				7139	// Check rounding of negative int64_t values (and large uint64_t values).
				7140	TestUScvtf32Helper(0x8000000000000000, 0xdf000000, 0x5f000000);
				7141	TestUScvtf32Helper(0x8000000000000001, 0xdf000000, 0x5f000000);
				7142	TestUScvtf32Helper(0x8000004000000000, 0xdf000000, 0x5f000000);
				7143	TestUScvtf32Helper(0x8000004000000001, 0xdeffffff, 0x5f000000);
				7144	TestUScvtf32Helper(0x8000008000000000, 0xdeffffff, 0x5f000000);
				7145	TestUScvtf32Helper(0x8000008000000001, 0xdeffffff, 0x5f000001);
				7146	TestUScvtf32Helper(0x800000c000000000, 0xdefffffe, 0x5f000001);
				7147	TestUScvtf32Helper(0x800000c000000001, 0xdefffffe, 0x5f000001);
				7148	TestUScvtf32Helper(0x8000010000000000, 0xdefffffe, 0x5f000001);
				7149	TestUScvtf32Helper(0x8000010000000001, 0xdefffffe, 0x5f000001);
				7150	TestUScvtf32Helper(0x8000014000000000, 0xdefffffe, 0x5f000001);
				7151	TestUScvtf32Helper(0x8000014000000001, 0xdefffffd, 0x5f000001);
				7152	TestUScvtf32Helper(0x8000018000000000, 0xdefffffd, 0x5f000002);
				7153	// Round up to produce a result that's too big for the input to represent.
				7154	TestUScvtf32Helper(0x000000007fffffc0, 0x4f000000, 0x4f000000);
				7155	TestUScvtf32Helper(0x000000007fffffff, 0x4f000000, 0x4f000000);
				7156	TestUScvtf32Helper(0x00000000ffffff80, 0x4f800000, 0x4f800000);
				7157	TestUScvtf32Helper(0x00000000ffffffff, 0x4f800000, 0x4f800000);
				7158	TestUScvtf32Helper(0x7fffffc000000000, 0x5f000000, 0x5f000000);
				7159	TestUScvtf32Helper(0x7fffffffffffffff, 0x5f000000, 0x5f000000);
				7160	TestUScvtf32Helper(0xffffff8000000000, 0xd3000000, 0x5f800000);
				7161	TestUScvtf32Helper(0xffffffffffffffff, 0xbf800000, 0x5f800000);
				7162	}
				7163
				7164
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7165	TEST(system_mrs) {
				7166	SETUP();
				7167
				7168	START();
				7169	__ Mov(w0, 0);
				7170	__ Mov(w1, 1);
				7171	__ Mov(w2, 0x80000000);
				7172
				7173	// Set the Z and C flags.
				7174	__ Cmp(w0, w0);
				7175	__ Mrs(x3, NZCV);
				7176
				7177	// Set the N flag.
				7178	__ Cmp(w0, w1);
				7179	__ Mrs(x4, NZCV);
				7180
				7181	// Set the Z, C and V flags.
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	7182	__ Adds(w0, w2, w2);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7183	__ Mrs(x5, NZCV);
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	7184
				7185	// Read the default FPCR.
				7186	__ Mrs(x6, FPCR);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7187	END();
				7188
				7189	RUN();
				7190
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	7191	// NZCV
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7192	ASSERT_EQUAL_32(ZCFlag, w3);
				7193	ASSERT_EQUAL_32(NFlag, w4);
				7194	ASSERT_EQUAL_32(ZCVFlag, w5);
				7195
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	7196	// FPCR
				7197	// The default FPCR on Linux-based platforms is 0.
				7198	ASSERT_EQUAL_32(0, w6);
				7199
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7200	TEARDOWN();
				7201	}
				7202
				7203
				7204	TEST(system_msr) {
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	7205	// All FPCR fields that must be implemented: AHP, DN, FZ, RMode
				7206	const uint64_t fpcr_core = 0x07c00000;
				7207
				7208	// All FPCR fields (including fields which may be read-as-zero):
				7209	// Stride, Len
				7210	// IDE, IXE, UFE, OFE, DZE, IOE
				7211	const uint64_t fpcr_all = fpcr_core \| 0x00379f00;
				7212
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7213	SETUP();
				7214
				7215	START();
				7216	__ Mov(w0, 0);
				7217	__ Mov(w1, 0x7fffffff);
				7218
				7219	__ Mov(x7, 0);
				7220
				7221	__ Mov(x10, NVFlag);
				7222	__ Cmp(w0, w0); // Set Z and C.
				7223	__ Msr(NZCV, x10); // Set N and V.
				7224	// The Msr should have overwritten every flag set by the Cmp.
				7225	__ Cinc(x7, x7, mi); // N
				7226	__ Cinc(x7, x7, ne); // !Z
				7227	__ Cinc(x7, x7, lo); // !C
				7228	__ Cinc(x7, x7, vs); // V
				7229
				7230	__ Mov(x10, ZCFlag);
				7231	__ Cmn(w1, w1); // Set N and V.
				7232	__ Msr(NZCV, x10); // Set Z and C.
				7233	// The Msr should have overwritten every flag set by the Cmn.
				7234	__ Cinc(x7, x7, pl); // !N
				7235	__ Cinc(x7, x7, eq); // Z
				7236	__ Cinc(x7, x7, hs); // C
				7237	__ Cinc(x7, x7, vc); // !V
				7238
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	7239	// All core FPCR fields must be writable.
				7240	__ Mov(x8, fpcr_core);
				7241	__ Msr(FPCR, x8);
				7242	__ Mrs(x8, FPCR);
				7243
				7244	// All FPCR fields, including optional ones. This part of the test doesn't
				7245	// achieve much other than ensuring that supported fields can be cleared by
				7246	// the next test.
				7247	__ Mov(x9, fpcr_all);
				7248	__ Msr(FPCR, x9);
				7249	__ Mrs(x9, FPCR);
				7250	__ And(x9, x9, fpcr_core);
				7251
				7252	// The undefined bits must ignore writes.
				7253	// It's conceivable that a future version of the architecture could use these
				7254	// fields (making this test fail), but in the meantime this is a useful test
				7255	// for the simulator.
				7256	__ Mov(x10, ~fpcr_all);
				7257	__ Msr(FPCR, x10);
				7258	__ Mrs(x10, FPCR);
				7259
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7260	END();
				7261
				7262	RUN();
				7263
				7264	// We should have incremented x7 (from 0) exactly 8 times.
				7265	ASSERT_EQUAL_64(8, x7);
				7266
armvixl	578645f	2013-08-15 17:21:42 +0100	[diff] [blame]	7267	ASSERT_EQUAL_64(fpcr_core, x8);
				7268	ASSERT_EQUAL_64(fpcr_core, x9);
				7269	ASSERT_EQUAL_64(0, x10);
				7270
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7271	TEARDOWN();
				7272	}
				7273
				7274
				7275	TEST(system_nop) {
				7276	SETUP();
				7277	RegisterDump before;
				7278
				7279	START();
				7280	before.Dump(&masm);
				7281	__ Nop();
				7282	END();
				7283
				7284	RUN();
				7285
				7286	ASSERT_EQUAL_REGISTERS(before);
				7287	ASSERT_EQUAL_NZCV(before.flags_nzcv());
				7288
				7289	TEARDOWN();
				7290	}
				7291
				7292
				7293	TEST(zero_dest) {
				7294	SETUP();
				7295	RegisterDump before;
				7296
				7297	START();
				7298	// Preserve the stack pointer, in case we clobber it.
				7299	__ Mov(x30, sp);
				7300	// Initialize the other registers used in this test.
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	7301	uint64_t literal_base = 0x0100001000100101;
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7302	__ Mov(x0, 0);
				7303	__ Mov(x1, literal_base);
				7304	for (unsigned i = 2; i < x30.code(); i++) {
				7305	__ Add(Register::XRegFromCode(i), Register::XRegFromCode(i-1), x1);
				7306	}
				7307	before.Dump(&masm);
				7308
				7309	// All of these instructions should be NOPs in these forms, but have
				7310	// alternate forms which can write into the stack pointer.
				7311	__ add(xzr, x0, x1);
				7312	__ add(xzr, x1, xzr);
				7313	__ add(xzr, xzr, x1);
				7314
				7315	__ and_(xzr, x0, x2);
				7316	__ and_(xzr, x2, xzr);
				7317	__ and_(xzr, xzr, x2);
				7318
				7319	__ bic(xzr, x0, x3);
				7320	__ bic(xzr, x3, xzr);
				7321	__ bic(xzr, xzr, x3);
				7322
				7323	__ eon(xzr, x0, x4);
				7324	__ eon(xzr, x4, xzr);
				7325	__ eon(xzr, xzr, x4);
				7326
				7327	__ eor(xzr, x0, x5);
				7328	__ eor(xzr, x5, xzr);
				7329	__ eor(xzr, xzr, x5);
				7330
				7331	__ orr(xzr, x0, x6);
				7332	__ orr(xzr, x6, xzr);
				7333	__ orr(xzr, xzr, x6);
				7334
				7335	__ sub(xzr, x0, x7);
				7336	__ sub(xzr, x7, xzr);
				7337	__ sub(xzr, xzr, x7);
				7338
				7339	// Swap the saved stack pointer with the real one. If sp was written
				7340	// during the test, it will show up in x30. This is done because the test
				7341	// framework assumes that sp will be valid at the end of the test.
				7342	__ Mov(x29, x30);
				7343	__ Mov(x30, sp);
				7344	__ Mov(sp, x29);
				7345	// We used x29 as a scratch register, so reset it to make sure it doesn't
				7346	// trigger a test failure.
				7347	__ Add(x29, x28, x1);
				7348	END();
				7349
				7350	RUN();
				7351
				7352	ASSERT_EQUAL_REGISTERS(before);
				7353	ASSERT_EQUAL_NZCV(before.flags_nzcv());
				7354
				7355	TEARDOWN();
				7356	}
				7357
				7358
				7359	TEST(zero_dest_setflags) {
				7360	SETUP();
				7361	RegisterDump before;
				7362
				7363	START();
				7364	// Preserve the stack pointer, in case we clobber it.
				7365	__ Mov(x30, sp);
				7366	// Initialize the other registers used in this test.
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	7367	uint64_t literal_base = 0x0100001000100101;
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7368	__ Mov(x0, 0);
				7369	__ Mov(x1, literal_base);
				7370	for (int i = 2; i < 30; i++) {
				7371	__ Add(Register::XRegFromCode(i), Register::XRegFromCode(i-1), x1);
				7372	}
				7373	before.Dump(&masm);
				7374
				7375	// All of these instructions should only write to the flags in these forms,
				7376	// but have alternate forms which can write into the stack pointer.
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	7377	__ adds(xzr, x0, Operand(x1, UXTX));
				7378	__ adds(xzr, x1, Operand(xzr, UXTX));
				7379	__ adds(xzr, x1, 1234);
				7380	__ adds(xzr, x0, x1);
				7381	__ adds(xzr, x1, xzr);
				7382	__ adds(xzr, xzr, x1);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7383
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	7384	__ ands(xzr, x2, ~0xf);
				7385	__ ands(xzr, xzr, ~0xf);
				7386	__ ands(xzr, x0, x2);
				7387	__ ands(xzr, x2, xzr);
				7388	__ ands(xzr, xzr, x2);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7389
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	7390	__ bics(xzr, x3, ~0xf);
				7391	__ bics(xzr, xzr, ~0xf);
				7392	__ bics(xzr, x0, x3);
				7393	__ bics(xzr, x3, xzr);
				7394	__ bics(xzr, xzr, x3);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7395
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	7396	__ subs(xzr, x0, Operand(x3, UXTX));
				7397	__ subs(xzr, x3, Operand(xzr, UXTX));
				7398	__ subs(xzr, x3, 1234);
				7399	__ subs(xzr, x0, x3);
				7400	__ subs(xzr, x3, xzr);
				7401	__ subs(xzr, xzr, x3);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7402
				7403	// Swap the saved stack pointer with the real one. If sp was written
				7404	// during the test, it will show up in x30. This is done because the test
				7405	// framework assumes that sp will be valid at the end of the test.
				7406	__ Mov(x29, x30);
				7407	__ Mov(x30, sp);
				7408	__ Mov(sp, x29);
				7409	// We used x29 as a scratch register, so reset it to make sure it doesn't
				7410	// trigger a test failure.
				7411	__ Add(x29, x28, x1);
				7412	END();
				7413
				7414	RUN();
				7415
				7416	ASSERT_EQUAL_REGISTERS(before);
				7417
				7418	TEARDOWN();
				7419	}
				7420
				7421
				7422	TEST(register_bit) {
				7423	// No code generation takes place in this test, so no need to setup and
				7424	// teardown.
				7425
				7426	// Simple tests.
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	7427	assert(x0.Bit() == (UINT64_C(1) << 0));
				7428	assert(x1.Bit() == (UINT64_C(1) << 1));
				7429	assert(x10.Bit() == (UINT64_C(1) << 10));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7430
				7431	// AAPCS64 definitions.
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	7432	assert(lr.Bit() == (UINT64_C(1) << kLinkRegCode));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7433
				7434	// Fixed (hardware) definitions.
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	7435	assert(xzr.Bit() == (UINT64_C(1) << kZeroRegCode));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7436
				7437	// Internal ABI definitions.
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	7438	assert(sp.Bit() == (UINT64_C(1) << kSPRegInternalCode));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7439	assert(sp.Bit() != xzr.Bit());
				7440
				7441	// xn.Bit() == wn.Bit() at all times, for the same n.
