/* Copyright © 2019 Michal Schulz https://github.com/michalsc This Source Code Form is subject to the terms of the Mozilla Public License, v. 2.0. If a copy of the MPL was not distributed with this file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #include "support.h" #include "M68k.h" #include "RegisterAllocator.h" #include "cache.h" static uint32_t *EMIT_CMPA(uint32_t *ptr, uint16_t opcode, uint16_t **m68k_ptr) __attribute__((alias("EMIT_CMPA_reg"))); static uint32_t *EMIT_CMPA_reg(uint32_t *ptr, uint16_t opcode, uint16_t **m68k_ptr) __attribute__((alias("EMIT_CMPA_mem"))); static uint32_t *EMIT_CMPA_mem(uint32_t *ptr, uint16_t opcode, uint16_t **m68k_ptr) __attribute__((alias("EMIT_CMPA_ext"))); static uint32_t *EMIT_CMPA_ext(uint32_t *ptr, uint16_t opcode, uint16_t **m68k_ptr) { uint8_t update_mask = M68K_GetSRMask(*m68k_ptr - 1); uint8_t size = ((opcode >> 8) & 1) ? 4 : 2; uint8_t src = 0xff; uint8_t dst = RA_MapM68kRegister(&ptr, 8 + ((opcode >> 9) & 7)); uint8_t ext_words = 0; if (size == 4) ptr = EMIT_LoadFromEffectiveAddress(ptr, size, &src, opcode & 0x3f, *m68k_ptr, &ext_words, 1, NULL); else ptr = EMIT_LoadFromEffectiveAddress(ptr, 0x80 | size, &src, opcode & 0x3f, *m68k_ptr, &ext_words, 0, NULL); *ptr++ = cmp_reg(dst, src, LSL, 0); RA_FreeARMRegister(&ptr, src); ptr = EMIT_AdvancePC(ptr, 2 * (ext_words + 1)); (*m68k_ptr) += ext_words; if (update_mask) { uint8_t cc = RA_ModifyCC(&ptr); if (__builtin_popcount(update_mask) != 0) { ptr = EMIT_GetNZnCV(ptr, cc, &update_mask); if (update_mask & SR_Z) ptr = EMIT_SetFlagsConditional(ptr, cc, SR_Z, ARM_CC_EQ); if (update_mask & SR_N) ptr = EMIT_SetFlagsConditional(ptr, cc, SR_N, ARM_CC_MI); if (update_mask & SR_V) ptr = EMIT_SetFlagsConditional(ptr, cc, SR_Valt, ARM_CC_VS); if (update_mask & SR_C) ptr = EMIT_SetFlagsConditional(ptr, cc, SR_Calt, ARM_CC_CC); } } return ptr; } static uint32_t *EMIT_CMPM(uint32_t *ptr, uint16_t opcode, uint16_t **m68k_ptr) { uint8_t update_mask = M68K_GetSRMask(*m68k_ptr - 1); uint8_t size = 1 << ((opcode >> 6) & 3); uint8_t src = 0xff; uint8_t dst = 0xff; uint8_t ext_words = 0; uint8_t tmp = RA_AllocARMRegister(&ptr); ptr = EMIT_LoadFromEffectiveAddress(ptr, size, &src, 0x18 | (opcode & 7), *m68k_ptr, &ext_words, 1, NULL); ptr = EMIT_LoadFromEffectiveAddress(ptr, size, &dst, 0x18 | ((opcode >> 9) & 7), *m68k_ptr, &ext_words, 1, NULL); switch (size) { case 4: *ptr++ = subs_reg(tmp, dst, src, LSL, 0); break; case 2: *ptr++ = lsl(tmp, dst, 16); *ptr++ = subs_reg(tmp, tmp, src, LSL, 16); break; case 1: *ptr++ = lsl(tmp, dst, 24); *ptr++ = subs_reg(tmp, tmp, src, LSL, 24); break; } RA_FreeARMRegister(&ptr, tmp); RA_FreeARMRegister(&ptr, src); RA_FreeARMRegister(&ptr, dst); ptr = EMIT_AdvancePC(ptr, 2 * (ext_words + 1)); (*m68k_ptr) += ext_words; if (update_mask) { uint8_t cc = RA_ModifyCC(&ptr); if (__builtin_popcount(update_mask) != 0) { ptr = EMIT_GetNZnCV(ptr, cc, &update_mask); if (update_mask & SR_Z) ptr = EMIT_SetFlagsConditional(ptr, cc, SR_Z, ARM_CC_EQ); if (update_mask & SR_N) ptr = EMIT_SetFlagsConditional(ptr, cc, SR_N, ARM_CC_MI); if (update_mask & SR_V) ptr = EMIT_SetFlagsConditional(ptr, cc, SR_Valt, ARM_CC_VS); if (update_mask & SR_C) ptr = EMIT_SetFlagsConditional(ptr, cc, SR_Calt, ARM_CC_CC); } } return ptr; } static uint32_t *EMIT_CMP(uint32_t *ptr, uint16_t opcode, uint16_t **m68k_ptr) __attribute__((alias("EMIT_CMP_reg"))); static uint32_t *EMIT_CMP_reg(uint32_t *ptr, uint16_t opcode, uint16_t **m68k_ptr) __attribute__((alias("EMIT_CMP_mem"))); static uint32_t *EMIT_CMP_mem(uint32_t *ptr, uint16_t opcode, uint16_t **m68k_ptr) __attribute__((alias("EMIT_CMP_ext"))); static uint32_t *EMIT_CMP_ext(uint32_t *ptr, uint16_t opcode, uint16_t **m68k_ptr) { uint8_t update_mask = M68K_GetSRMask(*m68k_ptr - 1); uint8_t size = 1 << ((opcode >> 6) & 3); uint8_t src = 0xff; uint8_t dst = RA_MapM68kRegister(&ptr, (opcode >> 9) & 7); uint8_t ext_words = 0; uint8_t tmp = RA_AllocARMRegister(&ptr); ptr = EMIT_LoadFromEffectiveAddress(ptr, size, &src, opcode & 0x3f, *m68k_ptr, &ext_words, 1, NULL); switch(size) { case 4: *ptr++ = subs_reg(31, dst, src, LSL, 0); break; case 2: *ptr++ = lsl(tmp, dst, 16); *ptr++ = subs_reg(31, tmp, src, LSL, 16); break; case 1: *ptr++ = lsl(tmp, dst, 24); *ptr++ = subs_reg(31, tmp, src, LSL, 24); break; } RA_FreeARMRegister(&ptr, tmp); RA_FreeARMRegister(&ptr, src); ptr = EMIT_AdvancePC(ptr, 2 * (ext_words + 1)); (*m68k_ptr) += ext_words; if (update_mask) { uint8_t cc = RA_ModifyCC(&ptr); if (__builtin_popcount(update_mask) != 0) { ptr = EMIT_GetNZnCV(ptr, cc, &update_mask); if (update_mask & SR_Z) ptr = EMIT_SetFlagsConditional(ptr, cc, SR_Z, ARM_CC_EQ); if (update_mask & SR_N) ptr = EMIT_SetFlagsConditional(ptr, cc, SR_N, ARM_CC_MI); if (update_mask & SR_V) ptr = EMIT_SetFlagsConditional(ptr, cc, SR_Valt, ARM_CC_VS); if (update_mask & SR_C) ptr = EMIT_SetFlagsConditional(ptr, cc, SR_Calt, ARM_CC_CC); } } return ptr; } static uint32_t *EMIT_EOR(uint32_t *ptr, uint16_t opcode, uint16_t **m68k_ptr) __attribute__((alias("EMIT_EOR_reg"))); static uint32_t *EMIT_EOR_reg(uint32_t *ptr, uint16_t opcode, uint16_t **m68k_ptr) __attribute__((alias("EMIT_EOR_mem"))); static uint32_t *EMIT_EOR_mem(uint32_t *ptr, uint16_t opcode, uint16_t **m68k_ptr) __attribute__((alias("EMIT_EOR_ext"))); static uint32_t *EMIT_EOR_ext(uint32_t *ptr, uint16_t opcode, uint16_t **m68k_ptr) { uint8_t update_mask = M68K_GetSRMask(*m68k_ptr - 1); uint8_t size = 1 << ((opcode >> 6) & 3); uint8_t ext_words = 0; uint8_t test_register; if ((opcode & 0x38) == 0) { uint8_t src = RA_MapM68kRegister(&ptr, (opcode >> 9) & 7); uint8_t dest = RA_MapM68kRegister(&ptr, (opcode) & 7); uint8_t tmp = 0xff; test_register = dest; RA_SetDirtyM68kRegister(&ptr, opcode & 7); switch (size) { case 4: *ptr++ = eor_reg(dest, dest, src, LSL, 0); break; case 2: tmp = RA_AllocARMRegister(&ptr); *ptr++ = eor_reg(tmp, src, dest, LSL, 0); *ptr++ = bfi(dest, tmp, 0, 16); RA_FreeARMRegister(&ptr, tmp); break; case 1: tmp = RA_AllocARMRegister(&ptr); *ptr++ = eor_reg(tmp, src, dest, LSL, 0); *ptr++ = bfi(dest, tmp, 0, 