/* * RISC-V translation routines for the T-Head vendor extensions (xthead*). * * Copyright (c) 2022 VRULL GmbH. * * This program is free software; you can redistribute it and/or modify it * under the terms and conditions of the GNU General Public License, * version 2 or later, as published by the Free Software Foundation. * * This program is distributed in the hope it will be useful, but WITHOUT * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for * more details. * * You should have received a copy of the GNU General Public License along with * this program. If not, see . */ #define REQUIRE_XTHEADBA(ctx) do { \ if (!ctx->cfg_ptr->ext_xtheadba) { \ return false; \ } \ } while (0) #define REQUIRE_XTHEADBB(ctx) do { \ if (!ctx->cfg_ptr->ext_xtheadbb) { \ return false; \ } \ } while (0) #define REQUIRE_XTHEADBS(ctx) do { \ if (!ctx->cfg_ptr->ext_xtheadbs) { \ return false; \ } \ } while (0) #define REQUIRE_XTHEADCMO(ctx) do { \ if (!ctx->cfg_ptr->ext_xtheadcmo) { \ return false; \ } \ } while (0) #define REQUIRE_XTHEADCONDMOV(ctx) do { \ if (!ctx->cfg_ptr->ext_xtheadcondmov) { \ return false; \ } \ } while (0) #define REQUIRE_XTHEADFMEMIDX(ctx) do { \ if (!ctx->cfg_ptr->ext_xtheadfmemidx) { \ return false; \ } \ } while (0) #define REQUIRE_XTHEADFMV(ctx) do { \ if (!ctx->cfg_ptr->ext_xtheadfmv) { \ return false; \ } \ } while (0) #define REQUIRE_XTHEADMAC(ctx) do { \ if (!ctx->cfg_ptr->ext_xtheadmac) { \ return false; \ } \ } while (0) #define REQUIRE_XTHEADMEMIDX(ctx) do { \ if (!ctx->cfg_ptr->ext_xtheadmemidx) { \ return false; \ } \ } while (0) #define REQUIRE_XTHEADMEMPAIR(ctx) do { \ if (!ctx->cfg_ptr->ext_xtheadmempair) { \ return false; \ } \ } while (0) #define REQUIRE_XTHEADSYNC(ctx) do { \ if (!ctx->cfg_ptr->ext_xtheadsync) { \ return false; \ } \ } while (0) /* * Calculate and return the address for indexed mem operations: * If !zext_offs, then the address is rs1 + (rs2 << imm2). * If zext_offs, then the address is rs1 + (zext(rs2[31:0]) << imm2). */ static TCGv get_th_address_indexed(DisasContext *ctx, int rs1, int rs2, int imm2, bool zext_offs) { TCGv src2 = get_gpr(ctx, rs2, EXT_NONE); TCGv offs = tcg_temp_new(); if (zext_offs) { tcg_gen_extract_tl(offs, src2, 0, 32); tcg_gen_shli_tl(offs, offs, imm2); } else { tcg_gen_shli_tl(offs, src2, imm2); } return get_address_indexed(ctx, rs1, offs); } /* XTheadBa */ /* * th.addsl is similar to sh[123]add (from Zba), but not an * alternative encoding: while sh[123] applies the shift to rs1, * th.addsl shifts rs2. */ #define GEN_TH_ADDSL(SHAMT) \ static void gen_th_addsl##SHAMT(TCGv ret, TCGv arg1, TCGv arg2) \ { \ TCGv t = tcg_temp_new(); \ tcg_gen_shli_tl(t, arg2, SHAMT); \ tcg_gen_add_tl(ret, t, arg1); \ } GEN_TH_ADDSL(1) GEN_TH_ADDSL(2) GEN_TH_ADDSL(3) #define GEN_TRANS_TH_ADDSL(SHAMT) \ static bool trans_th_addsl##SHAMT(DisasContext *ctx, \ arg_th_addsl##SHAMT * a) \ { \ REQUIRE_XTHEADBA(ctx); \ return gen_arith(ctx, a, EXT_NONE, gen_th_addsl##SHAMT, NULL); \ } GEN_TRANS_TH_ADDSL(1) GEN_TRANS_TH_ADDSL(2) GEN_TRANS_TH_ADDSL(3) /* XTheadBb */ /* th.srri is an alternate encoding for rori (from Zbb) */ static bool trans_th_srri(DisasContext *ctx, arg_th_srri * a) { REQUIRE_XTHEADBB(ctx); return gen_shift_imm_fn_per_ol(ctx, a, EXT_NONE, tcg_gen_rotri_tl, gen_roriw, NULL); } /* th.srriw is an alternate encoding for roriw (from Zbb) */ static bool trans_th_srriw(DisasContext *ctx, arg_th_srriw *a) { REQUIRE_XTHEADBB(ctx); REQUIRE_64BIT(ctx); ctx->ol = MXL_RV32; return gen_shift_imm_fn(ctx, a, EXT_NONE, gen_roriw, NULL); } /* th.ext and th.extu perform signed/unsigned bitfield extraction */ static bool gen_th_bfextract(DisasContext *ctx, arg_th_bfext *a, void (*f)(TCGv, TCGv, unsigned int, unsigned int)) { TCGv dest = dest_gpr(ctx, a->rd); TCGv source = get_gpr(ctx, a->rs1, EXT_ZERO); if (a->lsb <= a->msb) { f(dest, source, a->lsb, a->msb - a->lsb + 1); gen_set_gpr(ctx, a->rd, dest); } return true; } static bool trans_th_ext(DisasContext *ctx, arg_th_ext *a) { REQUIRE_XTHEADBB(ctx); return gen_th_bfextract(ctx, a, tcg_gen_sextract_tl); } static bool trans_th_extu(DisasContext *ctx, arg_th_extu *a) { REQUIRE_XTHEADBB(ctx); return gen_th_bfextract(ctx, a, tcg_gen_extract_tl); } /* th.ff0: find first zero (clz on an inverted input) */ static bool gen_th_ff0(DisasContext *ctx, arg_th_ff0 *a, DisasExtend ext) { TCGv dest = dest_gpr(ctx, a->rd); TCGv src1 = get_gpr(ctx, a->rs1, ext); int olen = get_olen(ctx); TCGv t = tcg_temp_new(); tcg_gen_not_tl(t, src1); if (olen != TARGET_LONG_BITS) { if (olen == 32) { gen_clzw(dest, t); } else { g_assert_not_reached(); } } else { gen_clz(dest, t); } gen_set_gpr(ctx, a->rd, dest); return true; } static bool trans_th_ff0(DisasContext *ctx, arg_th_ff0 *a) { REQUIRE_XTHEADBB(ctx); return gen_th_ff0(ctx, a, EXT_NONE); } /* th.ff1 is an alternate encoding for clz (from Zbb) */ static bool trans_th_ff1(DisasContext *ctx, arg_th_ff1 *a) { REQUIRE_XTHEADBB(ctx); return gen_unary_per_ol(ctx, a, EXT_NONE, gen_clz, gen_clzw); } static void gen_th_revw(TCGv ret, TCGv arg1) { tcg_gen_bswap32_tl(ret, arg1, TCG_BSWAP_OS); } /* th.rev is an alternate encoding for the RV64 rev8 (from Zbb) */ static bool trans_th_rev(DisasContext *ctx, arg_th_rev *a) { REQUIRE_XTHEADBB(ctx); return gen_unary_per_ol(ctx, a, EXT_NONE, tcg_gen_bswap_tl, gen_th_revw); } /* th.revw is a sign-extended byte-swap of the lower word */ static bool trans_th_revw(DisasContext *ctx, arg_th_revw *a) { REQUIRE_XTHEADBB(ctx); REQUIRE_64BIT(ctx); return gen_unary(ctx, a, EXT_NONE, gen_th_revw); } /* th.tstnbz is equivalent to an orc.b (from Zbb) with inverted result */ static void gen_th_tstnbz(TCGv ret, TCGv source1) { gen_orc_b(ret, source1); tcg_gen_not_tl(ret, ret); } static bool trans_th_tstnbz(DisasContext *ctx, arg_th_tstnbz *a) { REQUIRE_XTHEADBB(ctx); return gen_unary(ctx, a, EXT_ZERO, gen_th_tstnbz); } /* XTheadBs */ /* th.tst is an alternate encoding for bexti (from Zbs) */ static bool trans_th_tst(DisasContext *ctx, arg_th_tst *a) { REQUIRE_XTHEADBS(ctx); return gen_shift_imm_tl(ctx, a, EXT_NONE, gen_bext); } /* XTheadCmo */ /* Test if priv level is M, S, or U (cannot fail). */ #define REQUIRE_PRIV_MSU(ctx) /* Test if priv level is M or S. */ #define REQUIRE_PRIV_MS(ctx) \ do { \ if (ctx->priv == PRV_U) { \ return false; \ } \ } while (0) #define NOP_PRIVCHECK(insn, extcheck, privcheck) \ static bool trans_ ## insn(DisasContext *ctx, arg_ ## insn * a) \ { \ (void) a; \ extcheck(ctx); \ privcheck(ctx); \ return true; \ } NOP_PRIVCHECK(th_dcache_call, REQUIRE_XTHEADCMO, REQUIRE_PRIV_MS) NOP_PRIVCHECK(th_dcache_ciall, REQUIRE_XTHEADCMO, REQUIRE_PRIV_MS) NOP_PRIVCHECK(th_dcache_iall, REQUIRE_XTHEADCMO, REQUIRE_PRIV_MS) NOP_PRIVCHECK(th_dcache_cpa, REQUIRE_XTHEADCMO, REQUIRE_PRIV_MS) NOP_PRIVCHECK(th_dcache_cipa, REQUIRE_XTHEADCMO, REQUIRE_PRIV_MS) NOP_PRIVCHECK(th_dcache_ipa, REQUIRE_XTHEADCMO, REQUIRE_PRIV_MS) NOP_PRIVCHECK(th_dcache_cva, REQUIRE_XTHEADCMO, REQUIRE_PRIV_MSU) NOP_PRIVCHECK(th_dcache_civa, REQUIRE_XTHEADCMO, REQUIRE_PRIV_MSU) NOP_PRIVCHECK(th_dcache_iva, REQUIRE_XTHEADCMO, REQUIRE_PRIV_MSU) NOP_PRIVCHECK(th_dcache_csw, REQUIRE_XTHEADCMO, REQUIRE_PRIV_MS) NOP_PRIVCHECK(th_dcache_cisw, REQUIRE_XTHEADCMO, REQUIRE_PRIV_MS) NOP_PRIVCHECK(th_dcache_isw, REQUIRE_XTHEADCMO, REQUIRE_PRIV_MS) NOP_PRIVCHECK(th_dcache_cpal1, REQUIRE_XTHEADCMO, REQUIRE_PRIV_MS) NOP_PRIVCHECK(th_dcache_cval1, REQUIRE_XTHEADCMO, REQUIRE_PRIV_MSU) NOP_PRIVCHECK(th_icache_iall, REQUIRE_XTHEADCMO, REQUIRE_PRIV_MS) NOP_PRIVCHECK(th_icache_ialls, REQUIRE_XTHEADCMO, REQUIRE_PRIV_MS) NOP_PRIVCHECK(th_icache_ipa, REQUIRE_XTHEADCMO, REQUIRE_PRIV_MS) NOP_PRIVCHECK(th_icache_iva, REQUIRE_XTHEADCMO, REQUIRE_PRIV_MSU) NOP_PRIVCHECK(th_l2cache_call, REQUIRE_XTHEADCMO, REQUIRE_PRIV_MS) NOP_PRIVCHECK(th_l2cache_ciall, REQUIRE_XTHEADCMO, REQUIRE_PRIV_MS) NOP_PRIVCHECK(th_l2cache_iall, REQUIRE_XTHEADCMO, REQUIRE_PRIV_MS) /* XTheadCondMov */ static bool gen_th_condmove(DisasContext *ctx, arg_r *a, TCGCond cond) { TCGv src1 = get_gpr(ctx, a->rs1, EXT_NONE); TCGv src2 = get_gpr(ctx, a->rs2, EXT_NONE); TCGv old = get_gpr(ctx, a->rd, EXT_NONE); TCGv dest = dest_gpr(ctx, a->rd); tcg_gen_movcond_tl(cond, dest, src2, ctx->zero, src1, old); gen_set_gpr(ctx, a->rd, dest); return true; } /* th.mveqz: "if (rs2 == 0) rd = rs1;" */ static bool trans_th_mveqz(DisasContext *ctx, arg_th_mveqz *a) { REQUIRE_XTHEADCONDMOV(ctx); return gen_th_condmove(ctx, a, TCG_COND_EQ); } /* th.mvnez: "if (rs2 != 0) rd = rs1;" */ static bool trans_th_mvnez(DisasContext *ctx, arg_th_mveqz *a) { REQUIRE_XTHEADCONDMOV(ctx); return gen_th_condmove(ctx, a, TCG_COND_NE); } /* XTheadFMem */ /* * Load 64-bit float from indexed address. * If !zext_offs, then address is rs1 + (rs2 << imm2). * If zext_offs, then address is rs1 + (zext(rs2[31:0]) << imm2). */ static bool gen_fload_idx(DisasContext *ctx, arg_th_memidx *a, MemOp memop, bool zext_offs) { TCGv_i64 rd = cpu_fpr[a->rd]; TCGv addr = get_th_address_indexed(ctx, a->rs1, a->rs2, a->imm2, zext_offs); tcg_gen_qemu_ld_i64(rd, addr, ctx->mem_idx, memop); if ((memop & MO_SIZE) == MO_32) { gen_nanbox_s(rd, rd); } mark_fs_dirty(ctx); return true; } /* * Store 64-bit float to indexed address. * If !zext_offs, then address is rs1 + (rs2 << imm2). * If zext_offs, then address is rs1 + (zext(rs2[31:0]) << imm2). */ static bool gen_fstore_idx(DisasContext *ctx, arg_th_memidx *a, MemOp memop, bool zext_offs) { TCGv_i64 rd = cpu_fpr[a->rd]; TCGv addr = get_th_address_indexed(ctx, a->rs1, a->rs2, a->imm2, zext_offs); tcg_gen_qemu_st_i64(rd, addr, ctx->mem_idx, memop); return true; } static bool trans_th_flrd(DisasContext *ctx, arg_th_memidx *a) { REQUIRE_XTHEADFMEMIDX(ctx); REQUIRE_FPU; REQUIRE_EXT(ctx, RVD); return gen_fload_idx(ctx, a, MO_TEUQ, false); } static bool trans_th_flrw(DisasContext *ctx, arg_th_memidx *a) { REQUIRE_XTHEADFMEMIDX(ctx); REQUIRE_FPU; REQUIRE_EXT(ctx, RVF); return gen_fload_idx(ctx, a, MO_TEUL, false); } static bool trans_th_flurd(DisasContext *ctx, arg_th_memidx *a) { REQUIRE_XTHEADFMEMIDX(ctx); REQUIRE_FPU; REQUIRE_EXT(ctx, RVD); return gen_fload_idx(ctx, a, MO_TEUQ, true); } static bool trans_th_flurw(DisasContext *ctx, arg_th_memidx *a) { REQUIRE_XTHEADFMEMIDX(ctx); REQUIRE_FPU; REQUIRE_EXT(ctx, RVF); return gen_fload_idx(ctx, a, MO_TEUL, true); } static bool trans_th_fsrd(DisasContext *ctx, arg_th_memidx *a) { REQUIRE_XTHEADFMEMIDX(ctx); REQUIRE_FPU; REQUIRE_EXT(ctx, RVD); return gen_fstore_idx(ctx, a, MO_TEUQ, false); } static bool trans_th_fsrw(DisasContext *ctx, arg_th_memidx *a) { REQUIRE_XTHEADFMEMIDX(ctx); REQUIRE_FPU; REQUIRE_EXT(ctx, RVF); return gen_fstore_idx(ctx, a, MO_TEUL, false); } static bool trans_th_fsurd(DisasContext *ctx, arg_th_memidx *a) { REQUIRE_XTHEADFMEMIDX(ctx); REQUIRE_FPU; REQUIRE_EXT(ctx, RVD); return gen_fstore_idx(ctx, a, MO_TEUQ, true); } static bool trans_th_fsurw(DisasContext *ctx, arg_th_memidx *a) { REQUIRE_XTHEADFMEMIDX(ctx); REQUIRE_FPU; REQUIRE_EXT(ctx, RVF); return gen_fstore_idx(ctx, a, MO_TEUL, true); } /* XTheadFmv */ static bool trans_th_fmv_hw_x(DisasContext *ctx, arg_th_fmv_hw_x *a) { REQUIRE_XTHEADFMV(ctx); REQUIRE_32BIT(ctx); REQUIRE_FPU; REQUIRE_EXT(ctx, RVD); TCGv src1 = get_gpr(ctx, a->rs1, EXT_ZERO); TCGv_i64 t1 = tcg_temp_new_i64(); tcg_gen_extu_tl_i64(t1, src1); tcg_gen_deposit_i64(cpu_fpr[a->rd], cpu_fpr[a->rd], t1, 32, 32); mark_fs_dirty(ctx); return true; } static bool trans_th_fmv_x_hw(DisasContext *ctx, arg_th_fmv_x_hw *a) { REQUIRE_XTHEADFMV(ctx); REQUIRE_32BIT(ctx); REQUIRE_FPU; REQUIRE_EXT(ctx, RVD); TCGv dst; TCGv_i64 t1; dst = dest_gpr(ctx, a->rd); t1 = tcg_temp_new_i64(); tcg_gen_extract_i64(t1, cpu_fpr[a->rs1], 32, 32); tcg_gen_trunc_i64_tl(dst, t1); gen_set_gpr(ctx, a->rd, dst); mark_fs_dirty(ctx); return true; } /* XTheadMac */ static bool gen_th_mac(DisasContext *ctx, arg_r *a, void (*accumulate_func)(TCGv, TCGv, TCGv), void (*extend_operand_func)(TCGv, TCGv)) { TCGv dest = dest_gpr(ctx, a->rd); TCGv src0 = get_gpr(ctx, a->rd, EXT_NONE); TCGv src1 = get_gpr(ctx, a->rs1, EXT_NONE); TCGv src2 = get_gpr(ctx, a->rs2, EXT_NONE); TCGv tmp = tcg_temp_new(); if (extend_operand_func) { TCGv tmp2 = tcg_temp_new(); extend_operand_func(tmp, src1); extend_operand_func(tmp2, src2); tcg_gen_mul_tl(tmp, tmp, tmp2); } else { tcg_gen_mul_tl(tmp, src1, src2); } accumulate_func(dest, src0, tmp); gen_set_gpr(ctx, a->rd, dest); return true; } /* th.mula: "rd = rd + rs1 * rs2" */ static bool trans_th_mula(DisasContext *ctx, arg_th_mula *a) { REQUIRE_XTHEADMAC(ctx); return gen_th_mac(ctx, a, tcg_gen_add_tl, NULL); } /* th.mulah: "rd = sext.w(rd + sext.w(rs1[15:0]) * sext.w(rs2[15:0]))" */ static bool trans_th_mulah(DisasContext *ctx, arg_th_mulah *a) { REQUIRE_XTHEADMAC(ctx); ctx->ol = MXL_RV32; return gen_th_mac(ctx, a, tcg_gen_add_tl, tcg_gen_ext16s_tl); } /* th.mulaw: "rd = sext.w(rd + rs1 * rs2)" */ static bool trans_th_mulaw(DisasContext *ctx, arg_th_mulaw *a) { REQUIRE_XTHEADMAC(ctx); REQUIRE_64BIT(ctx); ctx->ol = MXL_RV32; return gen_th_mac(ctx, a, tcg_gen_add_tl, NULL); } /* th.muls: "rd = rd - rs1 * rs2" */ static bool trans_th_muls(DisasContext *ctx, arg_th_muls *a) { REQUIRE_XTHEADMAC(ctx); return gen_th_mac(ctx, a, tcg_gen_sub_tl, NULL); } /* th.mulsh: "rd = sext.w(rd - sext.w(rs1[15:0]) * sext.w(rs2[15:0]))" */ static bool trans_th_mulsh(DisasContext *ctx, arg_th_mulsh *a) { REQUIRE_XTHEADMAC(ctx); ctx->ol = MXL_RV32; return gen_th_mac(ctx, a, tcg_gen_sub_tl, tcg_gen_ext16s_tl); } /* th.mulsw: "rd = sext.w(rd - rs1 * rs2)" */ static bool trans_th_mulsw(DisasContext *ctx, arg_th_mulsw *a) { REQUIRE_XTHEADMAC(ctx); REQUIRE_64BIT(ctx); ctx->ol = MXL_RV32; return gen_th_mac(ctx, a, tcg_gen_sub_tl, NULL); } /* XTheadMemIdx */ /* * Load with memop from indexed address and add (imm5 << imm2) to rs1. * If !preinc, then the load address is rs1. * If preinc, then the load address is rs1 + (imm5) << imm2). */ static bool gen_load_inc(DisasContext *ctx, arg_th_meminc *a, MemOp memop, bool preinc) { if (a->rs1 == a->rd) { return false; } int imm = a->imm5 << a->imm2; TCGv addr = get_address(ctx, a->rs1, preinc ? imm : 0); TCGv rd = dest_gpr(ctx, a->rd); TCGv rs1 = get_gpr(ctx, a->rs1, EXT_NONE); tcg_gen_qemu_ld_tl(rd, addr, ctx->mem_idx, memop); tcg_gen_addi_tl(rs1, rs1, imm); gen_set_gpr(ctx, a->rd, rd); gen_set_gpr(ctx, a->rs1, rs1); return true; } /* * Store with memop to indexed address and add (imm5 << imm2) to rs1. * If !preinc, then the store address is rs1. * If preinc, then the store address is rs1 + (imm5) << imm2). */ static bool gen_store_inc(DisasContext *ctx, arg_th_meminc *a, MemOp memop, bool preinc) { int imm = a->imm5 << a->imm2; TCGv addr = get_address(ctx, a->rs1, preinc ? imm : 0); TCGv data = get_gpr(ctx, a->rd, EXT_NONE); TCGv rs1 = get_gpr(ctx, a->rs1, EXT_NONE); tcg_gen_qemu_st_tl(data, addr, ctx->mem_idx, memop); tcg_gen_addi_tl(rs1, rs1, imm); gen_set_gpr(ctx, a->rs1, rs1); return true; } static bool trans_th_ldia(DisasContext *ctx, arg_th_meminc *a) { REQUIRE_XTHEADMEMIDX(ctx); REQUIRE_64BIT(ctx); return gen_load_inc(ctx, a, MO_TESQ, false); } static bool trans_th_ldib(DisasContext *ctx, arg_th_meminc *a) { REQUIRE_XTHEADMEMIDX(ctx); REQUIRE_64BIT(ctx); return gen_load_inc(ctx, a, MO_TESQ, true); } static bool trans_th_lwia(DisasContext *ctx, arg_th_meminc *a) { REQUIRE_XTHEADMEMIDX(ctx); return gen_load_inc(ctx, a, MO_TESL, false); } static bool trans_th_lwib(DisasContext *ctx, arg_th_meminc *a) { REQUIRE_XTHEADMEMIDX(ctx); return gen_load_inc(ctx, a, MO_TESL, true); } static bool trans_th_lwuia(DisasContext *ctx, arg_th_meminc *a) { REQUIRE_XTHEADMEMIDX(ctx); REQUIRE_64BIT(ctx); return gen_load_inc(ctx, a, MO_TEUL, false); } static bool trans_th_lwuib(DisasContext *ctx, arg_th_meminc *a) { REQUIRE_XTHEADMEMIDX(ctx); REQUIRE_64BIT(ctx); return