				7442	assert(x0.Bit() == w0.Bit());
				7443	assert(x1.Bit() == w1.Bit());
				7444	assert(x10.Bit() == w10.Bit());
				7445	assert(xzr.Bit() == wzr.Bit());
				7446	assert(sp.Bit() == wsp.Bit());
				7447	}
				7448
				7449
				7450	TEST(stack_pointer_override) {
				7451	// This test generates some stack maintenance code, but the test only checks
				7452	// the reported state.
				7453	SETUP();
				7454	START();
				7455
				7456	// The default stack pointer in VIXL is sp.
				7457	assert(sp.Is(__ StackPointer()));
				7458	__ SetStackPointer(x0);
				7459	assert(x0.Is(__ StackPointer()));
				7460	__ SetStackPointer(x28);
				7461	assert(x28.Is(__ StackPointer()));
				7462	__ SetStackPointer(sp);
				7463	assert(sp.Is(__ StackPointer()));
				7464
				7465	END();
				7466	RUN();
				7467	TEARDOWN();
				7468	}
				7469
				7470
				7471	TEST(peek_poke_simple) {
				7472	SETUP();
				7473	START();
				7474
				7475	static const RegList x0_to_x3 = x0.Bit() \| x1.Bit() \| x2.Bit() \| x3.Bit();
				7476	static const RegList x10_to_x13 = x10.Bit() \| x11.Bit() \|
				7477	x12.Bit() \| x13.Bit();
				7478
				7479	// The literal base is chosen to have two useful properties:
				7480	// * When multiplied by small values (such as a register index), this value
				7481	// is clearly readable in the result.
				7482	// * The value is not formed from repeating fixed-size smaller values, so it
				7483	// can be used to detect endianness-related errors.
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	7484	uint64_t literal_base = 0x0100001000100101;
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7485
				7486	// Initialize the registers.
				7487	__ Mov(x0, literal_base);
				7488	__ Add(x1, x0, x0);
				7489	__ Add(x2, x1, x0);
				7490	__ Add(x3, x2, x0);
				7491
				7492	__ Claim(32);
				7493
				7494	// Simple exchange.
				7495	// After this test:
				7496	// x0-x3 should be unchanged.
				7497	// w10-w13 should contain the lower words of x0-x3.
				7498	__ Poke(x0, 0);
				7499	__ Poke(x1, 8);
				7500	__ Poke(x2, 16);
				7501	__ Poke(x3, 24);
				7502	Clobber(&masm, x0_to_x3);
				7503	__ Peek(x0, 0);
				7504	__ Peek(x1, 8);
				7505	__ Peek(x2, 16);
				7506	__ Peek(x3, 24);
				7507
				7508	__ Poke(w0, 0);
				7509	__ Poke(w1, 4);
				7510	__ Poke(w2, 8);
				7511	__ Poke(w3, 12);
				7512	Clobber(&masm, x10_to_x13);
				7513	__ Peek(w10, 0);
				7514	__ Peek(w11, 4);
				7515	__ Peek(w12, 8);
				7516	__ Peek(w13, 12);
				7517
				7518	__ Drop(32);
				7519
				7520	END();
				7521	RUN();
				7522
				7523	ASSERT_EQUAL_64(literal_base * 1, x0);
				7524	ASSERT_EQUAL_64(literal_base * 2, x1);
				7525	ASSERT_EQUAL_64(literal_base * 3, x2);
				7526	ASSERT_EQUAL_64(literal_base * 4, x3);
				7527
				7528	ASSERT_EQUAL_64((literal_base * 1) & 0xffffffff, x10);
				7529	ASSERT_EQUAL_64((literal_base * 2) & 0xffffffff, x11);
				7530	ASSERT_EQUAL_64((literal_base * 3) & 0xffffffff, x12);
				7531	ASSERT_EQUAL_64((literal_base * 4) & 0xffffffff, x13);
				7532
				7533	TEARDOWN();
				7534	}
				7535
				7536
				7537	TEST(peek_poke_unaligned) {
				7538	SETUP();
				7539	START();
				7540
				7541	// The literal base is chosen to have two useful properties:
				7542	// * When multiplied by small values (such as a register index), this value
				7543	// is clearly readable in the result.
				7544	// * The value is not formed from repeating fixed-size smaller values, so it
				7545	// can be used to detect endianness-related errors.
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	7546	uint64_t literal_base = 0x0100001000100101;
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7547
				7548	// Initialize the registers.
				7549	__ Mov(x0, literal_base);
				7550	__ Add(x1, x0, x0);
				7551	__ Add(x2, x1, x0);
				7552	__ Add(x3, x2, x0);
				7553	__ Add(x4, x3, x0);
				7554	__ Add(x5, x4, x0);
				7555	__ Add(x6, x5, x0);
				7556
				7557	__ Claim(32);
				7558
				7559	// Unaligned exchanges.
				7560	// After this test:
				7561	// x0-x6 should be unchanged.
				7562	// w10-w12 should contain the lower words of x0-x2.
				7563	__ Poke(x0, 1);
				7564	Clobber(&masm, x0.Bit());
				7565	__ Peek(x0, 1);
				7566	__ Poke(x1, 2);
				7567	Clobber(&masm, x1.Bit());
				7568	__ Peek(x1, 2);
				7569	__ Poke(x2, 3);
				7570	Clobber(&masm, x2.Bit());
				7571	__ Peek(x2, 3);
				7572	__ Poke(x3, 4);
				7573	Clobber(&masm, x3.Bit());
				7574	__ Peek(x3, 4);
				7575	__ Poke(x4, 5);
				7576	Clobber(&masm, x4.Bit());
				7577	__ Peek(x4, 5);
				7578	__ Poke(x5, 6);
				7579	Clobber(&masm, x5.Bit());
				7580	__ Peek(x5, 6);
				7581	__ Poke(x6, 7);
				7582	Clobber(&masm, x6.Bit());
				7583	__ Peek(x6, 7);
				7584
				7585	__ Poke(w0, 1);
				7586	Clobber(&masm, w10.Bit());
				7587	__ Peek(w10, 1);
				7588	__ Poke(w1, 2);
				7589	Clobber(&masm, w11.Bit());
				7590	__ Peek(w11, 2);
				7591	__ Poke(w2, 3);
				7592	Clobber(&masm, w12.Bit());
				7593	__ Peek(w12, 3);
				7594
				7595	__ Drop(32);
				7596
				7597	END();
				7598	RUN();
				7599
				7600	ASSERT_EQUAL_64(literal_base * 1, x0);
				7601	ASSERT_EQUAL_64(literal_base * 2, x1);
				7602	ASSERT_EQUAL_64(literal_base * 3, x2);
				7603	ASSERT_EQUAL_64(literal_base * 4, x3);
				7604	ASSERT_EQUAL_64(literal_base * 5, x4);
				7605	ASSERT_EQUAL_64(literal_base * 6, x5);
				7606	ASSERT_EQUAL_64(literal_base * 7, x6);
				7607
				7608	ASSERT_EQUAL_64((literal_base * 1) & 0xffffffff, x10);
				7609	ASSERT_EQUAL_64((literal_base * 2) & 0xffffffff, x11);
				7610	ASSERT_EQUAL_64((literal_base * 3) & 0xffffffff, x12);
				7611
				7612	TEARDOWN();
				7613	}
				7614
				7615
				7616	TEST(peek_poke_endianness) {
				7617	SETUP();
				7618	START();
				7619
				7620	// The literal base is chosen to have two useful properties:
				7621	// * When multiplied by small values (such as a register index), this value
				7622	// is clearly readable in the result.
				7623	// * The value is not formed from repeating fixed-size smaller values, so it
				7624	// can be used to detect endianness-related errors.
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	7625	uint64_t literal_base = 0x0100001000100101;
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7626
				7627	// Initialize the registers.
				7628	__ Mov(x0, literal_base);
				7629	__ Add(x1, x0, x0);
				7630
				7631	__ Claim(32);
				7632
				7633	// Endianness tests.
				7634	// After this section:
				7635	// x4 should match x0[31:0]:x0[63:32]
				7636	// w5 should match w1[15:0]:w1[31:16]
				7637	__ Poke(x0, 0);
				7638	__ Poke(x0, 8);
				7639	__ Peek(x4, 4);
				7640
				7641	__ Poke(w1, 0);
				7642	__ Poke(w1, 4);
				7643	__ Peek(w5, 2);
				7644
				7645	__ Drop(32);
				7646
				7647	END();
				7648	RUN();
				7649
				7650	uint64_t x0_expected = literal_base * 1;
				7651	uint64_t x1_expected = literal_base * 2;
				7652	uint64_t x4_expected = (x0_expected << 32) \| (x0_expected >> 32);
				7653	uint64_t x5_expected = ((x1_expected << 16) & 0xffff0000) \|
				7654	((x1_expected >> 16) & 0x0000ffff);
				7655
				7656	ASSERT_EQUAL_64(x0_expected, x0);
				7657	ASSERT_EQUAL_64(x1_expected, x1);
				7658	ASSERT_EQUAL_64(x4_expected, x4);
				7659	ASSERT_EQUAL_64(x5_expected, x5);
				7660
				7661	TEARDOWN();
				7662	}
				7663
				7664
				7665	TEST(peek_poke_mixed) {
				7666	SETUP();
				7667	START();
				7668
				7669	// The literal base is chosen to have two useful properties:
				7670	// * When multiplied by small values (such as a register index), this value
				7671	// is clearly readable in the result.
				7672	// * The value is not formed from repeating fixed-size smaller values, so it
				7673	// can be used to detect endianness-related errors.
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	7674	uint64_t literal_base = 0x0100001000100101;
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7675
				7676	// Initialize the registers.
				7677	__ Mov(x0, literal_base);
				7678	__ Add(x1, x0, x0);
				7679	__ Add(x2, x1, x0);
				7680	__ Add(x3, x2, x0);
				7681
				7682	__ Claim(32);
				7683
				7684	// Mix with other stack operations.
				7685	// After this section:
				7686	// x0-x3 should be unchanged.
				7687	// x6 should match x1[31:0]:x0[63:32]
				7688	// w7 should match x1[15:0]:x0[63:48]
				7689	__ Poke(x1, 8);
				7690	__ Poke(x0, 0);
				7691	{
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	7692	VIXL_ASSERT(__ StackPointer().Is(sp));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7693	__ Mov(x4, __ StackPointer());
				7694	__ SetStackPointer(x4);
				7695
				7696	__ Poke(wzr, 0); // Clobber the space we're about to drop.
				7697	__ Drop(4);
				7698	__ Peek(x6, 0);
				7699	__ Claim(8);
				7700	__ Peek(w7, 10);
				7701	__ Poke(x3, 28);
				7702	__ Poke(xzr, 0); // Clobber the space we're about to drop.
				7703	__ Drop(8);
				7704	__ Poke(x2, 12);
				7705	__ Push(w0);
				7706
				7707	__ Mov(sp, __ StackPointer());
				7708	__ SetStackPointer(sp);
				7709	}
				7710
				7711	__ Pop(x0, x1, x2, x3);
				7712
				7713	END();
				7714	RUN();
				7715
				7716	uint64_t x0_expected = literal_base * 1;
				7717	uint64_t x1_expected = literal_base * 2;
				7718	uint64_t x2_expected = literal_base * 3;
				7719	uint64_t x3_expected = literal_base * 4;
				7720	uint64_t x6_expected = (x1_expected << 32) \| (x0_expected >> 32);
				7721	uint64_t x7_expected = ((x1_expected << 16) & 0xffff0000) \|
				7722	((x0_expected >> 48) & 0x0000ffff);
				7723
				7724	ASSERT_EQUAL_64(x0_expected, x0);
				7725	ASSERT_EQUAL_64(x1_expected, x1);
				7726	ASSERT_EQUAL_64(x2_expected, x2);
				7727	ASSERT_EQUAL_64(x3_expected, x3);
				7728	ASSERT_EQUAL_64(x6_expected, x6);
				7729	ASSERT_EQUAL_64(x7_expected, x7);
				7730
				7731	TEARDOWN();
				7732	}
				7733
				7734
				7735	// This enum is used only as an argument to the push-pop test helpers.
				7736	enum PushPopMethod {
				7737	// Push or Pop using the Push and Pop methods, with blocks of up to four
				7738	// registers. (Smaller blocks will be used if necessary.)
				7739	PushPopByFour,
				7740
				7741	// Use Push<Size>RegList and Pop<Size>RegList to transfer the registers.
				7742	PushPopRegList
				7743	};
				7744
				7745
				7746	// The maximum number of registers that can be used by the PushPopXReg* tests,
				7747	// where a reg_count field is provided.
				7748	static int const kPushPopXRegMaxRegCount = -1;
				7749
				7750	// Test a simple push-pop pattern:
				7751	// * Claim <claim> bytes to set the stack alignment.
				7752	// * Push <reg_count> registers with size <reg_size>.
				7753	// * Clobber the register contents.
				7754	// * Pop <reg_count> registers to restore the original contents.
				7755	// * Drop <claim> bytes to restore the original stack pointer.
				7756	//
				7757	// Different push and pop methods can be specified independently to test for
				7758	// proper word-endian behaviour.
				7759	static void PushPopXRegSimpleHelper(int reg_count,
				7760	int claim,
				7761	int reg_size,
				7762	PushPopMethod push_method,
				7763	PushPopMethod pop_method) {
				7764	SETUP();
				7765
				7766	START();
				7767
				7768	// Arbitrarily pick a register to use as a stack pointer.
				7769	const Register& stack_pointer = x20;
				7770	const RegList allowed = ~stack_pointer.Bit();
				7771	if (reg_count == kPushPopXRegMaxRegCount) {
				7772	reg_count = CountSetBits(allowed, kNumberOfRegisters);
				7773	}
				7774	// Work out which registers to use, based on reg_size.
