/* * ARM translation: AArch32 Neon instructions * * Copyright (c) 2003 Fabrice Bellard * Copyright (c) 2005-2007 CodeSourcery * Copyright (c) 2007 OpenedHand, Ltd. * Copyright (c) 2020 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 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 intended to be included from translate.c; it uses * some macros and definitions provided by that file. * It might be possible to convert it to a standalone .c file eventually. */ static inline int plus1(DisasContext *s, int x) { return x + 1; } /* Include the generated Neon decoder */ #include "decode-neon-dp.inc.c" #include "decode-neon-ls.inc.c" #include "decode-neon-shared.inc.c" static bool trans_VCMLA(DisasContext *s, arg_VCMLA *a) { int opr_sz; TCGv_ptr fpst; gen_helper_gvec_3_ptr *fn_gvec_ptr; if (!dc_isar_feature(aa32_vcma, s) || (!a->size && !dc_isar_feature(aa32_fp16_arith, s))) { return false; } /* UNDEF accesses to D16-D31 if they don't exist. */ if (!dc_isar_feature(aa32_simd_r32, s) && ((a->vd | a->vn | a->vm) & 0x10)) { return false; } if ((a->vn | a->vm | a->vd) & a->q) { return false; } if (!vfp_access_check(s)) { return true; } opr_sz = (1 + a->q) * 8; fpst = get_fpstatus_ptr(1); fn_gvec_ptr = a->size ? gen_helper_gvec_fcmlas : gen_helper_gvec_fcmlah; tcg_gen_gvec_3_ptr(vfp_reg_offset(1, a->vd), vfp_reg_offset(1, a->vn), vfp_reg_offset(1, a->vm), fpst, opr_sz, opr_sz, a->rot, fn_gvec_ptr); tcg_temp_free_ptr(fpst); return true; } static bool trans_VCADD(DisasContext *s, arg_VCADD *a) { int opr_sz; TCGv_ptr fpst; gen_helper_gvec_3_ptr *fn_gvec_ptr; if (!dc_isar_feature(aa32_vcma, s) || (!a->size && !dc_isar_feature(aa32_fp16_arith, s))) { return false; } /* UNDEF accesses to D16-D31 if they don't exist. */ if (!dc_isar_feature(aa32_simd_r32, s) && ((a->vd | a->vn | a->vm) & 0x10)) { return false; } if ((a->vn | a->vm | a->vd) & a->q) { return false; } if (!vfp_access_check(s)) { return true; } opr_sz = (1 + a->q) * 8; fpst = get_fpstatus_ptr(1); fn_gvec_ptr = a->size ? gen_helper_gvec_fcadds : gen_helper_gvec_fcaddh; tcg_gen_gvec_3_ptr(vfp_reg_offset(1, a->vd), vfp_reg_offset(1, a->vn), vfp_reg_offset(1, a->vm), fpst, opr_sz, opr_sz, a->rot, fn_gvec_ptr); tcg_temp_free_ptr(fpst); return true; } static bool trans_VDOT(DisasContext *s, arg_VDOT *a) { int opr_sz; gen_helper_gvec_3 *fn_gvec; if (!dc_isar_feature(aa32_dp, s)) { return false; } /* UNDEF accesses to D16-D31 if they don't exist. */ if (!dc_isar_feature(aa32_simd_r32, s) && ((a->vd | a->vn | a->vm) & 0x10)) { return false; } if ((a->vn | a->vm | a->vd) & a->q) { return false; } if (!vfp_access_check(s)) { return true; } opr_sz = (1 + a->q) * 8; fn_gvec = a->u ? gen_helper_gvec_udot_b : gen_helper_gvec_sdot_b; tcg_gen_gvec_3_ool(vfp_reg_offset(1, a->vd), vfp_reg_offset(1, a->vn), vfp_reg_offset(1, a->vm), opr_sz, opr_sz, 0, fn_gvec); return true; } static bool trans_VFML(DisasContext *s, arg_VFML *a) { int opr_sz; if (!dc_isar_feature(aa32_fhm, s)) { return false; } /* UNDEF accesses to D16-D31 if they don't exist. */ if (!dc_isar_feature(aa32_simd_r32, s) && (a->vd & 0x10)) { return false; } if (a->vd & a->q) { return false; } if (!vfp_access_check(s)) { return true; } opr_sz = (1 + a->q) * 8; tcg_gen_gvec_3_ptr(vfp_reg_offset(1, a->vd), vfp_reg_offset(a->q, a->vn), vfp_reg_offset(a->q, a->vm), cpu_env, opr_sz, opr_sz, a->s, /* is_2 == 0 */ gen_helper_gvec_fmlal_a32); return true; } static bool trans_VCMLA_scalar(DisasContext *s, arg_VCMLA_scalar *a) { gen_helper_gvec_3_ptr *fn_gvec_ptr; int opr_sz; TCGv_ptr fpst; if (!dc_isar_feature(aa32_vcma, s)) { return false; } if (a->size == 0 && !dc_isar_feature(aa32_fp16_arith, s)) { return false; } /* UNDEF accesses to D16-D31 if they don't exist. */ if (!dc_isar_feature(aa32_simd_r32, s) && ((a->vd | a->vn | a->vm) & 0x10)) { return false; } if ((a->vd | a->vn) & a->q) { return false; } if (!vfp_access_check(s)) { return true; } fn_gvec_ptr = (a->size ? gen_helper_gvec_fcmlas_idx : gen_helper_gvec_fcmlah_idx); opr_sz = (1 + a->q) * 8; fpst = get_fpstatus_ptr(1); tcg_gen_gvec_3_ptr(vfp_reg_offset(1, a->vd), vfp_reg_offset(1, a->vn), vfp_reg_offset(1, a->vm), fpst, opr_sz, opr_sz, (a->index << 2) | a->rot, fn_gvec_ptr); tcg_temp_free_ptr(fpst); return true; } static bool trans_VDOT_scalar(DisasContext *s, arg_VDOT_scalar *a) { gen_helper_gvec_3 *fn_gvec; int opr_sz; TCGv_ptr fpst; if (!dc_isar_feature(aa32_dp, s)) { return false; } /* UNDEF accesses to D16-D31 if they don't exist. */ if (!dc_isar_feature(aa32_simd_r32, s) && ((a->vd | a->vn) & 0x10)) { return false; } if ((a->vd | a->vn) & a->q) { return false; } if (!vfp_access_check(s)) { return true; } fn_gvec = a->u ? gen_helper_gvec_udot_idx_b : gen_helper_gvec_sdot_idx_b; opr_sz = (1 + a->q) * 8; fpst = get_fpstatus_ptr(1); tcg_gen_gvec_3_ool(vfp_reg_offset(1, a->vd), vfp_reg_offset(1, a->vn), vfp_reg_offset(1, a->rm), opr_sz, opr_sz, a->index, fn_gvec); tcg_temp_free_ptr(fpst); return true; } static bool trans_VFML_scalar(DisasContext *s, arg_VFML_scalar *a) { int opr_sz; if (!dc_isar_feature(aa32_fhm, s)) { return false; } /* UNDEF accesses to D16-D31 if they don't exist. */ if (!dc_isar_feature(aa32_simd_r32, s) && ((a->vd & 0x10) || (a->q && (a->vn & 0x10)))) { return false; } if (a->vd & a->q) { return false; } if (!vfp_access_check(s)) { return true; } opr_sz = (1 + a->q) * 8; tcg_gen_gvec_3_ptr(vfp_reg_offset(1, a->vd), vfp_reg_offset(a->q, a->vn), vfp_reg_offset(a->q, a->rm), cpu_env, opr_sz, opr_sz, (a->index << 2) | a->s, /* is_2 == 0 */ gen_helper_gvec_fmlal_idx_a32); return true; } static struct { int nregs; int interleave; int spacing; } const neon_ls_element_type[11] = { {1, 4, 1}, {1, 4, 2}, {4, 1, 1}, {2, 2, 2}, {1, 3, 1}, {1, 3, 2}, {3, 1, 1}, {1, 1, 1}, {1, 2, 1}, {1, 2, 2}, {2, 1, 1} }; static void gen_neon_ldst_base_update(DisasContext *s, int rm, int rn, int stride) { if (rm != 15) { TCGv_i32 base; base = load_reg(s, rn); if (rm == 13) { tcg_gen_addi_i32(base, base, stride); } else { TCGv_i32 index; index = load_reg(s, rm); tcg_gen_add_i32(base, base, index); tcg_temp_free_i32(index); } store_reg(s, rn, base); } } static bool trans_VLDST_multiple(DisasContext *s, arg_VLDST_multiple *a) { /* Neon load/store multiple structures */ int nregs, interleave, spacing, reg, n; MemOp endian = s->be_data; int mmu_idx = get_mem_index(s); int size = a->size; TCGv_i64 tmp64; TCGv_i32 addr, tmp; if (!arm_dc_feature(s, ARM_FEATURE_NEON)) { return false; } /* UNDEF accesses to D16-D31 if they don't exist */ if (!dc_isar_feature(aa32_simd_r32, s) && (a->vd & 0x10)) { return false; } if (a->itype > 10) { return false; } /* Catch UNDEF cases for bad values of align field */ switch (a->itype & 0xc) { case 4: if (a->align >= 2) { return false; } break; case 8: if (a->align == 3) { return false; } break; default: break; } nregs = neon_ls_element_type[a->itype].nregs; interleave = neon_ls_element_type[a->itype].interleave; spacing = neon_ls_element_type[a->itype].spacing; if (size == 3 && (interleave | spacing) != 1) { return false; } if (!vfp_access_check(s)) { return true; } /* For our purposes, bytes are always little-endian. */ if (size == 0) { endian = MO_LE; } /* * Consecutive little-endian elements from a single register * can be promoted to a larger little-endian operation. */ if (interleave == 1 && endian == MO_LE) { size = 3; } tmp64 = tcg_temp_new_i64(); addr = tcg_temp_new_i32(); tmp = tcg_const_i32(1 << size); load_reg_var(s, addr, a->rn); for (reg = 0; reg < nregs; reg++) { for (n = 0; n < 8 >> size; n++) { int xs; for (xs = 0; xs < interleave; xs++) { int tt = a->vd + reg + spacing * xs; if (a->l) { gen_aa32_ld_i64(s, tmp64, addr, mmu_idx, endian | size); neon_store_element64(tt, n, size, tmp64); } else { neon_load_element64(tmp64, tt, n, size); gen_aa32_st_i64(s, tmp64, addr, mmu_idx, endian | size); } tcg_gen_add_i32(addr, addr, tmp); } } } tcg_temp_free_i32(addr); tcg_temp_free_i32(tmp); tcg_temp_free_i64(tmp64); gen_neon_ldst_base_update(s, a->rm, a->rn, nregs * interleave * 8); return true; } static bool trans_VLD_all_lanes(DisasContext *s, arg_VLD_all_lanes *a) { /* Neon load single structure to all lanes */ int reg, stride, vec_size; int vd = a->vd; int size = a->size; int nregs = a->n + 1; TCGv_i32 addr, tmp; if (!arm_dc_feature(s, ARM_FEATURE_NEON)) { return false; } /* UNDEF accesses to D16-D31 if they don't exist */ if (!dc_isar_feature(aa32_simd_r32, s) && (a->vd & 0x10)) { return false; } if (size == 3) { if (nregs != 4 || a->a == 0) { return false; } /* For VLD4 size == 3 a == 1 means 32 bits at 16 byte alignment */ size = 2; } if (nregs == 1 && a->a == 1 && size == 0) { return false; } if (nregs == 3 && a->a == 1) { return false; } if (!vfp_access_check(s)) { return true; } /* * VLD1 to all lanes: T bit indicates how many Dregs to write. * VLD2/3/4 to all lanes: T bit indicates register stride. */ stride = a->t ? 2 : 1; vec_size = nregs == 1 ? stride * 8 : 8; tmp = tcg_temp_new_i32(); addr = tcg_temp_new_i32(); load_reg_var(s, addr, a->rn); for (reg = 0; reg < nregs; reg++) { gen_aa32_ld_i32(s, tmp, addr, get_mem_index(s), s->be_data | size); if ((vd & 1) && vec_size == 16) { /* * We cannot write 16 bytes at once because the * destination is unaligned. */ tcg_gen_gvec_dup_i32(size, neon_reg_offset(vd, 0), 8, 8, tmp); tcg_gen_gvec_mov(0, neon_reg_offset(vd + 1, 0), neon_reg_offset(vd, 0), 8, 8); } else { tcg_gen_gvec_dup_i32(size, neon_reg_offset(vd, 0), vec_size, vec_size, tmp); } tcg_gen_addi_i32(addr, addr, 1 << size); vd += stride; } tcg_temp_free_i32(tmp); tcg_temp_free_i32(addr); gen_neon_ldst_base_update(s, a->rm, a->rn, (1 << size) * nregs); return true; } static bool trans_VLDST_single(DisasContext *s, arg_VLDST_single *a) { /* Neon load/store single structure to one lane */ int reg; int nregs = a->n + 1; int vd = a->vd; TCGv_i32 addr, tmp; if (!arm_dc_feature(s, ARM_FEATURE_NEON)) { return false; } /* UNDEF accesses to D16-D31 if they don't exist */ if (!dc_isar_feature(aa32_simd_r32, s) && (a->vd & 0x10)) { return false; } /* Catch the UNDEF cases. This is unavoidably a bit messy. */ switch (nregs) { case 1: if (((a->align & (1 << a->size)) != 0) || (a->size == 2 && ((a->align & 3) == 1 || (a->align & 3) == 2))) { return false; } break; case 3: if ((a->align & 1) != 0) { return false; } /* fall through */ case 2: if (a->size == 2 && (a->align & 2) != 0) { return false; } break; case 