/* gameplaySP * * Copyright (C) 2006 Exophase * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License as * published by the Free Software Foundation; either version 2 of * the License, or (at your option) any later version. * * This program 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 * General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA */ // Not-so-important todo: // - stm reglist writeback when base is in the list needs adjustment // - block memory needs psr swapping and user mode reg swapping #include "common.h" #if defined(VITA) #include #include #elif defined(PS2) #include #endif u8 *last_rom_translation_ptr = NULL; u8 *last_ram_translation_ptr = NULL; #if defined(MMAP_JIT_CACHE) u8* rom_translation_cache; u8* ram_translation_cache; u8 *rom_translation_ptr; u8 *ram_translation_ptr; #elif defined(VITA) u8* rom_translation_cache; u8* ram_translation_cache; u8 *rom_translation_ptr; u8 *ram_translation_ptr; int sceBlock; #elif defined(_3DS) u8* rom_translation_cache_ptr; u8* ram_translation_cache_ptr; u8 *rom_translation_ptr = rom_translation_cache; u8 *ram_translation_ptr = ram_translation_cache; #else u8 *rom_translation_ptr = rom_translation_cache; u8 *ram_translation_ptr = ram_translation_cache; #endif /* Note, see stub files for more cache definitions */ u32 iwram_code_min = ~0U; u32 iwram_code_max = 0U; u32 ewram_code_min = ~0U; u32 ewram_code_max = 0U; #define INITIAL_ROM_WATERMARK 16 // To avoid NULL aliasing u32 rom_cache_watermark = INITIAL_ROM_WATERMARK; u8 *bios_swi_entrypoint = NULL; // Contains an offset table to rom_translation cache area // It features a chaining linked list for collisions // The rom area has a small header section that contains: // - PC value for the entry // - Offset to the next entry (if any) typedef struct { u32 pc_value; u32 next_entry; } hashhdr_type; u32 rom_branch_hash[ROM_BRANCH_HASH_SIZE]; typedef struct { u8 *block_offset; u16 flag_data; u8 condition; u8 update_cycles; } block_data_type; typedef struct { u32 branch_target; u8 *branch_source; } block_exit_type; // Div (6) and DivArm (7) #define is_div_swi(swinum) (((swinum) & 0xFE) == 0x06) #define arm_decode_data_proc_reg(opcode) \ u32 rn = (opcode >> 16) & 0x0F; \ u32 rd = (opcode >> 12) & 0x0F; \ u32 rm = opcode & 0x0F \ #define arm_decode_data_proc_imm(opcode) \ u32 rn = (opcode >> 16) & 0x0F; \ u32 rd = (opcode >> 12) & 0x0F; \ u32 imm = opcode & 0xFF; \ u32 imm_ror = ((opcode >> 8) & 0x0F) * 2 \ #define arm_decode_psr_reg(opcode) \ u32 psr_pfield = ((opcode >> 16) & 1) | ((opcode >> 18) & 2); \ u32 rd = (opcode >> 12) & 0x0F; \ u32 rm = opcode & 0x0F \ #define arm_decode_psr_imm(opcode) \ u32 psr_pfield = ((opcode >> 16) & 1) | ((opcode >> 18) & 2); \ u32 rd = (opcode >> 12) & 0x0F; \ u32 imm = opcode & 0xFF; \ u32 imm_ror = ((opcode >> 8) & 0x0F) * 2 \ #define arm_decode_branchx(opcode) \ u32 rn = opcode & 0x0F \ #define arm_decode_multiply() \ u32 rd = (opcode >> 16) & 0x0F; \ u32 rn = (opcode >> 12) & 0x0F; \ u32 rs = (opcode >> 8) & 0x0F; \ u32 rm = opcode & 0x0F \ #define arm_decode_multiply_long() \ u32 rdhi = (opcode >> 16) & 0x0F; \ u32 rdlo = (opcode >> 12) & 0x0F; \ u32 rs = (opcode >> 8) & 0x0F; \ u32 rm = opcode & 0x0F \ #define arm_decode_swap() \ u32 rn = (opcode >> 16) & 0x0F; \ u32 rd = (opcode >> 12) & 0x0F; \ u32 rm = opcode & 0x0F \ #define arm_decode_half_trans_r() \ u32 rn = (opcode >> 16) & 0x0F; \ u32 rd = (opcode >> 12) & 0x0F; \ u32 rm = opcode & 0x0F \ #define arm_decode_half_trans_of() \ u32 rn = (opcode >> 16) & 0x0F; \ u32 rd = (opcode >> 12) & 0x0F; \ u32 offset = ((opcode >> 4) & 0xF0) | (opcode & 0x0F) \ #define arm_decode_data_trans_imm() \ u32 rn = (opcode >> 16) & 0x0F; \ u32 rd = (opcode >> 12) & 0x0F; \ u32 offset = opcode & 0x0FFF \ #define arm_decode_data_trans_reg() \ u32 rn = (opcode >> 16) & 0x0F; \ u32 rd = (opcode >> 12) & 0x0F; \ u32 rm = opcode & 0x0F \ #define arm_decode_block_trans() \ u32 rn = (opcode >> 16) & 0x0F; \ u32 reg_list = opcode & 0xFFFF \ #define arm_decode_branch() \ s32 offset = ((s32)(opcode & 0xFFFFFF) << 8) >> 6 \ #define thumb_decode_shift() \ u32 imm = (opcode >> 6) & 0x1F; \ u32 rs = (opcode >> 3) & 0x07; \ u32 rd = opcode & 0x07 \ #define thumb_decode_add_sub() \ u32 rn = (opcode >> 6) & 0x07; \ u32 rs = (opcode >> 3) & 0x07; \ u32 rd = opcode & 0x07 \ #define thumb_decode_add_sub_imm() \ u32 imm = (opcode >> 6) & 0x07; \ u32 rs = (opcode >> 3) & 0x07; \ u32 rd = opcode & 0x07 \ #define thumb_decode_imm() \ u32 imm = opcode & 0xFF \ #define thumb_decode_alu_op() \ u32 rs = (opcode >> 3) & 0x07; \ u32 rd = opcode & 0x07 \ #define thumb_decode_hireg_op() \ u32 rs = (opcode >> 3) & 0x0F; \ u32 rd = ((opcode >> 4) & 0x08) | (opcode & 0x07) \ #define thumb_decode_mem_reg() \ u32 ro = (opcode >> 6) & 0x07; \ u32 rb = (opcode >> 3) & 0x07; \ u32 rd = opcode & 0x07 \ #define thumb_decode_mem_imm() \ u32 imm = (opcode >> 6) & 0x1F; \ u32 rb = (opcode >> 3) & 0x07; \ u32 rd = opcode & 0x07 \ #define thumb_decode_add_sp() \ u32 imm = opcode & 0x7F \ #define thumb_decode_rlist() \ u32 reg_list = opcode & 0xFF \ #define thumb_decode_branch_cond() \ s32 offset = (s8)(opcode & 0xFF) \ #define thumb_decode_branch() \ u32 offset = opcode & 0x07FF \ /* Include the right emitter headers */ #if defined(MIPS_ARCH) #include "mips/mips_emit.h" #elif defined(ARM_ARCH) #include "arm/arm_emit.h" #elif defined(ARM64_ARCH) #include "arm/arm64_emit.h" #else #include "x86/x86_emit.h" #endif /* Cache invalidation */ #if defined(PSP) void platform_cache_sync(void *baseaddr, void *endptr) { sceKernelDcacheWritebackRange(baseaddr, ((char*)endptr) - ((char*)baseaddr)); sceKernelIcacheInvalidateRange(baseaddr, ((char*)endptr) - ((char*)baseaddr)); } #elif defined(PS2) void platform_cache_sync(void *baseaddr, void *endptr) { FlushCache(0); // Dcache flush FlushCache(2); // Icache invalidate } #elif defined(VITA) void platform_cache_sync(void *baseaddr, void *endptr) { sceKernelSyncVMDomain(sceBlock, baseaddr, ((char*)endptr) - ((char*)baseaddr) + 64); } #elif defined(_3DS) #include "3ds/3ds_utils.h" void platform_cache_sync(void *baseaddr, void *endptr) { ctr_flush_invalidate_cache(); } #elif defined(ARM_ARCH) || defined(ARM64_ARCH) void platform_cache_sync(void *baseaddr, void *endptr) { __clear_cache(baseaddr, endptr); } #elif defined(MIPS_ARCH) void platform_cache_sync(void *baseaddr, void *endptr) { __builtin___clear_cache(baseaddr, endptr); } #else /* x86 CPUs have icache consistency checks */ void platform_cache_sync(void *baseaddr, void *endptr) {} #endif void translate_icache_sync() { // Cache emitted code can only grow if (last_rom_translation_ptr < rom_translation_ptr) { platform_cache_sync(last_rom_translation_ptr, rom_translation_ptr); last_rom_translation_ptr = rom_translation_ptr; } if (last_ram_translation_ptr < ram_translation_ptr) { platform_cache_sync(last_ram_translation_ptr, ram_translation_ptr); last_ram_translation_ptr = ram_translation_ptr; } } /* End of Cache invalidation */ #define check_pc_region(pc) \ new_pc_region = (pc >> 15); \ if(new_pc_region != pc_region) \ { \ pc_region = new_pc_region; \ pc_address_block = memory_map_read[new_pc_region]; \ \ if(!pc_address_block) \ pc_address_block = load_gamepak_page(pc_region & 0x3FF); \ } \ #define translate_arm_instruction() \ check_pc_region(pc); \ opcode = readaddress32(pc_address_block, (pc & 0x7FFF)); \ condition = block_data[block_data_position].condition; \ printf("%x: %08x ", pc, opcode); \ if((condition != last_condition) || (condition >= 0x20)) \ { \ if((last_condition & 0x0F) != 0x0E) \ { \ generate_branch_patch_conditional(backpatch_address, translation_ptr); \ } \ \ last_condition = condition; \ \ condition &= 0x0F; \ \ if(condition != 0x0E) \ { \ arm_conditional_block_header(); \ } \ } \ emit_trace_arm_instruction(pc); \ \ switch((opcode >> 20) & 0xFF) \ { \ case 0x00: \ if((opcode & 0x90) == 0x90) \ { \ if(opcode & 0x20) \ { \ printf("STRH rd, [rn], -rm\n"); \ arm_access_memory(store, down, post, u16, half_reg); \ } \ else \ { \ printf("MUL rd, rm, rs\n"); \ arm_multiply(no, no); \ cycle_count += 