				7775	Register r[kNumberOfRegisters];
				7776	Register x[kNumberOfRegisters];
				7777	RegList list = PopulateRegisterArray(NULL, x, r, reg_size, reg_count,
				7778	allowed);
				7779
				7780	// The literal base is chosen to have two useful properties:
				7781	// * When multiplied by small values (such as a register index), this value
				7782	// is clearly readable in the result.
				7783	// * The value is not formed from repeating fixed-size smaller values, so it
				7784	// can be used to detect endianness-related errors.
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	7785	uint64_t literal_base = 0x0100001000100101;
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7786
				7787	{
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	7788	VIXL_ASSERT(__ StackPointer().Is(sp));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7789	__ Mov(stack_pointer, __ StackPointer());
				7790	__ SetStackPointer(stack_pointer);
				7791
				7792	int i;
				7793
				7794	// Initialize the registers.
				7795	for (i = 0; i < reg_count; i++) {
				7796	// Always write into the X register, to ensure that the upper word is
				7797	// properly ignored by Push when testing W registers.
				7798	__ Mov(x[i], literal_base * i);
				7799	}
				7800
				7801	// Claim memory first, as requested.
				7802	__ Claim(claim);
				7803
				7804	switch (push_method) {
				7805	case PushPopByFour:
				7806	// Push high-numbered registers first (to the highest addresses).
				7807	for (i = reg_count; i >= 4; i -= 4) {
				7808	__ Push(r[i-1], r[i-2], r[i-3], r[i-4]);
				7809	}
				7810	// Finish off the leftovers.
				7811	switch (i) {
				7812	case 3: __ Push(r[2], r[1], r[0]); break;
				7813	case 2: __ Push(r[1], r[0]); break;
				7814	case 1: __ Push(r[0]); break;
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	7815	default: VIXL_ASSERT(i == 0); break;
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7816	}
				7817	break;
				7818	case PushPopRegList:
				7819	__ PushSizeRegList(list, reg_size);
				7820	break;
				7821	}
				7822
				7823	// Clobber all the registers, to ensure that they get repopulated by Pop.
				7824	Clobber(&masm, list);
				7825
				7826	switch (pop_method) {
				7827	case PushPopByFour:
				7828	// Pop low-numbered registers first (from the lowest addresses).
				7829	for (i = 0; i <= (reg_count-4); i += 4) {
				7830	__ Pop(r[i], r[i+1], r[i+2], r[i+3]);
				7831	}
				7832	// Finish off the leftovers.
				7833	switch (reg_count - i) {
				7834	case 3: __ Pop(r[i], r[i+1], r[i+2]); break;
				7835	case 2: __ Pop(r[i], r[i+1]); break;
				7836	case 1: __ Pop(r[i]); break;
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	7837	default: VIXL_ASSERT(i == reg_count); break;
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7838	}
				7839	break;
				7840	case PushPopRegList:
				7841	__ PopSizeRegList(list, reg_size);
				7842	break;
				7843	}
				7844
				7845	// Drop memory to restore stack_pointer.
				7846	__ Drop(claim);
				7847
				7848	__ Mov(sp, __ StackPointer());
				7849	__ SetStackPointer(sp);
				7850	}
				7851
				7852	END();
				7853
				7854	RUN();
				7855
				7856	// Check that the register contents were preserved.
				7857	// Always use ASSERT_EQUAL_64, even when testing W registers, so we can test
				7858	// that the upper word was properly cleared by Pop.
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	7859	literal_base &= (0xffffffffffffffff >> (64-reg_size));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7860	for (int i = 0; i < reg_count; i++) {
				7861	if (x[i].Is(xzr)) {
				7862	ASSERT_EQUAL_64(0, x[i]);
				7863	} else {
				7864	ASSERT_EQUAL_64(literal_base * i, x[i]);
				7865	}
				7866	}
				7867
				7868	TEARDOWN();
				7869	}
				7870
				7871
				7872	TEST(push_pop_xreg_simple_32) {
				7873	for (int claim = 0; claim <= 8; claim++) {
				7874	for (int count = 0; count <= 8; count++) {
				7875	PushPopXRegSimpleHelper(count, claim, kWRegSize,
				7876	PushPopByFour, PushPopByFour);
				7877	PushPopXRegSimpleHelper(count, claim, kWRegSize,
				7878	PushPopByFour, PushPopRegList);
				7879	PushPopXRegSimpleHelper(count, claim, kWRegSize,
				7880	PushPopRegList, PushPopByFour);
				7881	PushPopXRegSimpleHelper(count, claim, kWRegSize,
				7882	PushPopRegList, PushPopRegList);
				7883	}
				7884	// Test with the maximum number of registers.
				7885	PushPopXRegSimpleHelper(kPushPopXRegMaxRegCount,
				7886	claim, kWRegSize, PushPopByFour, PushPopByFour);
				7887	PushPopXRegSimpleHelper(kPushPopXRegMaxRegCount,
				7888	claim, kWRegSize, PushPopByFour, PushPopRegList);
				7889	PushPopXRegSimpleHelper(kPushPopXRegMaxRegCount,
				7890	claim, kWRegSize, PushPopRegList, PushPopByFour);
				7891	PushPopXRegSimpleHelper(kPushPopXRegMaxRegCount,
				7892	claim, kWRegSize, PushPopRegList, PushPopRegList);
				7893	}
				7894	}
				7895
				7896
				7897	TEST(push_pop_xreg_simple_64) {
				7898	for (int claim = 0; claim <= 8; claim++) {
				7899	for (int count = 0; count <= 8; count++) {
				7900	PushPopXRegSimpleHelper(count, claim, kXRegSize,
				7901	PushPopByFour, PushPopByFour);
				7902	PushPopXRegSimpleHelper(count, claim, kXRegSize,
				7903	PushPopByFour, PushPopRegList);
				7904	PushPopXRegSimpleHelper(count, claim, kXRegSize,
				7905	PushPopRegList, PushPopByFour);
				7906	PushPopXRegSimpleHelper(count, claim, kXRegSize,
				7907	PushPopRegList, PushPopRegList);
				7908	}
				7909	// Test with the maximum number of registers.
				7910	PushPopXRegSimpleHelper(kPushPopXRegMaxRegCount,
				7911	claim, kXRegSize, PushPopByFour, PushPopByFour);
				7912	PushPopXRegSimpleHelper(kPushPopXRegMaxRegCount,
				7913	claim, kXRegSize, PushPopByFour, PushPopRegList);
				7914	PushPopXRegSimpleHelper(kPushPopXRegMaxRegCount,
				7915	claim, kXRegSize, PushPopRegList, PushPopByFour);
				7916	PushPopXRegSimpleHelper(kPushPopXRegMaxRegCount,
				7917	claim, kXRegSize, PushPopRegList, PushPopRegList);
				7918	}
				7919	}
				7920
				7921
				7922	// The maximum number of registers that can be used by the PushPopFPXReg* tests,
				7923	// where a reg_count field is provided.
				7924	static int const kPushPopFPXRegMaxRegCount = -1;
				7925
				7926	// Test a simple push-pop pattern:
				7927	// * Claim <claim> bytes to set the stack alignment.
				7928	// * Push <reg_count> FP registers with size <reg_size>.
				7929	// * Clobber the register contents.
				7930	// * Pop <reg_count> FP registers to restore the original contents.
				7931	// * Drop <claim> bytes to restore the original stack pointer.
				7932	//
				7933	// Different push and pop methods can be specified independently to test for
				7934	// proper word-endian behaviour.
				7935	static void PushPopFPXRegSimpleHelper(int reg_count,
				7936	int claim,
				7937	int reg_size,
				7938	PushPopMethod push_method,
				7939	PushPopMethod pop_method) {
				7940	SETUP();
				7941
				7942	START();
				7943
				7944	// We can use any floating-point register. None of them are reserved for
				7945	// debug code, for example.
				7946	static RegList const allowed = ~0;
				7947	if (reg_count == kPushPopFPXRegMaxRegCount) {
				7948	reg_count = CountSetBits(allowed, kNumberOfFPRegisters);
				7949	}
				7950	// Work out which registers to use, based on reg_size.
				7951	FPRegister v[kNumberOfRegisters];
				7952	FPRegister d[kNumberOfRegisters];
				7953	RegList list = PopulateFPRegisterArray(NULL, d, v, reg_size, reg_count,
				7954	allowed);
				7955
				7956	// Arbitrarily pick a register to use as a stack pointer.
				7957	const Register& stack_pointer = x10;
				7958
				7959	// The literal base is chosen to have two useful properties:
				7960	// * When multiplied (using an integer) by small values (such as a register
				7961	// index), this value is clearly readable in the result.
				7962	// * The value is not formed from repeating fixed-size smaller values, so it
				7963	// can be used to detect endianness-related errors.
				7964	// * It is never a floating-point NaN, and will therefore always compare
				7965	// equal to itself.
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	7966	uint64_t literal_base = 0x0100001000100101;
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7967
				7968	{
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	7969	VIXL_ASSERT(__ StackPointer().Is(sp));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	7970	__ Mov(stack_pointer, __ StackPointer());
				7971	__ SetStackPointer(stack_pointer);
				7972
				7973	int i;
				7974
				7975	// Initialize the registers, using X registers to load the literal.
				7976	__ Mov(x0, 0);
				7977	__ Mov(x1, literal_base);
				7978	for (i = 0; i < reg_count; i++) {
				7979	// Always write into the D register, to ensure that the upper word is
				7980	// properly ignored by Push when testing S registers.
				7981	__ Fmov(d[i], x0);
				7982	// Calculate the next literal.
				7983	__ Add(x0, x0, x1);
				7984	}
				7985
				7986	// Claim memory first, as requested.
				7987	__ Claim(claim);
				7988
				7989	switch (push_method) {
				7990	case PushPopByFour:
				7991	// Push high-numbered registers first (to the highest addresses).
				7992	for (i = reg_count; i >= 4; i -= 4) {
				7993	__ Push(v[i-1], v[i-2], v[i-3], v[i-4]);
				7994	}
				7995	// Finish off the leftovers.
				7996	switch (i) {
				7997	case 3: __ Push(v[2], v[1], v[0]); break;
				7998	case 2: __ Push(v[1], v[0]); break;
				7999	case 1: __ Push(v[0]); break;
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8000	default: VIXL_ASSERT(i == 0); break;
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8001	}
				8002	break;
				8003	case PushPopRegList:
				8004	__ PushSizeRegList(list, reg_size, CPURegister::kFPRegister);
				8005	break;
				8006	}
				8007
				8008	// Clobber all the registers, to ensure that they get repopulated by Pop.
				8009	ClobberFP(&masm, list);
				8010
				8011	switch (pop_method) {
				8012	case PushPopByFour:
				8013	// Pop low-numbered registers first (from the lowest addresses).
				8014	for (i = 0; i <= (reg_count-4); i += 4) {
				8015	__ Pop(v[i], v[i+1], v[i+2], v[i+3]);
				8016	}
				8017	// Finish off the leftovers.
				8018	switch (reg_count - i) {
				8019	case 3: __ Pop(v[i], v[i+1], v[i+2]); break;
				8020	case 2: __ Pop(v[i], v[i+1]); break;
				8021	case 1: __ Pop(v[i]); break;
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8022	default: VIXL_ASSERT(i == reg_count); break;
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8023	}
				8024	break;
				8025	case PushPopRegList:
				8026	__ PopSizeRegList(list, reg_size, CPURegister::kFPRegister);
				8027	break;
				8028	}
				8029
				8030	// Drop memory to restore the stack pointer.
				8031	__ Drop(claim);
				8032
				8033	__ Mov(sp, __ StackPointer());
				8034	__ SetStackPointer(sp);
				8035	}
				8036
				8037	END();
				8038
				8039	RUN();
				8040
				8041	// Check that the register contents were preserved.
				8042	// Always use ASSERT_EQUAL_FP64, even when testing S registers, so we can
				8043	// test that the upper word was properly cleared by Pop.
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8044	literal_base &= (0xffffffffffffffff >> (64-reg_size));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8045	for (int i = 0; i < reg_count; i++) {
				8046	uint64_t literal = literal_base * i;
				8047	double expected;
				8048	memcpy(&expected, &literal, sizeof(expected));
				8049	ASSERT_EQUAL_FP64(expected, d[i]);
				8050	}
				8051
				8052	TEARDOWN();
				8053	}
				8054
				8055
				8056	TEST(push_pop_fp_xreg_simple_32) {
				8057	for (int claim = 0; claim <= 8; claim++) {
				8058	for (int count = 0; count <= 8; count++) {
				8059	PushPopFPXRegSimpleHelper(count, claim, kSRegSize,
				8060	PushPopByFour, PushPopByFour);
				8061	PushPopFPXRegSimpleHelper(count, claim, kSRegSize,
				8062	PushPopByFour, PushPopRegList);
				8063	PushPopFPXRegSimpleHelper(count, claim, kSRegSize,
				8064	PushPopRegList, PushPopByFour);
				8065	PushPopFPXRegSimpleHelper(count, claim, kSRegSize,
				8066	PushPopRegList, PushPopRegList);
				8067	}
				8068	// Test with the maximum number of registers.
