/* * Basic macros to emit x86 instructions and some utils * Copyright (C) 2008,2009,2010 notaz * Copyright (C) 2019 kub * * This work is licensed under the terms of MAME license. * See COPYING file in the top-level directory. * * note: * temp registers must be eax-edx due to use of SETcc and r/w 8/16. * note about silly things like emith_eor_r_r_r: * these are here because the compiler was designed * for ARM as it's primary target. */ #include enum { xAX = 0, xCX, xDX, xBX, xSP, xBP, xSI, xDI, // x86-64,i386 common xR8, xR9, xR10, xR11, xR12, xR13, xR14, xR15 }; // x86-64 only #define CONTEXT_REG xBP #define RET_REG xAX #define ICOND_JO 0x00 #define ICOND_JNO 0x01 #define ICOND_JB 0x02 #define ICOND_JAE 0x03 #define ICOND_JE 0x04 #define ICOND_JNE 0x05 #define ICOND_JBE 0x06 #define ICOND_JA 0x07 #define ICOND_JS 0x08 #define ICOND_JNS 0x09 #define ICOND_JL 0x0c #define ICOND_JGE 0x0d #define ICOND_JLE 0x0e #define ICOND_JG 0x0f #define IOP_JMP 0xeb // unified conditions (we just use rel8 jump instructions for x86) #define DCOND_EQ ICOND_JE #define DCOND_NE ICOND_JNE #define DCOND_MI ICOND_JS // MInus #define DCOND_PL ICOND_JNS // PLus or zero #define DCOND_HI ICOND_JA // higher (unsigned) #define DCOND_HS ICOND_JAE // higher || same (unsigned) #define DCOND_LO ICOND_JB // lower (unsigned) #define DCOND_LS ICOND_JBE // lower || same (unsigned) #define DCOND_GE ICOND_JGE // greater || equal (signed) #define DCOND_GT ICOND_JG // greater (signed) #define DCOND_LE ICOND_JLE // less || equal (signed) #define DCOND_LT ICOND_JL // less (signed) #define DCOND_VS ICOND_JO // oVerflow Set #define DCOND_VC ICOND_JNO // oVerflow Clear #define DCOND_CS ICOND_JB // carry set #define DCOND_CC ICOND_JAE // carry clear #define EMIT_PTR(ptr, val, type) \ *(type *)(ptr) = val #define EMIT(val, type) do { \ EMIT_PTR(tcache_ptr, val, type); \ tcache_ptr += sizeof(type); \ } while (0) #define EMIT_OP(op) do { \ COUNT_OP; \ if ((op) > 0xff) EMIT((op) >> 8, u8); \ EMIT((u8)(op), u8); \ } while (0) #define EMIT_MODRM(mod, r, rm) do { \ assert((mod) < 4u); \ assert((r) < 8u); \ assert((rm) < 8u); \ EMIT(((mod)<<6) | ((r)<<3) | (rm), u8); \ } while (0) #define EMIT_SIB(scale, index, base) do { \ assert((scale) < 4u); \ assert((index) < 8u); \ assert((base) < 8u); \ EMIT(((scale)<<6) | ((index)<<3) | (base), u8); \ } while (0) #define EMIT_SIB64(scale, index, base) \ EMIT_SIB(scale, (index) & ~8u, (base) & ~8u) #define EMIT_REX(w,r,x,b) \ EMIT(0x40 | ((w)<<3) | ((r)<<2) | ((x)<<1) | (b), u8) #define EMIT_OP_MODRM(op,mod,r,rm) do { \ EMIT_OP(op); \ EMIT_MODRM(mod, (r), rm); \ } while (0) // 64bit friendly, rm when everything is converted #define EMIT_OP_MODRM64(op, mod, r, rm) \ EMIT_OP_MODRM(op, mod, (r) & ~8u, (rm) & ~8u) #define JMP8_POS(ptr) \ ptr = tcache_ptr; \ tcache_ptr += 2 #define JMP8_EMIT(op, ptr) \ EMIT_PTR(ptr, 0x70|(op), u8); \ EMIT_PTR(ptr + 1, (tcache_ptr - (ptr+2)), u8) #define JMP8_EMIT_NC(ptr) \ EMIT_PTR(ptr, IOP_JMP, u8); \ EMIT_PTR(ptr + 1, (tcache_ptr - (ptr+2)), u8) // _r_r #define emith_move_r_r(dst, src) do {\ EMIT_REX_IF(0, dst, src); \ EMIT_OP_MODRM64(0x8b, 3, dst, src); \ } while (0) #define emith_move_r_r_ptr(dst, src) do { \ EMIT_REX_IF(1, dst, src); \ EMIT_OP_MODRM64(0x8b, 3, dst, src); \ } while (0) #define emith_add_r_r(d, s) do { \ EMIT_REX_IF(0, s, d); \ EMIT_OP_MODRM64(0x01, 3, s, d); \ } while (0) #define emith_add_r_r_ptr(d, s) do { \ EMIT_REX_IF(1, s, d); \ EMIT_OP_MODRM64(0x01, 3, s, d); \ } while (0) #define emith_sub_r_r(d, s) do {\ EMIT_REX_IF(0, s, d); \ EMIT_OP_MODRM64(0x29, 3, s, d); \ } while (0) #define emith_adc_r_r(d, s) do { \ EMIT_REX_IF(0, s, d); \ EMIT_OP_MODRM64(0x11, 3, s, d); \ } while (0) #define emith_sbc_r_r(d, s) do { \ EMIT_REX_IF(0, s, d); \ EMIT_OP_MODRM64(0x19, 3, s, d); /* SBB */ \ } while (0) #define emith_or_r_r(d, s) do { \ EMIT_REX_IF(0, s, d); \ EMIT_OP_MODRM64(0x09, 3, s, d); \ } while (0) #define emith_and_r_r(d, s) do { \ EMIT_REX_IF(0, s, d); \ EMIT_OP_MODRM64(0x21, 3, s, d); \ } while (0) #define emith_eor_r_r(d, s) do { \ EMIT_REX_IF(0, s, d); \ EMIT_OP_MODRM64(0x31, 3, s, d); /* XOR */ \ } while (0) #define emith_tst_r_r(d, s) do { \ EMIT_REX_IF(0, s, d); \ EMIT_OP_MODRM64(0x85, 3, s, d); /* TEST */ \ } while (0) #define emith_tst_r_r_ptr(d, s) do { \ EMIT_REX_IF(1, s, d); \ EMIT_OP_MODRM64(0x85, 3, s, d); /* TEST */ \ } while (0) #define emith_cmp_r_r(d, s) do { \ EMIT_REX_IF(0, s, d); \ EMIT_OP_MODRM64(0x39, 3, s, d); \ } while (0) // fake teq - test equivalence - get_flags(d ^ s) #define emith_teq_r_r(d, s) do { \ emith_push(d); \ emith_eor_r_r(d, s); \ emith_pop(d); \ } while (0) #define emith_mvn_r_r(d, s) do { \ if (d != s) \ emith_move_r_r(d, s); \ EMIT_REX_IF(0, 0, d); \ EMIT_OP_MODRM64(0xf7, 3, 2, d); /* NOT d */ \ } while (0) #define emith_negc_r_r(d, s) do { \ int tmp_ = rcache_get_tmp(); \ emith_move_r_imm(tmp_, 0); \ emith_sbc_r_r(tmp_, s); \ emith_move_r_r(d, tmp_); \ rcache_free_tmp(tmp_); \ } while (0) #define emith_neg_r_r(d, s) do { \ if (d != s) \ emith_move_r_r(d, s); \ EMIT_REX_IF(0, 0, d); \ EMIT_OP_MODRM64(0xf7, 3, 3, d); /* NEG d */ \ } while (0) // _r_r_r #define emith_add_r_r_r(d, s1, s2) do { \ if (d == s1) { \ emith_add_r_r(d, s2); \ } else if (d == s2) { \ emith_add_r_r(d, s1); \ } else { \ emith_move_r_r(d, s1); \ emith_add_r_r(d, s2); \ } \ } while (0) #define emith_add_r_r_r_ptr(d, s1, s2) do { \ if (d == s1) { \ emith_add_r_r_ptr(d, s2); \ } else if (d == s2) { \ emith_add_r_r_ptr(d, s1); \ } else { \ emith_move_r_r_ptr(d, s1); \ emith_add_r_r_ptr(d, s2); \ } \ } while (0) #define emith_sub_r_r_r(d, s1, s2) do { \ if (d == s1) { \ emith_sub_r_r(d, s2); \ } else if (d == s2) { \ emith_sub_r_r(d, s1); \ } else { \ emith_move_r_r(d, s1); \ emith_sub_r_r(d, s2); \ } \ } while (0) #define emith_adc_r_r_r(d, s1, s2) do { \ if (d == s1) { \ emith_adc_r_r(d, s2); \ } else if (d == s2) { \ emith_adc_r_r(d, s1); \ } else { \ emith_move_r_r(d, s1); \ emith_adc_r_r(d, s2); \ } \ } while (0) #define emith_sbc_r_r_r(d, s1, s2) do { \ if (d == s1) { \ emith_sbc_r_r(d, s2); \ } else if (d == s2) { \ emith_sbc_r_r(d, s1); \ } else { \ emith_move_r_r(d, s1); \ emith_sbc_r_r(d, s2); \ } \ } while (0) #define emith_and_r_r_r(d, s1, s2) do { \ if (d == s1) { \ emith_and_r_r(d, s2); \ } else if (d == s2) { \ emith_and_r_r(d, s1); \ } else { \ emith_move_r_r(d, s1); \ emith_and_r_r(d, s2); \ } \ } while (0) #define emith_or_r_r_r(d, s1, s2) do { \ if (d == s1) { \ emith_or_r_r(d, s2); \ } else if (d == s2) { \ emith_or_r_r(d, s1); \ } else { \ emith_move_r_r(d, s1); \ emith_or_r_r(d, s2); \ } \ } while (0) #define emith_eor_r_r_r(d, s1, s2) do { \ if (d == s1) { \ emith_eor_r_r(d, s2); \ } else if (d == s2) { \ emith_eor_r_r(d, s1); \ } else { \ emith_move_r_r(d, s1); \ emith_eor_r_r(d, s2); \ } \ } while (0) // _r_r_r_shift #define emith_add_r_r_r_lsl(d, s1, s2, lslimm) do { \ if (lslimm) { \ int tmp_ = rcache_get_tmp(); \ emith_lsl(tmp_, s2, lslimm); \ emith_add_r_r_r(d, s1, tmp_); \ rcache_free_tmp(tmp_); \ } else emith_add_r_r_r(d, s1, s2); \ } while (0) #define emith_add_r_r_r_lsl_ptr(d, s1, s2, lslimm) do { \ if (lslimm) { \ int tmp_ = rcache_get_tmp(); \ emith_lsl(tmp_, s2, lslimm); \ emith_add_r_r_r_ptr(d, s1, tmp_); \ rcache_free_tmp(tmp_); \ } else emith_add_r_r_r_ptr(d, s1, s2); \ } while (0) #define emith_add_r_r_r_lsr(d, s1, s2, lsrimm) do { \ if (lsrimm) { \ int tmp_ = rcache_get_tmp(); \ emith_lsr(tmp_, s2, lsrimm); \ emith_add_r_r_r(d, s1, tmp_); \ rcache_free_tmp(tmp_); \ } else emith_add_r_r_r(d, s1, s2); \ } while (0) #define emith_sub_r_r_r_lsl(d, s1, s2, lslimm) do { \ if (lslimm) { \ int tmp_ = rcache_get_tmp(); \ emith_lsl(tmp_, s2, lslimm); \ emith_sub_r_r_r(d, s1, tmp_); \ rcache_free_tmp(tmp_); \ } else emith_sub_r_r_r(d, s1, s2); \ } while (0) #define emith_or_r_r_r_lsl(d, s1, s2, lslimm) do { \ if (lslimm) { \ int tmp_ = rcache_get_tmp(); \ emith_lsl(tmp_, s2, lslimm); \ emith_or_r_r_r(d, s1, tmp_); \ rcache_free_tmp(tmp_); \ } else emith_or_r_r_r(d, s1, s2); \ } while (0) #define emith_or_r_r_r_lsr(d, s1, s2, lsrimm) do { \ if (lsrimm) { \ int tmp_ = rcache_get_tmp(); \ emith_lsr(tmp_, s2, lsrimm); \ emith_or_r_r_r(d, s1, tmp_); \ rcache_free_tmp(tmp_); \ } else emith_or_r_r_r(d, s1, s2); \ } while (0) // _r_r_shift #define emith_or_r_r_lsl(d, s, lslimm) \ emith_or_r_r_r_lsl(d, d, s, lslimm) #define emith_or_r_r_lsr(d, s, lsrimm) \ emith_or_r_r_r_lsr(d, d, s, lsrimm) #define emith_eor_r_r_lsl(d, s, lslimm) do { \ if (lslimm) { \ int tmp_ = rcache_get_tmp(); \ emith_lsl(tmp_, s, lslimm); \ emith_eor_r_r(d, tmp_); \ rcache_free_tmp(tmp_); \ } else emith_eor_r_r(d, s); \ } while (0) #define emith_eor_r_r_lsr(d, s, lsrimm) do { \ if (lsrimm) { \ int tmp_ = rcache_get_tmp(); \ emith_lsr(tmp_, s, lsrimm); \ emith_eor_r_r(d, tmp_); \ rcache_free_tmp(tmp_); \ } else emith_eor_r_r(d, s); \ } while (0) // _r_imm #define emith_move_r_imm(r, imm) do { \ EMIT_REX_IF(0, 0, r); \ EMIT_OP(0xb8 + ((r)&7)); \ EMIT(imm, u32); \ } while (0) #define emith_move_r_ptr_imm(r, imm) do { \ if ((uintptr_t)(imm) <= UINT32_MAX) \ emith_move_r_imm(r, (uintptr_t)(imm)); \ else { \ EMIT_REX_IF(1, 0, r); \ EMIT_OP(0xb8 + ((r)&7)); \ EMIT((uintptr_t)(imm), uint64_t); \ } \ } while (0) #define emith_move_r_imm_s8_patchable(r, imm) do { \ EMIT_REX_IF(0, 0, r); \ EMIT_OP(0xb8 + ((r)&7)); \ EMIT((s8)(imm), u32); \ } while (0) #define emith_move_r_imm_s8_patch(ptr, imm) do { \ u8 *ptr_ = ptr; \ while ((*ptr_ & 0xf8) != 0xb8) ptr_++; \ EMIT_PTR(ptr_ + 1, (s8)(imm), u32); \ } while (0) #define emith_arith_r_imm(op, r, imm) do { \ EMIT_REX_IF(0, 0, r); \ EMIT_OP_MODRM64(0x81, 3, op, r); \ EMIT(imm, u32); \ } while (0) #define emith_add_r_imm(r, imm) \ emith_arith_r_imm(0, r, imm) #define emith_or_r_imm(r, imm) \ emith_arith_r_imm(1, r, imm) #define emith_adc_r_imm(r, imm) \ emith_arith_r_imm(2, r, imm) #define emith_sbc_r_imm(r, imm) \ emith_arith_r_imm(3, r, imm) // sbb #define emith_and_r_imm(r, imm) \ emith_arith_r_imm(4, r, imm) #define emith_sub_r_imm(r, imm) \ emith_arith_r_imm(5, r, imm) #define emith_eor_r_imm(r, imm) \ emith_arith_r_imm(6, r, imm) #define emith_cmp_r_imm(r, imm) \ emith_arith_r_imm(7, r, imm) #define emith_eor_r_imm_ptr(r, imm) do { \ EMIT_REX_IF(1, 0, r); \ EMIT_OP_MODRM64(0x81, 3, 6, r); \ EMIT(imm, u32); \ } while (0) #define emith_tst_r_imm(r, imm) do { \ EMIT_REX_IF(0, 0, r); \ EMIT_OP_MODRM64(0xf7, 3, 0, r); \ EMIT(imm, u32); \ } while (0) // fake #define emith_bic_r_imm(r, imm) \ emith_arith_r_imm(4, r, ~(imm)) // fake conditionals (using SJMP instead) #define emith_move_r_imm_c(cond, r, imm) \ emith_move_r_imm(r, imm) #define emith_add_r_imm_c(cond, r, imm) \ emith_add_r_imm(r, imm) #define emith_sub_r_imm_c(cond, r, imm) \ emith_sub_r_imm(r, imm) #define emith_or_r_imm_c(cond, r, imm) \ emith_or_r_imm(r, imm) #define emith_eor_r_imm_c(cond, r, imm) \ emith_eor_r_imm(r, imm) #define emith_eor_r_imm_ptr_c(cond, r, imm) \ emith_eor_r_imm_ptr(r, imm) #define emith_bic_r_imm_c(cond, r, imm) \ emith_bic_r_imm(r, imm) #define emith_tst_r_imm_c(cond, r, imm) \ emith_tst_r_imm(r, imm) #define emith_move_r_r_ptr_c(cond, d, s) \ emith_move_r_r_ptr(d, s) #define emith_ror_c(cond, d, s, cnt) \ emith_ror(d, s, cnt) #define emith_and_r_r_c(cond, d, s) \ emith_and_r_r(d, s) #define emith_add_r_r_imm_c(cond, d, s, imm) \ emith_add_r_r_imm(d, s, imm) #define emith_sub_r_r_imm_c(cond, d, s, imm) \ emith_sub_r_r_imm(d, s, imm) #define emith_read8_r_r_r_c(cond, r, rs, rm) \ emith_read8_r_r_r(r, rs, rm) #define emith_read8s_r_r_r_c(cond, r, rs, rm) \ emith_read8s_r_r_r(r, rs, rm) #define emith_read16_r_r_r_c(cond, r, rs, rm) \ emith_read16_r_r_r(r, rs, rm) #define emith_read16s_r_r_r_c(cond, r, rs, rm) \ emith_read16s_r_r_r(r, rs, rm) #define emith_read_r_r_r_c(cond, r, rs, rm) \ emith_read_r_r_r(r, rs, rm) #define emith_read_r_r_offs_c(cond, r, rs, offs) \ emith_read_r_r_offs(r, rs, offs) #define emith_read_r_r_offs_ptr_c(cond, r, rs, offs) \ emith_read_r_r_offs_ptr(r, rs, offs) #define emith_write_r_r_offs_c(cond, r, rs, offs) \ emith_write_r_r_offs(r, rs, offs) #define emith_write_r_r_offs_ptr_c(cond, r, rs, offs) \ emith_write_r_r_offs_ptr(r, rs, offs) #define emith_read8_r_r_offs_c(cond, r, rs, offs) \ emith_read8_r_r_offs(r, rs, offs) #define emith_write8_r_r_offs_c(cond, r, rs, offs) \ emith_write8_r_r_offs(r, rs, offs) #define emith_read16_r_r_offs_c(cond, r, rs, offs) \ emith_read16_r_r_offs(r, rs, offs) #define emith_write16_r_r_offs_c(cond, r, rs, offs) \ emith_write16_r_r_offs(r, rs, offs) #define emith_jump_reg_c(cond, r) \ emith_jump_reg(r) #define emith_jump_ctx_c(cond, offs) \ emith_jump_ctx(offs) #define emith_ret_c(cond) \ emith_ret() // _r_r_imm - use lea #define emith_add_r_r_imm(d, s, imm) do { \ EMIT_REX_IF(0, d, s); \ emith_deref_modrm(0x8d, 2, d, s); \ EMIT(imm, s32); \ } while (0) #define emith_add_r_r_ptr_imm(d, s, imm) do { \ EMIT_REX_IF(1, d, s); \ emith_deref_modrm(0x8d, 2, d, s); \ EMIT(imm, s32); \ } while (0) #define emith_sub_r_r_imm(d, s, imm) do { \ if (d != s) \ emith_move_r_r(d, s); \ if ((s32)(imm) != 0) \ emith_sub_r_imm(d, imm); \ } while (0) #define emith_and_r_r_imm(d, s, imm) do { \ if (d != s) \ emith_move_r_r(d, s); \ if ((s32)(imm) != -1) \ emith_and_r_imm(d, imm); \ } while (0) #define emith_or_r_r_imm(d, s, imm) do { \ if (d != s) \ emith_move_r_r(d, s); \ if ((s32)(imm) != 0) \ emith_or_r_imm(d, imm); \ } while (0) #define emith_eor_r_r_imm(d, s, imm) do { \ if (d != s) \ emith_move_r_r(d, s); \ if ((s32)(imm) != 0) \ emith_eor_r_imm(d, imm); \ } while (0) // shift #define emith_shift(op, d, s, cnt) do { \ if (d != s) \ emith_move_r_r(d, s); \ EMIT_REX_IF(0, 0, d); \ EMIT_OP_MODRM64(0xc1, 3, op, d); \ EMIT(cnt, u8); \ } while (0) #define emith_lsl(d, s, cnt) \ emith_shift(4, d, s, cnt) #define emith_lsr(d, s, cnt) \ emith_shift(5, d, s, cnt) #define emith_asr(d, s, cnt) \ emith_shift(7, d, s, cnt) #define emith_rol(d, s, cnt) \ emith_shift(0, d, s, cnt) #define emith_ror(d, s, cnt) \ emith_shift(1, d, s, cnt) #define emith_rolc(r) do { \ EMIT_REX_IF(0, 0, r); \ EMIT_OP_MODRM64(0xd1, 3, 2, r); \ } while (0) #define emith_rorc(r) do { \ EMIT_REX_IF(0, 0, r); \ EMIT_OP_MODRM64(0xd1, 3, 3, r); \ } while (0) // misc #define emith_push(r) do { \ EMIT_REX_IF(0, 0, r); \ EMIT_OP(0x50 + ((r)&7)); \ } while (0) #define emith_push_imm(imm) do { \ EMIT_OP(0x68); \ EMIT(imm, u32); \ } while (0) #define emith_pop(r) do { \ EMIT_REX_IF(0, 0, r); \ EMIT_OP(0x58 + ((r)&7)); \ } while (0) #define emith_neg_r(r) do { \ EMIT_REX_IF(0, 0, r); \ EMIT_OP_MODRM64(0xf7, 3, 3, r); \ } while (0) #define emith_clear_msb(d, s, count) do { \ u32 t = (u32)-1; \ t >>= count; \ if (d != s) \ emith_move_r_r(d, s); \ emith_and_r_imm(d, t); \ } while (0) #define emith_clear_msb_c(cond, d, s, count) do { \ (void)(cond); \ emith_clear_msb(d, s, count); \ } while (0) #define emith_sext(d, s, bits) do { \ emith_lsl(d, s, 32 - (bits)); \ emith_asr(d, d, 32 - (bits)); \ } while (0) #define emith_setc(r) do { \ assert(is_abcdx(r)); \ EMIT_REX_IF(0, 0, r); \ EMIT_OP_MODRM64(0x0f92, 3, 0, r); /* SETC r */ \ } while (0) // XXX: stupid mess #define emith_mul_(op, dlo, dhi, s1, s2) do { \ int rmr; \ if (dlo != xAX && dhi != xAX && rcache_is_hreg_used(xAX)) \ emith_push(xAX); \ if (dlo != xDX && dhi != xDX && rcache_is_hreg_used(xDX)) \ emith_push(xDX); \ if ((s1) == xAX) \ rmr = s2; \ else if ((s2) == xAX) \ rmr = s1; \ else { \ emith_move_r_r(xAX, s1); \ rmr = s2; \ } \ EMIT_REX_IF(0, 0, rmr); \ EMIT_OP_MODRM64(0xf7, 3, op, rmr); /* xMUL rmr */ \ if (dlo != xAX) { \ EMIT_REX_IF(0, 0, dlo); \ EMIT_OP(0x90 + ((dlo)&7)); /* XCHG eax, dlo */ \ } \ if (dhi != xDX && dhi != -1 && !(dhi == xAX && dlo == xDX)) \ emith_move_r_r(dhi, (dlo == xDX ? xAX : xDX)); \ if (dlo != xDX && dhi != xDX && rcache_is_hreg_used(xDX)) \ emith_pop(xDX); \ if (dlo != xAX && dhi != xAX && rcache_is_hreg_used(xAX)) \ emith_pop(xAX); \ } while (0) #define emith_mul_u64(dlo, dhi, s1, s2) \ emith_mul_(4, dlo, dhi, s1, s2) /* MUL */ #define emith_mul_s64(dlo, dhi, s1, s2) \ emith_mul_(5, dlo, dhi, s1, s2) /* IMUL */ #define emith_mul(d, s1, s2) do { \ if (d == s1) { \ EMIT_REX_IF(0, d, s2); \ EMIT_OP_MODRM64(0x0faf, 3, d, s2); \ } else if (d == s2) { \ EMIT_REX_IF(0, d, s1); \ EMIT_OP_MODRM64(0x0faf, 3, d, s1); \ } else { \ emith_move_r_r(d, s1); \ EMIT_REX_IF(0, d, s2); \ EMIT_OP_MODRM64(0x0faf, 3, d, s2); \ } \ } while (0) // (dlo,dhi) += signed(s1) * signed(s2) #define emith_mula_s64(dlo, dhi, s1, s2) do { \ emith_push(dhi); \ emith_push(dlo); \ emith_mul_(5, dlo, dhi, s1, s2); \ EMIT_REX_IF(0, dlo, xSP); \ emith_deref_modrm(0x03, 0, dlo, xSP); /* add dlo, [xsp] */ \ EMIT_REX_IF(0, dhi, xSP); \ emith_deref_modrm(0x13, 1, dhi, xSP); /* adc dhi, [xsp+{4,8}] */ \ EMIT(sizeof(void *), u8); \ emith_add_r_r_ptr_imm(xSP, xSP, sizeof(void *) * 2); \ } while (0) // "flag" instructions are the same #define emith_adcf_r_imm emith_adc_r_imm #define emith_subf_r_imm emith_sub_r_imm #define emith_addf_r_r emith_add_r_r #define emith_subf_r_r emith_sub_r_r #define emith_adcf_r_r emith_adc_r_r #define emith_sbcf_r_r emith_sbc_r_r #define emith_eorf_r_r emith_eor_r_r #define emith_negcf_r_r emith_negc_r_r #define emith_subf_r_r_imm emith_sub_r_r_imm #define emith_addf_r_r_r emith_add_r_r_r #define emith_subf_r_r_r emith_sub_r_r_r #define emith_adcf_r_r_r emith_adc_r_r_r #define emith_sbcf_r_r_r emith_sbc_r_r_r #define emith_eorf_r_r_r emith_eor_r_r_r #define emith_addf_r_r_r_lsr emith_add_r_r_r_lsr #define emith_lslf emith_lsl #define emith_lsrf emith_lsr #define emith_asrf emith_asr #define emith_rolf emith_rol #define emith_rorf emith_ror #define emith_rolcf emith_rolc #define emith_rorcf emith_rorc #define emith_deref_modrm(op, m, r, rs) do { \ if (((rs) & 7) == 5 && m == 0) { /* xBP,xR13 not in mod 0, use mod 1 */\ EMIT_OP_MODRM64(op, 1, r, rs); \ EMIT(0, u8); \ } else if (((rs) & 7) == 4) { /* xSP,xR12 must use SIB */ \ EMIT_OP_MODRM64(op, m, r, 4); \ EMIT_SIB64(0, 4, rs); \ } else \ EMIT_OP_MODRM64(op, m, r, rs); \ } while (0) #define emith_deref_op(op, r, rs, offs) do { \ /* mov r <-> [ebp+#offs] */ \ if ((offs) == 0) { \ emith_deref_modrm(op, 0, r, rs); \ } else if (abs(offs) >= 0x80) { \ emith_deref_modrm(op, 2, r, rs); \ EMIT(offs, u32); \ } else { \ emith_deref_modrm(op, 1, r, rs); \ EMIT((u8)offs, u8); \ } \ } while (0) #define is_abcdx(r) !