2; /* variable 1..4, pick 2 as an aprox. */ \ } \ } \ else \ { \ printf("AND rd, rn, reg_op\n"); \ arm_data_proc(and, reg, no_flags); \ } \ break; \ \ case 0x01: \ if((opcode & 0x90) == 0x90) \ { \ switch((opcode >> 5) & 0x03) \ { \ case 0: \ printf("MULS rd, rm, rs\n"); \ arm_multiply(no, yes); \ cycle_count += 2; /* variable 1..4, pick 2 as an aprox. */ \ break; \ \ case 1: \ printf("LDRH rd, [rn], -rm\n"); \ arm_access_memory(load, down, post, u16, half_reg); \ break; \ \ case 2: \ printf("LDRSB rd, [rn], -rm\n"); \ arm_access_memory(load, down, post, s8, half_reg); \ break; \ \ case 3: \ printf("LDRSH rd, [rn], -rm\n"); \ arm_access_memory(load, down, post, s16, half_reg); \ break; \ } \ } \ else \ { \ printf("ANDS rd, rn, reg_op\n"); \ arm_data_proc(ands, reg_flags, flags); \ } \ break; \ \ case 0x02: \ if((opcode & 0x90) == 0x90) \ { \ if(opcode & 0x20) \ { \ printf("STRH rd, [rn], -rm\n"); \ arm_access_memory(store, down, post, u16, half_reg); \ } \ else \ { \ printf("MLA rd, rm, rs, rn\n"); \ arm_multiply(yes, no); \ cycle_count += 3; /* variable 2..5, pick 3 as an aprox. */ \ } \ } \ else \ { \ printf("EOR rd, rn, reg_op\n"); \ arm_data_proc(eor, reg, no_flags); \ } \ break; \ \ case 0x03: \ if((opcode & 0x90) == 0x90) \ { \ switch((opcode >> 5) & 0x03) \ { \ case 0: \ printf("MLAS rd, rm, rs, rn\n"); \ arm_multiply(yes, yes); \ cycle_count += 3; printf("variable 2..5, pick 3 as an aprox.\n"); \ break; \ \ case 1: \ printf("LDRH rd, [rn], -rm\n"); \ arm_access_memory(load, down, post, u16, half_reg); \ break; \ \ case 2: \ printf("LDRSB rd, [rn], -rm\n"); \ arm_access_memory(load, down, post, s8, half_reg); \ break; \ \ case 3: \ printf("LDRSH rd, [rn], -rm\n"); \ arm_access_memory(load, down, post, s16, half_reg); \ break; \ } \ } \ else \ { \ printf("EORS rd, rn, reg_op\n"); \ arm_data_proc(eors, reg_flags, flags); \ } \ break; \ \ case 0x04: \ if((opcode & 0x90) == 0x90) \ { \ printf("STRH rd, [rn], -imm\n"); \ arm_access_memory(store, down, post, u16, half_imm); \ } \ else \ { \ printf("SUB rd, rn, reg_op\n"); \ arm_data_proc(sub, reg, no_flags); \ } \ break; \ \ case 0x05: \ if((opcode & 0x90) == 0x90) \ { \ switch((opcode >> 5) & 0x03) \ { \ case 1: \ printf("LDRH rd, [rn], -imm\n"); \ arm_access_memory(load, down, post, u16, half_imm); \ break; \ \ case 2: \ printf("LDRSB rd, [rn], -imm\n"); \ arm_access_memory(load, down, post, s8, half_imm); \ break; \ \ case 3: \ printf("LDRSH rd, [rn], -imm\n"); \ arm_access_memory(load, down, post, s16, half_imm); \ break; \ } \ } \ else \ { \ printf("SUBS rd, rn, reg_op\n"); \ arm_data_proc(subs, reg, flags); \ } \ break; \ \ case 0x06: \ if((opcode & 0x90) == 0x90) \ { \ printf("STRH rd, [rn], -imm\n"); \ arm_access_memory(store, down, post, u16, half_imm); \ } \ else \ { \ printf("RSB rd, rn, reg_op\n"); \ arm_data_proc(rsb, reg, no_flags); \ } \ break; \ \ case 0x07: \ if((opcode & 0x90) == 0x90) \ { \ switch((opcode >> 5) & 0x03) \ { \ case 1: \ printf("LDRH rd, [rn], -imm\n"); \ arm_access_memory(load, down, post, u16, half_imm); \ break; \ \ case 2: \ printf("LDRSB rd, [rn], -imm\n"); \ arm_access_memory(load, down, post, s8, half_imm); \ break; \ \ case 3: \ printf("LDRSH rd, [rn], -imm\n"); \ arm_access_memory(load, down, post, s16, half_imm); \ break; \ } \ } \ else \ { \ printf("RSBS rd, rn, reg_op\n"); \ arm_data_proc(rsbs, reg, flags); \ } \ break; \ \ case 0x08: \ if((opcode & 0x90) == 0x90) \ { \ if(opcode & 0x20) \ { \ printf("STRH rd, [rn], +rm\n"); \ arm_access_memory(store, up, post, u16, half_reg); \ } \ else \ { \ printf("UMULL rd, rm, rs\n"); \ arm_multiply_long(u64, no, no); \ cycle_count += 3; /* this is an aproximation :P */ \ } \ } \ else \ { \ printf("ADD rd, rn, reg_op\n"); \ arm_data_proc(add, reg, no_flags); \ } \ break; \ \ case 0x09: \ if((opcode & 0x90) == 0x90) \ { \ switch((opcode >> 5) & 0x03) \ { \ case 0: \ printf("UMULLS rdlo, rdhi, rm, rs\n"); \ arm_multiply_long(u64, no, yes); \ cycle_count += 3; /* this is an aproximation :P */ \ break; \ \ case 1: \ printf("LDRH rd, [rn], +rm\n"); \ arm_access_memory(load, up, post, u16, half_reg); \ break; \ \ case 2: \ printf("LDRSB rd, [rn], +rm\n"); \ arm_access_memory(load, up, post, s8, half_reg); \ break; \ \ case 3: \ printf("LDRSH rd, [rn], +rm\n"); \ arm_access_memory(load, up, post, s16, half_reg); \ break; \ } \ } \ else \ { \ printf("ADDS rd, rn, reg_op\n"); \ arm_data_proc(adds, reg, flags); \ } \ break; \ \ case 0x0A: \ if((opcode & 0x90) == 0x90) \ { \ if(opcode & 0x20) \ { \ printf("STRH rd, [rn], +rm\n"); \ arm_access_memory(store, up, post, u16, half_reg); \ } \ else \ { \ printf("UMLAL rd, rm, rs\n"); \ arm_multiply_long(u64_add, yes, no); \ cycle_count += 3; /* Between 2 and 5 cycles? */ \ } \ } \ else \ { \ printf("ADC rd, rn, reg_op\n"); \ arm_data_proc(adc, reg, no_flags); \ } \ break; \ \ case 0x0B: \ if((opcode & 0x90) == 0x90) \ { \ switch((opcode >> 5) & 0x03) \ { \ case 0: \ printf("UMLALS rdlo, rdhi, rm, rs\n"); \ arm_multiply_long(u64_add, yes, yes); \ cycle_count += 3; /* Between 2 and 5 cycles? */ \ break; \ \ case 1: \ printf("LDRH rd, [rn], +rm\n"); \ arm_access_memory(load, up, post, u16, half_reg); \ break; \ \ case 2: \ printf("LDRSB rd, [rn], +rm\n"); \ arm_access_memory(load, up, post, s8, half_reg); \ break; \ \ case 3: \ printf("LDRSH rd, [rn], +rm\n"); \ arm_access_memory(load, up, post, s16, half_reg); \ break; \ } \ } \ else \ { \ printf("ADCS rd, rn, reg_op\n"); \ arm_data_proc(adcs, reg, flags); \ } \ break; \ \ case 0x0C: \ if((opcode & 0x90) == 0x90) \ { \ if(opcode & 0x20) \ { \ printf("STRH rd, [rn], +imm\n"); \ arm_access_memory(store, up, post, u16, half_imm); \ } \ else \ { \ printf("SMULL rd, rm, rs\n"); \ arm_multiply_long(s64, no, no); \ cycle_count += 2; /* Between 1 and 4 cycles? */ \ } \ } \ else \ { \ printf("SBC rd, rn, reg_op\n"); \ arm_data_proc(sbc, reg, no_flags); \ } \ break; \ \ case 0x0D: \ if((opcode & 0x90) == 0x90) \ { \ switch((opcode >> 5) & 0x03) \ { \ case 0: \ printf("SMULLS rdlo, rdhi, rm, rs\n"); \ arm_multiply_long(s64, no, yes); \ cycle_count += 2; /* Between 1 and 4 cycles? */ \ break; \ \ case 1: \ printf("LDRH rd, [rn], +imm\n"); \ arm_access_memory(load, up, post, u16, half_imm); \ break; \ \ case 2: \ printf("LDRSB rd, [rn], +imm\n"); \ arm_access_memory(load, up, post, s8, half_imm); \ break; \ \ case 3: \ printf("LDRSH rd, [rn], +imm\n"); \ arm_access_memory(load, up, post, s16, half_imm); \ break; \ } \ } \ else \ { \ printf("SBCS rd, rn, reg_op\n"); \ arm_data_proc(sbcs, reg, flags); \ } \ break; \ \ case 0x0E: \ if((opcode & 0x90) == 0x90) \ { \ if(opcode & 0x20) \ { \ printf("STRH rd, [rn], +imm\n"); \ arm_access_memory(store, up, post, u16, half_imm); \ } \ else \ { \ printf("SMLAL rd, rm, rs\n"); \ arm_multiply_long(s64_add, yes, no); \ cycle_count += 3; /* Between 2 and 5 cycles? */ \ } \ } \ else \ { \ printf("RSC rd, rn, reg_op\n"); \ arm_data_proc(rsc, reg, no_flags); \ } \ break; \ \ case 0x0F: \ if((opcode & 0x90) == 0x90) \ { \ switch((opcode >> 5) & 0x03) \ { \ case 0: \ printf("SMLALS rdlo, rdhi, rm, rs\n"); \ arm_multiply_long(s64_add, yes, yes); \ cycle_count += 3; /* Between 2 and 5 cycles? */ \ break; \ \ case 1: \ printf("LDRH rd, [rn], +imm\n"); \ arm_access_memory(load, up, post, u16, half_imm); \ break; \ \ case 2: \ printf("LDRSB rd, [rn], +imm\n"); \ arm_access_memory(load, up, post, s8, half_imm); \ break; \ \ case 3: \ printf("LDRSH rd, [rn], +imm\n"); \ arm_access_memory(load, up, post, s16, half_imm); \ break; \ } \ } \ else \ { \ printf("RSCS rd, rn, reg_op\n"); \ arm_data_proc(rscs, reg, flags); \ } \ break; \ \ case 0x10: \ if((opcode & 0x90) == 0x90) \ { \ if(opcode & 0x20) \ { \ printf("STRH rd, [rn - rm]\n"); \ arm_access_memory(store, down, pre, u16, half_reg); \ } \ else \ { \ printf("SWP rd, rm, [rn]\n"); \ arm_swap(u32); \ } \ } \ else \ { \ printf("MRS rd, cpsr\n"); \ arm_psr(reg, read, cpsr); \ } \ break; \ \ case 0x11: \ if((opcode & 0x90) == 0x90) \ { \ switch((opcode >> 5) & 0x03) \ { \ case 1: \ printf("LDRH rd, [rn - rm]\n"); \ arm_access_memory(load, down, pre, u16, half_reg); \ break; \ \ case 2: \ printf("LDRSB rd, [rn - rm]\n"); \ arm_access_memory(load, down, pre, s8, half_reg); \ break; \ \ case 3: \ printf("LDRSH rd, [rn - rm]\n"); \ arm_access_memory(load, down, pre, s16, half_reg); \ break; \ } \ } \ else \ { \ printf("TST rd, rn, reg_op\n"); \ arm_data_proc_test(tst, reg_flags); \ } \ break; \ \ case 0x12: \ if((opcode & 0x90) == 0x90) \ { \ printf("STRH rd, [rn - rm]!