				8069	PushPopFPXRegSimpleHelper(kPushPopFPXRegMaxRegCount, claim, kSRegSize,
				8070	PushPopByFour, PushPopByFour);
				8071	PushPopFPXRegSimpleHelper(kPushPopFPXRegMaxRegCount, claim, kSRegSize,
				8072	PushPopByFour, PushPopRegList);
				8073	PushPopFPXRegSimpleHelper(kPushPopFPXRegMaxRegCount, claim, kSRegSize,
				8074	PushPopRegList, PushPopByFour);
				8075	PushPopFPXRegSimpleHelper(kPushPopFPXRegMaxRegCount, claim, kSRegSize,
				8076	PushPopRegList, PushPopRegList);
				8077	}
				8078	}
				8079
				8080
				8081	TEST(push_pop_fp_xreg_simple_64) {
				8082	for (int claim = 0; claim <= 8; claim++) {
				8083	for (int count = 0; count <= 8; count++) {
				8084	PushPopFPXRegSimpleHelper(count, claim, kDRegSize,
				8085	PushPopByFour, PushPopByFour);
				8086	PushPopFPXRegSimpleHelper(count, claim, kDRegSize,
				8087	PushPopByFour, PushPopRegList);
				8088	PushPopFPXRegSimpleHelper(count, claim, kDRegSize,
				8089	PushPopRegList, PushPopByFour);
				8090	PushPopFPXRegSimpleHelper(count, claim, kDRegSize,
				8091	PushPopRegList, PushPopRegList);
				8092	}
				8093	// Test with the maximum number of registers.
				8094	PushPopFPXRegSimpleHelper(kPushPopFPXRegMaxRegCount, claim, kDRegSize,
				8095	PushPopByFour, PushPopByFour);
				8096	PushPopFPXRegSimpleHelper(kPushPopFPXRegMaxRegCount, claim, kDRegSize,
				8097	PushPopByFour, PushPopRegList);
				8098	PushPopFPXRegSimpleHelper(kPushPopFPXRegMaxRegCount, claim, kDRegSize,
				8099	PushPopRegList, PushPopByFour);
				8100	PushPopFPXRegSimpleHelper(kPushPopFPXRegMaxRegCount, claim, kDRegSize,
				8101	PushPopRegList, PushPopRegList);
				8102	}
				8103	}
				8104
				8105
				8106	// Push and pop data using an overlapping combination of Push/Pop and
				8107	// RegList-based methods.
				8108	static void PushPopXRegMixedMethodsHelper(int claim, int reg_size) {
				8109	SETUP();
				8110
				8111	// Arbitrarily pick a register to use as a stack pointer.
				8112	const Register& stack_pointer = x5;
				8113	const RegList allowed = ~stack_pointer.Bit();
				8114	// Work out which registers to use, based on reg_size.
				8115	Register r[10];
				8116	Register x[10];
				8117	PopulateRegisterArray(NULL, x, r, reg_size, 10, allowed);
				8118
				8119	// Calculate some handy register lists.
				8120	RegList r0_to_r3 = 0;
				8121	for (int i = 0; i <= 3; i++) {
				8122	r0_to_r3 \|= x[i].Bit();
				8123	}
				8124	RegList r4_to_r5 = 0;
				8125	for (int i = 4; i <= 5; i++) {
				8126	r4_to_r5 \|= x[i].Bit();
				8127	}
				8128	RegList r6_to_r9 = 0;
				8129	for (int i = 6; i <= 9; i++) {
				8130	r6_to_r9 \|= x[i].Bit();
				8131	}
				8132
				8133	// The literal base is chosen to have two useful properties:
				8134	// * When multiplied by small values (such as a register index), this value
				8135	// is clearly readable in the result.
				8136	// * The value is not formed from repeating fixed-size smaller values, so it
				8137	// can be used to detect endianness-related errors.
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8138	uint64_t literal_base = 0x0100001000100101;
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8139
				8140	START();
				8141	{
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8142	VIXL_ASSERT(__ StackPointer().Is(sp));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8143	__ Mov(stack_pointer, __ StackPointer());
				8144	__ SetStackPointer(stack_pointer);
				8145
				8146	// Claim memory first, as requested.
				8147	__ Claim(claim);
				8148
				8149	__ Mov(x[3], literal_base * 3);
				8150	__ Mov(x[2], literal_base * 2);
				8151	__ Mov(x[1], literal_base * 1);
				8152	__ Mov(x[0], literal_base * 0);
				8153
				8154	__ PushSizeRegList(r0_to_r3, reg_size);
				8155	__ Push(r[3], r[2]);
				8156
				8157	Clobber(&masm, r0_to_r3);
				8158	__ PopSizeRegList(r0_to_r3, reg_size);
				8159
				8160	__ Push(r[2], r[1], r[3], r[0]);
				8161
				8162	Clobber(&masm, r4_to_r5);
				8163	__ Pop(r[4], r[5]);
				8164	Clobber(&masm, r6_to_r9);
				8165	__ Pop(r[6], r[7], r[8], r[9]);
				8166
				8167	// Drop memory to restore stack_pointer.
				8168	__ Drop(claim);
				8169
				8170	__ Mov(sp, __ StackPointer());
				8171	__ SetStackPointer(sp);
				8172	}
				8173
				8174	END();
				8175
				8176	RUN();
				8177
				8178	// Always use ASSERT_EQUAL_64, even when testing W registers, so we can test
				8179	// that the upper word was properly cleared by Pop.
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8180	literal_base &= (0xffffffffffffffff >> (64-reg_size));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8181
				8182	ASSERT_EQUAL_64(literal_base * 3, x[9]);
				8183	ASSERT_EQUAL_64(literal_base * 2, x[8]);
				8184	ASSERT_EQUAL_64(literal_base * 0, x[7]);
				8185	ASSERT_EQUAL_64(literal_base * 3, x[6]);
				8186	ASSERT_EQUAL_64(literal_base * 1, x[5]);
				8187	ASSERT_EQUAL_64(literal_base * 2, x[4]);
				8188
				8189	TEARDOWN();
				8190	}
				8191
				8192
				8193	TEST(push_pop_xreg_mixed_methods_64) {
				8194	for (int claim = 0; claim <= 8; claim++) {
				8195	PushPopXRegMixedMethodsHelper(claim, kXRegSize);
				8196	}
				8197	}
				8198
				8199
				8200	TEST(push_pop_xreg_mixed_methods_32) {
				8201	for (int claim = 0; claim <= 8; claim++) {
				8202	PushPopXRegMixedMethodsHelper(claim, kWRegSize);
				8203	}
				8204	}
				8205
				8206
				8207	// Push and pop data using overlapping X- and W-sized quantities.
				8208	static void PushPopXRegWXOverlapHelper(int reg_count, int claim) {
				8209	SETUP();
				8210
				8211	// Arbitrarily pick a register to use as a stack pointer.
				8212	const Register& stack_pointer = x10;
				8213	const RegList allowed = ~stack_pointer.Bit();
				8214	if (reg_count == kPushPopXRegMaxRegCount) {
				8215	reg_count = CountSetBits(allowed, kNumberOfRegisters);
				8216	}
				8217	// Work out which registers to use, based on reg_size.
				8218	Register w[kNumberOfRegisters];
				8219	Register x[kNumberOfRegisters];
				8220	RegList list = PopulateRegisterArray(w, x, NULL, 0, reg_count, allowed);
				8221
				8222	// The number of W-sized slots we expect to pop. When we pop, we alternate
				8223	// between W and X registers, so we need reg_count*1.5 W-sized slots.
				8224	int const requested_w_slots = reg_count + reg_count / 2;
				8225
				8226	// Track what _should_ be on the stack, using W-sized slots.
				8227	static int const kMaxWSlots = kNumberOfRegisters + kNumberOfRegisters / 2;
				8228	uint32_t stack[kMaxWSlots];
				8229	for (int i = 0; i < kMaxWSlots; i++) {
				8230	stack[i] = 0xdeadbeef;
				8231	}
				8232
				8233	// The literal base is chosen to have two useful properties:
				8234	// * When multiplied by small values (such as a register index), this value
				8235	// is clearly readable in the result.
				8236	// * The value is not formed from repeating fixed-size smaller values, so it
				8237	// can be used to detect endianness-related errors.
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8238	static uint64_t const literal_base = 0x0100001000100101;
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8239	static uint64_t const literal_base_hi = literal_base >> 32;
				8240	static uint64_t const literal_base_lo = literal_base & 0xffffffff;
				8241	static uint64_t const literal_base_w = literal_base & 0xffffffff;
				8242
				8243	START();
				8244	{
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8245	VIXL_ASSERT(__ StackPointer().Is(sp));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8246	__ Mov(stack_pointer, __ StackPointer());
				8247	__ SetStackPointer(stack_pointer);
				8248
				8249	// Initialize the registers.
				8250	for (int i = 0; i < reg_count; i++) {
				8251	// Always write into the X register, to ensure that the upper word is
				8252	// properly ignored by Push when testing W registers.
				8253	__ Mov(x[i], literal_base * i);
				8254	}
				8255
				8256	// Claim memory first, as requested.
				8257	__ Claim(claim);
				8258
				8259	// The push-pop pattern is as follows:
				8260	// Push: Pop:
				8261	// x[0](hi) -> w[0]
				8262	// x[0](lo) -> x[1](hi)
				8263	// w[1] -> x[1](lo)
				8264	// w[1] -> w[2]
				8265	// x[2](hi) -> x[2](hi)
				8266	// x[2](lo) -> x[2](lo)
				8267	// x[2](hi) -> w[3]
				8268	// x[2](lo) -> x[4](hi)
				8269	// x[2](hi) -> x[4](lo)
				8270	// x[2](lo) -> w[5]
				8271	// w[3] -> x[5](hi)
				8272	// w[3] -> x[6](lo)
				8273	// w[3] -> w[7]
				8274	// w[3] -> x[8](hi)
				8275	// x[4](hi) -> x[8](lo)
				8276	// x[4](lo) -> w[9]
				8277	// ... pattern continues ...
				8278	//
				8279	// That is, registers are pushed starting with the lower numbers,
				8280	// alternating between x and w registers, and pushing i%4+1 copies of each,
				8281	// where i is the register number.
				8282	// Registers are popped starting with the higher numbers one-by-one,
				8283	// alternating between x and w registers, but only popping one at a time.
				8284	//
				8285	// This pattern provides a wide variety of alignment effects and overlaps.
				8286
				8287	// ---- Push ----
				8288
				8289	int active_w_slots = 0;
				8290	for (int i = 0; active_w_slots < requested_w_slots; i++) {
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8291	VIXL_ASSERT(i < reg_count);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8292	// In order to test various arguments to PushMultipleTimes, and to try to
				8293	// exercise different alignment and overlap effects, we push each
				8294	// register a different number of times.
				8295	int times = i % 4 + 1;
				8296	if (i & 1) {
				8297	// Push odd-numbered registers as W registers.
				8298	__ PushMultipleTimes(times, w[i]);
				8299	// Fill in the expected stack slots.
				8300	for (int j = 0; j < times; j++) {
				8301	if (w[i].Is(wzr)) {
				8302	// The zero register always writes zeroes.
				8303	stack[active_w_slots++] = 0;
				8304	} else {
				8305	stack[active_w_slots++] = literal_base_w * i;
				8306	}
				8307	}
				8308	} else {
				8309	// Push even-numbered registers as X registers.
				8310	__ PushMultipleTimes(times, x[i]);
				8311	// Fill in the expected stack slots.
				8312	for (int j = 0; j < times; j++) {
				8313	if (x[i].Is(xzr)) {
				8314	// The zero register always writes zeroes.
				8315	stack[active_w_slots++] = 0;
				8316	stack[active_w_slots++] = 0;
				8317	} else {
				8318	stack[active_w_slots++] = literal_base_hi * i;
				8319	stack[active_w_slots++] = literal_base_lo * i;
				8320	}
				8321	}
				8322	}
				8323	}
				8324	// Because we were pushing several registers at a time, we probably pushed
				8325	// more than we needed to.
				8326	if (active_w_slots > requested_w_slots) {
				8327	__ Drop((active_w_slots - requested_w_slots) * kWRegSizeInBytes);
				8328	// Bump the number of active W-sized slots back to where it should be,
				8329	// and fill the empty space with a dummy value.
				8330	do {
				8331	stack[active_w_slots--] = 0xdeadbeef;
				8332	} while (active_w_slots > requested_w_slots);
				8333	}
				8334
				8335	// ---- Pop ----
				8336
				8337	Clobber(&masm, list);
				8338
				8339	// If popping an even number of registers, the first one will be X-sized.
				8340	// Otherwise, the first one will be W-sized.
				8341	bool next_is_64 = !(reg_count & 1);
				8342	for (int i = reg_count-1; i >= 0; i--) {
				8343	if (next_is_64) {
				8344	__ Pop(x[i]);
				8345	active_w_slots -= 2;
				8346	} else {
				8347	__ Pop(w[i]);
				8348	active_w_slots -= 1;
				8349	}
				8350	next_is_64 = !next_is_64;
				8351	}
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8352	VIXL_ASSERT(active_w_slots == 0);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8353
				8354	// Drop memory to restore stack_pointer.
				8355	__ Drop(claim);
				8356
				8357	__ Mov(sp, __ StackPointer());
				8358	__ SetStackPointer(sp);
				8359	}
				8360
				8361	END();
				8362
				8363	RUN();
				8364
				8365	int slot = 0;
				8366	for (int i = 0; i < reg_count; i++) {
				8367	// Even-numbered registers were written as W registers.
				8368	// Odd-numbered registers were written as X registers.
				8369	bool expect_64 = (i & 1);
				8370	uint64_t expected;
				8371
				8372	if (expect_64) {
				8373	uint64_t hi = stack[slot++];
				8374	uint64_t lo = stack[slot++];
				8375	expected = (hi << 32) \| lo;
				8376	} else {
				8377	expected = stack[slot++];
				8378	}
				8379
				8380	// Always use ASSERT_EQUAL_64, even when testing W registers, so we can
				8381	// test that the upper word was properly cleared by Pop.