gen_load_inc(ctx, a, MO_TEUL, true); } static bool trans_th_lhia(DisasContext *ctx, arg_th_meminc *a) { REQUIRE_XTHEADMEMIDX(ctx); return gen_load_inc(ctx, a, MO_TESW, false); } static bool trans_th_lhib(DisasContext *ctx, arg_th_meminc *a) { REQUIRE_XTHEADMEMIDX(ctx); return gen_load_inc(ctx, a, MO_TESW, true); } static bool trans_th_lhuia(DisasContext *ctx, arg_th_meminc *a) { REQUIRE_XTHEADMEMIDX(ctx); return gen_load_inc(ctx, a, MO_TEUW, false); } static bool trans_th_lhuib(DisasContext *ctx, arg_th_meminc *a) { REQUIRE_XTHEADMEMIDX(ctx); return gen_load_inc(ctx, a, MO_TEUW, true); } static bool trans_th_lbia(DisasContext *ctx, arg_th_meminc *a) { REQUIRE_XTHEADMEMIDX(ctx); return gen_load_inc(ctx, a, MO_SB, false); } static bool trans_th_lbib(DisasContext *ctx, arg_th_meminc *a) { REQUIRE_XTHEADMEMIDX(ctx); return gen_load_inc(ctx, a, MO_SB, true); } static bool trans_th_lbuia(DisasContext *ctx, arg_th_meminc *a) { REQUIRE_XTHEADMEMIDX(ctx); return gen_load_inc(ctx, a, MO_UB, false); } static bool trans_th_lbuib(DisasContext *ctx, arg_th_meminc *a) { REQUIRE_XTHEADMEMIDX(ctx); return gen_load_inc(ctx, a, MO_UB, true); } static bool trans_th_sdia(DisasContext *ctx, arg_th_meminc *a) { REQUIRE_XTHEADMEMIDX(ctx); REQUIRE_64BIT(ctx); return gen_store_inc(ctx, a, MO_TESQ, false); } static bool trans_th_sdib(DisasContext *ctx, arg_th_meminc *a) { REQUIRE_XTHEADMEMIDX(ctx); REQUIRE_64BIT(ctx); return gen_store_inc(ctx, a, MO_TESQ, true); } static bool trans_th_swia(DisasContext *ctx, arg_th_meminc *a) { REQUIRE_XTHEADMEMIDX(ctx); return gen_store_inc(ctx, a, MO_TESL, false); } static bool trans_th_swib(DisasContext *ctx, arg_th_meminc *a) { REQUIRE_XTHEADMEMIDX(ctx); return gen_store_inc(ctx, a, MO_TESL, true); } static bool trans_th_shia(DisasContext *ctx, arg_th_meminc *a) { REQUIRE_XTHEADMEMIDX(ctx); return gen_store_inc(ctx, a, MO_TESW, false); } static bool trans_th_shib(DisasContext *ctx, arg_th_meminc *a) { REQUIRE_XTHEADMEMIDX(ctx); return gen_store_inc(ctx, a, MO_TESW, true); } static bool trans_th_sbia(DisasContext *ctx, arg_th_meminc *a) { REQUIRE_XTHEADMEMIDX(ctx); return gen_store_inc(ctx, a, MO_SB, false); } static bool trans_th_sbib(DisasContext *ctx, arg_th_meminc *a) { REQUIRE_XTHEADMEMIDX(ctx); return gen_store_inc(ctx, a, MO_SB, true); } /* * Load with memop from indexed address. * If !zext_offs, then address is rs1 + (rs2 << imm2). * If zext_offs, then address is rs1 + (zext(rs2[31:0]) << imm2). */ static bool gen_load_idx(DisasContext *ctx, arg_th_memidx *a, MemOp memop, bool zext_offs) { TCGv rd = dest_gpr(ctx, a->rd); TCGv addr = get_th_address_indexed(ctx, a->rs1, a->rs2, a->imm2, zext_offs); tcg_gen_qemu_ld_tl(rd, addr, ctx->mem_idx, memop); gen_set_gpr(ctx, a->rd, rd); return true; } /* * Store with memop to indexed address. * If !zext_offs, then address is rs1 + (rs2 << imm2). * If zext_offs, then address is rs1 + (zext(rs2[31:0]) << imm2). */ static bool gen_store_idx(DisasContext *ctx, arg_th_memidx *a, MemOp memop, bool zext_offs) { TCGv data = get_gpr(ctx, a->rd, EXT_NONE); TCGv addr = get_th_address_indexed(ctx, a->rs1, a->rs2, a->imm2, zext_offs); tcg_gen_qemu_st_tl(data, addr, ctx->mem_idx, memop); return true; } static bool trans_th_lrd(DisasContext *ctx, arg_th_memidx *a) { REQUIRE_XTHEADMEMIDX(ctx); REQUIRE_64BIT(ctx); return gen_load_idx(ctx, a, MO_TESQ, false); } static bool trans_th_lrw(DisasContext *ctx, arg_th_memidx *a) { REQUIRE_XTHEADMEMIDX(ctx); return gen_load_idx(ctx, a, MO_TESL, false); } static bool trans_th_lrwu(DisasContext *ctx, arg_th_memidx *a) { REQUIRE_XTHEADMEMIDX(ctx); REQUIRE_64BIT(ctx); return gen_load_idx(ctx, a, MO_TEUL, false); } static bool trans_th_lrh(DisasContext *ctx, arg_th_memidx *a) { REQUIRE_XTHEADMEMIDX(ctx); return gen_load_idx(ctx, a, MO_TESW, false); } static bool trans_th_lrhu(DisasContext *ctx, arg_th_memidx *a) { REQUIRE_XTHEADMEMIDX(ctx); return gen_load_idx(ctx, a, MO_TEUW, false); } static bool trans_th_lrb(DisasContext *ctx, arg_th_memidx *a) { REQUIRE_XTHEADMEMIDX(ctx); return gen_load_idx(ctx, a, MO_SB, false); } static bool trans_th_lrbu(DisasContext *ctx, arg_th_memidx *a) { REQUIRE_XTHEADMEMIDX(ctx); return gen_load_idx(ctx, a, MO_UB, false); } static bool trans_th_srd(DisasContext *ctx, arg_th_memidx *a) { REQUIRE_XTHEADMEMIDX(ctx); REQUIRE_64BIT(ctx); return gen_store_idx(ctx, a, MO_TESQ, false); } static bool trans_th_srw(DisasContext *ctx, arg_th_memidx *a) { REQUIRE_XTHEADMEMIDX(ctx); return gen_store_idx(ctx, a, MO_TESL, false); } static bool trans_th_srh(DisasContext *ctx, arg_th_memidx *a) { REQUIRE_XTHEADMEMIDX(ctx); return gen_store_idx(ctx, a, MO_TESW, false); } static bool trans_th_srb(DisasContext *ctx, arg_th_memidx *a) { REQUIRE_XTHEADMEMIDX(ctx); return gen_store_idx(ctx, a, MO_SB, false); } static bool trans_th_lurd(DisasContext *ctx, arg_th_memidx *a) { REQUIRE_XTHEADMEMIDX(ctx); REQUIRE_64BIT(ctx); return gen_load_idx(ctx, a, MO_TESQ, true); } static bool trans_th_lurw(DisasContext *ctx, arg_th_memidx *a) { REQUIRE_XTHEADMEMIDX(ctx); return gen_load_idx(ctx, a, MO_TESL, true); } static bool trans_th_lurwu(DisasContext *ctx, arg_th_memidx *a) { REQUIRE_XTHEADMEMIDX(ctx); REQUIRE_64BIT(ctx); return gen_load_idx(ctx, a, MO_TEUL, true); } static bool trans_th_lurh(DisasContext *ctx, arg_th_memidx *a) { REQUIRE_XTHEADMEMIDX(ctx); return gen_load_idx(ctx, a, MO_TESW, true); } static bool trans_th_lurhu(DisasContext *ctx, arg_th_memidx *a) { REQUIRE_XTHEADMEMIDX(ctx); return gen_load_idx(ctx, a, MO_TEUW, true); } static bool trans_th_lurb(DisasContext *ctx, arg_th_memidx *a) { REQUIRE_XTHEADMEMIDX(ctx); return gen_load_idx(ctx, a, MO_SB, true); } static bool trans_th_lurbu(DisasContext *ctx, arg_th_memidx *a) { REQUIRE_XTHEADMEMIDX(ctx); return gen_load_idx(ctx, a, MO_UB, true); } static bool trans_th_surd(DisasContext *ctx, arg_th_memidx *a) { REQUIRE_XTHEADMEMIDX(ctx); REQUIRE_64BIT(ctx); return gen_store_idx(ctx, a, MO_TESQ, true); } static bool trans_th_surw(DisasContext *ctx, arg_th_memidx *a) { REQUIRE_XTHEADMEMIDX(ctx); return gen_store_idx(ctx, a, MO_TESL, true); } static bool trans_th_surh(DisasContext *ctx, arg_th_memidx *a) { REQUIRE_XTHEADMEMIDX(ctx); return gen_store_idx(ctx, a, MO_TESW, true); } static bool trans_th_surb(DisasContext *ctx, arg_th_memidx *a) { REQUIRE_XTHEADMEMIDX(ctx); return gen_store_idx(ctx, a, MO_SB, true); } /* XTheadMemPair */ static bool gen_loadpair_tl(DisasContext *ctx, arg_th_pair *a, MemOp memop, int shamt) { if (a->rs == a->rd1 || a->rs == a->rd2 || a->rd1 == a->rd2) { return false; } TCGv t1 = tcg_temp_new(); TCGv t2 = tcg_temp_new(); TCGv addr1 = tcg_temp_new(); TCGv addr2 = tcg_temp_new(); int imm = a->sh2 << shamt; addr1 = get_address(ctx, a->rs, imm); addr2 = get_address(ctx, a->rs, memop_size(memop) + imm); tcg_gen_qemu_ld_tl(t1, addr1, ctx->mem_idx, memop); tcg_gen_qemu_ld_tl(t2, addr2, ctx->mem_idx, memop); gen_set_gpr(ctx, a->rd1, t1); gen_set_gpr(ctx, a->rd2, t2); return true; } static bool trans_th_ldd(DisasContext *ctx, arg_th_pair *a) { REQUIRE_XTHEADMEMPAIR(ctx); REQUIRE_64BIT(ctx); return gen_loadpair_tl(ctx, a, MO_TESQ, 4); } static bool trans_th_lwd(DisasContext *ctx, arg_th_pair *a) { REQUIRE_XTHEADMEMPAIR(ctx); return gen_loadpair_tl(ctx, a, MO_TESL, 3); } static bool trans_th_lwud(DisasContext *ctx, arg_th_pair *a) { REQUIRE_XTHEADMEMPAIR(ctx); return gen_loadpair_tl(ctx, a, MO_TEUL, 3); } static bool gen_storepair_tl(DisasContext *ctx, arg_th_pair *a, MemOp memop, int shamt) { TCGv data1 = get_gpr(ctx, a->rd1, EXT_NONE); TCGv data2 = get_gpr(ctx, a->rd2, EXT_NONE); TCGv addr1 = tcg_temp_new(); TCGv addr2 = tcg_temp_new(); int imm = a->sh2 << shamt; addr1 = get_address(ctx, a->rs, imm); addr2 = get_address(ctx, a->rs, memop_size(memop) + imm); tcg_gen_qemu_st_tl(data1, addr1, ctx->mem_idx, memop); tcg_gen_qemu_st_tl(data2, addr2, ctx->mem_idx, memop); return true; } static bool trans_th_sdd(DisasContext *ctx, arg_th_pair *a) { REQUIRE_XTHEADMEMPAIR(ctx); REQUIRE_64BIT(ctx); return gen_storepair_tl(ctx, a, MO_TESQ, 4); } static bool trans_th_swd(DisasContext *ctx, arg_th_pair *a) { REQUIRE_XTHEADMEMPAIR(ctx); return gen_storepair_tl(ctx, a, MO_TESL, 3); } /* XTheadSync */ static bool trans_th_sfence_vmas(DisasContext *ctx, arg_th_sfence_vmas *a) { (void) a; REQUIRE_XTHEADSYNC(ctx); #ifndef CONFIG_USER_ONLY REQUIRE_PRIV_MS(ctx); gen_helper_tlb_flush_all(tcg_env); return true; #else return false; #endif } static void gen_th_sync_local(DisasContext *ctx) { /* * Emulate out-of-order barriers with pipeline flush * by exiting the translation block. */ gen_update_pc(ctx, ctx->cur_insn_len); tcg_gen_exit_tb(NULL, 0); ctx->base.is_jmp = DISAS_NORETURN; } static bool trans_th_sync(DisasContext *ctx, arg_th_sync *a) { (void) a; REQUIRE_XTHEADSYNC(ctx); REQUIRE_PRIV_MSU(ctx); /* * th.sync is an out-of-order barrier. */ gen_th_sync_local(ctx); return true; } static bool trans_th_sync_i(DisasContext *ctx, arg_th_sync_i *a) { (void) a; REQUIRE_XTHEADSYNC(ctx); REQUIRE_PRIV_MSU(ctx); /* * th.sync.i is th.sync plus pipeline flush. */ gen_th_sync_local(ctx); return true; } static bool trans_th_sync_is(DisasContext *ctx, arg_th_sync_is *a) { /* This instruction has the same behaviour like th.sync.i. */ return trans_th_sync_i(ctx, a); } static bool trans_th_sync_s(DisasContext *ctx, arg_th_sync_s *a) { /* This instruction has the same behaviour like th.sync. */ return trans_th_sync(ctx, a); }