\n"); \ arm_access_memory(store, down, pre_wb, u16, half_reg); \ } \ else \ { \ if(opcode & 0x10) \ { \ printf("BX rn\n"); \ arm_bx(); \ } \ else \ { \ printf("MSR cpsr, rm\n"); \ arm_psr(reg, store, cpsr); \ } \ } \ break; \ \ case 0x13: \ if((opcode & 0x90) == 0x90) \ { \ switch((opcode >> 5) & 0x03) \ { \ case 1: \ printf("LDRH rd, [rn - rm]!\n"); \ arm_access_memory(load, down, pre_wb, u16, half_reg); \ break; \ \ case 2: \ printf("LDRSB rd, [rn - rm]!\n"); \ arm_access_memory(load, down, pre_wb, s8, half_reg); \ break; \ \ case 3: \ printf("LDRSH rd, [rn - rm]!\n"); \ arm_access_memory(load, down, pre_wb, s16, half_reg); \ break; \ } \ } \ else \ { \ printf("TEQ rd, rn, reg_op\n"); \ arm_data_proc_test(teq, reg_flags); \ } \ break; \ \ case 0x14: \ if((opcode & 0x90) == 0x90) \ { \ if(opcode & 0x20) \ { \ printf("STRH rd, [rn - imm]\n"); \ arm_access_memory(store, down, pre, u16, half_imm); \ } \ else \ { \ printf("SWPB rd, rm, [rn]\n"); \ arm_swap(u8); \ } \ } \ else \ { \ printf("MRS rd, spsr\n"); \ arm_psr(reg, read, spsr); \ } \ break; \ \ case 0x15: \ if((opcode & 0x90) == 0x90) \ { \ switch((opcode >> 5) & 0x03) \ { \ case 1: \ printf("LDRH rd, [rn - imm]\n"); \ arm_access_memory(load, down, pre, u16, half_imm); \ break; \ \ case 2: \ printf("LDRSB rd, [rn - imm]\n"); \ arm_access_memory(load, down, pre, s8, half_imm); \ break; \ \ case 3: \ printf("LDRSH rd, [rn - imm]\n"); \ arm_access_memory(load, down, pre, s16, half_imm); \ break; \ } \ } \ else \ { \ printf("CMP rn, reg_op\n"); \ arm_data_proc_test(cmp, reg); \ } \ break; \ \ case 0x16: \ if((opcode & 0x90) == 0x90) \ { \ printf("STRH rd, [rn - imm]!\n"); \ arm_access_memory(store, down, pre_wb, u16, half_imm); \ } \ else \ { \ printf("MSR spsr, rm\n"); \ arm_psr(reg, store, spsr); \ } \ break; \ \ case 0x17: \ if((opcode & 0x90) == 0x90) \ { \ switch((opcode >> 5) & 0x03) \ { \ case 1: \ printf("LDRH rd, [rn - imm]!\n"); \ arm_access_memory(load, down, pre_wb, u16, half_imm); \ break; \ \ case 2: \ printf("LDRSB rd, [rn - imm]!\n"); \ arm_access_memory(load, down, pre_wb, s8, half_imm); \ break; \ \ case 3: \ printf("LDRSH rd, [rn - imm]!\n"); \ arm_access_memory(load, down, pre_wb, s16, half_imm); \ break; \ } \ } \ else \ { \ printf("CMN rd, rn, reg_op\n"); \ arm_data_proc_test(cmn, reg); \ } \ break; \ \ case 0x18: \ if((opcode & 0x90) == 0x90) \ { \ printf("STRH rd, [rn + rm]\n"); \ arm_access_memory(store, up, pre, u16, half_reg); \ } \ else \ { \ printf("ORR rd, rn, reg_op\n"); \ arm_data_proc(orr, reg, no_flags); \ } \ break; \ \ case 0x19: \ if((opcode & 0x90) == 0x90) \ { \ switch((opcode >> 5) & 0x03) \ { \ case 1: \ printf("LDRH rd, [rn + rm]\n"); \ arm_access_memory(load, up, pre, u16, half_reg); \ break; \ \ case 2: \ printf("LDRSB rd, [rn + rm]\n"); \ arm_access_memory(load, up, pre, s8, half_reg); \ break; \ \ case 3: \ printf("LDRSH rd, [rn + rm]\n"); \ arm_access_memory(load, up, pre, s16, half_reg); \ break; \ } \ } \ else \ { \ printf("ORRS rd, rn, reg_op\n"); \ arm_data_proc(orrs, reg_flags, flags); \ } \ break; \ \ case 0x1A: \ if((opcode & 0x90) == 0x90) \ { \ printf("STRH rd, [rn + rm]!\n"); \ arm_access_memory(store, up, pre_wb, u16, half_reg); \ } \ else \ { \ printf("MOV rd, reg_op\n"); \ arm_data_proc_unary(mov, reg, no_flags); \ } \ break; \ \ case 0x1B: \ if((opcode & 0x90) == 0x90) \ { \ switch((opcode >> 5) & 0x03) \ { \ case 1: \ printf("LDRH rd, [rn + rm]!\n"); \ arm_access_memory(load, up, pre_wb, u16, half_reg); \ break; \ \ case 2: \ printf("LDRSB rd, [rn + rm]!\n"); \ arm_access_memory(load, up, pre_wb, s8, half_reg); \ break; \ \ case 3: \ printf("LDRSH rd, [rn + rm]!\n"); \ arm_access_memory(load, up, pre_wb, s16, half_reg); \ break; \ } \ } \ else \ { \ printf("MOVS rd, reg_op\n"); \ arm_data_proc_unary(movs, reg_flags, flags); \ } \ break; \ \ case 0x1C: \ if((opcode & 0x90) == 0x90) \ { \ printf("STRH rd, [rn + imm]\n"); \ arm_access_memory(store, up, pre, u16, half_imm); \ } \ else \ { \ printf("BIC rd, rn, reg_op\n"); \ arm_data_proc(bic, reg, no_flags); \ } \ break; \ \ case 0x1D: \ if((opcode & 0x90) == 0x90) \ { \ switch((opcode >> 5) & 0x03) \ { \ case 1: \ printf("LDRH rd, [rn + imm]\n"); \ arm_access_memory(load, up, pre, u16, half_imm); \ break; \ \ case 2: \ printf("LDRSB rd, [rn + imm]\n"); \ arm_access_memory(load, up, pre, s8, half_imm); \ break; \ \ case 3: \ printf("LDRSH rd, [rn + imm]\n"); \ arm_access_memory(load, up, pre, s16, half_imm); \ break; \ } \ } \ else \ { \ printf("BICS rd, rn, reg_op\n"); \ arm_data_proc(bics, reg_flags, flags); \ } \ break; \ \ case 0x1E: \ if((opcode & 0x90) == 0x90) \ { \ printf("STRH rd, [rn + imm]!\n"); \ arm_access_memory(store, up, pre_wb, u16, half_imm); \ } \ else \ { \ printf("MVN rd, reg_op\n"); \ arm_data_proc_unary(mvn, reg, no_flags); \ } \ break; \ \ case 0x1F: \ if((opcode & 0x90) == 0x90) \ { \ switch((opcode >> 5) & 0x03) \ { \ case 1: \ printf("LDRH rd, [rn + imm]!\n"); \ arm_access_memory(load, up, pre_wb, u16, half_imm); \ break; \ \ case 2: \ printf("LDRSB rd, [rn + imm]!\n"); \ arm_access_memory(load, up, pre_wb, s8, half_imm); \ break; \ \ case 3: \ printf("LDRSH rd, [rn + imm]!\n"); \ arm_access_memory(load, up, pre_wb, s16, half_imm); \ break; \ } \ } \ else \ { \ printf("MVNS rd, rn, reg_op\n"); \ arm_data_proc_unary(mvns, reg_flags, flags); \ } \ break; \ \ case 0x20: \ printf("AND rd, rn, imm\n"); \ arm_data_proc(and, imm, no_flags); \ break; \ \ case 0x21: \ printf("ANDS rd, rn, imm\n"); \ arm_data_proc(ands, imm_flags, flags); \ break; \ \ case 0x22: \ printf("EOR rd, rn, imm\n"); \ arm_data_proc(eor, imm, no_flags); \ break; \ \ case 0x23: \ printf("EORS rd, rn, imm\n"); \ arm_data_proc(eors, imm_flags, flags); \ break; \ \ case 0x24: \ printf("SUB rd, rn, imm\n"); \ arm_data_proc(sub, imm, no_flags); \ break; \ \ case 0x25: \ printf("SUBS rd, rn, imm\n"); \ arm_data_proc(subs, imm, flags); \ break; \ \ case 0x26: \ printf("RSB rd, rn, imm\n"); \ arm_data_proc(rsb, imm, no_flags); \ break; \ \ case 0x27: \ printf("RSBS rd, rn, imm\n"); \ arm_data_proc(rsbs, imm, flags); \ break; \ \ case 0x28: \ printf("ADD rd, rn, imm\n"); \ arm_data_proc(add, imm, no_flags); \ break; \ \ case 0x29: \ printf("ADDS rd, rn, imm\n"); \ arm_data_proc(adds, imm, flags); \ break; \ \ case 0x2A: \ printf("ADC rd, rn, imm\n"); \ arm_data_proc(adc, imm, no_flags); \ break; \ \ case 0x2B: \ printf("ADCS rd, rn, imm\n"); \ arm_data_proc(adcs, imm, flags); \ break; \ \ case 0x2C: \ printf("SBC rd, rn, imm\n"); \ arm_data_proc(sbc, imm, no_flags); \ break; \ \ case 0x2D: \ printf("SBCS rd, rn, imm\n"); \ arm_data_proc(sbcs, imm, flags); \ break; \ \ case 0x2E: \ printf("RSC rd, rn, imm\n"); \ arm_data_proc(rsc, imm, no_flags); \ break; \ \ case 0x2F: \ printf("RSCS rd, rn, imm\n"); \ arm_data_proc(rscs, imm, flags); \ break; \ \ case 0x30 ... 0x31: \ printf("TST rn, imm\n"); \ arm_data_proc_test(tst, imm); \ break; \ \ case 0x32: \ printf("MSR cpsr, imm\n"); \ arm_psr(imm, store, cpsr); \ break; \ \ case 0x33: \ printf("TEQ rn, imm\n"); \ arm_data_proc_test(teq, imm); \ break; \ \ case 0x34 ... 