((r) & ~0x3) #define emith_read_r_r_offs(r, rs, offs) do { \ EMIT_REX_IF(0, r, rs); \ emith_deref_op(0x8b, r, rs, offs); \ } while (0) #define emith_read_r_r_offs_ptr(r, rs, offs) do { \ EMIT_REX_IF(1, r, rs); \ emith_deref_op(0x8b, r, rs, offs); \ } while (0) #define emith_write_r_r_offs(r, rs, offs) do { \ EMIT_REX_IF(0, r, rs); \ emith_deref_op(0x89, r, rs, offs); \ } while (0) #define emith_write_r_r_offs_ptr(r, rs, offs) do { \ EMIT_REX_IF(1, r, rs); \ emith_deref_op(0x89, r, rs, offs); \ } while (0) #define emith_read8_r_r_offs(r, rs, offs) do { \ EMIT_REX_IF(0, r, rs); \ emith_deref_op(0x0fb6, r, rs, offs); \ } while (0) #define emith_read8s_r_r_offs(r, rs, offs) do { \ EMIT_REX_IF(0, r, rs); \ emith_deref_op(0x0fbe, r, rs, offs); \ } while (0) #define emith_write8_r_r_offs(r, rs, offs) do {\ EMIT_REX_IF(0, r, rs); \ emith_deref_op(0x88, r, rs, offs); \ } while (0) #define emith_read16_r_r_offs(r, rs, offs) do { \ EMIT_REX_IF(0, r, rs); \ emith_deref_op(0x0fb7, r, rs, offs); \ } while (0) #define emith_read16s_r_r_offs(r, rs, offs) do { \ EMIT_REX_IF(0, r, rs); \ emith_deref_op(0x0fbf, r, rs, offs); \ } while (0) #define emith_write16_r_r_offs(r, rs, offs) do { \ EMIT(0x66, u8); /* Intel SDM Vol 2a: REX must be closest to opcode */ \ EMIT_REX_IF(0, r, rs); \ emith_deref_op(0x89, r, rs, offs); \ } while (0) #define emith_read8_r_r_r(r, rs, rm) do { \ EMIT_XREX_IF(0, r, rm, rs); \ EMIT_OP_MODRM64(0x0fb6, 0, r, 4); \ EMIT_SIB64(0, rs, rm); /* mov r, [rm + rs * 1] */ \ } while (0) #define emith_read8s_r_r_r(r, rs, rm) do { \ EMIT_XREX_IF(0, r, rm, rs); \ EMIT_OP_MODRM64(0x0fbe, 0, r, 4); \ EMIT_SIB64(0, rs, rm); /* mov r, [rm + rs * 1] */ \ } while (0) #define emith_read16_r_r_r(r, rs, rm) do { \ EMIT_XREX_IF(0, r, rm, rs); \ EMIT_OP_MODRM64(0x0fb7, 0, r, 4); \ EMIT_SIB64(0, rs, rm); /* mov r, [rm + rs * 1] */ \ } while (0) #define emith_read16s_r_r_r(r, rs, rm) do { \ EMIT_XREX_IF(0, r, rm, rs); \ EMIT_OP_MODRM64(0x0fbf, 0, r, 4); \ EMIT_SIB64(0, rs, rm); /* mov r, [rm + rs * 1] */ \ } while (0) #define emith_read_r_r_r(r, rs, rm) do { \ EMIT_XREX_IF(0, r, rm, rs); \ EMIT_OP_MODRM64(0x8b, 0, r, 4); \ EMIT_SIB64(0, rs, rm); /* mov r, [rm + rs * 1] */ \ } while (0) #define emith_read_r_r_r_ptr(r, rs, rm) do { \ EMIT_XREX_IF(1, r, rm, rs); \ EMIT_OP_MODRM64(0x8b, 0, r, 4); \ EMIT_SIB64(0, rs, rm); /* mov r, [rm + rs * 1] */ \ } while (0) #define emith_write_r_r_r(r, rs, rm) do { \ EMIT_XREX_IF(0, r, rm, rs); \ EMIT_OP_MODRM64(0x89, 0, r, 4); \ EMIT_SIB64(0, rs, rm); /* mov [rm + rs * 1], r */ \ } while (0) #define emith_write_r_r_r_ptr(r, rs, rm) do { \ EMIT_XREX_IF(1, r, rm, rs); \ EMIT_OP_MODRM64(0x89, 0, r, 4); \ EMIT_SIB64(0, rs, rm); /* mov [rm + rs * 1], r */ \ } while (0) #define emith_ctx_read(r, offs) \ emith_read_r_r_offs(r, CONTEXT_REG, offs) #define emith_ctx_read_c(cond, r, offs) \ emith_ctx_read(r, offs) #define emith_ctx_read_ptr(r, offs) do { \ EMIT_REX_IF(1, r, CONTEXT_REG); \ emith_deref_op(0x8b, r, CONTEXT_REG, offs); \ } while (0) #define emith_ctx_write(r, offs) \ emith_write_r_r_offs(r, CONTEXT_REG, offs) #define emith_ctx_read_multiple(r, offs, cnt, tmpr) do { \ int r_ = r, offs_ = offs, cnt_ = cnt; \ for (; cnt_ > 0; r_++, offs_ += 4, cnt_--) \ emith_ctx_read(r_, offs_); \ } while (0) #define emith_ctx_write_multiple(r, offs, cnt, tmpr) do { \ int r_ = r, offs_ = offs, cnt_ = cnt; \ for (; cnt_ > 0; r_++, offs_ += 4, cnt_--) \ emith_ctx_write(r_, offs_); \ } while (0) #define emith_ret_to_ctx(offs) do { \ int tmp_ = rcache_get_tmp(); \ emith_pop(tmp_); \ emith_ctx_write(tmp_, offs); \ rcache_free_tmp(tmp_); \ } while (0) #define emith_jump(ptr) do { \ u32 disp = (u8 *)(ptr) - ((u8 *)tcache_ptr + 5); \ EMIT_OP(0xe9); \ EMIT(disp, u32); \ } while (0) #define emith_jump_patchable(target) \ emith_jump(target) #define emith_jump_cond(cond, ptr) do { \ u32 disp = (u8 *)(ptr) - ((u8 *)tcache_ptr + 6); \ EMIT_OP(0x0f80 | (cond)); \ EMIT(disp, u32); \ } while (0) #define emith_jump_cond_inrange(ptr) !0 #define emith_jump_cond_patchable(cond, target) \ emith_jump_cond(cond, target) #define emith_jump_patch(ptr, target, pos) do { \ u32 disp_ = (u8 *)(target) - ((u8 *)(ptr) + 4); \ u32 offs_ = (*(u8 *)(ptr) == 0x0f) ? 