				8382	if (x[i].Is(xzr)) {
				8383	ASSERT_EQUAL_64(0, x[i]);
				8384	} else {
				8385	ASSERT_EQUAL_64(expected, x[i]);
				8386	}
				8387	}
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8388	VIXL_ASSERT(slot == requested_w_slots);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8389
				8390	TEARDOWN();
				8391	}
				8392
				8393
				8394	TEST(push_pop_xreg_wx_overlap) {
				8395	for (int claim = 0; claim <= 8; claim++) {
				8396	for (int count = 1; count <= 8; count++) {
				8397	PushPopXRegWXOverlapHelper(count, claim);
				8398	}
				8399	// Test with the maximum number of registers.
				8400	PushPopXRegWXOverlapHelper(kPushPopXRegMaxRegCount, claim);
				8401	}
				8402	}
				8403
				8404
				8405	TEST(push_pop_sp) {
				8406	SETUP();
				8407
				8408	START();
				8409
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8410	VIXL_ASSERT(sp.Is(__ StackPointer()));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8411
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8412	__ Mov(x3, 0x3333333333333333);
				8413	__ Mov(x2, 0x2222222222222222);
				8414	__ Mov(x1, 0x1111111111111111);
				8415	__ Mov(x0, 0x0000000000000000);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8416	__ Claim(2 * kXRegSizeInBytes);
				8417	__ PushXRegList(x0.Bit() \| x1.Bit() \| x2.Bit() \| x3.Bit());
				8418	__ Push(x3, x2);
				8419	__ PopXRegList(x0.Bit() \| x1.Bit() \| x2.Bit() \| x3.Bit());
				8420	__ Push(x2, x1, x3, x0);
				8421	__ Pop(x4, x5);
				8422	__ Pop(x6, x7, x8, x9);
				8423
				8424	__ Claim(2 * kXRegSizeInBytes);
				8425	__ PushWRegList(w0.Bit() \| w1.Bit() \| w2.Bit() \| w3.Bit());
				8426	__ Push(w3, w1, w2, w0);
				8427	__ PopWRegList(w10.Bit() \| w11.Bit() \| w12.Bit() \| w13.Bit());
				8428	__ Pop(w14, w15, w16, w17);
				8429
				8430	__ Claim(2 * kXRegSizeInBytes);
				8431	__ Push(w2, w2, w1, w1);
				8432	__ Push(x3, x3);
				8433	__ Pop(w18, w19, w20, w21);
				8434	__ Pop(x22, x23);
				8435
				8436	__ Claim(2 * kXRegSizeInBytes);
				8437	__ PushXRegList(x1.Bit() \| x22.Bit());
				8438	__ PopXRegList(x24.Bit() \| x26.Bit());
				8439
				8440	__ Claim(2 * kXRegSizeInBytes);
				8441	__ PushWRegList(w1.Bit() \| w2.Bit() \| w4.Bit() \| w22.Bit());
				8442	__ PopWRegList(w25.Bit() \| w27.Bit() \| w28.Bit() \| w29.Bit());
				8443
				8444	__ Claim(2 * kXRegSizeInBytes);
				8445	__ PushXRegList(0);
				8446	__ PopXRegList(0);
				8447	__ PushXRegList(0xffffffff);
				8448	__ PopXRegList(0xffffffff);
				8449	__ Drop(12 * kXRegSizeInBytes);
				8450	END();
				8451
				8452	RUN();
				8453
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8454	ASSERT_EQUAL_64(0x1111111111111111, x3);
				8455	ASSERT_EQUAL_64(0x0000000000000000, x2);
				8456	ASSERT_EQUAL_64(0x3333333333333333, x1);
				8457	ASSERT_EQUAL_64(0x2222222222222222, x0);
				8458	ASSERT_EQUAL_64(0x3333333333333333, x9);
				8459	ASSERT_EQUAL_64(0x2222222222222222, x8);
				8460	ASSERT_EQUAL_64(0x0000000000000000, x7);
				8461	ASSERT_EQUAL_64(0x3333333333333333, x6);
				8462	ASSERT_EQUAL_64(0x1111111111111111, x5);
				8463	ASSERT_EQUAL_64(0x2222222222222222, x4);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8464
				8465	ASSERT_EQUAL_32(0x11111111U, w13);
				8466	ASSERT_EQUAL_32(0x33333333U, w12);
				8467	ASSERT_EQUAL_32(0x00000000U, w11);
				8468	ASSERT_EQUAL_32(0x22222222U, w10);
				8469	ASSERT_EQUAL_32(0x11111111U, w17);
				8470	ASSERT_EQUAL_32(0x00000000U, w16);
				8471	ASSERT_EQUAL_32(0x33333333U, w15);
				8472	ASSERT_EQUAL_32(0x22222222U, w14);
				8473
				8474	ASSERT_EQUAL_32(0x11111111U, w18);
				8475	ASSERT_EQUAL_32(0x11111111U, w19);
				8476	ASSERT_EQUAL_32(0x11111111U, w20);
				8477	ASSERT_EQUAL_32(0x11111111U, w21);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8478	ASSERT_EQUAL_64(0x3333333333333333, x22);
				8479	ASSERT_EQUAL_64(0x0000000000000000, x23);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8480
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8481	ASSERT_EQUAL_64(0x3333333333333333, x24);
				8482	ASSERT_EQUAL_64(0x3333333333333333, x26);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8483
				8484	ASSERT_EQUAL_32(0x33333333U, w25);
				8485	ASSERT_EQUAL_32(0x00000000U, w27);
				8486	ASSERT_EQUAL_32(0x22222222U, w28);
				8487	ASSERT_EQUAL_32(0x33333333U, w29);
				8488	TEARDOWN();
				8489	}
				8490
				8491
				8492	TEST(noreg) {
				8493	// This test doesn't generate any code, but it verifies some invariants
				8494	// related to NoReg.
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8495	VIXL_CHECK(NoReg.Is(NoFPReg));
				8496	VIXL_CHECK(NoFPReg.Is(NoReg));
				8497	VIXL_CHECK(NoReg.Is(NoCPUReg));
				8498	VIXL_CHECK(NoCPUReg.Is(NoReg));
				8499	VIXL_CHECK(NoFPReg.Is(NoCPUReg));
				8500	VIXL_CHECK(NoCPUReg.Is(NoFPReg));
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8501
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8502	VIXL_CHECK(NoReg.IsNone());
				8503	VIXL_CHECK(NoFPReg.IsNone());
				8504	VIXL_CHECK(NoCPUReg.IsNone());
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8505	}
				8506
				8507
				8508	TEST(isvalid) {
				8509	// This test doesn't generate any code, but it verifies some invariants
				8510	// related to IsValid().
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8511	VIXL_CHECK(!NoReg.IsValid());
				8512	VIXL_CHECK(!NoFPReg.IsValid());
				8513	VIXL_CHECK(!NoCPUReg.IsValid());
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8514
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8515	VIXL_CHECK(x0.IsValid());
				8516	VIXL_CHECK(w0.IsValid());
				8517	VIXL_CHECK(x30.IsValid());
				8518	VIXL_CHECK(w30.IsValid());
				8519	VIXL_CHECK(xzr.IsValid());
				8520	VIXL_CHECK(wzr.IsValid());
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8521
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8522	VIXL_CHECK(sp.IsValid());
				8523	VIXL_CHECK(wsp.IsValid());
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8524
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8525	VIXL_CHECK(d0.IsValid());
				8526	VIXL_CHECK(s0.IsValid());
				8527	VIXL_CHECK(d31.IsValid());
				8528	VIXL_CHECK(s31.IsValid());
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8529
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8530	VIXL_CHECK(x0.IsValidRegister());
				8531	VIXL_CHECK(w0.IsValidRegister());
				8532	VIXL_CHECK(xzr.IsValidRegister());
				8533	VIXL_CHECK(wzr.IsValidRegister());
				8534	VIXL_CHECK(sp.IsValidRegister());
				8535	VIXL_CHECK(wsp.IsValidRegister());
				8536	VIXL_CHECK(!x0.IsValidFPRegister());
				8537	VIXL_CHECK(!w0.IsValidFPRegister());
				8538	VIXL_CHECK(!xzr.IsValidFPRegister());
				8539	VIXL_CHECK(!wzr.IsValidFPRegister());
				8540	VIXL_CHECK(!sp.IsValidFPRegister());
				8541	VIXL_CHECK(!wsp.IsValidFPRegister());
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8542
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8543	VIXL_CHECK(d0.IsValidFPRegister());
				8544	VIXL_CHECK(s0.IsValidFPRegister());
				8545	VIXL_CHECK(!d0.IsValidRegister());
				8546	VIXL_CHECK(!s0.IsValidRegister());
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8547
				8548	// Test the same as before, but using CPURegister types. This shouldn't make
				8549	// any difference.
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8550	VIXL_CHECK(static_cast<CPURegister>(x0).IsValid());
				8551	VIXL_CHECK(static_cast<CPURegister>(w0).IsValid());
				8552	VIXL_CHECK(static_cast<CPURegister>(x30).IsValid());
				8553	VIXL_CHECK(static_cast<CPURegister>(w30).IsValid());
				8554	VIXL_CHECK(static_cast<CPURegister>(xzr).IsValid());
				8555	VIXL_CHECK(static_cast<CPURegister>(wzr).IsValid());
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8556
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8557	VIXL_CHECK(static_cast<CPURegister>(sp).IsValid());
				8558	VIXL_CHECK(static_cast<CPURegister>(wsp).IsValid());
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8559
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8560	VIXL_CHECK(static_cast<CPURegister>(d0).IsValid());
				8561	VIXL_CHECK(static_cast<CPURegister>(s0).IsValid());
				8562	VIXL_CHECK(static_cast<CPURegister>(d31).IsValid());
				8563	VIXL_CHECK(static_cast<CPURegister>(s31).IsValid());
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8564
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8565	VIXL_CHECK(static_cast<CPURegister>(x0).IsValidRegister());
				8566	VIXL_CHECK(static_cast<CPURegister>(w0).IsValidRegister());
				8567	VIXL_CHECK(static_cast<CPURegister>(xzr).IsValidRegister());
				8568	VIXL_CHECK(static_cast<CPURegister>(wzr).IsValidRegister());
				8569	VIXL_CHECK(static_cast<CPURegister>(sp).IsValidRegister());
				8570	VIXL_CHECK(static_cast<CPURegister>(wsp).IsValidRegister());
				8571	VIXL_CHECK(!static_cast<CPURegister>(x0).IsValidFPRegister());
				8572	VIXL_CHECK(!static_cast<CPURegister>(w0).IsValidFPRegister());
				8573	VIXL_CHECK(!static_cast<CPURegister>(xzr).IsValidFPRegister());
				8574	VIXL_CHECK(!static_cast<CPURegister>(wzr).IsValidFPRegister());
				8575	VIXL_CHECK(!static_cast<CPURegister>(sp).IsValidFPRegister());
				8576	VIXL_CHECK(!static_cast<CPURegister>(wsp).IsValidFPRegister());
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8577
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8578	VIXL_CHECK(static_cast<CPURegister>(d0).IsValidFPRegister());
				8579	VIXL_CHECK(static_cast<CPURegister>(s0).IsValidFPRegister());
				8580	VIXL_CHECK(!static_cast<CPURegister>(d0).IsValidRegister());
				8581	VIXL_CHECK(!static_cast<CPURegister>(s0).IsValidRegister());
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8582	}
				8583
				8584
				8585	TEST(printf) {
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	8586	SETUP_SIZE(BUF_SIZE * 2);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8587	START();
				8588
				8589	char const * test_plain_string = "Printf with no arguments.\n";
				8590	char const * test_substring = "'This is a substring.'";
				8591	RegisterDump before;
				8592
				8593	// Initialize x29 to the value of the stack pointer. We will use x29 as a
				8594	// temporary stack pointer later, and initializing it in this way allows the
				8595	// RegisterDump check to pass.
				8596	__ Mov(x29, __ StackPointer());
				8597
				8598	// Test simple integer arguments.
				8599	__ Mov(x0, 1234);
				8600	__ Mov(x1, 0x1234);
				8601
				8602	// Test simple floating-point arguments.
				8603	__ Fmov(d0, 1.234);
				8604
				8605	// Test pointer (string) arguments.
				8606	__ Mov(x2, reinterpret_cast<uintptr_t>(test_substring));
				8607
				8608	// Test the maximum number of arguments, and sign extension.
				8609	__ Mov(w3, 0xffffffff);
				8610	__ Mov(w4, 0xffffffff);
				8611	__ Mov(x5, 0xffffffffffffffff);
				8612	__ Mov(x6, 0xffffffffffffffff);
				8613	__ Fmov(s1, 1.234);
				8614	__ Fmov(s2, 2.345);
				8615	__ Fmov(d3, 3.456);
				8616	__ Fmov(d4, 4.567);
				8617
				8618	// Test printing callee-saved registers.
				8619	__ Mov(x28, 0x123456789abcdef);
				8620	__ Fmov(d10, 42.0);
				8621
				8622	// Test with three arguments.
				8623	__ Mov(x10, 3);
				8624	__ Mov(x11, 40);
				8625	__ Mov(x12, 500);
				8626
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	8627	// A single character.
				8628	__ Mov(w13, 'x');
				8629
				8630	// Check that we don't clobber any registers.
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8631	before.Dump(&masm);
				8632
				8633	__ Printf(test_plain_string); // NOLINT(runtime/printf)
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	8634	__ Printf("x0: %" PRId64 ", x1: 0x%08" PRIx64 "\n", x0, x1);
				8635	__ Printf("w5: %" PRId32 ", x5: %" PRId64"\n", w5, x5);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8636	__ Printf("d0: %f\n", d0);
				8637	__ Printf("Test %%s: %s\n", x2);
				8638	__ Printf("w3(uint32): %" PRIu32 "\nw4(int32): %" PRId32 "\n"
				8639	"x5(uint64): %" PRIu64 "\nx6(int64): %" PRId64 "\n",
				8640	w3, w4, x5, x6);
				8641	__ Printf("%%f: %f\n%%g: %g\n%%e: %e\n%%E: %E\n", s1, s2, d3, d4);
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	8642	__ Printf("0x%" PRIx32 ", 0x%" PRIx64 "\n", w28, x28);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8643	__ Printf("%g\n", d10);
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	8644	__ Printf("%%%%%s%%%c%%\n", x2, w13);
				8645
				8646	// Print the stack pointer (sp).