0x35: \ printf("CMP rn, imm\n"); \ arm_data_proc_test(cmp, imm); \ break; \ \ case 0x36: \ printf("MSR spsr, imm\n"); \ arm_psr(imm, store, spsr); \ break; \ \ case 0x37: \ printf("CMN rn, imm\n"); \ arm_data_proc_test(cmn, imm); \ break; \ \ case 0x38: \ printf("ORR rd, rn, imm\n"); \ arm_data_proc(orr, imm, no_flags); \ break; \ \ case 0x39: \ printf("ORRS rd, rn, imm\n"); \ arm_data_proc(orrs, imm_flags, flags); \ break; \ \ case 0x3A: \ printf("MOV rd, imm\n"); \ arm_data_proc_unary(mov, imm, no_flags); \ break; \ \ case 0x3B: \ printf("MOVS rd, imm\n"); \ arm_data_proc_unary(movs, imm_flags, flags); \ break; \ \ case 0x3C: \ printf("BIC rd, rn, imm\n"); \ arm_data_proc(bic, imm, no_flags); \ break; \ \ case 0x3D: \ printf("BICS rd, rn, imm\n"); \ arm_data_proc(bics, imm_flags, flags); \ break; \ \ case 0x3E: \ printf("MVN rd, imm\n"); \ arm_data_proc_unary(mvn, imm, no_flags); \ break; \ \ case 0x3F: \ printf("MVNS rd, imm\n"); \ arm_data_proc_unary(mvns, imm_flags, flags); \ break; \ \ case 0x40: \ printf("STR rd, [rn], -imm\n"); \ arm_access_memory(store, down, post, u32, imm); \ break; \ \ case 0x41: \ printf("LDR rd, [rn], -imm\n"); \ arm_access_memory(load, down, post, u32, imm); \ break; \ \ case 0x42: \ printf("STRT rd, [rn], -imm\n"); \ arm_access_memory(store, down, post, u32, imm); \ break; \ \ case 0x43: \ printf("LDRT rd, [rn], -imm\n"); \ arm_access_memory(load, down, post, u32, imm); \ break; \ \ case 0x44: \ printf("STRB rd, [rn], -imm\n"); \ arm_access_memory(store, down, post, u8, imm); \ break; \ \ case 0x45: \ printf("LDRB rd, [rn], -imm\n"); \ arm_access_memory(load, down, post, u8, imm); \ break; \ \ case 0x46: \ printf("STRBT rd, [rn], -imm\n"); \ arm_access_memory(store, down, post, u8, imm); \ break; \ \ case 0x47: \ printf("LDRBT rd, [rn], -imm\n"); \ arm_access_memory(load, down, post, u8, imm); \ break; \ \ case 0x48: \ printf("STR rd, [rn], +imm\n"); \ arm_access_memory(store, up, post, u32, imm); \ break; \ \ case 0x49: \ printf("LDR rd, [rn], +imm\n"); \ arm_access_memory(load, up, post, u32, imm); \ break; \ \ case 0x4A: \ printf("STRT rd, [rn], +imm\n"); \ arm_access_memory(store, up, post, u32, imm); \ break; \ \ case 0x4B: \ printf("LDRT rd, [rn], +imm\n"); \ arm_access_memory(load, up, post, u32, imm); \ break; \ \ case 0x4C: \ printf("STRB rd, [rn], +imm\n"); \ arm_access_memory(store, up, post, u8, imm); \ break; \ \ case 0x4D: \ printf("LDRB rd, [rn], +imm\n"); \ arm_access_memory(load, up, post, u8, imm); \ break; \ \ case 0x4E: \ printf("STRBT rd, [rn], +imm\n"); \ arm_access_memory(store, up, post, u8, imm); \ break; \ \ case 0x4F: \ printf("LDRBT rd, [rn], +imm\n"); \ arm_access_memory(load, up, post, u8, imm); \ break; \ \ case 0x50: \ printf("STR rd, [rn - imm]\n"); \ arm_access_memory(store, down, pre, u32, imm); \ break; \ \ case 0x51: \ printf("LDR rd, [rn - imm]\n"); \ arm_access_memory(load, down, pre, u32, imm); \ break; \ \ case 0x52: \ printf("STR rd, [rn - imm]!\n"); \ arm_access_memory(store, down, pre_wb, u32, imm); \ break; \ \ case 0x53: \ printf("LDR rd, [rn - imm]!\n"); \ arm_access_memory(load, down, pre_wb, u32, imm); \ break; \ \ case 0x54: \ printf("STRB rd, [rn - imm]\n"); \ arm_access_memory(store, down, pre, u8, imm); \ break; \ \ case 0x55: \ printf("LDRB rd, [rn - imm]\n"); \ arm_access_memory(load, down, pre, u8, imm); \ break; \ \ case 0x56: \ printf("STRB rd, [rn - imm]!\n"); \ arm_access_memory(store, down, pre_wb, u8, imm); \ break; \ \ case 0x57: \ printf("LDRB rd, [rn - imm]!\n"); \ arm_access_memory(load, down, pre_wb, u8, imm); \ break; \ \ case 0x58: \ printf("STR rd, [rn + imm]\n"); \ arm_access_memory(store, up, pre, u32, imm); \ break; \ \ case 0x59: \ printf("LDR rd, [rn + imm]\n"); \ arm_access_memory(load, up, pre, u32, imm); \ break; \ \ case 0x5A: \ printf("STR rd, [rn + imm]!\n"); \ arm_access_memory(store, up, pre_wb, u32, imm); \ break; \ \ case 0x5B: \ printf("LDR rd, [rn + imm]!\n"); \ arm_access_memory(load, up, pre_wb, u32, imm); \ break; \ \ case 0x5C: \ printf("STRB rd, [rn + imm]\n"); \ arm_access_memory(store, up, pre, u8, imm); \ break; \ \ case 0x5D: \ printf("LDRB rd, [rn + imm]\n"); \ arm_access_memory(load, up, pre, u8, imm); \ break; \ \ case 0x5E: \ printf("STRB rd, [rn + imm]!\n"); \ arm_access_memory(store, up, pre_wb, u8, imm); \ break; \ \ case 0x5F: \ printf("LDRBT rd, [rn + imm]!\n"); \ arm_access_memory(load, up, pre_wb, u8, imm); \ break; \ \ case 0x60: \ printf("STR rd, [rn], -rm\n"); \ arm_access_memory(store, down, post, u32, reg); \ break; \ \ case 0x61: \ printf("LDR rd, [rn], -rm\n"); \ arm_access_memory(load, down, post, u32, reg); \ break; \ \ case 0x62: \ printf("STRT rd, [rn], -rm\n"); \ arm_access_memory(store, down, post, u32, reg); \ break; \ \ case 0x63: \ printf("LDRT rd, [rn], -rm\n"); \ arm_access_memory(load, down, post, u32, reg); \ break; \ \ case 0x64: \ printf("STRB rd, [rn], -rm\n"); \ arm_access_memory(store, down, post, u8, reg); \ break; \ \ case 0x65: \ printf("LDRB rd, [rn], -rm\n"); \ arm_access_memory(load, down, post, u8, reg); \ break; \ \ case 0x66: \ printf("STRBT rd, [rn], -rm\n"); \ arm_access_memory(store, down, post, u8, reg); \ break; \ \ case 0x67: \ printf("LDRBT rd, [rn], -rm\n"); \ arm_access_memory(load, down, post, u8, reg); \ break; \ \ case 0x68: \ printf("STR rd, [rn], +rm\n"); \ arm_access_memory(store, up, post, u32, reg); \ break; \ \ case 0x69: \ printf("LDR rd, [rn], +rm\n"); \ arm_access_memory(load, up, post, u32, reg); \ break; \ \ case 0x6A: \ printf("STRT rd, [rn], +rm\n"); \ arm_access_memory(store, up, post, u32, reg); \ break; \ \ case 0x6B: \ printf("LDRT rd, [rn], +rm\n"); \ arm_access_memory(load, up, post, u32, reg); \ break; \ \ case 0x6C: \ printf("STRB rd, [rn], +rm\n"); \ arm_access_memory(store, up, post, u8, reg); \ break; \ \ case 0x6D: \ printf("LDRB rd, [rn], +rm\n"); \ arm_access_memory(load, up, post, u8, reg); \ break; \ \ case 0x6E: \ printf("STRBT rd, [rn], +rm\n"); \ arm_access_memory(store, up, post, u8, reg); \ break; \ \ case 0x6F: \ printf("LDRBT rd, [rn], +rm\n"); \ arm_access_memory(load, up, post, u8, reg); \ break; \ \ case 0x70: \ printf("STR rd, [rn - rm]\n"); \ arm_access_memory(store, down, pre, u32, reg); \ break; \ \ case 0x71: \ printf("LDR rd, [rn - rm]\n"); \ arm_access_memory(load, down, pre, u32, reg); \ break; \ \ case 0x72: \ printf("STR rd, [rn - rm]!\n"); \ arm_access_memory(store, down, pre_wb, u32, reg); \ break; \ \ case 0x73: \ printf("LDR rd, [rn - rm]!\n"); \ arm_access_memory(load, down, pre_wb, u32, reg); \ break; \ \ case 0x74: \ printf("STRB rd, [rn - rm]\n"); \ arm_access_memory(store, down, pre, u8, reg); \ break; \ \ case 0x75: \ printf("LDRB rd, [rn - rm]\n"); \ arm_access_memory(load, down, pre, u8, reg); \ break; \ \ case 0x76: \ printf("STRB rd, [rn - rm]!\n"); \ arm_access_memory(store, down, pre_wb, u8, reg); \ break; \ \ case 0x77: \ printf("LDRB rd, [rn - rm]!\n"); \ arm_access_memory(load, down, pre_wb, u8, reg); \ break; \ \ case 0x78: \ printf("STR rd, [rn + rm]\n"); \ arm_access_memory(store, up, pre, u32, reg); \ break; \ \ case 0x79: \ printf("LDR rd, [rn + rm]\n"); \ arm_access_memory(load, up, pre, u32, reg); \ break; \ \ case 0x7A: \ printf("STR rd, [rn + rm]!\n"); \ arm_access_memory(store, up, pre_wb, u32, reg); \ break; \ \ case 0x7B: \ printf("LDR rd, [rn + rm]!\n"); \ arm_access_memory(load, up, pre_wb, u32, reg); \ break; \ \ case 0x7C: \ printf("STRB rd, [rn + rm]\n"); \ arm_access_memory(store, up, pre, u8, reg); \ break; \ \ case 0x7D: \ printf("LDRB rd, [rn + rm]\n"); \ arm_access_memory(load, up, pre, u8, reg); \ break; \ \ case 0x7E: \ printf("STRB rd, [rn + rm]!\n"); \ arm_access_memory(store, up, pre_wb, u8, reg); \ break; \ \ case 0x7F: \ printf("LDRBT rd, [rn + rm]!