4: if ((a->size == 2) && ((a->align & 3) == 3)) { return false; } break; default: abort(); } if ((vd + a->stride * (nregs - 1)) > 31) { /* * Attempts to write off the end of the register file are * UNPREDICTABLE; we choose to UNDEF because otherwise we would * access off the end of the array that holds the register data. */ return false; } if (!vfp_access_check(s)) { return true; } tmp = tcg_temp_new_i32(); addr = tcg_temp_new_i32(); load_reg_var(s, addr, a->rn); /* * TODO: if we implemented alignment exceptions, we should check * addr against the alignment encoded in a->align here. */ for (reg = 0; reg < nregs; reg++) { if (a->l) { gen_aa32_ld_i32(s, tmp, addr, get_mem_index(s), s->be_data | a->size); neon_store_element(vd, a->reg_idx, a->size, tmp); } else { /* Store */ neon_load_element(tmp, vd, a->reg_idx, a->size); gen_aa32_st_i32(s, tmp, addr, get_mem_index(s), s->be_data | a->size); } vd += a->stride; tcg_gen_addi_i32(addr, addr, 1 << a->size); } tcg_temp_free_i32(addr); tcg_temp_free_i32(tmp); gen_neon_ldst_base_update(s, a->rm, a->rn, (1 << a->size) * nregs); return true; } static bool do_3same(DisasContext *s, arg_3same *a, GVecGen3Fn fn) { int vec_size = a->q ? 16 : 8; int rd_ofs = neon_reg_offset(a->vd, 0); int rn_ofs = neon_reg_offset(a->vn, 0); int rm_ofs = neon_reg_offset(a->vm, 0); if (!arm_dc_feature(s, ARM_FEATURE_NEON)) { return false; } /* UNDEF accesses to D16-D31 if they don't exist. */ if (!dc_isar_feature(aa32_simd_r32, s) && ((a->vd | a->vn | a->vm) & 0x10)) { return false; } if ((a->vn | a->vm | a->vd) & a->q) { return false; } if (!vfp_access_check(s)) { return true; } fn(a->size, rd_ofs, rn_ofs, rm_ofs, vec_size, vec_size); return true; } #define DO_3SAME(INSN, FUNC) \ static bool trans_##INSN##_3s(DisasContext *s, arg_3same *a) \ { \ return do_3same(s, a, FUNC); \ } DO_3SAME(VADD, tcg_gen_gvec_add) DO_3SAME(VSUB, tcg_gen_gvec_sub) DO_3SAME(VAND, tcg_gen_gvec_and) DO_3SAME(VBIC, tcg_gen_gvec_andc) DO_3SAME(VORR, tcg_gen_gvec_or) DO_3SAME(VORN, tcg_gen_gvec_orc) DO_3SAME(VEOR, tcg_gen_gvec_xor) DO_3SAME(VSHL_S, gen_gvec_sshl) DO_3SAME(VSHL_U, gen_gvec_ushl) DO_3SAME(VQADD_S, gen_gvec_sqadd_qc) DO_3SAME(VQADD_U, gen_gvec_uqadd_qc) DO_3SAME(VQSUB_S, gen_gvec_sqsub_qc) DO_3SAME(VQSUB_U, gen_gvec_uqsub_qc) /* These insns are all gvec_bitsel but with the inputs in various orders. */ #define DO_3SAME_BITSEL(INSN, O1, O2, O3) \ static void gen_##INSN##_3s(unsigned vece, uint32_t rd_ofs, \ uint32_t rn_ofs, uint32_t rm_ofs, \ uint32_t oprsz, uint32_t maxsz) \ { \ tcg_gen_gvec_bitsel(vece, rd_ofs, O1, O2, O3, oprsz, maxsz); \ } \ DO_3SAME(INSN, gen_##INSN##_3s) DO_3SAME_BITSEL(VBSL, rd_ofs, rn_ofs, rm_ofs) DO_3SAME_BITSEL(VBIT, rm_ofs, rn_ofs, rd_ofs) DO_3SAME_BITSEL(VBIF, rm_ofs, rd_ofs, rn_ofs) #define DO_3SAME_NO_SZ_3(INSN, FUNC) \ static bool trans_##INSN##_3s(DisasContext *s, arg_3same *a) \ { \ if (a->size == 3) { \ return false; \ } \ return do_3same(s, a, FUNC); \ } DO_3SAME_NO_SZ_3(VMAX_S, tcg_gen_gvec_smax) DO_3SAME_NO_SZ_3(VMAX_U, tcg_gen_gvec_umax) DO_3SAME_NO_SZ_3(VMIN_S, tcg_gen_gvec_smin) DO_3SAME_NO_SZ_3(VMIN_U, tcg_gen_gvec_umin) DO_3SAME_NO_SZ_3(VMUL, tcg_gen_gvec_mul) DO_3SAME_NO_SZ_3(VMLA, gen_gvec_mla) DO_3SAME_NO_SZ_3(VMLS, gen_gvec_mls) DO_3SAME_NO_SZ_3(VTST, gen_gvec_cmtst) DO_3SAME_NO_SZ_3(VABD_S, gen_gvec_sabd) DO_3SAME_NO_SZ_3(VABA_S, gen_gvec_saba) DO_3SAME_NO_SZ_3(VABD_U, gen_gvec_uabd) DO_3SAME_NO_SZ_3(VABA_U, gen_gvec_uaba) #define DO_3SAME_CMP(INSN, COND) \ static void gen_##INSN##_3s(unsigned vece, uint32_t rd_ofs, \ uint32_t rn_ofs, uint32_t rm_ofs, \ uint32_t oprsz, uint32_t maxsz) \ { \ tcg_gen_gvec_cmp(COND, vece, rd_ofs, rn_ofs, rm_ofs, oprsz, maxsz); \ } \ DO_3SAME_NO_SZ_3(INSN, gen_##INSN##_3s) DO_3SAME_CMP(VCGT_S, TCG_COND_GT) DO_3SAME_CMP(VCGT_U, TCG_COND_GTU) DO_3SAME_CMP(VCGE_S, TCG_COND_GE) DO_3SAME_CMP(VCGE_U, TCG_COND_GEU) DO_3SAME_CMP(VCEQ, TCG_COND_EQ) static void gen_VMUL_p_3s(unsigned vece, uint32_t rd_ofs, uint32_t rn_ofs, uint32_t rm_ofs, uint32_t oprsz, uint32_t maxsz) { tcg_gen_gvec_3_ool(rd_ofs, rn_ofs, rm_ofs, oprsz, maxsz, 0, gen_helper_gvec_pmul_b); } static bool trans_VMUL_p_3s(DisasContext *s, arg_3same *a) { if (a->size != 0) { return false; } return do_3same(s, a, gen_VMUL_p_3s); } #define DO_VQRDMLAH(INSN, FUNC) \ static bool trans_##INSN##_3s(DisasContext *s, arg_3same *a) \ { \ if (!dc_isar_feature(aa32_rdm, s)) { \ return false; \ } \ if (a->size != 1 && a->size != 2) { \ return false; \ } \ return do_3same(s, a, FUNC); \ } DO_VQRDMLAH(VQRDMLAH, gen_gvec_sqrdmlah_qc) DO_VQRDMLAH(VQRDMLSH, gen_gvec_sqrdmlsh_qc) static bool trans_SHA1_3s(DisasContext *s, arg_SHA1_3s *a) { TCGv_ptr ptr1, ptr2, ptr3; TCGv_i32 tmp; if (!arm_dc_feature(s, ARM_FEATURE_NEON) || !dc_isar_feature(aa32_sha1, s)) { return false; } /* UNDEF accesses to D16-D31 if they don't exist. */ if (!dc_isar_feature(aa32_simd_r32, s) && ((a->vd | a->vn | a->vm) & 0x10)) { return false; } if ((a->vn | a->vm | a->vd) & 1) { return false; } if (!vfp_access_check(s)) { return true; } ptr1 = vfp_reg_ptr(true, a->vd); ptr2 = vfp_reg_ptr(true, a->vn); ptr3 = vfp_reg_ptr(true, a->vm); tmp = tcg_const_i32(a->optype); gen_helper_crypto_sha1_3reg(ptr1, ptr2, ptr3, tmp); tcg_temp_free_i32(tmp); tcg_temp_free_ptr(ptr1); tcg_temp_free_ptr(ptr2); tcg_temp_free_ptr(ptr3); return true; } static bool trans_SHA256H_3s(DisasContext *s, arg_SHA256H_3s *a) { TCGv_ptr ptr1, ptr2, ptr3; if (!arm_dc_feature(s, ARM_FEATURE_NEON) || !dc_isar_feature(aa32_sha2, s)) { return false; } /* UNDEF accesses to D16-D31 if they don't exist. */ if (!dc_isar_feature(aa32_simd_r32, s) && ((a->vd | a->vn | a->vm) & 0x10)) { return false; } if ((a->vn | a->vm | a->vd) & 1) { return false; } if (!vfp_access_check(s)) { return true; } ptr1 = vfp_reg_ptr(true, a->vd); ptr2 = vfp_reg_ptr(true, a->vn); ptr3 = vfp_reg_ptr(true, a->vm); gen_helper_crypto_sha256h(ptr1, ptr2, ptr3); tcg_temp_free_ptr(ptr1); tcg_temp_free_ptr(ptr2); tcg_temp_free_ptr(ptr3); return true; } static bool trans_SHA256H2_3s(DisasContext *s, arg_SHA256H2_3s *a) { TCGv_ptr ptr1, ptr2, ptr3; if (!arm_dc_feature(s, ARM_FEATURE_NEON) || !dc_isar_feature(aa32_sha2, s)) { return false; } /* UNDEF accesses to D16-D31 if they don't exist. */ if (!dc_isar_feature(aa32_simd_r32, s) && ((a->vd | a->vn | a->vm) & 0x10)) { return false; } if ((a->vn | a->vm | a->vd) & 1) { return false; } if (!vfp_access_check(s)) { return true; } ptr1 = vfp_reg_ptr(true, a->vd); ptr2 = vfp_reg_ptr(true, a->vn); ptr3 = vfp_reg_ptr(true, a->vm); gen_helper_crypto_sha256h2(ptr1, ptr2, ptr3); tcg_temp_free_ptr(ptr1); tcg_temp_free_ptr(ptr2); tcg_temp_free_ptr(ptr3); return true; } static bool trans_SHA256SU1_3s(DisasContext *s, arg_SHA256SU1_3s *a) { TCGv_ptr ptr1, ptr2, ptr3; if (!arm_dc_feature(s, ARM_FEATURE_NEON) || !dc_isar_feature(aa32_sha2, s)) { return false; } /* UNDEF accesses to D16-D31 if they don't exist. */ if (!dc_isar_feature(aa32_simd_r32, s) && ((a->vd | a->vn | a->vm) & 0x10)) { return false; } if ((a->vn | a->vm | a->vd) & 1) { return false; } if (!vfp_access_check(s)) { return true; } ptr1 = vfp_reg_ptr(true, a->vd); ptr2 = vfp_reg_ptr(true, a->vn); ptr3 = vfp_reg_ptr(true, a->vm); gen_helper_crypto_sha256su1(ptr1, ptr2, ptr3); tcg_temp_free_ptr(ptr1); tcg_temp_free_ptr(ptr2); tcg_temp_free_ptr(ptr3); return true; } #define DO_3SAME_64(INSN, FUNC) \ static void gen_##INSN##_3s(unsigned vece, uint32_t rd_ofs, \ uint32_t rn_ofs, uint32_t rm_ofs, \ uint32_t oprsz, uint32_t maxsz) \ { \ static const GVecGen3 op = { .fni8 = FUNC }; \ tcg_gen_gvec_3(rd_ofs, rn_ofs, rm_ofs, oprsz, maxsz, &op); \ } \ DO_3SAME(INSN, gen_##INSN##_3s) #define DO_3SAME_64_ENV(INSN, FUNC) \ static void gen_##INSN##_elt(TCGv_i64 d, TCGv_i64 n, TCGv_i64 m) \ { \ FUNC(d, cpu_env, n, m); \ } \ DO_3SAME_64(INSN, gen_##INSN##_elt) DO_3SAME_64(VRSHL_S64, gen_helper_neon_rshl_s64) DO_3SAME_64(VRSHL_U64, gen_helper_neon_rshl_u64) DO_3SAME_64_ENV(VQSHL_S64, gen_helper_neon_qshl_s64) DO_3SAME_64_ENV(VQSHL_U64, gen_helper_neon_qshl_u64) DO_3SAME_64_ENV(VQRSHL_S64, gen_helper_neon_qrshl_s64) DO_3SAME_64_ENV(VQRSHL_U64, gen_helper_neon_qrshl_u64) #define DO_3SAME_32(INSN, FUNC) \ static void gen_##INSN##_3s(unsigned vece, uint32_t rd_ofs, \ uint32_t rn_ofs, uint32_t rm_ofs, \ uint32_t oprsz, uint32_t maxsz) \ { \ static const GVecGen3 ops[4] = { \ { .fni4 = gen_helper_neon_##FUNC##8 }, \ { .fni4 = gen_helper_neon_##FUNC##16 }, \ { .fni4 = gen_helper_neon_##FUNC##32 }, \ { 0 }, \ }; \ tcg_gen_gvec_3(rd_ofs, rn_ofs, rm_ofs, oprsz, maxsz, &ops[vece]); \ } \ static bool trans_##INSN##_3s(DisasContext *s, arg_3same *a) \ { \ if (a->size > 2) { \ return false; \ } \ return do_3same(s, a, gen_##INSN##_3s); \ } /* * Some helper functions need to be passed the cpu_env. In order * to use those with the gvec APIs like tcg_gen_gvec_3() we need * to create wrapper functions whose prototype is a NeonGenTwoOpFn() * and which call a NeonGenTwoOpEnvFn(). */ #define WRAP_ENV_FN(WRAPNAME, FUNC) \ static void WRAPNAME(TCGv_i32 d, TCGv_i32 n, TCGv_i32 m) \ { \ FUNC(d, cpu_env, n, m); \ } #define DO_3SAME_32_ENV(INSN, FUNC) \ WRAP_ENV_FN(gen_##INSN##_tramp8, gen_helper_neon_##FUNC##8); \ WRAP_ENV_FN(gen_##INSN##_tramp16, gen_helper_neon_##FUNC##16); \ WRAP_ENV_FN(gen_##INSN##_tramp32, gen_helper_neon_##FUNC##32); \ static void gen_##INSN##_3s(unsigned vece, uint32_t rd_ofs, \ uint32_t rn_ofs, uint32_t rm_ofs, \ uint32_t oprsz, uint32_t maxsz) \ { \ static const GVecGen3 ops[4] = { \ { .fni4 = gen_##INSN##_tramp8 }, \ { .fni4 = gen_##INSN##_tramp16 }, \ { .fni4 = gen_##INSN##_tramp32 }, \ { 0 }, \ }; \ tcg_gen_gvec_3(rd_ofs, rn_ofs, rm_ofs, oprsz, maxsz, &ops[vece]); \ } \ static bool trans_##INSN##_3s(DisasContext *s, arg_3same *a) \ { \ if (a->size > 2) { \ return false; \ } \ return do_3same(s, a, gen_##INSN##_3s); \ } DO_3SAME_32(VHADD_S, hadd_s) DO_3SAME_32(VHADD_U, hadd_u) DO_3SAME_32(VHSUB_S, hsub_s) DO_3SAME_32(VHSUB_U, hsub_u) DO_3SAME_32(VRHADD_S, rhadd_s) DO_3SAME_32(VRHADD_U, rhadd_u) DO_3SAME_32(VRSHL_S, rshl_s) DO_3SAME_32(VRSHL_U, rshl_u) DO_3SAME_32_ENV(VQSHL_S, qshl_s) DO_3SAME_32_ENV(VQSHL_U, qshl_u) DO_3SAME_32_ENV(VQRSHL_S, qrshl_s) DO_3SAME_32_ENV(VQRSHL_U, qrshl_u) static bool do_3same_pair(DisasContext *s, arg_3same *a, NeonGenTwoOpFn *fn) { /* Operations handled pairwise 32 bits at a time */ TCGv_i32 tmp, tmp2, tmp3; if (!arm_dc_feature(s, ARM_FEATURE_NEON)) { return