				8647	__ Printf("StackPointer(sp): 0x%016" PRIx64 ", 0x%08" PRIx32 "\n",
				8648	__ StackPointer(), __ StackPointer().W());
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8649
				8650	// Test with a different stack pointer.
				8651	const Register old_stack_pointer = __ StackPointer();
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	8652	__ Mov(x29, old_stack_pointer);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8653	__ SetStackPointer(x29);
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	8654	// Print the stack pointer (not sp).
				8655	__ Printf("StackPointer(not sp): 0x%016" PRIx64 ", 0x%08" PRIx32 "\n",
				8656	__ StackPointer(), __ StackPointer().W());
				8657	__ Mov(old_stack_pointer, __ StackPointer());
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8658	__ SetStackPointer(old_stack_pointer);
				8659
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	8660	// Test with three arguments.
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8661	__ Printf("3=%u, 4=%u, 5=%u\n", x10, x11, x12);
				8662
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	8663	// Mixed argument types.
				8664	__ Printf("w3: %" PRIu32 ", s1: %f, x5: %" PRIu64 ", d3: %f\n",
				8665	w3, s1, x5, d3);
				8666	__ Printf("s1: %f, d3: %f, w3: %" PRId32 ", x5: %" PRId64 "\n",
				8667	s1, d3, w3, x5);
				8668
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8669	END();
				8670	RUN();
				8671
				8672	// We cannot easily test the output of the Printf sequences, and because
				8673	// Printf preserves all registers by default, we can't look at the number of
				8674	// bytes that were printed. However, the printf_no_preserve test should check
				8675	// that, and here we just test that we didn't clobber any registers.
				8676	ASSERT_EQUAL_REGISTERS(before);
				8677
				8678	TEARDOWN();
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8679	}
				8680
				8681
				8682	TEST(printf_no_preserve) {
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8683	SETUP();
				8684	START();
				8685
				8686	char const * test_plain_string = "Printf with no arguments.\n";
				8687	char const * test_substring = "'This is a substring.'";
				8688
				8689	__ PrintfNoPreserve(test_plain_string);
				8690	__ Mov(x19, x0);
				8691
				8692	// Test simple integer arguments.
				8693	__ Mov(x0, 1234);
				8694	__ Mov(x1, 0x1234);
				8695	__ PrintfNoPreserve("x0: %" PRId64", x1: 0x%08" PRIx64 "\n", x0, x1);
				8696	__ Mov(x20, x0);
				8697
				8698	// Test simple floating-point arguments.
				8699	__ Fmov(d0, 1.234);
				8700	__ PrintfNoPreserve("d0: %f\n", d0);
				8701	__ Mov(x21, x0);
				8702
				8703	// Test pointer (string) arguments.
				8704	__ Mov(x2, reinterpret_cast<uintptr_t>(test_substring));
				8705	__ PrintfNoPreserve("Test %%s: %s\n", x2);
				8706	__ Mov(x22, x0);
				8707
				8708	// Test the maximum number of arguments, and sign extension.
				8709	__ Mov(w3, 0xffffffff);
				8710	__ Mov(w4, 0xffffffff);
				8711	__ Mov(x5, 0xffffffffffffffff);
				8712	__ Mov(x6, 0xffffffffffffffff);
				8713	__ PrintfNoPreserve("w3(uint32): %" PRIu32 "\nw4(int32): %" PRId32 "\n"
				8714	"x5(uint64): %" PRIu64 "\nx6(int64): %" PRId64 "\n",
				8715	w3, w4, x5, x6);
				8716	__ Mov(x23, x0);
				8717
				8718	__ Fmov(s1, 1.234);
				8719	__ Fmov(s2, 2.345);
				8720	__ Fmov(d3, 3.456);
				8721	__ Fmov(d4, 4.567);
				8722	__ PrintfNoPreserve("%%f: %f\n%%g: %g\n%%e: %e\n%%E: %E\n", s1, s2, d3, d4);
				8723	__ Mov(x24, x0);
				8724
				8725	// Test printing callee-saved registers.
				8726	__ Mov(x28, 0x123456789abcdef);
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	8727	__ PrintfNoPreserve("0x%" PRIx32 ", 0x%" PRIx64 "\n", w28, x28);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8728	__ Mov(x25, x0);
				8729
				8730	__ Fmov(d10, 42.0);
				8731	__ PrintfNoPreserve("%g\n", d10);
				8732	__ Mov(x26, x0);
				8733
				8734	// Test with a different stack pointer.
				8735	const Register old_stack_pointer = __ StackPointer();
				8736	__ Mov(x29, old_stack_pointer);
				8737	__ SetStackPointer(x29);
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	8738	// Print the stack pointer (not sp).
				8739	__ PrintfNoPreserve(
				8740	"StackPointer(not sp): 0x%016" PRIx64 ", 0x%08" PRIx32 "\n",
				8741	__ StackPointer(), __ StackPointer().W());
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8742	__ Mov(x27, x0);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8743	__ Mov(old_stack_pointer, __ StackPointer());
				8744	__ SetStackPointer(old_stack_pointer);
				8745
				8746	// Test with three arguments.
				8747	__ Mov(x3, 3);
				8748	__ Mov(x4, 40);
				8749	__ Mov(x5, 500);
				8750	__ PrintfNoPreserve("3=%u, 4=%u, 5=%u\n", x3, x4, x5);
				8751	__ Mov(x28, x0);
				8752
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	8753	// Mixed argument types.
				8754	__ Mov(w3, 0xffffffff);
				8755	__ Fmov(s1, 1.234);
				8756	__ Mov(x5, 0xffffffffffffffff);
				8757	__ Fmov(d3, 3.456);
				8758	__ PrintfNoPreserve("w3: %" PRIu32 ", s1: %f, x5: %" PRIu64 ", d3: %f\n",
				8759	w3, s1, x5, d3);
				8760	__ Mov(x29, x0);
				8761
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8762	END();
				8763	RUN();
				8764
				8765	// We cannot easily test the exact output of the Printf sequences, but we can
				8766	// use the return code to check that the string length was correct.
				8767
				8768	// Printf with no arguments.
				8769	ASSERT_EQUAL_64(strlen(test_plain_string), x19);
				8770	// x0: 1234, x1: 0x00001234
				8771	ASSERT_EQUAL_64(25, x20);
				8772	// d0: 1.234000
				8773	ASSERT_EQUAL_64(13, x21);
				8774	// Test %s: 'This is a substring.'
				8775	ASSERT_EQUAL_64(32, x22);
				8776	// w3(uint32): 4294967295
				8777	// w4(int32): -1
				8778	// x5(uint64): 18446744073709551615
				8779	// x6(int64): -1
				8780	ASSERT_EQUAL_64(23 + 14 + 33 + 14, x23);
				8781	// %f: 1.234000
				8782	// %g: 2.345
				8783	// %e: 3.456000e+00
				8784	// %E: 4.567000E+00
				8785	ASSERT_EQUAL_64(13 + 10 + 17 + 17, x24);
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	8786	// 0x89abcdef, 0x123456789abcdef
				8787	ASSERT_EQUAL_64(30, x25);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8788	// 42
				8789	ASSERT_EQUAL_64(3, x26);
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	8790	// StackPointer(not sp): 0x00007fb037ae2370, 0x37ae2370
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8791	// Note: This is an example value, but the field width is fixed here so the
				8792	// string length is still predictable.
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	8793	ASSERT_EQUAL_64(53, x27);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8794	// 3=3, 4=40, 5=500
				8795	ASSERT_EQUAL_64(17, x28);
armvixl	5799d6c	2014-05-01 11:05:00 +0100	[diff] [blame^]	8796	// w3: 4294967295, s1: 1.234000, x5: 18446744073709551615, d3: 3.456000
				8797	ASSERT_EQUAL_64(69, x29);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8798
				8799	TEARDOWN();
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8800	}
				8801
				8802
				8803	#ifndef USE_SIMULATOR
				8804	TEST(trace) {
				8805	// The Trace helper should not generate any code unless the simulator (or
				8806	// debugger) is being used.
				8807	SETUP();
				8808	START();
				8809
				8810	Label start;
				8811	__ Bind(&start);
				8812	__ Trace(LOG_ALL, TRACE_ENABLE);
				8813	__ Trace(LOG_ALL, TRACE_DISABLE);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8814	VIXL_CHECK(__ SizeOfCodeGeneratedSince(&start) == 0);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8815
				8816	END();
				8817	TEARDOWN();
				8818	}
				8819	#endif
				8820
				8821
				8822	#ifndef USE_SIMULATOR
				8823	TEST(log) {
				8824	// The Log helper should not generate any code unless the simulator (or
				8825	// debugger) is being used.
				8826	SETUP();
				8827	START();
				8828
				8829	Label start;
				8830	__ Bind(&start);
				8831	__ Log(LOG_ALL);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8832	VIXL_CHECK(__ SizeOfCodeGeneratedSince(&start) == 0);
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8833
				8834	END();
				8835	TEARDOWN();
				8836	}
				8837	#endif
				8838
				8839
				8840	TEST(instruction_accurate_scope) {
				8841	SETUP();
				8842	START();
				8843
				8844	// By default macro instructions are allowed.
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8845	VIXL_ASSERT(masm.AllowMacroInstructions());
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8846	{
				8847	InstructionAccurateScope scope1(&masm);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8848	VIXL_ASSERT(!masm.AllowMacroInstructions());
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8849	{
				8850	InstructionAccurateScope scope2(&masm);
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8851	VIXL_ASSERT(!masm.AllowMacroInstructions());
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8852	}
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8853	VIXL_ASSERT(!masm.AllowMacroInstructions());
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8854	}
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8855	VIXL_ASSERT(masm.AllowMacroInstructions());
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	8856
				8857	{
				8858	InstructionAccurateScope scope(&masm, 2);
				8859	__ add(x0, x0, x0);
				8860	__ sub(x0, x0, x0);
				8861	}
				8862
				8863	END();
				8864	RUN();
				8865	TEARDOWN();
				8866	}
				8867
				8868
				8869	TEST(blr_lr) {
				8870	// A simple test to check that the simulator correcty handle "blr lr".
				8871	SETUP();
				8872
				8873	START();
				8874	Label target;
				8875	Label end;
				8876
				8877	__ Mov(x0, 0x0);
				8878	__ Adr(lr, &target);
				8879
				8880	__ Blr(lr);
				8881	__ Mov(x0, 0xdeadbeef);
				8882	__ B(&end);
				8883
				8884	__ Bind(&target);
				8885	__ Mov(x0, 0xc001c0de);
				8886
				8887	__ Bind(&end);
				8888	END();
				8889
				8890	RUN();
				8891
				8892	ASSERT_EQUAL_64(0xc001c0de, x0);
				8893
				8894	TEARDOWN();
				8895	}
				8896
armvixl	f37fdc0	2014-02-05 13:22:16 +0000	[diff] [blame]	8897
				8898	TEST(barriers) {
				8899	// Generate all supported barriers, this is just a smoke test
				8900	SETUP();
				8901
				8902	START();
				8903
				8904	// DMB
				8905	__ Dmb(FullSystem, BarrierAll);
				8906	__ Dmb(FullSystem, BarrierReads);
				8907	__ Dmb(FullSystem, BarrierWrites);
				8908	__ Dmb(FullSystem, BarrierOther);
				8909
				8910	__ Dmb(InnerShareable, BarrierAll);
				8911	__ Dmb(InnerShareable, BarrierReads);
				8912	__ Dmb(InnerShareable, BarrierWrites);
				8913	__ Dmb(InnerShareable, BarrierOther);
				8914
				8915	__ Dmb(NonShareable, BarrierAll);
				8916	__ Dmb(NonShareable, BarrierReads);
				8917	__ Dmb(NonShareable, BarrierWrites);
				8918	__ Dmb(NonShareable, BarrierOther);
				8919
				8920	__ Dmb(OuterShareable, BarrierAll);
				8921	__ Dmb(OuterShareable, BarrierReads);
				8922	__ Dmb(OuterShareable, BarrierWrites);
				8923	__ Dmb(OuterShareable, BarrierOther);
				8924
				8925	// DSB
				8926	__ Dsb(FullSystem, BarrierAll);
				8927	__ Dsb(FullSystem, BarrierReads);
				8928	__ Dsb(FullSystem, BarrierWrites);
				8929	__ Dsb(FullSystem, BarrierOther);
				8930
				8931	__ Dsb(InnerShareable, BarrierAll);
				8932	__ Dsb(InnerShareable, BarrierReads);
				8933	__ Dsb(InnerShareable, BarrierWrites);
				8934	__ Dsb(InnerShareable, BarrierOther);
				8935
				8936	__ Dsb(NonShareable, BarrierAll);
				8937	__ Dsb(NonShareable, BarrierReads);
				8938	__ Dsb(NonShareable, BarrierWrites);
				8939	__ Dsb(NonShareable, BarrierOther);
				8940
				8941	__ Dsb(OuterShareable, BarrierAll);
				8942	__ Dsb(OuterShareable, BarrierReads);
				8943	__ Dsb(OuterShareable, BarrierWrites);
				8944	__ Dsb(OuterShareable, BarrierOther);
				8945
				8946	// ISB
				8947	__ Isb();
				8948
				8949	END();
				8950
				8951	RUN();
				8952
				8953	TEARDOWN();
				8954	}
				8955
armvixl	b0c8ae2	2014-03-21 14:03:59 +0000	[diff] [blame]	8956
				8957	TEST(process_nan_double) {
				8958	// Make sure that NaN propagation works correctly.