\n"); \ arm_access_memory(load, up, pre_wb, u8, reg); \ break; \ \ case 0x80: \ printf("STMDA rn, rlist\n"); \ arm_block_memory(store, down_a, no, no); \ break; \ \ case 0x81: \ printf("LDMDA rn, rlist\n"); \ arm_block_memory(load, down_a, no, no); \ break; \ \ case 0x82: \ printf("STMDA rn!, rlist\n"); \ arm_block_memory(store, down_a, down, no); \ break; \ \ case 0x83: \ printf("LDMDA rn!, rlist\n"); \ arm_block_memory(load, down_a, down, no); \ break; \ \ case 0x84: \ printf("STMDA rn, rlist^\n"); \ arm_block_memory(store, down_a, no, yes); \ break; \ \ case 0x85: \ printf("LDMDA rn, rlist^\n"); \ arm_block_memory(load, down_a, no, yes); \ break; \ \ case 0x86: \ printf("STMDA rn!, rlist^\n"); \ arm_block_memory(store, down_a, down, yes); \ break; \ \ case 0x87: \ printf("LDMDA rn!, rlist^\n"); \ arm_block_memory(load, down_a, down, yes); \ break; \ \ case 0x88: \ printf("STMIA rn, rlist\n"); \ arm_block_memory(store, no, no, no); \ break; \ \ case 0x89: \ printf("LDMIA rn, rlist\n"); \ arm_block_memory(load, no, no, no); \ break; \ \ case 0x8A: \ printf("STMIA rn!, rlist\n"); \ arm_block_memory(store, no, up, no); \ break; \ \ case 0x8B: \ printf("LDMIA rn!, rlist\n"); \ arm_block_memory(load, no, up, no); \ break; \ \ case 0x8C: \ printf("STMIA rn, rlist^\n"); \ arm_block_memory(store, no, no, yes); \ break; \ \ case 0x8D: \ printf("LDMIA rn, rlist^\n"); \ arm_block_memory(load, no, no, yes); \ break; \ \ case 0x8E: \ printf("STMIA rn!, rlist^\n"); \ arm_block_memory(store, no, up, yes); \ break; \ \ case 0x8F: \ printf("LDMIA rn!, rlist^\n"); \ arm_block_memory(load, no, up, yes); \ break; \ \ case 0x90: \ printf("STMDB rn, rlist\n"); \ arm_block_memory(store, down_b, no, no); \ break; \ \ case 0x91: \ printf("LDMDB rn, rlist\n"); \ arm_block_memory(load, down_b, no, no); \ break; \ \ case 0x92: \ printf("STMDB rn!, rlist\n"); \ arm_block_memory(store, down_b, down, no); \ break; \ \ case 0x93: \ printf("LDMDB rn!, rlist\n"); \ arm_block_memory(load, down_b, down, no); \ break; \ \ case 0x94: \ printf("STMDB rn, rlist^\n"); \ arm_block_memory(store, down_b, no, yes); \ break; \ \ case 0x95: \ printf("LDMDB rn, rlist^\n"); \ arm_block_memory(load, down_b, no, yes); \ break; \ \ case 0x96: \ printf("STMDB rn!, rlist^\n"); \ arm_block_memory(store, down_b, down, yes); \ break; \ \ case 0x97: \ printf("LDMDB rn!, rlist^\n"); \ arm_block_memory(load, down_b, down, yes); \ break; \ \ case 0x98: \ printf("STMIB rn, rlist\n"); \ arm_block_memory(store, up, no, no); \ break; \ \ case 0x99: \ printf("LDMIB rn, rlist\n"); \ arm_block_memory(load, up, no, no); \ break; \ \ case 0x9A: \ printf("STMIB rn!, rlist\n"); \ arm_block_memory(store, up, up, no); \ break; \ \ case 0x9B: \ printf("LDMIB rn!, rlist\n"); \ arm_block_memory(load, up, up, no); \ break; \ \ case 0x9C: \ printf("STMIB rn, rlist^\n"); \ arm_block_memory(store, up, no, yes); \ break; \ \ case 0x9D: \ printf("LDMIB rn, rlist^\n"); \ arm_block_memory(load, up, no, yes); \ break; \ \ case 0x9E: \ printf("STMIB rn!, rlist^\n"); \ arm_block_memory(store, up, up, yes); \ break; \ \ case 0x9F: \ printf("LDMIB rn!, rlist^\n"); \ arm_block_memory(load, up, up, yes); \ break; \ \ case 0xA0 ... 0xAF: \ { \ printf("B offset\n"); \ arm_b(); \ break; \ } \ \ case 0xB0 ... 0xBF: \ { \ printf("BL offset\n"); \ arm_bl(); \ break; \ } \ \ case 0xF0 ... 0xFF: \ { \ u32 swinum = (opcode >> 16) & 0xFF; \ if (swinum == 6) { \ cycle_count += 64; printf("Big under-estimation here\n"); \ arm_hle_div(arm); \ } \ else if (swinum == 7) { \ cycle_count += 64; printf("Big under-estimation here\n"); \ arm_hle_div_arm(arm); \ } \ else { \ arm_swi(); \ } \ break; \ } \ } \ \ pc += 4 \ #define arm_flag_status() \ #define translate_thumb_instruction() \ flag_status = block_data[block_data_position].flag_data; \ check_pc_region(pc); \ last_opcode = opcode; \ opcode = readaddress16(pc_address_block, (pc & 0x7FFF)); \ emit_trace_thumb_instruction(pc); \ u8 hiop = opcode >> 8; \ printf("%x: %04x ", pc, opcode); \ switch(hiop) \ { \ case 0x00 ... 0x07: \ printf("LSL rd, rs, imm\n"); \ thumb_shift(shift, lsl, imm); \ break; \ \ case 0x08 ... 0x0F: \ printf("LSR rd, rs, imm\n"); \ thumb_shift(shift, lsr, imm); \ break; \ \ case 0x10 ... 0x17: \ printf("ASR rd, rs, imm\n"); \ thumb_shift(shift, asr, imm); \ break; \ \ case 0x18 ... 0x19: \ printf("ADD rd, rs, rn\n"); \ thumb_data_proc(add_sub, adds, reg, rd, rs, rn); \ break; \ \ case 0x1A ... 0x1B: \ printf("SUB rd, rs, rn\n"); \ thumb_data_proc(add_sub, subs, reg, rd, rs, rn); \ break; \ \ case 0x1C ... 0x1D: \ printf("ADD rd, rs, imm\n"); \ thumb_data_proc(add_sub_imm, adds, imm, rd, rs, imm); \ break; \ \ case 0x1E ... 0x1F: \ printf("SUB rd, rs, imm\n"); \ thumb_data_proc(add_sub_imm, subs, imm, rd, rs, imm); \ break; \ \ printf("MOV r0..7, imm\n"); \ case 0x20: thumb_data_proc_unary(imm, movs, imm, 0, imm); break; \ case 0x21: thumb_data_proc_unary(imm, movs, imm, 1, imm); break; \ case 0x22: thumb_data_proc_unary(imm, movs, imm, 2, imm); break; \ case 0x23: thumb_data_proc_unary(imm, movs, imm, 3, imm); break; \ case 0x24: thumb_data_proc_unary(imm, movs, imm, 4, imm); break; \ case 0x25: thumb_data_proc_unary(imm, movs, imm, 5, imm); break; \ case 0x26: thumb_data_proc_unary(imm, movs, imm, 6, imm); break; \ case 0x27: thumb_data_proc_unary(imm, movs, imm, 7, imm); break; \ \ printf("CMP r0, imm\n"); \ case 0x28: thumb_data_proc_test(imm, cmp, imm, 0, imm); break; \ case 0x29: thumb_data_proc_test(imm, cmp, imm, 1, imm); break; \ case 0x2A: thumb_data_proc_test(imm, cmp, imm, 2, imm); break; \ case 0x2B: thumb_data_proc_test(imm, cmp, imm, 3, imm); break; \ case 0x2C: thumb_data_proc_test(imm, cmp, imm, 4, imm); break; \ case 0x2D: thumb_data_proc_test(imm, cmp, imm, 5, imm); break; \ case 0x2E: thumb_data_proc_test(imm, cmp, imm, 6, imm); break; \ case 0x2F: thumb_data_proc_test(imm, cmp, imm, 7, imm); break; \ \ printf("ADD r0..7, imm\n"); \ case 0x30: thumb_data_proc(imm, adds, imm, 0, 0, imm); break; \ case 0x31: thumb_data_proc(imm, adds, imm, 1, 1, imm); break; \ case 0x32: thumb_data_proc(imm, adds, imm, 2, 2, imm); break; \ case 0x33: thumb_data_proc(imm, adds, imm, 3, 3, imm); break; \ case 0x34: thumb_data_proc(imm, adds, imm, 4, 4, imm); break; \ case 0x35: thumb_data_proc(imm, adds, imm, 5, 5, imm); break; \ case 0x36: thumb_data_proc(imm, adds, imm, 6, 6, imm); break; \ case 0x37: thumb_data_proc(imm, adds, imm, 7, 7, imm); break; \ \ printf("SUB r0..7, imm\n"); \ case 0x38: thumb_data_proc(imm, subs, imm, 0, 0, imm); break; \ case 0x39: thumb_data_proc(imm, subs, imm, 1, 1, imm); break; \ case 0x3A: thumb_data_proc(imm, subs, imm, 2, 2, imm); break; \ case 0x3B: thumb_data_proc(imm, subs, imm, 3, 3, imm); break; \ case 0x3C: thumb_data_proc(imm, subs, imm, 4, 4, imm); break; \ case 0x3D: thumb_data_proc(imm, subs, imm, 5, 5, imm); break; \ case 0x3E: thumb_data_proc(imm, subs, imm, 6, 6, imm); break; \ case 0x3F: thumb_data_proc(imm, subs, imm, 7, 7, imm); break; \ \ case 0x40: \ switch((opcode >> 6) & 0x03) \ { \ case 0x00: \ printf("AND rd, rs\n"); \ thumb_data_proc(alu_op, ands, reg, rd, rd, rs); \ break; \ \ case 0x01: \ printf("EOR rd, rs\n"); \ thumb_data_proc(alu_op, eors, reg, rd, rd, rs); \ break; \ \ case 0x02: \ printf("LSL rd, rs\n"); \ thumb_shift(alu_op, lsl, reg); \ break; \ \ case 0x03: \ printf("LSR rd, rs\n"); \ thumb_shift(alu_op, lsr, reg); \ break; \ } \ break; \ \ case 0x41: \ switch((opcode >> 6) & 0x03) \ { \ case 0x00: \ printf("ASR rd, rs\n"); \ thumb_shift(alu_op, asr, reg); \ break; \ \ case 0x01: \ printf("ADC rd, rs\n"); \ thumb_data_proc(alu_op, adcs, reg, rd, rd, rs); \ break; \ \ case 0x02: \ printf("SBC rd, rs\n"); \ thumb_data_proc(alu_op, sbcs, reg, rd, rd, rs); \ break; \ \ case 0x03: \ printf("ROR rd, rs\n"); \ thumb_shift(alu_op, ror, reg); \ break; \ } \ break; \ \ case 0x42: \ switch((opcode >> 6) & 0x03) \ { \ case 0x00: \ printf("TST rd, rs\n"); \ thumb_data_proc_test(alu_op, tst, reg, rd, rs); \ break; \ \ case 0x01: \ printf("NEG rd, rs\n"); \ thumb_data_proc_unary(alu_op, neg, reg, rd, rs); \ break; \ \ case 0x02: \ printf("CMP rd, rs\n"); \ thumb_data_proc_test(alu_op, cmp, reg, rd, rs); \ break; \ \ case 0x03: \ printf("CMN rd, rs\n"); \ thumb_data_proc_test(alu_op, cmn, reg, rd, rs); \ break; \ } \ break; \ \ case 0x43: \ switch((opcode >> 6) & 0x03) \ { \ case 0x00: \ printf("ORR rd, rs\n"); \ thumb_data_proc(alu_op, orrs, reg, rd, rd, rs); \ break; \ \ case 0x01: \ printf("MUL rd, rs\n"); \ thumb_data_proc(alu_op, muls, reg, rd, rs, rd); \ cycle_count += 2; /* Between 1 and 4 extra cycles */ \ break; \ \ case 0x02: \ printf("BIC rd, rs\n"); \ thumb_data_proc(alu_op, bics, reg, rd, rd, rs); \ break; \ \ case 0x03: \ printf("MVN rd, rs\n"); \ thumb_data_proc_unary(alu_op, mvns, reg, rd, rs); \ break; \ } \ break; \ \ case 0x44: \ printf("ADD rd, rs\n"); \ thumb_data_proc_hi(add); \ break; \ \ case 0x45: \ printf("CMP rd, rs\n"); \ thumb_data_proc_test_hi(cmp); \ break; \ \ case 0x46: \ printf("MOV rd, rs\n"); \ thumb_data_proc_mov_hi(); \ break; \ \ case 0x47: \ printf("BX rs\n"); \ thumb_bx(); \ break; \ \ case 0x48 ... 