false; } /* UNDEF accesses to D16-D31 if they don't exist. */ if (!dc_isar_feature(aa32_simd_r32, s) && ((a->vd | a->vn | a->vm) & 0x10)) { return false; } if (a->size == 3) { return false; } if (!vfp_access_check(s)) { return true; } assert(a->q == 0); /* enforced by decode patterns */ /* * Note that we have to be careful not to clobber the source operands * in the "vm == vd" case by storing the result of the first pass too * early. Since Q is 0 there are always just two passes, so instead * of a complicated loop over each pass we just unroll. */ tmp = neon_load_reg(a->vn, 0); tmp2 = neon_load_reg(a->vn, 1); fn(tmp, tmp, tmp2); tcg_temp_free_i32(tmp2); tmp3 = neon_load_reg(a->vm, 0); tmp2 = neon_load_reg(a->vm, 1); fn(tmp3, tmp3, tmp2); tcg_temp_free_i32(tmp2); neon_store_reg(a->vd, 0, tmp); neon_store_reg(a->vd, 1, tmp3); return true; } #define DO_3SAME_PAIR(INSN, func) \ static bool trans_##INSN##_3s(DisasContext *s, arg_3same *a) \ { \ static NeonGenTwoOpFn * const fns[] = { \ gen_helper_neon_##func##8, \ gen_helper_neon_##func##16, \ gen_helper_neon_##func##32, \ }; \ if (a->size > 2) { \ return false; \ } \ return do_3same_pair(s, a, fns[a->size]); \ } /* 32-bit pairwise ops end up the same as the elementwise versions. */ #define gen_helper_neon_pmax_s32 tcg_gen_smax_i32 #define gen_helper_neon_pmax_u32 tcg_gen_umax_i32 #define gen_helper_neon_pmin_s32 tcg_gen_smin_i32 #define gen_helper_neon_pmin_u32 tcg_gen_umin_i32 #define gen_helper_neon_padd_u32 tcg_gen_add_i32 DO_3SAME_PAIR(VPMAX_S, pmax_s) DO_3SAME_PAIR(VPMIN_S, pmin_s) DO_3SAME_PAIR(VPMAX_U, pmax_u) DO_3SAME_PAIR(VPMIN_U, pmin_u) DO_3SAME_PAIR(VPADD, padd_u) #define DO_3SAME_VQDMULH(INSN, FUNC) \ WRAP_ENV_FN(gen_##INSN##_tramp16, gen_helper_neon_##FUNC##_s16); \ WRAP_ENV_FN(gen_##INSN##_tramp32, gen_helper_neon_##FUNC##_s32); \ static void gen_##INSN##_3s(unsigned vece, uint32_t rd_ofs, \ uint32_t rn_ofs, uint32_t rm_ofs, \ uint32_t oprsz, uint32_t maxsz) \ { \ static const GVecGen3 ops[2] = { \ { .fni4 = gen_##INSN##_tramp16 }, \ { .fni4 = gen_##INSN##_tramp32 }, \ }; \ tcg_gen_gvec_3(rd_ofs, rn_ofs, rm_ofs, oprsz, maxsz, &ops[vece - 1]); \ } \ static bool trans_##INSN##_3s(DisasContext *s, arg_3same *a) \ { \ if (a->size != 1 && a->size != 2) { \ return false; \ } \ return do_3same(s, a, gen_##INSN##_3s); \ } DO_3SAME_VQDMULH(VQDMULH, qdmulh) DO_3SAME_VQDMULH(VQRDMULH, qrdmulh) static bool do_3same_fp(DisasContext *s, arg_3same *a, VFPGen3OpSPFn *fn, bool reads_vd) { /* * FP operations handled elementwise 32 bits at a time. * If reads_vd is true then the old value of Vd will be * loaded before calling the callback function. This is * used for multiply-accumulate type operations. */ TCGv_i32 tmp, tmp2; int pass; if (!arm_dc_feature(s, ARM_FEATURE_NEON)) { return false; } /* UNDEF accesses to D16-D31 if they don't exist. */ if (!dc_isar_feature(aa32_simd_r32, s) && ((a->vd | a->vn | a->vm) & 0x10)) { return false; } if ((a->vn | a->vm | a->vd) & a->q) { return false; } if (!vfp_access_check(s)) { return true; } TCGv_ptr fpstatus = get_fpstatus_ptr(1); for (pass = 0; pass < (a->q ? 