				8959	double sn = rawbits_to_double(0x7ff5555511111111);
				8960	double qn = rawbits_to_double(0x7ffaaaaa11111111);
				8961	VIXL_ASSERT(IsSignallingNaN(sn));
				8962	VIXL_ASSERT(IsQuietNaN(qn));
				8963
				8964	// The input NaNs after passing through ProcessNaN.
				8965	double sn_proc = rawbits_to_double(0x7ffd555511111111);
				8966	double qn_proc = qn;
				8967	VIXL_ASSERT(IsQuietNaN(sn_proc));
				8968	VIXL_ASSERT(IsQuietNaN(qn_proc));
				8969
				8970	SETUP();
				8971	START();
				8972
				8973	// Execute a number of instructions which all use ProcessNaN, and check that
				8974	// they all handle the NaN correctly.
				8975	__ Fmov(d0, sn);
				8976	__ Fmov(d10, qn);
				8977
				8978	// Operations that always propagate NaNs unchanged, even signalling NaNs.
				8979	// - Signalling NaN
				8980	__ Fmov(d1, d0);
				8981	__ Fabs(d2, d0);
				8982	__ Fneg(d3, d0);
				8983	// - Quiet NaN
				8984	__ Fmov(d11, d10);
				8985	__ Fabs(d12, d10);
				8986	__ Fneg(d13, d10);
				8987
				8988	// Operations that use ProcessNaN.
				8989	// - Signalling NaN
				8990	__ Fsqrt(d4, d0);
				8991	__ Frinta(d5, d0);
				8992	__ Frintn(d6, d0);
				8993	__ Frintz(d7, d0);
				8994	// - Quiet NaN
				8995	__ Fsqrt(d14, d10);
				8996	__ Frinta(d15, d10);
				8997	__ Frintn(d16, d10);
				8998	__ Frintz(d17, d10);
				8999
				9000	// The behaviour of fcvt is checked in TEST(fcvt_sd).
				9001
				9002	END();
				9003	RUN();
				9004
				9005	uint64_t qn_raw = double_to_rawbits(qn);
				9006	uint64_t sn_raw = double_to_rawbits(sn);
				9007
				9008	// - Signalling NaN
				9009	ASSERT_EQUAL_FP64(sn, d1);
				9010	ASSERT_EQUAL_FP64(rawbits_to_double(sn_raw & ~kDSignMask), d2);
				9011	ASSERT_EQUAL_FP64(rawbits_to_double(sn_raw ^ kDSignMask), d3);
				9012	// - Quiet NaN
				9013	ASSERT_EQUAL_FP64(qn, d11);
				9014	ASSERT_EQUAL_FP64(rawbits_to_double(qn_raw & ~kDSignMask), d12);
				9015	ASSERT_EQUAL_FP64(rawbits_to_double(qn_raw ^ kDSignMask), d13);
				9016
				9017	// - Signalling NaN
				9018	ASSERT_EQUAL_FP64(sn_proc, d4);
				9019	ASSERT_EQUAL_FP64(sn_proc, d5);
				9020	ASSERT_EQUAL_FP64(sn_proc, d6);
				9021	ASSERT_EQUAL_FP64(sn_proc, d7);
				9022	// - Quiet NaN
				9023	ASSERT_EQUAL_FP64(qn_proc, d14);
				9024	ASSERT_EQUAL_FP64(qn_proc, d15);
				9025	ASSERT_EQUAL_FP64(qn_proc, d16);
				9026	ASSERT_EQUAL_FP64(qn_proc, d17);
				9027
				9028	TEARDOWN();
				9029	}
				9030
				9031
				9032	TEST(process_nan_float) {
				9033	// Make sure that NaN propagation works correctly.
				9034	float sn = rawbits_to_float(0x7f951111);
				9035	float qn = rawbits_to_float(0x7fea1111);
				9036	VIXL_ASSERT(IsSignallingNaN(sn));
				9037	VIXL_ASSERT(IsQuietNaN(qn));
				9038
				9039	// The input NaNs after passing through ProcessNaN.
				9040	float sn_proc = rawbits_to_float(0x7fd51111);
				9041	float qn_proc = qn;
				9042	VIXL_ASSERT(IsQuietNaN(sn_proc));
				9043	VIXL_ASSERT(IsQuietNaN(qn_proc));
				9044
				9045	SETUP();
				9046	START();
				9047
				9048	// Execute a number of instructions which all use ProcessNaN, and check that
				9049	// they all handle the NaN correctly.
				9050	__ Fmov(s0, sn);
				9051	__ Fmov(s10, qn);
				9052
				9053	// Operations that always propagate NaNs unchanged, even signalling NaNs.
				9054	// - Signalling NaN
				9055	__ Fmov(s1, s0);
				9056	__ Fabs(s2, s0);
				9057	__ Fneg(s3, s0);
				9058	// - Quiet NaN
				9059	__ Fmov(s11, s10);
				9060	__ Fabs(s12, s10);
				9061	__ Fneg(s13, s10);
				9062
				9063	// Operations that use ProcessNaN.
				9064	// - Signalling NaN
				9065	__ Fsqrt(s4, s0);
				9066	__ Frinta(s5, s0);
				9067	__ Frintn(s6, s0);
				9068	__ Frintz(s7, s0);
				9069	// - Quiet NaN
				9070	__ Fsqrt(s14, s10);
				9071	__ Frinta(s15, s10);
				9072	__ Frintn(s16, s10);
				9073	__ Frintz(s17, s10);
				9074
				9075	// The behaviour of fcvt is checked in TEST(fcvt_sd).
				9076
				9077	END();
				9078	RUN();
				9079
				9080	uint32_t qn_raw = float_to_rawbits(qn);
				9081	uint32_t sn_raw = float_to_rawbits(sn);
				9082
				9083	// - Signalling NaN
				9084	ASSERT_EQUAL_FP32(sn, s1);
				9085	ASSERT_EQUAL_FP32(rawbits_to_float(sn_raw & ~kSSignMask), s2);
				9086	ASSERT_EQUAL_FP32(rawbits_to_float(sn_raw ^ kSSignMask), s3);
				9087	// - Quiet NaN
				9088	ASSERT_EQUAL_FP32(qn, s11);
				9089	ASSERT_EQUAL_FP32(rawbits_to_float(qn_raw & ~kSSignMask), s12);
				9090	ASSERT_EQUAL_FP32(rawbits_to_float(qn_raw ^ kSSignMask), s13);
				9091
				9092	// - Signalling NaN
				9093	ASSERT_EQUAL_FP32(sn_proc, s4);
				9094	ASSERT_EQUAL_FP32(sn_proc, s5);
				9095	ASSERT_EQUAL_FP32(sn_proc, s6);
				9096	ASSERT_EQUAL_FP32(sn_proc, s7);
				9097	// - Quiet NaN
				9098	ASSERT_EQUAL_FP32(qn_proc, s14);
				9099	ASSERT_EQUAL_FP32(qn_proc, s15);
				9100	ASSERT_EQUAL_FP32(qn_proc, s16);
				9101	ASSERT_EQUAL_FP32(qn_proc, s17);
				9102
				9103	TEARDOWN();
				9104	}
				9105
				9106
				9107	static void ProcessNaNsHelper(double n, double m, double expected) {
				9108	VIXL_ASSERT(isnan(n) \|\| isnan(m));
				9109	VIXL_ASSERT(isnan(expected));
				9110
				9111	SETUP();
				9112	START();
				9113
				9114	// Execute a number of instructions which all use ProcessNaNs, and check that
				9115	// they all propagate NaNs correctly.
				9116	__ Fmov(d0, n);
				9117	__ Fmov(d1, m);
				9118
				9119	__ Fadd(d2, d0, d1);
				9120	__ Fsub(d3, d0, d1);
				9121	__ Fmul(d4, d0, d1);
				9122	__ Fdiv(d5, d0, d1);
				9123	__ Fmax(d6, d0, d1);
				9124	__ Fmin(d7, d0, d1);
				9125
				9126	END();
				9127	RUN();
				9128
				9129	ASSERT_EQUAL_FP64(expected, d2);
				9130	ASSERT_EQUAL_FP64(expected, d3);
				9131	ASSERT_EQUAL_FP64(expected, d4);
				9132	ASSERT_EQUAL_FP64(expected, d5);
				9133	ASSERT_EQUAL_FP64(expected, d6);
				9134	ASSERT_EQUAL_FP64(expected, d7);
				9135
				9136	TEARDOWN();
				9137	}
				9138
				9139
				9140	TEST(process_nans_double) {
				9141	// Make sure that NaN propagation works correctly.
				9142	double sn = rawbits_to_double(0x7ff5555511111111);
				9143	double sm = rawbits_to_double(0x7ff5555522222222);
				9144	double qn = rawbits_to_double(0x7ffaaaaa11111111);
				9145	double qm = rawbits_to_double(0x7ffaaaaa22222222);
				9146	VIXL_ASSERT(IsSignallingNaN(sn));
				9147	VIXL_ASSERT(IsSignallingNaN(sm));
				9148	VIXL_ASSERT(IsQuietNaN(qn));
				9149	VIXL_ASSERT(IsQuietNaN(qm));
				9150
				9151	// The input NaNs after passing through ProcessNaN.
				9152	double sn_proc = rawbits_to_double(0x7ffd555511111111);
				9153	double sm_proc = rawbits_to_double(0x7ffd555522222222);
				9154	double qn_proc = qn;
				9155	double qm_proc = qm;
				9156	VIXL_ASSERT(IsQuietNaN(sn_proc));
				9157	VIXL_ASSERT(IsQuietNaN(sm_proc));
				9158	VIXL_ASSERT(IsQuietNaN(qn_proc));
				9159	VIXL_ASSERT(IsQuietNaN(qm_proc));
				9160
				9161	// Quiet NaNs are propagated.
				9162	ProcessNaNsHelper(qn, 0, qn_proc);
				9163	ProcessNaNsHelper(0, qm, qm_proc);
				9164	ProcessNaNsHelper(qn, qm, qn_proc);
				9165
				9166	// Signalling NaNs are propagated, and made quiet.
				9167	ProcessNaNsHelper(sn, 0, sn_proc);
				9168	ProcessNaNsHelper(0, sm, sm_proc);
				9169	ProcessNaNsHelper(sn, sm, sn_proc);
				9170
				9171	// Signalling NaNs take precedence over quiet NaNs.
				9172	ProcessNaNsHelper(sn, qm, sn_proc);
				9173	ProcessNaNsHelper(qn, sm, sm_proc);
				9174	ProcessNaNsHelper(sn, sm, sn_proc);
				9175	}
				9176
				9177
				9178	static void ProcessNaNsHelper(float n, float m, float expected) {
				9179	VIXL_ASSERT(isnan(n) \|\| isnan(m));
				9180	VIXL_ASSERT(isnan(expected));
				9181
				9182	SETUP();
				9183	START();
				9184
				9185	// Execute a number of instructions which all use ProcessNaNs, and check that
				9186	// they all propagate NaNs correctly.
				9187	__ Fmov(s0, n);
				9188	__ Fmov(s1, m);
				9189
				9190	__ Fadd(s2, s0, s1);
				9191	__ Fsub(s3, s0, s1);
				9192	__ Fmul(s4, s0, s1);
				9193	__ Fdiv(s5, s0, s1);
				9194	__ Fmax(s6, s0, s1);
				9195	__ Fmin(s7, s0, s1);
				9196
				9197	END();
				9198	RUN();
				9199
				9200	ASSERT_EQUAL_FP32(expected, s2);
				9201	ASSERT_EQUAL_FP32(expected, s3);
				9202	ASSERT_EQUAL_FP32(expected, s4);
				9203	ASSERT_EQUAL_FP32(expected, s5);
				9204	ASSERT_EQUAL_FP32(expected, s6);
				9205	ASSERT_EQUAL_FP32(expected, s7);
				9206
				9207	TEARDOWN();
				9208	}
				9209
				9210
				9211	TEST(process_nans_float) {
				9212	// Make sure that NaN propagation works correctly.
				9213	float sn = rawbits_to_float(0x7f951111);
				9214	float sm = rawbits_to_float(0x7f952222);
				9215	float qn = rawbits_to_float(0x7fea1111);
				9216	float qm = rawbits_to_float(0x7fea2222);
				9217	VIXL_ASSERT(IsSignallingNaN(sn));
				9218	VIXL_ASSERT(IsSignallingNaN(sm));
				9219	VIXL_ASSERT(IsQuietNaN(qn));
				9220	VIXL_ASSERT(IsQuietNaN(qm));
				9221
				9222	// The input NaNs after passing through ProcessNaN.
				9223	float sn_proc = rawbits_to_float(0x7fd51111);
				9224	float sm_proc = rawbits_to_float(0x7fd52222);
				9225	float qn_proc = qn;
				9226	float qm_proc = qm;
				9227	VIXL_ASSERT(IsQuietNaN(sn_proc));
				9228	VIXL_ASSERT(IsQuietNaN(sm_proc));
				9229	VIXL_ASSERT(IsQuietNaN(qn_proc));
				9230	VIXL_ASSERT(IsQuietNaN(qm_proc));
				9231
				9232	// Quiet NaNs are propagated.
				9233	ProcessNaNsHelper(qn, 0, qn_proc);
				9234	ProcessNaNsHelper(0, qm, qm_proc);
				9235	ProcessNaNsHelper(qn, qm, qn_proc);
				9236
				9237	// Signalling NaNs are propagated, and made quiet.