0x4F: \ printf("LDR r0..7, [pc + imm]\n"); \ { \ thumb_decode_imm(); \ u32 rdreg = (hiop & 7); \ u32 aoff = (pc & ~2) + (imm*4) + 4; \ /* ROM + same page -> optimize as const load */ \ if (!ram_region && (((aoff + 4) >> 15) == (pc >> 15))) { \ u32 value = readaddress32(pc_address_block, (aoff & 0x7FFF)); \ thumb_load_pc_pool_const(rdreg, value); \ } else { \ thumb_access_memory(load, imm, rdreg, 0, 0, pc_relative, aoff, u32);\ } \ } \ break; \ \ case 0x50 ... 0x51: \ printf("STR rd, [rb + ro]\n"); \ thumb_access_memory(store, mem_reg, rd, rb, ro, reg_reg, 0, u32); \ break; \ \ case 0x52 ... 0x53: \ printf("STRH rd, [rb + ro]\n"); \ thumb_access_memory(store, mem_reg, rd, rb, ro, reg_reg, 0, u16); \ break; \ \ case 0x54 ... 0x55: \ printf("STRB rd, [rb + ro]\n"); \ thumb_access_memory(store, mem_reg, rd, rb, ro, reg_reg, 0, u8); \ break; \ \ case 0x56 ... 0x57: \ printf("LDSB rd, [rb + ro]\n"); \ thumb_access_memory(load, mem_reg, rd, rb, ro, reg_reg, 0, s8); \ break; \ \ case 0x58 ... 0x59: \ printf("LDR rd, [rb + ro]\n"); \ thumb_access_memory(load, mem_reg, rd, rb, ro, reg_reg, 0, u32); \ break; \ \ case 0x5A ... 0x5B: \ printf("LDRH rd, [rb + ro]\n"); \ thumb_access_memory(load, mem_reg, rd, rb, ro, reg_reg, 0, u16); \ break; \ \ case 0x5C ... 0x5D: \ printf("LDRB rd, [rb + ro]\n"); \ thumb_access_memory(load, mem_reg, rd, rb, ro, reg_reg, 0, u8); \ break; \ \ case 0x5E ... 0x5F: \ printf("LDSH rd, [rb + ro]\n"); \ thumb_access_memory(load, mem_reg, rd, rb, ro, reg_reg, 0, s16); \ break; \ \ case 0x60 ... 0x67: \ printf("STR rd, [rb + imm]\n"); \ thumb_access_memory(store, mem_imm, rd, rb, 0, reg_imm, (imm * 4), \ u32); \ break; \ \ case 0x68 ... 0x6F: \ printf("LDR rd, [rb + imm]\n"); \ thumb_access_memory(load, mem_imm, rd, rb, 0, reg_imm, (imm * 4), u32); \ break; \ \ case 0x70 ... 0x77: \ printf("STRB rd, [rb + imm]\n"); \ thumb_access_memory(store, mem_imm, rd, rb, 0, reg_imm, imm, u8); \ break; \ \ case 0x78 ... 0x7F: \ printf("LDRB rd, [rb + imm]\n"); \ thumb_access_memory(load, mem_imm, rd, rb, 0, reg_imm, imm, u8); \ break; \ \ case 0x80 ... 0x87: \ printf("STRH rd, [rb + imm]\n"); \ thumb_access_memory(store, mem_imm, rd, rb, 0, reg_imm, \ (imm * 2), u16); \ break; \ \ case 0x88 ... 0x8F: \ printf("LDRH rd, [rb + imm]\n"); \ thumb_access_memory(load, mem_imm, rd, rb, 0, reg_imm, (imm * 2), u16); \ break; \ \ printf("STR r0..7, [sp + imm]\n"); \ case 0x90: \ thumb_access_memory(store, imm, 0, 13, 0, reg_imm_sp, imm, u32); \ break; \ case 0x91: \ thumb_access_memory(store, imm, 1, 13, 0, reg_imm_sp, imm, u32); \ break; \ case 0x92: \ thumb_access_memory(store, imm, 2, 13, 0, reg_imm_sp, imm, u32); \ break; \ case 0x93: \ thumb_access_memory(store, imm, 3, 13, 0, reg_imm_sp, imm, u32); \ break; \ case 0x94: \ thumb_access_memory(store, imm, 4, 13, 0, reg_imm_sp, imm, u32); \ break; \ case 0x95: \ thumb_access_memory(store, imm, 5, 13, 0, reg_imm_sp, imm, u32); \ break; \ case 0x96: \ thumb_access_memory(store, imm, 6, 13, 0, reg_imm_sp, imm, u32); \ break; \ case 0x97: \ thumb_access_memory(store, imm, 7, 13, 0, reg_imm_sp, imm, u32); \ break; \ \ printf("LDR r0..7, [sp + imm]\n"); \ case 0x98: \ thumb_access_memory(load, imm, 0, 13, 0, reg_imm_sp, imm, u32); \ break; \ case 0x99: \ thumb_access_memory(load, imm, 1, 13, 0, reg_imm_sp, imm, u32); \ break; \ case 0x9A: \ thumb_access_memory(load, imm, 2, 13, 0, reg_imm_sp, imm, u32); \ break; \ case 0x9B: \ thumb_access_memory(load, imm, 3, 13, 0, reg_imm_sp, imm, u32); \ break; \ case 0x9C: \ thumb_access_memory(load, imm, 4, 13, 0, reg_imm_sp, imm, u32); \ break; \ case 0x9D: \ thumb_access_memory(load, imm, 5, 13, 0, reg_imm_sp, imm, u32); \ break; \ case 0x9E: \ thumb_access_memory(load, imm, 6, 13, 0, reg_imm_sp, imm, u32); \ break; \ case 0x9F: \ thumb_access_memory(load, imm, 7, 13, 0, reg_imm_sp, imm, u32); \ break; \ \ printf("ADD r0..7, pc, +imm\n"); \ case 0xA0: thumb_load_pc(0); break; \ case 0xA1: thumb_load_pc(1); break; \ case 0xA2: thumb_load_pc(2); break; \ case 0xA3: thumb_load_pc(3); break; \ case 0xA4: thumb_load_pc(4); break; \ case 0xA5: thumb_load_pc(5); break; \ case 0xA6: thumb_load_pc(6); break; \ case 0xA7: thumb_load_pc(7); break; \ \ printf("ADD r0..7, sp, +imm\n"); \ case 0xA8: thumb_load_sp(0); break; \ case 0xA9: thumb_load_sp(1); break; \ case 0xAA: thumb_load_sp(2); break; \ case 0xAB: thumb_load_sp(3); break; \ case 0xAC: thumb_load_sp(4); break; \ case 0xAD: thumb_load_sp(5); break; \ case 0xAE: thumb_load_sp(6); break; \ case 0xAF: thumb_load_sp(7); break; \ \ case 0xB0 ... 0xB3: \ if((opcode >> 7) & 0x01) \ { \ printf("ADD sp, -imm\n"); \ thumb_adjust_sp(down); \ } \ else \ { \ printf("ADD sp, +imm\n"); \ thumb_adjust_sp(up); \ } \ break; \ \ case 0xB4: \ printf("PUSH rlist\n"); \ thumb_block_memory(store, down, no, 13); \ break; \ \ case 0xB5: \ printf("PUSH rlist, lr\n"); \ thumb_block_memory(store, push_lr, push_lr, 13); \ break; \ \ case 0xBC: \ printf("POP rlist\n"); \ thumb_block_memory(load, no, up, 13); \ break; \ \ case 0xBD: \ printf("POP rlist, pc\n"); \ thumb_block_memory(load, no, pop_pc, 13); \ break; \ \ case 0xC0: \ printf("STMIA r0!, rlist\n"); \ thumb_block_memory(store, no, up, 0); \ break; \ \ case 0xC1: \ printf("STMIA r1!, rlist\n"); \ thumb_block_memory(store, no, up, 1); \ break; \ \ case 0xC2: \ printf("STMIA r2!, rlist\n"); \ thumb_block_memory(store, no, up, 2); \ break; \ \ case 0xC3: \ printf("STMIA r3!, rlist\n"); \ thumb_block_memory(store, no, up, 3); \ break; \ \ case 0xC4: \ printf("STMIA r4!, rlist\n"); \ thumb_block_memory(store, no, up, 4); \ break; \ \ case 0xC5: \ printf("STMIA r5!, rlist\n"); \ thumb_block_memory(store, no, up, 5); \ break; \ \ case 0xC6: \ printf("STMIA r6!, rlist\n"); \ thumb_block_memory(store, no, up, 6); \ break; \ \ case 0xC7: \ printf("STMIA r7!, rlist\n"); \ thumb_block_memory(store, no, up, 7); \ break; \ \ case 0xC8: \ printf("LDMIA r0!, rlist\n"); \ thumb_block_memory(load, no, up, 0); \ break; \ \ case 0xC9: \ printf("LDMIA r1!, rlist\n"); \ thumb_block_memory(load, no, up, 1); \ break; \ \ case 0xCA: \ printf("LDMIA r2!, rlist\n"); \ thumb_block_memory(load, no, up, 2); \ break; \ \ case 0xCB: \ printf("LDMIA r3!, rlist\n"); \ thumb_block_memory(load, no, up, 3); \ break; \ \ case 0xCC: \ printf("LDMIA r4!, rlist\n"); \ thumb_block_memory(load, no, up, 4); \ break; \ \ case 0xCD: \ printf("LDMIA r5!, rlist\n"); \ thumb_block_memory(load, no, up, 5); \ break; \ \ case 0xCE: \ printf("LDMIA r6!, rlist\n"); \ thumb_block_memory(load, no, up, 6); \ break; \ \ case 0xCF: \ printf("LDMIA r7!, rlist\n"); \ thumb_block_memory(load, no, up, 7); \ break; \ \ case 0xD0: \ printf("BEQ label\n"); \ thumb_conditional_branch(eq); \ break; \ \ case 0xD1: \ printf("BNE label\n"); \ thumb_conditional_branch(ne); \ break; \ \ case 0xD2: \ printf("BCS label\n"); \ thumb_conditional_branch(cs); \ break; \ \ case 0xD3: \ printf("BCC label\n"); \ thumb_conditional_branch(cc); \ break; \ \ case 0xD4: \ printf("BMI label\n"); \ thumb_conditional_branch(mi); \ break; \ \ case 0xD5: \ printf("BPL label\n"); \ thumb_conditional_branch(pl); \ break; \ \ case 0xD6: \ printf("BVS label\n"); \ thumb_conditional_branch(vs); \ break; \ \ case 0xD7: \ printf("BVC label\n"); \ thumb_conditional_branch(vc); \ break; \ \ case 0xD8: \ printf("BHI label\n"); \ thumb_conditional_branch(hi); \ break; \ \ case 0xD9: \ printf("BLS label\n"); \ thumb_conditional_branch(ls); \ break; \ \ case 0xDA: \ printf("BGE label\n"); \ thumb_conditional_branch(ge); \ break; \ \ case 0xDB: \ printf("BLT label\n"); \ thumb_conditional_branch(lt); \ break; \ \ case 0xDC: \ printf("BGT label\n"); \ thumb_conditional_branch(gt); \ break; \ \ case 0xDD: \ printf("BLE label\n"); \ thumb_conditional_branch(le); \ break; \ \ case 0xDF: \ { \ u32 swinum = opcode & 0xFF; \ if (swinum == 6) { \ cycle_count += 64; /* Big under-estimation here */ \ arm_hle_div(thumb); \ } \ else if (swinum == 7) { \ cycle_count += 64; /* Big under-estimation here */ \ arm_hle_div_arm(thumb); \ } \ else { \ thumb_swi(); \ } \ break; \ } \ \ case 0xE0 ... 