2 : 1; \ EMIT_PTR((u8 *)(ptr) + offs_, disp_ - offs_, u32); \ if ((void *)(pos) != NULL) *(u8 **)(pos) = (u8 *)ptr + offs_; \ } while (0) #define emith_jump_patch_size() 4 #define emith_jump_patch_inrange(ptr, target) !0 #define emith_jump_at(ptr, target) do { \ u32 disp_ = (u8 *)(target) - ((u8 *)(ptr) + 5); \ EMIT_PTR(ptr, 0xe9, u8); \ EMIT_PTR((u8 *)(ptr) + 1, disp_, u32); \ } while (0) #define emith_jump_at_size() 5 #define emith_call(ptr) do { \ u32 disp = (u8 *)(ptr) - ((u8 *)tcache_ptr + 5); \ EMIT_OP(0xe8); \ EMIT(disp, u32); \ } while (0) #define emith_call_cond(cond, ptr) \ emith_call(ptr) #define emith_call_reg(r) \ EMIT_OP_MODRM(0xff, 3, 2, r) #define emith_call_ctx(offs) do { \ EMIT_OP_MODRM(0xff, 2, 2, CONTEXT_REG); \ EMIT(offs, u32); \ } while (0) #define emith_call_cleanup() \ emith_add_r_r_ptr_imm(xSP, xSP, sizeof(void *)); // remove return addr #define emith_ret() \ EMIT_OP(0xc3) #define emith_add_r_ret(r) do { \ EMIT_REX_IF(1, r, xSP); \ emith_deref_modrm(0x03, 0, r, xSP); /* add r, [xsp] */ \ } while (0) #define emith_jump_reg(r) \ EMIT_OP_MODRM(0xff, 3, 4, r) #define emith_jump_ctx(offs) do { \ EMIT_OP_MODRM(0xff, 2, 4, CONTEXT_REG); \ EMIT(offs, u32); \ } while (0) #define emith_push_ret(r) do { \ int r_ = (r >= 0 ? r : xSI); \ emith_push(r_); /* always push to align */ \ emith_add_r_r_ptr_imm(xSP, xSP, -8*4); /* args shadow space */ \ } while (0) #define emith_pop_and_ret(r) do { \ int r_ = (r >= 0 ? r : xSI); \ emith_add_r_r_ptr_imm(xSP, xSP, 8*4); /* args shadow space */ \ emith_pop(r_); \ emith_ret(); \ } while (0) #define EMITH_JMP_START(cond) { \ u8 *cond_ptr; \ JMP8_POS(cond_ptr) #define EMITH_JMP_END(cond) \ JMP8_EMIT(cond, cond_ptr); \ } #define EMITH_JMP3_START(cond) { \ u8 *cond_ptr, *else_ptr; \ JMP8_POS(cond_ptr) #define EMITH_JMP3_MID(cond) \ JMP8_POS(else_ptr); \ JMP8_EMIT(cond, cond_ptr); #define EMITH_JMP3_END() \ JMP8_EMIT_NC(else_ptr); \ } // "simple" jump (no more then a few insns) // ARM will use conditional instructions here #define EMITH_SJMP_START EMITH_JMP_START #define EMITH_SJMP_END EMITH_JMP_END #define EMITH_SJMP3_START EMITH_JMP3_START #define EMITH_SJMP3_MID EMITH_JMP3_MID #define EMITH_SJMP3_END EMITH_JMP3_END #define EMITH_SJMP2_START(cond) \ EMITH_SJMP3_START(cond) #define EMITH_SJMP2_MID(cond) \ EMITH_SJMP3_MID(cond) #define EMITH_SJMP2_END(cond) \ EMITH_SJMP3_END() #define EMITH_HINT_COND(cond) /**/ #define emith_pass_arg_r(arg, reg) do { \ int rd = 7; \ host_arg2reg(rd, arg); \ emith_move_r_r_ptr(rd, reg); \ } while (0) #define emith_pass_arg_imm(arg, imm) do { \ int rd = 7; \ host_arg2reg(rd, arg); \ emith_move_r_imm(rd, imm); \ } while (0) #define host_instructions_updated(base, end) (void)(base),(void)(end) #define emith_update_cache() /**/ #define emith_rw_offs_max() 0xffffffff #ifdef __x86_64__ #define HOST_REGS 16 #define PTR_SCALE 3 #define EMIT_XREX_IF(w, r, rm, rs) do { \ int xr_ = (r) > 7 ? 1 : 0; \ int xb_ = (rm) > 7 ? 1 : 0; \ int xx_ = (rs) > 7 ? 1 : 0; \ if ((w) | xr_ | xx_ | xb_) \ EMIT_REX(w, xr_, xx_, xb_); \ } while (0) #define EMIT_REX_IF(w, r, rm) \ EMIT_XREX_IF(w, r, rm, 0) #ifndef _WIN32 // SystemV ABI conventions: // rbx,rbp,r12-r15 are preserved, rax,rcx,rdx,rsi,rdi,r8-r11 are temporaries // parameters in rdi,rsi,rdx,rcx,r8,r9, return values in rax,rdx #define PARAM_REGS { xDI, xSI, xDX, xCX, xR8, xR9 } #define PRESERVED_REGS { xR12, xR13, xR14, xR15, xBX, xBP } #define TEMPORARY_REGS { xAX, xR10, xR11 } #define STATIC_SH2_REGS { SHR_SR,xBX , SHR_R0,xR15 } #define host_arg2reg(rd, arg) \ switch (arg) { \ case 0: rd = xDI; break; \ case 1: rd = xSI; break; \ case 2: rd = xDX; break; \ default: rd = xCX; break; \ } #define emith_sh2_drc_entry() do { \ emith_push(xBX); \ emith_push(xBP); \ emith_push(xR12); \ emith_push(xR13); \ emith_push(xR14); \ emith_push(xR15); \ emith_push(xSI); /* to align */ \ } while (0) #define emith_sh2_drc_exit() do { \ emith_pop(xSI); \ emith_pop(xR15); \ emith_pop(xR14); \ emith_pop(xR13); \ emith_pop(xR12); \ emith_pop(xBP); \ emith_pop(xBX); \ emith_ret(); \ } while (0) #else // _WIN32 // M$ ABI conventions: // rbx,rbp,rsi,rdi,r12-r15 are preserved, rcx,rdx,rax,r8,r9,r10,r11 temporaries // parameters in rcx,rdx,r8,r9, return values in rax,rdx #define PARAM_REGS { xCX, xDX, xR8, xR9 } #define PRESERVED_REGS { xSI, xDI, xR12, xR13, xR14, xR15, xBX, xBP } #define TEMPORARY_REGS { xAX, xR10, xR11 } #define STATIC_SH2_REGS { SHR_SR,xBX , SHR_R0,xR15 , SH2_R0+1,xR14 } #define host_arg2reg(rd, arg) \ switch (arg) { \ case 0: rd = xCX; break; \ case 1: rd = xDX; break; \ case 2: rd = xR8; break; \ default: rd = xR9; break; \ } #define emith_sh2_drc_entry() do { \ emith_push(xBX); \ emith_push(xBP); \ emith_push(xR12); \ emith_push(xR13); \ emith_push(xR14); \ emith_push(xR15); \ emith_push(xSI); \ emith_push(xDI); \ emith_add_r_r_ptr_imm(xSP, xSP, -8*5); /* align + args shadow space */ \ } while (0) #define emith_sh2_drc_exit() do { \ emith_add_r_r_ptr_imm(xSP, xSP, 8*5); \ emith_pop(xDI); \ emith_pop(xSI); \ emith_pop(xR15); \ emith_pop(xR14); \ emith_pop(xR13); \ emith_pop(xR12); \ emith_pop(xBP); \ emith_pop(xBX); \ emith_ret(); \ } while (0) #endif // _WIN32 #else // !