8); RA_FreeARMRegister(&ptr, tmp); break; } RA_FreeARMRegister(&ptr, src); } else { uint8_t dest = 0xff; uint8_t src = RA_MapM68kRegister(&ptr, (opcode >> 9) & 7); uint8_t tmp = RA_AllocARMRegister(&ptr); uint8_t mode = (opcode & 0x0038) >> 3; test_register = tmp; if (mode == 4 || mode == 3) ptr = EMIT_LoadFromEffectiveAddress(ptr, 0, &dest, opcode & 0x3f, *m68k_ptr, &ext_words, 0, NULL); else ptr = EMIT_LoadFromEffectiveAddress(ptr, 0, &dest, opcode & 0x3f, *m68k_ptr, &ext_words, 1, NULL); /* Fetch data into temporary register, perform add, store it back */ switch (size) { case 4: if (mode == 4) { *ptr++ = ldr_offset_preindex(dest, tmp, -4); RA_SetDirtyM68kRegister(&ptr, 8 + (opcode & 7)); } else *ptr++ = ldr_offset(dest, tmp, 0); /* Perform calcualtion */ *ptr++ = eor_reg(tmp, tmp, src, LSL, 0); /* Store back */ if (mode == 3) { *ptr++ = str_offset_postindex(dest, tmp, 4); RA_SetDirtyM68kRegister(&ptr, 8 + (opcode & 7)); } else *ptr++ = str_offset(dest, tmp, 0); break; case 2: if (mode == 4) { *ptr++ = ldrh_offset_preindex(dest, tmp, -2); RA_SetDirtyM68kRegister(&ptr, 8 + (opcode & 7)); } else *ptr++ = ldrh_offset(dest, tmp, 0); /* Perform calcualtion */ *ptr++ = eor_reg(tmp, tmp, src, LSL, 0); /* Store back */ if (mode == 3) { *ptr++ = strh_offset_postindex(dest, tmp, 2); RA_SetDirtyM68kRegister(&ptr, 8 + (opcode & 7)); } else *ptr++ = strh_offset(dest, tmp, 0); break; case 1: if (mode == 4) { *ptr++ = ldrb_offset_preindex(dest, tmp, (opcode & 7) == 7 ? -2 : -1); RA_SetDirtyM68kRegister(&ptr, 8 + (opcode & 7)); } else *ptr++ = ldrb_offset(dest, tmp, 0); /* Perform calcualtion */ *ptr++ = eor_reg(tmp, tmp, src, LSL, 0); /* Store back */ if (mode == 3) { *ptr++ = strb_offset_postindex(dest, tmp, (opcode & 7) == 7 ? 2 : 1); RA_SetDirtyM68kRegister(&ptr, 8 + (opcode & 7)); } else *ptr++ = strb_offset(dest, tmp, 0); break; } RA_FreeARMRegister(&ptr, dest); } ptr = EMIT_AdvancePC(ptr, 2 * (ext_words + 1)); (*m68k_ptr) += ext_words; if (update_mask) { switch(size) { case 4: *ptr++ = cmn_reg(31, test_register, LSL, 0); break; case 2: *ptr++ = cmn_reg(31, test_register, LSL, 16); break; case 1: *ptr++ = cmn_reg(31, test_register, LSL, 24); break; } uint8_t cc = RA_ModifyCC(&ptr); ptr = EMIT_GetNZ00(ptr, cc, &update_mask); if (update_mask & SR_Z) ptr = EMIT_SetFlagsConditional(ptr, cc, SR_Z, ARM_CC_EQ); if (update_mask & SR_N) ptr = EMIT_SetFlagsConditional(ptr, cc, SR_N, ARM_CC_MI); } RA_FreeARMRegister(&ptr, test_register); return ptr; } static struct OpcodeDef InsnTable[512] = { [0000 ... 0007] = { { EMIT_CMP_reg }, NULL, 0, SR_NZVC, 1, 0, 1 }, //D0 destination, Byte [0020 ... 0047] = { { EMIT_CMP_mem }, NULL, 0, SR_NZVC, 1, 0, 1 }, //(An) [0050 ... 0074] = { { EMIT_CMP_ext }, NULL, 0, SR_NZVC, 1, 1, 1 }, //memory indirect [0100 ... 0117] = { { EMIT_CMP_reg }, NULL, 0, SR_NZVC, 1, 0, 2 }, //register, Word [0120 ... 0147] = { { EMIT_CMP_mem }, NULL, 0, SR_NZVC, 1, 0, 2 }, //(An) [0150 ... 0174] = { { EMIT_CMP_ext }, NULL, 0, SR_NZVC, 1, 1, 2 }, //memory indirect [0200 ... 0217] = { { EMIT_CMP_reg }, NULL, 0, SR_NZVC, 1, 0, 4 }, //register Long [0220 ... 