0xE7: \ { \ printf("B label\n"); \ thumb_b(); \ break; \ } \ \ case 0xF0 ... 0xF7: \ { \ printf("(low word) BL label\n"); \ /* This should possibly generate code if not in conjunction with a BLH \ next, but I don't think anyone will do that. */ \ break; \ } \ \ case 0xF8 ... 0xFF: \ { \ printf("(high word) BL label\n"); \ /* This might not be preceeding a BL low word (Golden Sun 2), if so \ it must be handled like an indirect branch. */ \ if((last_opcode >= 0xF000) && (last_opcode < 0xF800)) \ { \ thumb_bl(); \ } \ else \ { \ thumb_blh(); \ } \ break; \ } \ } \ \ pc += 2 \ #define thumb_flag_modifies_all() \ flag_status |= 0xFF \ #define thumb_flag_modifies_zn() \ flag_status |= 0xCC \ #define thumb_flag_modifies_znc() \ flag_status |= 0xEE \ #define thumb_flag_modifies_zn_maybe_c() \ flag_status |= 0xCE \ #define thumb_flag_modifies_c() \ flag_status |= 0x22 \ #define thumb_flag_requires_c() \ flag_status |= 0x200 \ #define thumb_flag_requires_all() \ flag_status |= 0xF00 \ #define thumb_flag_status() \ { \ u16 flag_status = 0; \ switch((opcode >> 8) & 0xFF) \ { \ /* left shift by imm */ \ case 0x00 ... 0x07: \ thumb_flag_modifies_zn(); \ if(((opcode >> 6) & 0x1F) != 0) \ { \ thumb_flag_modifies_c(); \ } \ break; \ \ /* right shift by imm */ \ case 0x08 ... 0x17: \ thumb_flag_modifies_znc(); \ break; \ \ /* add, subtract */ \ case 0x18 ... 0x1F: \ thumb_flag_modifies_all(); \ break; \ \ /* mov reg, imm */ \ case 0x20 ... 0x27: \ thumb_flag_modifies_zn(); \ break; \ \ /* cmp reg, imm; add, subtract */ \ case 0x28 ... 0x3F: \ thumb_flag_modifies_all(); \ break; \ \ case 0x40: \ switch((opcode >> 6) & 0x03) \ { \ case 0x00: \ printf("AND rd, rs\n"); \ thumb_flag_modifies_zn(); \ break; \ \ case 0x01: \ printf("EOR rd, rs\n"); \ thumb_flag_modifies_zn(); \ break; \ \ case 0x02: \ printf("LSL rd, rs\n"); \ thumb_flag_modifies_zn_maybe_c(); \ break; \ \ case 0x03: \ printf("LSR rd, rs\n"); \ thumb_flag_modifies_zn_maybe_c(); \ break; \ } \ break; \ \ case 0x41: \ switch((opcode >> 6) & 0x03) \ { \ case 0x00: \ printf("ASR rd, rs\n"); \ thumb_flag_modifies_zn_maybe_c(); \ break; \ \ case 0x01: \ printf("ADC rd, rs\n"); \ thumb_flag_modifies_all(); \ thumb_flag_requires_c(); \ break; \ \ case 0x02: \ printf("SBC rd, rs\n"); \ thumb_flag_modifies_all(); \ thumb_flag_requires_c(); \ break; \ \ case 0x03: \ printf("ROR rd, rs\n"); \ thumb_flag_modifies_zn_maybe_c(); \ break; \ } \ break; \ \ printf("TST, NEG, CMP, CMN\n"); \ case 0x42: \ thumb_flag_modifies_all(); \ break; \ \ printf("ORR, MUL, BIC, MVN\n"); \ case 0x43: \ thumb_flag_modifies_zn(); \ break; \ \ case 0x45: \ printf("CMP rd, rs\n"); \ thumb_flag_modifies_all(); \ break; \ \ /* mov might change PC (fall through if so) */ \ case 0x46: \ if((opcode & 0xFF87) != 0x4687) \ break; \ \ /* branches (can change PC) */ \ case 0x47: \ case 0xBD: \ case 0xD0 ... 0xE7: \ case 0xF0 ... 0xFF: \ thumb_flag_requires_all(); \ break; \ } \ block_data[block_data_position].flag_data = flag_status; \ } \ // I/EWRAM memory tagging // Code emitted in the RAM cache has tags (16 bit values) in the mirror tag ram // that indicate that the address contains code. The following values are used: // 0x0000 : this is just data (never translated) // 0x00XX : not used (since first byte is zero) // 0x0101 : this is code that is not the start of a translated block // 0xXXXX : this is the start of a translated block, starting from 0xFFFF downwards // LSB is always set (we decrement by two) to ensure both bytes != 0 // // The tag value is an index to a `ramtag_type` structure that sits at the end // of the RAM CACHE (grows like a stack). For simplicity we start tags at 0xFFFF // and grow like a stack. #define LAST_TAG_NUM 0x0101 #define INITIAL_TOP_TAG 0xFFFF #define CODE_TAG_BLOCK16 0x0101 #define CODE_TAG_BLOCK32 0x01010101 #define VALID_TAG(tagn) (tagn > LAST_TAG_NUM) #define allocate_tag_arm(location) { \ location[0] = ram_block_tag; \ /* Could be another thumb inst */ \ if (!location[1]) \ location[1] = CODE_TAG_BLOCK16; \ ram_block_tag -= 2; \ } #define allocate_tag_thumb(location) { \ location[0] = ram_block_tag; \ ram_block_tag -= 2; \ } typedef struct { u32 offset_arm; // Cache offset to the ARM-mode compiled block u32 offset_thumb; // Cache offset to the Thumb-mode compiled block } ramtag_type; static u32 ram_block_tag = INITIAL_TOP_TAG; inline static ramtag_type* get_ram_tag(u16 tagval) { ramtag_type *tbl = (ramtag_type*)&ram_translation_cache[RAM_TRANSLATION_CACHE_SIZE]; s16 tgidx = (s16)(tagval); return &tbl[tgidx >> 1]; /* Since LSB is always 1 and thus unused */ } // This function will return a pointer to a translated block of code. If it // doesn't exist it will translate it, if it does it will pass it back. // type should be "arm", "thumb", or "dual." For arm or thumb the PC should // be a real PC, for dual the least significant bit will determine if it's // ARM or Thumb mode. #define block_lookup_address_pc_arm() \ u32 thumb = 0; \ pc &= ~0x03 #define block_lookup_address_pc_thumb() \ u32 thumb = 1; \ pc &= ~0x01 \ #define block_lookup_translate_builder(type) \ u8 function_cc *block_lookup_translate_##type(u32 pc) \ { \ u8 pcregion = (pc >> 24); \ u16 *location; \ u32 block_tag; \ \ block_lookup_address_pc_##type(); \ \ switch(pcregion) \ { \ case 0x2: \ case 0x3: \ { \ u16* tagp = (pcregion == 2) ? (u16 *)(ewram + (pc & 0x3FFFF) + 0x40000) \ : (u16 *)(iwram + (pc & 0x7FFF)); \ ramtag_type* trentry; \ /* Allocate a tag if not a valid one, and initialize header */ \ if (!VALID_TAG(*tagp)) { \ allocate_tag_##type(tagp); \ trentry = get_ram_tag(*tagp); \ trentry->offset_arm = 0; \ trentry->offset_thumb = 0; \ } else { \ trentry = get_ram_tag(*tagp); \ } \ \ if (!trentry->offset_##type) { \ bool result; \ u8 *blkptr = ram_translation_ptr + block_prologue_size; \ trentry->offset_##type = blkptr - ram_translation_cache; \ result = translate_block_##type(pc, true); \ \ if (result) \ return blkptr; \ } else { \ return &ram_translation_cache[trentry->offset_##type]; \ } \ return NULL; \ } \ \ case 0x0: \ case 0x8 ... 0xD: \ { \ u32 key = pc | thumb; \ u32 hash_target = ((key * 2654435761U) >> (32 - ROM_BRANCH_HASH_BITS)) \ & (ROM_BRANCH_HASH_SIZE - 1); \ \ hashhdr_type *bhdr; \ u32 blk_offset = rom_branch_hash[hash_target]; \ u32 *blk_offset_addr = &rom_branch_hash[hash_target]; \ while(blk_offset) \ { \ bhdr = (hashhdr_type*)&rom_translation_cache[blk_offset]; \ if(bhdr->pc_value == key) \ return &rom_translation_cache[ \ blk_offset + sizeof(hashhdr_type) + block_prologue_size]; \ \ blk_offset = bhdr->next_entry; \ blk_offset_addr = &bhdr->next_entry; \ } \ \ { /* Not found, go ahead and translate, and backfill the hash table */ \ u8 *blkptr; \ bool result; \ bhdr = (hashhdr_type*)rom_translation_ptr; \ bhdr->pc_value = key; \ bhdr->next_entry = 0; \ *blk_offset_addr = (u32)(rom_translation_ptr - rom_translation_cache);\ rom_translation_ptr += sizeof(hashhdr_type); \ blkptr = rom_translation_ptr + block_prologue_size; \ result = translate_block_##type(pc, false); \ \ if (result) \ return blkptr; \ } \ return NULL; \ } \ } \ \ /* Do not return NULL since it could indeed happen that some branch \ points to some random place (perhaps due to being garbage). This can \ happen when especulatively compiling code in RAM. Perhaps the game \ patches these instructions later, which would trigger a flush */ \ return (u8*)(~0); \ } \ block_lookup_translate_builder(arm); block_lookup_translate_builder(thumb); u8 function_cc *block_lookup_address_dual(u32 pc) { u32 thumb = pc & 0x01; if(thumb) { pc &= ~1; reg[REG_CPSR] |= 0x20; return block_lookup_address_thumb(pc); } else { pc = (pc + 2) & ~0x03; reg[REG_CPSR] &= ~0x20; return block_lookup_address_arm(pc); } } u8 function_cc *block_lookup_address_arm(u32 pc) { unsigned i; for (i = 0; i < 4; i++) { u8 *ret = block_lookup_translate_arm(pc); if (ret) { translate_icache_sync(); return ret; } } printf("bad jump %x (%x)\n", pc, reg[REG_PC]); fflush(stdout); return NULL; } u8 function_cc *block_lookup_address_thumb(u32 