				9238	ProcessNaNsHelper(sn, 0, sn_proc);
				9239	ProcessNaNsHelper(0, sm, sm_proc);
				9240	ProcessNaNsHelper(sn, sm, sn_proc);
				9241
				9242	// Signalling NaNs take precedence over quiet NaNs.
				9243	ProcessNaNsHelper(sn, qm, sn_proc);
				9244	ProcessNaNsHelper(qn, sm, sm_proc);
				9245	ProcessNaNsHelper(sn, sm, sn_proc);
				9246	}
				9247
				9248
				9249	static void DefaultNaNHelper(float n, float m, float a) {
				9250	VIXL_ASSERT(isnan(n) \|\| isnan(m) \|\| isnan(a));
				9251
				9252	bool test_1op = isnan(n);
				9253	bool test_2op = isnan(n) \|\| isnan(m);
				9254
				9255	SETUP();
				9256	START();
				9257
				9258	// Enable Default-NaN mode in the FPCR.
				9259	__ Mrs(x0, FPCR);
				9260	__ Orr(x1, x0, DN_mask);
				9261	__ Msr(FPCR, x1);
				9262
				9263	// Execute a number of instructions which all use ProcessNaNs, and check that
				9264	// they all produce the default NaN.
				9265	__ Fmov(s0, n);
				9266	__ Fmov(s1, m);
				9267	__ Fmov(s2, a);
				9268
				9269	if (test_1op) {
				9270	// Operations that always propagate NaNs unchanged, even signalling NaNs.
				9271	__ Fmov(s10, s0);
				9272	__ Fabs(s11, s0);
				9273	__ Fneg(s12, s0);
				9274
				9275	// Operations that use ProcessNaN.
				9276	__ Fsqrt(s13, s0);
				9277	__ Frinta(s14, s0);
				9278	__ Frintn(s15, s0);
				9279	__ Frintz(s16, s0);
				9280
				9281	// Fcvt usually has special NaN handling, but it respects default-NaN mode.
				9282	__ Fcvt(d17, s0);
				9283	}
				9284
				9285	if (test_2op) {
				9286	__ Fadd(s18, s0, s1);
				9287	__ Fsub(s19, s0, s1);
				9288	__ Fmul(s20, s0, s1);
				9289	__ Fdiv(s21, s0, s1);
				9290	__ Fmax(s22, s0, s1);
				9291	__ Fmin(s23, s0, s1);
				9292	}
				9293
				9294	__ Fmadd(s24, s0, s1, s2);
				9295	__ Fmsub(s25, s0, s1, s2);
				9296	__ Fnmadd(s26, s0, s1, s2);
				9297	__ Fnmsub(s27, s0, s1, s2);
				9298
				9299	// Restore FPCR.
				9300	__ Msr(FPCR, x0);
				9301
				9302	END();
				9303	RUN();
				9304
				9305	if (test_1op) {
				9306	uint32_t n_raw = float_to_rawbits(n);
				9307	ASSERT_EQUAL_FP32(n, s10);
				9308	ASSERT_EQUAL_FP32(rawbits_to_float(n_raw & ~kSSignMask), s11);
				9309	ASSERT_EQUAL_FP32(rawbits_to_float(n_raw ^ kSSignMask), s12);
				9310	ASSERT_EQUAL_FP32(kFP32DefaultNaN, s13);
				9311	ASSERT_EQUAL_FP32(kFP32DefaultNaN, s14);
				9312	ASSERT_EQUAL_FP32(kFP32DefaultNaN, s15);
				9313	ASSERT_EQUAL_FP32(kFP32DefaultNaN, s16);
				9314	ASSERT_EQUAL_FP64(kFP64DefaultNaN, d17);
				9315	}
				9316
				9317	if (test_2op) {
				9318	ASSERT_EQUAL_FP32(kFP32DefaultNaN, s18);
				9319	ASSERT_EQUAL_FP32(kFP32DefaultNaN, s19);
				9320	ASSERT_EQUAL_FP32(kFP32DefaultNaN, s20);
				9321	ASSERT_EQUAL_FP32(kFP32DefaultNaN, s21);
				9322	ASSERT_EQUAL_FP32(kFP32DefaultNaN, s22);
				9323	ASSERT_EQUAL_FP32(kFP32DefaultNaN, s23);
				9324	}
				9325
				9326	ASSERT_EQUAL_FP32(kFP32DefaultNaN, s24);
				9327	ASSERT_EQUAL_FP32(kFP32DefaultNaN, s25);
				9328	ASSERT_EQUAL_FP32(kFP32DefaultNaN, s26);
				9329	ASSERT_EQUAL_FP32(kFP32DefaultNaN, s27);
				9330
				9331	TEARDOWN();
				9332	}
				9333
				9334
				9335	TEST(default_nan_float) {
				9336	float sn = rawbits_to_float(0x7f951111);
				9337	float sm = rawbits_to_float(0x7f952222);
				9338	float sa = rawbits_to_float(0x7f95aaaa);
				9339	float qn = rawbits_to_float(0x7fea1111);
				9340	float qm = rawbits_to_float(0x7fea2222);
				9341	float qa = rawbits_to_float(0x7feaaaaa);
				9342	VIXL_ASSERT(IsSignallingNaN(sn));
				9343	VIXL_ASSERT(IsSignallingNaN(sm));
				9344	VIXL_ASSERT(IsSignallingNaN(sa));
				9345	VIXL_ASSERT(IsQuietNaN(qn));
				9346	VIXL_ASSERT(IsQuietNaN(qm));
				9347	VIXL_ASSERT(IsQuietNaN(qa));
				9348
				9349	// - Signalling NaNs
				9350	DefaultNaNHelper(sn, 0.0f, 0.0f);
				9351	DefaultNaNHelper(0.0f, sm, 0.0f);
				9352	DefaultNaNHelper(0.0f, 0.0f, sa);
				9353	DefaultNaNHelper(sn, sm, 0.0f);
				9354	DefaultNaNHelper(0.0f, sm, sa);
				9355	DefaultNaNHelper(sn, 0.0f, sa);
				9356	DefaultNaNHelper(sn, sm, sa);
				9357	// - Quiet NaNs
				9358	DefaultNaNHelper(qn, 0.0f, 0.0f);
				9359	DefaultNaNHelper(0.0f, qm, 0.0f);
				9360	DefaultNaNHelper(0.0f, 0.0f, qa);
				9361	DefaultNaNHelper(qn, qm, 0.0f);
				9362	DefaultNaNHelper(0.0f, qm, qa);
				9363	DefaultNaNHelper(qn, 0.0f, qa);
				9364	DefaultNaNHelper(qn, qm, qa);
				9365	// - Mixed NaNs
				9366	DefaultNaNHelper(qn, sm, sa);
				9367	DefaultNaNHelper(sn, qm, sa);
				9368	DefaultNaNHelper(sn, sm, qa);
				9369	DefaultNaNHelper(qn, qm, sa);
				9370	DefaultNaNHelper(sn, qm, qa);
				9371	DefaultNaNHelper(qn, sm, qa);
				9372	DefaultNaNHelper(qn, qm, qa);
				9373	}
				9374
				9375
				9376	static void DefaultNaNHelper(double n, double m, double a) {
				9377	VIXL_ASSERT(isnan(n) \|\| isnan(m) \|\| isnan(a));
				9378
				9379	bool test_1op = isnan(n);
				9380	bool test_2op = isnan(n) \|\| isnan(m);
				9381
				9382	SETUP();
				9383	START();
				9384
				9385	// Enable Default-NaN mode in the FPCR.
				9386	__ Mrs(x0, FPCR);
				9387	__ Orr(x1, x0, DN_mask);
				9388	__ Msr(FPCR, x1);
				9389
				9390	// Execute a number of instructions which all use ProcessNaNs, and check that
				9391	// they all produce the default NaN.
				9392	__ Fmov(d0, n);
				9393	__ Fmov(d1, m);
				9394	__ Fmov(d2, a);
				9395
				9396	if (test_1op) {
				9397	// Operations that always propagate NaNs unchanged, even signalling NaNs.
				9398	__ Fmov(d10, d0);
				9399	__ Fabs(d11, d0);
				9400	__ Fneg(d12, d0);
				9401
				9402	// Operations that use ProcessNaN.
				9403	__ Fsqrt(d13, d0);
				9404	__ Frinta(d14, d0);
				9405	__ Frintn(d15, d0);
				9406	__ Frintz(d16, d0);
				9407
				9408	// Fcvt usually has special NaN handling, but it respects default-NaN mode.
				9409	__ Fcvt(s17, d0);
				9410	}
				9411
				9412	if (test_2op) {
				9413	__ Fadd(d18, d0, d1);
				9414	__ Fsub(d19, d0, d1);
				9415	__ Fmul(d20, d0, d1);
				9416	__ Fdiv(d21, d0, d1);
				9417	__ Fmax(d22, d0, d1);
				9418	__ Fmin(d23, d0, d1);
				9419	}
				9420
				9421	__ Fmadd(d24, d0, d1, d2);
				9422	__ Fmsub(d25, d0, d1, d2);
				9423	__ Fnmadd(d26, d0, d1, d2);
				9424	__ Fnmsub(d27, d0, d1, d2);
				9425
				9426	// Restore FPCR.
				9427	__ Msr(FPCR, x0);
				9428
				9429	END();
				9430	RUN();
				9431
				9432	if (test_1op) {
				9433	uint64_t n_raw = double_to_rawbits(n);
				9434	ASSERT_EQUAL_FP64(n, d10);
				9435	ASSERT_EQUAL_FP64(rawbits_to_double(n_raw & ~kDSignMask), d11);
				9436	ASSERT_EQUAL_FP64(rawbits_to_double(n_raw ^ kDSignMask), d12);
				9437	ASSERT_EQUAL_FP64(kFP64DefaultNaN, d13);
				9438	ASSERT_EQUAL_FP64(kFP64DefaultNaN, d14);
				9439	ASSERT_EQUAL_FP64(kFP64DefaultNaN, d15);
				9440	ASSERT_EQUAL_FP64(kFP64DefaultNaN, d16);
				9441	ASSERT_EQUAL_FP32(kFP32DefaultNaN, s17);
				9442	}
				9443
				9444	if (test_2op) {
				9445	ASSERT_EQUAL_FP64(kFP64DefaultNaN, d18);
				9446	ASSERT_EQUAL_FP64(kFP64DefaultNaN, d19);
				9447	ASSERT_EQUAL_FP64(kFP64DefaultNaN, d20);
				9448	ASSERT_EQUAL_FP64(kFP64DefaultNaN, d21);
				9449	ASSERT_EQUAL_FP64(kFP64DefaultNaN, d22);
				9450	ASSERT_EQUAL_FP64(kFP64DefaultNaN, d23);
				9451	}
				9452
				9453	ASSERT_EQUAL_FP64(kFP64DefaultNaN, d24);
				9454	ASSERT_EQUAL_FP64(kFP64DefaultNaN, d25);
				9455	ASSERT_EQUAL_FP64(kFP64DefaultNaN, d26);
				9456	ASSERT_EQUAL_FP64(kFP64DefaultNaN, d27);
				9457
				9458	TEARDOWN();
				9459	}
				9460
				9461
				9462	TEST(default_nan_double) {
				9463	double sn = rawbits_to_double(0x7ff5555511111111);
				9464	double sm = rawbits_to_double(0x7ff5555522222222);
				9465	double sa = rawbits_to_double(0x7ff55555aaaaaaaa);
				9466	double qn = rawbits_to_double(0x7ffaaaaa11111111);
				9467	double qm = rawbits_to_double(0x7ffaaaaa22222222);
				9468	double qa = rawbits_to_double(0x7ffaaaaaaaaaaaaa);
				9469	VIXL_ASSERT(IsSignallingNaN(sn));
				9470	VIXL_ASSERT(IsSignallingNaN(sm));
				9471	VIXL_ASSERT(IsSignallingNaN(sa));
				9472	VIXL_ASSERT(IsQuietNaN(qn));
				9473	VIXL_ASSERT(IsQuietNaN(qm));
				9474	VIXL_ASSERT(IsQuietNaN(qa));
				9475
				9476	// - Signalling NaNs
				9477	DefaultNaNHelper(sn, 0.0, 0.0);
				9478	DefaultNaNHelper(0.0, sm, 0.0);
				9479	DefaultNaNHelper(0.0, 0.0, sa);
				9480	DefaultNaNHelper(sn, sm, 0.0);
				9481	DefaultNaNHelper(0.0, sm, sa);
				9482	DefaultNaNHelper(sn, 0.0, sa);
				9483	DefaultNaNHelper(sn, sm, sa);
				9484	// - Quiet NaNs
				9485	DefaultNaNHelper(qn, 0.0, 0.0);
				9486	DefaultNaNHelper(0.0, qm, 0.0);
				9487	DefaultNaNHelper(0.0, 0.0, qa);
				9488	DefaultNaNHelper(qn, qm, 0.0);
				9489	DefaultNaNHelper(0.0, qm, qa);
				9490	DefaultNaNHelper(qn, 0.0, qa);
				9491	DefaultNaNHelper(qn, qm, qa);
				9492	// - Mixed NaNs
				9493	DefaultNaNHelper(qn, sm, sa);
				9494	DefaultNaNHelper(sn, qm, sa);
				9495	DefaultNaNHelper(sn, sm, qa);
				9496	DefaultNaNHelper(qn, qm, sa);
				9497	DefaultNaNHelper(sn, qm, qa);
				9498	DefaultNaNHelper(qn, sm, qa);
				9499	DefaultNaNHelper(qn, qm, qa);
				9500	}
				9501
				9502
armvixl	ad96eda	2013-06-14 11:42:37 +0100	[diff] [blame]	9503	} // namespace vixl