# Thumb1 instructions # # Copyright (c) 2019 Linaro, Ltd # # This library is free software; you can redistribute it and/or # modify it under the terms of the GNU Lesser General Public # License as published by the Free Software Foundation; either # version 2.1 of the License, or (at your option) any later version. # # This library is distributed in the hope that it will be useful, # but WITHOUT ANY WARRANTY; without even the implied warranty of # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU # Lesser General Public License for more details. # # You should have received a copy of the GNU Lesser General Public # License along with this library; if not, see . # # This file is processed by scripts/decodetree.py # &empty !extern &s_rrr_shi !extern s rd rn rm shim shty &s_rrr_shr !extern s rn rd rm rs shty &s_rri_rot !extern s rn rd imm rot &s_rrrr !extern s rd rn rm ra &rrr_rot !extern rd rn rm rot &rr !extern rd rm &ri !extern rd imm &r !extern rm &i !extern imm &ldst_rr !extern p w u rn rt rm shimm shtype &ldst_ri !extern p w u rn rt imm &ldst_block !extern rn i b u w list &setend !extern E &cps !extern mode imod M A I F &ci !extern cond imm # Set S if the instruction is outside of an IT block. %s !function=t16_setflags # Data-processing (two low registers) %reg_0 0:3 @lll_noshr ...... .... rm:3 rd:3 \ &s_rrr_shi %s rn=%reg_0 shim=0 shty=0 @xll_noshr ...... .... rm:3 rn:3 \ &s_rrr_shi s=1 rd=0 shim=0 shty=0 @lxl_shr ...... .... rs:3 rd:3 \ &s_rrr_shr %s rm=%reg_0 rn=0 AND_rrri 010000 0000 ... ... @lll_noshr EOR_rrri 010000 0001 ... ... @lll_noshr MOV_rxrr 010000 0010 ... ... @lxl_shr shty=0 # LSL MOV_rxrr 010000 0011 ... ... @lxl_shr shty=1 # LSR MOV_rxrr 010000 0100 ... ... @lxl_shr shty=2 # ASR ADC_rrri 010000 0101 ... ... @lll_noshr SBC_rrri 010000 0110 ... ... @lll_noshr MOV_rxrr 010000 0111 ... ... @lxl_shr shty=3 # ROR TST_xrri 010000 1000 ... ... @xll_noshr RSB_rri 010000 1001 rn:3 rd:3 &s_rri_rot %s imm=0 rot=0 CMP_xrri 010000 1010 ... ... @xll_noshr CMN_xrri 010000 1011 ... ... @xll_noshr ORR_rrri 010000 1100 ... ... @lll_noshr MUL 010000 1101 rn:3 rd:3 &s_rrrr %s rm=%reg_0 ra=0 BIC_rrri 010000 1110 ... ... @lll_noshr MVN_rxri 010000 1111 ... ... @lll_noshr # Load/store (register offset) @ldst_rr ....... rm:3 rn:3 rt:3 \ &ldst_rr p=1 w=0 u=1 shimm=0 shtype=0 STR_rr 0101 000 ... ... ... @ldst_rr STRH_rr 0101 001 ... ... ... @ldst_rr STRB_rr 0101 010 ... ... ... @ldst_rr LDRSB_rr 0101 011 ... ... ... @ldst_rr LDR_rr 0101 100 ... ... ... @ldst_rr LDRH_rr 0101 101 ... ... ... @ldst_rr LDRB_rr 0101 110 ... ... ... @ldst_rr LDRSH_rr 0101 111 ... ... ... @ldst_rr # Load/store word/byte (immediate offset) %imm5_6x4 6:5 !function=times_4 @ldst_ri_1 ..... imm:5 rn:3 rt:3 \ &ldst_ri p=1 w=0 u=1 @ldst_ri_4 ..... ..... rn:3 rt:3 \ &ldst_ri p=1 w=0 u=1 imm=%imm5_6x4 STR_ri 01100 ..... ... ... @ldst_ri_4 LDR_ri 01101 ..... ... ... @ldst_ri_4 STRB_ri 01110 ..... ... ... @ldst_ri_1 LDRB_ri 01111 ..... ... ... @ldst_ri_1 # Load/store halfword (immediate offset) %imm5_6x2 6:5 !function=times_2 @ldst_ri_2 ..... ..... rn:3 rt:3 \ &ldst_ri p=1 w=0 u=1 imm=%imm5_6x2 STRH_ri 10000 ..... ... ... @ldst_ri_2 LDRH_ri 10001 ..... ... ... @ldst_ri_2 # Load/store (SP-relative) %imm8_0x4 0:8 !function=times_4 @ldst_spec_i ..... rt:3 ........ \ &ldst_ri p=1 w=0 u=1 imm=%imm8_0x4 STR_ri 10010 ... ........ @ldst_spec_i rn=13 LDR_ri 10011 ... ........ @ldst_spec_i rn=13 # Load (PC-relative) LDR_ri 01001 ... ........ @ldst_spec_i rn=15 # Add PC/SP (immediate) ADR 10100 rd:3 ........ imm=%imm8_0x4 ADD_rri 10101 rd:3 ........ \ &s_rri_rot rn=13 s=0 rot=0 imm=%imm8_0x4 # SP # Load/store multiple @ldstm ..... rn:3 list:8 &ldst_block i=1 b=0 u=0 w=1 STM 11000 ... ........ @ldstm LDM_t16 11001 ... ........ @ldstm # Shift (immediate) @shift_i ..... shim:5 rm:3 rd:3 &s_rrr_shi %s rn=%reg_0 MOV_rxri 000 00 ..... ... ... @shift_i shty=0 # LSL MOV_rxri 000 01 ..... ... ... @shift_i shty=1 # LSR MOV_rxri 000 10 ..... ... ... @shift_i shty=2 # ASR # Add/subtract (three low registers) @addsub_3 ....... rm:3 rn:3 rd:3 \ &s_rrr_shi %s shim=0 shty=0 ADD_rrri 0001100 ... ... ... @addsub_3 SUB_rrri 0001101 ... ... ... @addsub_3 # Add/subtract (two low registers and immediate) @addsub_2i ....... imm:3 rn:3 rd:3 \ &s_rri_rot %s rot=0 ADD_rri 0001 110 ... ... ... @addsub_2i SUB_rri 0001 111 ... ... ... @addsub_2i # Add, subtract, compare, move (one low register and immediate) %reg_8 8:3 @arith_1i ..... rd:3 imm:8 \ &s_rri_rot rot=0 rn=%reg_8 MOV_rxi 00100 ... ........ @arith_1i %s CMP_xri 00101 ... ........ @arith_1i s=1 ADD_rri 00110 ... ........ @arith_1i %s SUB_rri 00111 ... ........ @arith_1i %s # Add, compare, move (two high registers) %reg_0_7 7:1 0:3 @addsub_2h .... .... . rm:4 ... \ &s_rrr_shi rd=%reg_0_7 rn=%reg_0_7 shim=0 shty=0 ADD_rrri 0100 0100 . .... ... @addsub_2h s=0 CMP_xrri 0100 0101 . .... ... @addsub_2h s=1 MOV_rxri 0100 0110 . .... ... @addsub_2h s=0 # Adjust SP (immediate) %imm7_0x4 0:7 !function=times_4 @addsub_sp_i .... .... . ....... \ &s_rri_rot s=0 rd=13 rn=13 rot=0 imm=%imm7_0x4 ADD_rri 1011 0000 0 ....... @addsub_sp_i SUB_rri 1011 0000 1 ....... @addsub_sp_i # Branch and exchange @branchr .... .... . rm:4 ... &r BX 0100 0111 0 .... 000 @branchr BLX_r 0100 0111 1 .... 000 @branchr BXNS 0100 0111 0 .... 100 @branchr BLXNS 0100 0111 1 .... 100 @branchr # Extend @extend .... .... .. rm:3 rd:3 &rrr_rot rn=15 rot=0 SXTAH 1011 0010 00 ... ... @extend SXTAB 1011 0010 01 ... ... @extend UXTAH 1011 0010 10 ... ... @extend UXTAB 1011 0010 11 ... ... @extend # Change processor state %imod 4:1 !function=plus_2 SETEND 1011 0110 010 1 E:1 000 &setend { CPS 1011 0110 011 . 0 A:1 I:1 F:1 &cps mode=0 M=0 %imod CPS_v7m 1011 0110 011 im:1 00 I:1 F:1 } # Reverse bytes @rdm .... .... .. rm:3 rd:3 &rr REV 1011 1010 00 ... ... @rdm REV16 1011 1010 01 ... ... @rdm REVSH 1011 1010 11 ... ... @rdm # Hints { { YIELD 1011 1111 0001 0000 WFE 1011 1111 0010 0000 WFI 1011 1111 0011 0000 # TODO: Implement SEV, SEVL; may help SMP performance. # SEV 1011 1111 0100 0000 # SEVL 1011 1111 0101 0000 # The canonical nop has the second nibble as 0000, but the whole of the # rest of the space is a reserved hint, behaves as nop. NOP 1011 1111 ---- 0000 } IT 1011 1111 cond_mask:8 } # Miscellaneous 16-bit instructions %imm6_9_3 9:1 3:5 !function=times_2 HLT 1011 1010 10 imm:6 &i BKPT 1011 1110 imm:8 &i CBZ 1011 nz:1 0.1 ..... rn:3 imm=%imm6_9_3 # Push and Pop %push_list 0:9 !function=t16_push_list %pop_list 0:9 !function=t16_pop_list STM 1011 010 ......... \ &ldst_block i=0 b=1 u=0 w=1 rn=13 list=%push_list LDM_t16 1011 110 ......... \ &ldst_block i=1 b=0 u=0 w=1 rn=13 list=%pop_list # Conditional branches, Supervisor call %imm8_0x2 0:s8 !function=times_2 { UDF 1101 1110 ---- ---- SVC 1101 1111 imm:8 &i B_cond_thumb 1101 cond:4 ........ &ci imm=%imm8_0x2 } # Unconditional Branch %imm11_0x2 0:s11 !function=times_2 B 11100 ........... &i imm=%imm11_0x2 # thumb_insn_is_16bit() ensures we won't be decoding these as # T16 instructions for a Thumb2 CPU, so these patterns must be # a Thumb1 split BL/BLX. BLX_suffix 11101 imm:11 &i BL_BLX_prefix 11110 imm:s11 &i BL_suffix 11111 imm:11 &i