0247] = { { EMIT_CMP_mem }, NULL, 0, SR_NZVC, 1, 0, 4 }, //(An) [0250 ... 0274] = { { EMIT_CMP_ext }, NULL, 0, SR_NZVC, 1, 1, 4 }, //memory indirect [0300 ... 0317] = { { EMIT_CMPA_reg }, NULL, 0, SR_NZVC, 1, 0, 2 }, //A0, Word [0320 ... 0347] = { { EMIT_CMPA_mem }, NULL, 0, SR_NZVC, 1, 0, 2 }, //(An) [0350 ... 0374] = { { EMIT_CMPA_ext }, NULL, 0, SR_NZVC, 1, 1, 2 }, //memory indirect [0400 ... 0407] = { { EMIT_EOR_reg }, NULL, 0, SR_NZVC, 1, 0, 1 }, //D0, Byte [0410 ... 0417] = { { EMIT_CMPM }, NULL, 0, SR_NZVC, 1, 0, 1 }, [0420 ... 0447] = { { EMIT_EOR_mem }, NULL, 0, SR_NZVC, 1, 0, 1 }, [0450 ... 0471] = { { EMIT_EOR_ext }, NULL, 0, SR_NZVC, 1, 1, 1 }, [0500 ... 0507] = { { EMIT_EOR_reg }, NULL, 0, SR_NZVC, 1, 0, 2 }, //D0, Word [0510 ... 0517] = { { EMIT_CMPM }, NULL, 0, SR_NZVC, 1, 0, 2 }, [0520 ... 0547] = { { EMIT_EOR_mem }, NULL, 0, SR_NZVC, 1, 0, 2 }, [0550 ... 0571] = { { EMIT_EOR_ext }, NULL, 0, SR_NZVC, 1, 1, 2 }, [0600 ... 0607] = { { EMIT_EOR_reg }, NULL, 0, SR_NZVC, 1, 0, 4 }, //D0, Long [0610 ... 0617] = { { EMIT_CMPM }, NULL, 0, SR_NZVC, 1, 0, 4 }, [0620 ... 0647] = { { EMIT_EOR_mem }, NULL, 0, SR_NZVC, 1, 0, 4 }, [0650 ... 0671] = { { EMIT_EOR_ext }, NULL, 0, SR_NZVC, 1, 1, 4 }, [0700 ... 0717] = { { EMIT_CMPA_reg }, NULL, 0, SR_NZVC, 1, 0, 4 }, //A0, Long [0720 ... 0747] = { { EMIT_CMPA_mem }, NULL, 0, SR_NZVC, 1, 0, 4 }, //(An) [0750 ... 0774] = { { EMIT_CMPA_ext }, NULL, 0, SR_NZVC, 1, 1, 4 }, //memory indirect }; uint32_t *EMIT_lineB(uint32_t *ptr, uint16_t **m68k_ptr, uint16_t *insn_consumed) { uint16_t opcode = cache_read_16(ICACHE, (uintptr_t)&(*m68k_ptr)[0]); (*m68k_ptr)++; *insn_consumed = 1; /* 1011xxxx11xxxxxx - CMPA */ if (InsnTable[opcode & 00777].od_Emit) { ptr = InsnTable[opcode & 00777].od_Emit(ptr, opcode, m68k_ptr); } else { ptr = EMIT_FlushPC(ptr); ptr = EMIT_InjectDebugString(ptr, "[JIT] opcode %04x at %08x not implemented\n", opcode, *m68k_ptr - 1); *ptr++ = svc(0x100); *ptr++ = svc(0x101); *ptr++ = svc(0x103); *ptr++ = (uint32_t)(uintptr_t)(*m68k_ptr - 8); *ptr++ = 48; ptr = EMIT_Exception(ptr, VECTOR_ILLEGAL_INSTRUCTION, 0); *ptr++ = INSN_TO_LE(0xffffffff); } return ptr; } uint32_t GetSR_LineB(uint16_t opcode) { /* If instruction is in the table, return what flags it needs (shifted 16 bits left) and flags it sets */ if (InsnTable[opcode & 00777].od_Emit) { return (InsnTable[opcode & 00777].od_SRNeeds << 16) | InsnTable[opcode & 00777].od_SRSets; } /* Instruction not found, i.e. it needs all flags and sets none (ILLEGAL INSTRUCTION exception) */ else { kprintf("Undefined LineB\n"); return SR_CCR << 16; } } int M68K_GetLineBLength(uint16_t *insn_stream) { uint16_t opcode = cache_read_16(ICACHE, (uintptr_t)insn_stream); int length = 0; int need_ea = 0; int opsize = 0; if (InsnTable[opcode & 00777].od_Emit) { length = InsnTable[opcode & 00777].od_BaseLength; need_ea = InsnTable[opcode & 00777].od_HasEA; opsize = InsnTable[opcode & 00777].od_OpSize; } if (need_ea) { length += SR_GetEALength(&insn_stream[length], opcode & 0x3f, opsize); } return length; }