4 : 2); pass++) { tmp = neon_load_reg(a->vn, pass); tmp2 = neon_load_reg(a->vm, pass); if (reads_vd) { TCGv_i32 tmp_rd = neon_load_reg(a->vd, pass); fn(tmp_rd, tmp, tmp2, fpstatus); neon_store_reg(a->vd, pass, tmp_rd); tcg_temp_free_i32(tmp); } else { fn(tmp, tmp, tmp2, fpstatus); neon_store_reg(a->vd, pass, tmp); } tcg_temp_free_i32(tmp2); } tcg_temp_free_ptr(fpstatus); return true; } /* * For all the functions using this macro, size == 1 means fp16, * which is an architecture extension we don't implement yet. */ #define DO_3S_FP_GVEC(INSN,FUNC) \ static void gen_##INSN##_3s(unsigned vece, uint32_t rd_ofs, \ uint32_t rn_ofs, uint32_t rm_ofs, \ uint32_t oprsz, uint32_t maxsz) \ { \ TCGv_ptr fpst = get_fpstatus_ptr(1); \ tcg_gen_gvec_3_ptr(rd_ofs, rn_ofs, rm_ofs, fpst, \ oprsz, maxsz, 0, FUNC); \ tcg_temp_free_ptr(fpst); \ } \ static bool trans_##INSN##_fp_3s(DisasContext *s, arg_3same *a) \ { \ if (a->size != 0) { \ /* TODO fp16 support */ \ return false; \ } \ return do_3same(s, a, gen_##INSN##_3s); \ } DO_3S_FP_GVEC(VADD, gen_helper_gvec_fadd_s) DO_3S_FP_GVEC(VSUB, gen_helper_gvec_fsub_s) DO_3S_FP_GVEC(VABD, gen_helper_gvec_fabd_s) DO_3S_FP_GVEC(VMUL, gen_helper_gvec_fmul_s) /* * For all the functions using this macro, size == 1 means fp16, * which is an architecture extension we don't implement yet. */ #define DO_3S_FP(INSN,FUNC,READS_VD) \ static bool trans_##INSN##_fp_3s(DisasContext *s, arg_3same *a) \ { \ if (a->size != 0) { \ /* TODO fp16 support */ \ return false; \ } \ return do_3same_fp(s, a, FUNC, READS_VD); \ } DO_3S_FP(VCEQ, gen_helper_neon_ceq_f32, false) DO_3S_FP(VCGE, gen_helper_neon_cge_f32, false) DO_3S_FP(VCGT, gen_helper_neon_cgt_f32, false) DO_3S_FP(VACGE, gen_helper_neon_acge_f32, false) DO_3S_FP(VACGT, gen_helper_neon_acgt_f32, false) static void gen_VMLA_fp_3s(TCGv_i32 vd, TCGv_i32 vn, TCGv_i32 vm, TCGv_ptr fpstatus) { gen_helper_vfp_muls(vn, vn, vm, fpstatus); gen_helper_vfp_adds(vd, vd, vn, fpstatus); } static void gen_VMLS_fp_3s(TCGv_i32 vd, TCGv_i32 vn, TCGv_i32 vm, TCGv_ptr fpstatus) { gen_helper_vfp_muls(vn, vn, vm, fpstatus); gen_helper_vfp_subs(vd, vd, vn, fpstatus); } DO_3S_FP(VMLA, gen_VMLA_fp_3s, true) DO_3S_FP(VMLS, gen_VMLS_fp_3s, true) static bool do_3same_fp_pair(DisasContext *s, arg_3same *a, VFPGen3OpSPFn *fn) { /* FP operations handled pairwise 32 bits at a time */ TCGv_i32 tmp, tmp2, tmp3; TCGv_ptr fpstatus; if (!arm_dc_feature(s, ARM_FEATURE_NEON)) { return false; } /* UNDEF accesses to D16-D31 if they don't exist. */ if (!dc_isar_feature(aa32_simd_r32, s) && ((a->vd | a->vn | a->vm) & 0x10)) { return false; } if (!vfp_access_check(s)) { return true; } assert(a->q == 0); /* enforced by decode patterns */ /* * Note that we have to be careful not to clobber the source operands * in the "vm == vd" case by storing the result of the first pass too * early. Since Q is 0 there are always just two passes, so instead * of a complicated loop over each pass we just unroll. */ fpstatus = get_fpstatus_ptr(1); tmp = neon_load_reg(a->vn, 0); tmp2 = neon_load_reg(a->vn, 1); fn(tmp, tmp, tmp2, fpstatus); tcg_temp_free_i32(tmp2); tmp3 = neon_load_reg(a->vm, 0); tmp2 = neon_load_reg(a->vm, 1); fn(tmp3, tmp3, tmp2, fpstatus); tcg_temp_free_i32(tmp2); tcg_temp_free_ptr(fpstatus); neon_store_reg(a->vd, 0, tmp); neon_store_reg(a->vd, 1, tmp3); return true; } /* * For all the functions using this macro, size == 1 means fp16, * which is an architecture extension we don't implement yet. */ #define DO_3S_FP_PAIR(INSN,FUNC) \ static bool trans_##INSN##_fp_3s(DisasContext *s, arg_3same *a) \ { \ if (a->size != 0) { \ /* TODO fp16 support */ \ return false; \ } \ return do_3same_fp_pair(s, a, FUNC); \ } DO_3S_FP_PAIR(VPADD, gen_helper_vfp_adds) DO_3S_FP_PAIR(VPMAX, gen_helper_vfp_maxs) DO_3S_FP_PAIR(VPMIN, gen_helper_vfp_mins)