__x86_64__ #define HOST_REGS 8 #define PTR_SCALE 2 #define EMIT_REX_IF(w, r, rm) do { \ assert((u32)(r) < 8u); \ assert((u32)(rm) < 8u); \ } while (0) #define EMIT_XREX_IF(w, r, rs, rm) do { \ assert((u32)(r) < 8u); \ assert((u32)(rs) < 8u); \ assert((u32)(rm) < 8u); \ } while (0) // MS/SystemV ABI: ebx,esi,edi,ebp are preserved, eax,ecx,edx are temporaries // DRC uses REGPARM to pass upto 3 parameters in registers eax,ecx,edx. // To avoid conflicts with param passing ebx must be declared temp here. #define PARAM_REGS { xAX, xDX, xCX } #define PRESERVED_REGS { xSI, xDI, xBP } #define TEMPORARY_REGS { xBX } #define STATIC_SH2_REGS { SHR_SR,xDI , SHR_R0,xSI } #define host_arg2reg(rd, arg) \ switch (arg) { \ case 0: rd = xAX; break; \ case 1: rd = xDX; break; \ case 2: rd = xCX; break; \ default: rd = xBX; break; \ } #define emith_sh2_drc_entry() do { \ emith_push(xBX); \ emith_push(xBP); \ emith_push(xSI); \ emith_push(xDI); \ } while (0) #define emith_sh2_drc_exit() do { \ emith_pop(xDI); \ emith_pop(xSI); \ emith_pop(xBP); \ emith_pop(xBX); \ emith_ret(); \ } while (0) #endif #define emith_save_caller_regs(mask) do { \ int _c; u32 _m = mask & 0xfc7; /* AX, CX, DX, SI, DI, 8, 9, 10, 11 */ \ if (__builtin_parity(_m) == 1) _m |= 0x8; /* BX for ABI align */ \ for (_c = HOST_REGS-1; _m && _c >= 0; _m &= ~(1 << _c), _c--) \ if (_m & (1 << _c)) emith_push(_c); \ } while (0) #define emith_restore_caller_regs(mask) do { \ int _c; u32 _m = mask & 0xfc7; \ if (__builtin_parity(_m) == 1) _m |= 0x8; /* BX for ABI align */ \ for (_c = 0; _m && _c < HOST_REGS; _m &= ~(1 << _c), _c++) \ if (_m & (1 << _c)) emith_pop(_c); \ } while (0) #define emith_sh2_rcall(a, tab, func, mask) do { \ emith_lsr(mask, a, SH2_READ_SHIFT); \ EMIT_XREX_IF(1, tab, tab, mask); \ EMIT_OP_MODRM64(0x8d, 0, tab, 4); \ EMIT_SIB64(PTR_SCALE, mask, tab); /* lea tab, [tab + mask * {4,8}] */ \ EMIT_XREX_IF(1, tab, tab, mask); \ EMIT_OP_MODRM64(0x8d, 0, tab, 4); \ EMIT_SIB64(PTR_SCALE, mask, tab); /* lea tab, [tab + mask * {4,8}] */ \ EMIT_REX_IF(1, func, tab); \ emith_deref_modrm(0x8b, 0, func, tab); /* mov func, [tab] */ \ EMIT_REX_IF(0, mask, tab); \ emith_deref_modrm(0x8b, 1, mask, tab); \ EMIT(1 << PTR_SCALE, u8); /* mov mask, [tab + {4,8}] */ \ emith_add_r_r_ptr(func, func); \ } while (0) #define emith_sh2_wcall(a, val, tab, func) do { \ int arg2_; \ host_arg2reg(arg2_, 2); \ emith_lsr(func, a, SH2_WRITE_SHIFT); /* tmp = a >> WRT_SHIFT */ \ EMIT_XREX_IF(1, func, tab, func); \ EMIT_OP_MODRM64(0x8b, 0, func, 4); \ EMIT_SIB64(PTR_SCALE, func, tab); /* mov tmp, [tab + tmp * {4,8}] */ \ emith_move_r_r_ptr(arg2_, CONTEXT_REG); \ emith_jump_reg(func); \ } while (0) #define emith_sh2_dtbf_loop() do { \ u8 *jmp0; /* negative cycles check */ \ u8 *jmp1; /* unsinged overflow check */ \ int cr, rn; \ int tmp_ = rcache_get_tmp(); \ cr = rcache_get_reg(SHR_SR, RC_GR_RMW); \ rn = rcache_get_reg((op >> 8) & 0x0f, RC_GR_RMW);\ emith_sub_r_imm(rn, 1); \ emith_sub_r_imm(cr, (cycles+1) << 12); \ cycles = 0; \ emith_asr(tmp_, cr, 2+12); \ JMP8_POS(jmp0); /* no negative cycles */ \ emith_move_r_imm(tmp_, 0); \ JMP8_EMIT(ICOND_JNS, jmp0); \ emith_and_r_imm(cr, 0xffe); \ emith_subf_r_r(rn, tmp_); \ JMP8_POS(jmp1); /* no overflow */ \ emith_neg_r(rn); /* count left */ \ emith_lsl(rn, rn, 2+12); \ emith_or_r_r(cr, rn); \ emith_or_r_imm(cr, 1); \ emith_move_r_imm(rn, 0); \ JMP8_EMIT(ICOND_JA, jmp1); \ rcache_free_tmp(tmp_); \ } while (0) #define emith_sh2_delay_loop(cycles, reg) do { \ int sr = rcache_get_reg(SHR_SR, RC_GR_RMW, NULL); \ int t1 = rcache_get_tmp(); \ int t2 = rcache_get_tmp(); \ int t3 = rcache_get_tmp(); \ if (t3 == xAX) { t3 = t1; t1 = xAX; } /* for MUL */ \ if (t3 == xDX) { t3 = t2; t2 = xDX; } \ /* if (sr < 0) return */ \ emith_asrf(t2, sr, 12); \ EMITH_JMP_START(DCOND_LE); \ /* turns = sr.cycles / cycles */ \ emith_move_r_imm(t3, (u32)((1ULL<<32) / (cycles)) + 1); \ emith_mul_u64(t1, t2, t2, t3); /* multiply by 1/x */ \ rcache_free_tmp(t3); \ if (reg >= 0) { \ /* if (reg <= turns) turns = reg-1 */ \ t3 = rcache_get_reg(reg, RC_GR_RMW, NULL); \ emith_cmp_r_r(t3, t2); \ EMITH_SJMP_START(DCOND_HI); \ emith_sub_r_r_imm_c(DCOND_LS, t2, t3, 1); \ EMITH_SJMP_END(DCOND_HI); \ /* if (reg <= 1) turns = 0 */ \ emith_cmp_r_imm(t3, 1); \ EMITH_SJMP_START(DCOND_HI); \ emith_move_r_imm_c(DCOND_LS, t2, 0); \ EMITH_SJMP_END(DCOND_HI); \ /* reg -= turns */ \ emith_sub_r_r(t3, t2); \ } \ /* sr.cycles -= turns * cycles; */ \ emith_move_r_imm(t1, cycles); \ emith_mul_u64(t1, t2, t1, t2); \ emith_sub_r_r_r_lsl(sr, sr, t1, 12); \ EMITH_JMP_END(DCOND_LE); \ rcache_free_tmp(t1); \ rcache_free_tmp(t2); \ } while (0) #define emith_write_sr(sr, srcr) do { \ int tmp_ = rcache_get_tmp(); \ emith_clear_msb(tmp_, srcr, 22); \ emith_bic_r_imm(sr, 0x3ff); \ emith_or_r_r(sr, tmp_); \ rcache_free_tmp(tmp_); \ } while (0) #define emith_carry_to_t(sr, is_sub) do { \ emith_rorc(sr); \ emith_rol(sr, sr, 1); \ } while (0) #define emith_t_to_carry(sr, is_sub) do { \ emith_ror(sr, sr, 1); \ emith_rol(sr, sr, 1); \ } while (0) #define emith_tpop_carry(sr, is_sub) \ emith_lsr(sr, sr, 1) #define emith_tpush_carry(sr, is_sub) \ emith_adc_r_r(sr, sr) /* * if Q * t = carry(Rn += Rm) * else * t = carry(Rn -= Rm) * T ^= t */ #define emith_sh2_div1_step(rn, rm, sr) do { \ u8 *jmp0, *jmp1; \ int tmp_ = rcache_get_tmp(); \ emith_eor_r_r(tmp_, tmp_); \ emith_tst_r_imm(sr, Q); /* if (Q ^ M) */ \ JMP8_POS(jmp0); /* je do_sub */ \ emith_add_r_r(rn, rm); \ JMP8_POS(jmp1); /* jmp done */ \ JMP8_EMIT(ICOND_JE, jmp0); /* do_sub: */ \ emith_sub_r_r(rn, rm); \ JMP8_EMIT_NC(jmp1); /* done: */ \ emith_adc_r_r(tmp_, tmp_); \ emith_eor_r_r(sr, tmp_); \ rcache_free_tmp(tmp_); \ } while (0) /* mh:ml += rn*rm, does saturation if required by S bit. rn, rm must be TEMP */ #define emith_sh2_macl(ml, mh, rn, rm, sr) do { \ emith_tst_r_imm(sr, S); \ EMITH_SJMP_START(DCOND_EQ); \ /* MACH top 16 bits unused if saturated. sign ext for overfl detect */ \ emith_sext(mh, mh, 16); \ EMITH_SJMP_END(DCOND_EQ); \ emith_mula_s64(ml, mh, rn, rm); \ emith_tst_r_imm(sr, S); \ EMITH_SJMP_START(DCOND_EQ); \ /* overflow if top 17 bits of MACH aren't all 1 or 0 */ \ /* to check: add MACH[15] to MACH[31:16]. this is 0 if no overflow */ \ emith_asrf(rn, mh, 16); /* sum = (MACH>>16) + ((MACH>>15)&1) */ \ emith_adcf_r_imm(rn, 0); /* (MACH>>15) is in carry after shift */ \ EMITH_SJMP_START(DCOND_EQ); /* sum != 0 -> ov */ \ emith_move_r_imm_c(DCOND_NE, ml, 0x0000); /* -overflow */ \ emith_move_r_imm_c(DCOND_NE, mh, 0x8000); \ EMITH_SJMP_START(DCOND_LE); /* sum > 0 -> +ovl */ \ emith_sub_r_imm_c(DCOND_GT, ml, 1); /* 0xffffffff */ \ emith_sub_r_imm_c(DCOND_GT, mh, 1); /* 0x00007fff */ \ EMITH_SJMP_END(DCOND_LE); \ EMITH_SJMP_END(DCOND_EQ); \ EMITH_SJMP_END(DCOND_EQ); \ } while (0) /* mh:ml += rn*rm, does saturation if required by S bit. rn, rm must be TEMP */ #define emith_sh2_macw(ml, mh, rn, rm, sr) do { \ emith_tst_r_imm(sr, S); \ EMITH_SJMP_START(DCOND_EQ); \ /* XXX: MACH should be untouched when S is set? */ \ emith_asr(mh, ml, 31); /* sign ext MACL to MACH for ovrfl check */ \ EMITH_SJMP_END(DCOND_EQ); \ emith_mula_s64(ml, mh, rn, rm); \ emith_tst_r_imm(sr, S); \ EMITH_SJMP_START(DCOND_EQ); \ /* overflow if top 33 bits of MACH:MACL aren't all 1 or 0 */ \ /* to check: add MACL[31] to MACH. this is 0 if no overflow */ \ emith_lsr(rn, ml, 31); \ emith_addf_r_r(rn, mh); /* sum = MACH + ((MACL>>31)&1) */ \ EMITH_SJMP_START(DCOND_EQ); /* sum != 0 -> overflow */ \ /* XXX: LSB signalling only in SH1, or in SH2 too? */ \ emith_move_r_imm_c(DCOND_NE, mh, 0x00000001); /* LSB of MACH */ \ emith_move_r_imm_c(DCOND_NE, ml, 0x80000000); /* negative ovrfl */ \ EMITH_SJMP_START(DCOND_LE); /* sum > 0 -> positive ovrfl */ \ emith_sub_r_imm_c(DCOND_GT, ml, 1); /* 0x7fffffff */ \ EMITH_SJMP_END(DCOND_LE); \ EMITH_SJMP_END(DCOND_EQ); \ EMITH_SJMP_END(DCOND_EQ); \ } while (0) #define emith_pool_check() /**/ #define emith_pool_commit(j) /**/ #define emith_insn_ptr() ((u8 *)tcache_ptr) #define emith_flush() /**/ #ifdef T // T bit handling #define emith_invert_cond(cond) \ ((cond) ^ 1) static void emith_clr_t_cond(int sr) { emith_bic_r_imm(sr, T); } static void emith_set_t_cond(int sr, int cond) { EMITH_SJMP_START(emith_invert_cond(cond)); emith_or_r_imm_c(cond, sr, T); EMITH_SJMP_END(emith_invert_cond(cond)); } #define emith_get_t_cond() -1 #define emith_sync_t(sr) ((void)sr) #define emith_invalidate_t() static void emith_set_t(int sr, int val) { if (val) emith_or_r_imm(sr, T); else emith_bic_r_imm(sr, T); } static int emith_tst_t(int sr, int tf) { emith_tst_r_imm(sr, T); return tf ? DCOND_NE: DCOND_EQ; } #endif