pc) { unsigned i; for (i = 0; i < 4; i++) { u8 *ret = block_lookup_translate_thumb(pc); if (ret) { translate_icache_sync(); return ret; } } printf("bad jump %x (%x)\n", pc, reg[REG_PC]); fflush(stdout); return NULL; } // Potential exit point: If the rd field is pc for instructions is 0x0F, // the instruction is b/bl/bx, or the instruction is ldm with PC in the // register list. // All instructions with upper 3 bits less than 100b have an rd field // except bx, where the bits must be 0xF there anyway, multiplies, // which cannot have 0xF in the corresponding fields, and msr, which // has 0x0F there but doesn't end things (therefore must be special // checked against). Because MSR and BX overlap both are checked for. #define arm_exit_point \ (((opcode < 0x8000000) && ((opcode & 0x000F000) == 0x000F000) && \ ((opcode & 0xDB0F000) != 0x120F000)) || \ ((opcode & 0x12FFF10) == 0x12FFF10) || \ ((opcode & 0x8108000) == 0x8108000) || \ ((opcode >= 0xA000000) && (opcode < 0xF000000)) || \ ((opcode >= 0xF000000) && (!is_div_swi((opcode >> 16) & 0xFF)))) \ #define arm_opcode_branch \ ((opcode & 0xE000000) == 0xA000000) \ #define arm_opcode_swi \ ((opcode & 0xF000000) == 0xF000000) \ #define arm_opcode_unconditional_branch \ (condition == 0x0E) \ #define arm_load_opcode() \ opcode = readaddress32(pc_address_block, (block_end_pc & 0x7FFF)); \ condition = opcode >> 28; \ \ opcode &= 0xFFFFFFF; \ \ block_end_pc += 4 \ #define arm_branch_target() \ branch_target = (block_end_pc + 4 + (((s32)(opcode & 0xFFFFFF) << 8) >> 6)) \ // Contiguous conditional block flags modification - it will set 0x20 in the // condition's bits if this instruction modifies flags. Taken from the CPU // switch so it'd better be right this time. #define arm_set_condition(_condition) \ block_data[block_data_position].condition = _condition; \ switch((opcode >> 20) & 0xFF) \ { \ case 0x01: \ case 0x03: \ case 0x09: \ case 0x0B: \ case 0x0D: \ case 0x0F: \ if((((opcode >> 5) & 0x03) == 0) || ((opcode & 0x90) != 0x90)) \ block_data[block_data_position].condition |= 0x20; \ break; \ \ case 0x05: \ case 0x07: \ case 0x11: \ case 0x13: \ case 0x15 ... 0x17: \ case 0x19: \ case 0x1B: \ case 0x1D: \ case 0x1F: \ if((opcode & 0x90) != 0x90) \ block_data[block_data_position].condition |= 0x20; \ break; \ \ case 0x12: \ if(((opcode & 0x90) != 0x90) && !(opcode & 0x10)) \ block_data[block_data_position].condition |= 0x20; \ break; \ \ case 0x21: \ case 0x23: \ case 0x25: \ case 0x27: \ case 0x29: \ case 0x2B: \ case 0x2D: \ case 0x2F ... 0x37: \ case 0x39: \ case 0x3B: \ case 0x3D: \ case 0x3F: \ block_data[block_data_position].condition |= 0x20; \ break; \ } \ #define arm_instruction_width 4 #define arm_base_cycles() \ cycle_count += def_seq_cycles[pc >> 24][1] \ // For now this just sets a variable that says flags should always be // computed. #define arm_dead_flag_eliminate() \ flag_status = 0xF \ // The following Thumb instructions can exit: // b, bl, bx, swi, pop {... pc}, and mov pc, ..., the latter being a hireg // op only. Rather simpler to identify than the ARM set. #define thumb_exit_point \ (((opcode >= 0xD000) && (opcode < 0xDF00)) || \ (((opcode & 0xFF00) == 0xDF00) && \ (!is_div_swi(opcode & 0xFF))) || \ ((opcode >= 0xE000) && (opcode < 0xE800)) || \ ((opcode & 0xFF00) == 0x4700) || \ ((opcode & 0xFF00) == 0xBD00) || \ ((opcode & 0xFF87) == 0x4687) || \ ((opcode >= 0xF800))) \ #define thumb_opcode_branch \ (((opcode >= 0xD000) && (opcode < 0xDF00)) || \ ((opcode >= 0xE000) && (opcode < 0xE800)) || \ (opcode >= 0xF800)) \ #define thumb_opcode_swi \ ((opcode & 0xFF00) == 0xDF00) \ #define thumb_opcode_unconditional_branch \ ((opcode < 0xD000) || (opcode >= 0xDF00)) \ #define thumb_load_opcode() \ last_opcode = opcode; \ opcode = readaddress16(pc_address_block, (block_end_pc & 0x7FFF)); \ \ block_end_pc += 2 \ #define thumb_branch_target() \ if(opcode < 0xE000) \ { \ branch_target = block_end_pc + 2 + ((s8)(opcode & 0xFF) * 2); \ } \ else \ \ if(opcode < 0xF800) \ { \ branch_target = block_end_pc + 2 + ((s32)((opcode & 0x7FF) << 21) >> 20); \ } \ else \ { \ if((last_opcode >= 0xF000) && (last_opcode < 0xF800)) \ { \ branch_target = \ (block_end_pc + ((s32)((last_opcode & 0x07FF) << 21) >> 9) + \ ((opcode & 0x07FF) * 2)); \ } \ else \ { \ goto no_direct_branch; \ } \ } \ #define thumb_set_condition(_condition) \ #define thumb_instruction_width 2 #define thumb_base_cycles() \ cycle_count += def_seq_cycles[pc >> 24][0] \ // Here's how this works: each instruction has three different sets of flag // attributes, each consisiting of a 4bit mask describing how that instruction // interacts with the 4 main flags (N/Z/C/V). // The first set, in bits 0:3, is the set of flags the instruction may // modify. After this pass this is changed to the set of flags the instruction // should modify - if the bit for the corresponding flag is not set then code // does not have to be generated to calculate the flag for that instruction. // The second set, in bits 7:4, is the set of flags that the instruction must // modify (ie, for shifts by the register values the instruction may not // always modify the C flag, and thus the C bit won't be set here). // The third set, in bits 11:8, is the set of flags that the instruction uses // in its computation, or the set of flags that will be needed after the // instruction is done. For any instructions that change the PC all of the // bits should be set because it is (for now) unknown what flags will be // needed after it arrives at its destination. Instructions that use the // carry flag as input will have it set as well. // The algorithm is a simple liveness analysis procedure: It starts at the // bottom of the instruction stream and sets a "currently needed" mask to // the flags needed mask of the current instruction. Then it moves down // an instruction, ANDs that instructions "should generate" mask by the // "currently needed" mask, then ANDs the "currently needed" mask by // the 1's complement of the instruction's "must generate" mask, and ORs // the "currently needed" mask by the instruction's "flags needed" mask. #define thumb_dead_flag_eliminate() \ { \ u32 needed_mask = 0xff; \ \ while(--block_data_position >= 0) \ { \ flag_status = block_data[block_data_position].flag_data; \ block_data[block_data_position].flag_data = \ (flag_status & needed_mask); \ needed_mask &= ~((flag_status >> 4) & 0x0F); \ needed_mask |= flag_status >> 8; \ } \ } \ #define MAX_BLOCK_SIZE 8192 #define MAX_EXITS 256 block_data_type block_data[MAX_BLOCK_SIZE]; block_exit_type block_exits[MAX_EXITS]; #define smc_write_arm_yes() { \ intptr_t offset = (pc < 0x03000000) ? 0x40000 : -0x8000; \ if(address32(pc_address_block, (block_end_pc & 0x7FFF) + offset) == 0) \ { \ address32(pc_address_block, (block_end_pc & 0x7FFF) + offset) = \ CODE_TAG_BLOCK32; \ } \ } #define smc_write_thumb_yes() { \ intptr_t offset = (pc < 0x03000000) ? 0x40000 : -0x8000; \ if(address16(pc_address_block, (block_end_pc & 0x7FFF) + offset) == 0) \ { \ address16(pc_address_block, (block_end_pc & 0x7FFF) + offset) = \ CODE_TAG_BLOCK16; \ } \ } #define smc_write_arm_no() \ #define smc_write_thumb_no() \ #define scan_block(type, smc_write_op) \ { \ __label__ block_end; \ /* Find the end of the block */ \ do \ { \ check_pc_region(block_end_pc); \ smc_write_##type##_##smc_write_op(); \ type##_load_opcode(); \ type##_flag_status(); \ \ if(type##_exit_point) \ { \ /* Branch/branch with link */ \ if(type##_opcode_branch) \ { \ __label__ no_direct_branch; \ type##_branch_target(); \ block_exits[block_exit_position].branch_target = branch_target; \ block_exit_position++; \ \ /* Give the branch target macro somewhere to bail if it turns out to \ be an indirect branch (ala malformed Thumb bl) */ \ no_direct_branch:; \ } \ \ /* SWI branches to the BIOS, unless it's an HLE call, then it is \ not parsed as an exit_point but rather an "instruction" of sorts. */ \ if(type##_opcode_swi) \ { \ block_exits[block_exit_position].branch_target = 0x00000008; \ block_exit_position++; \ } \ \ type##_set_condition(condition | 0x10); \ \ /* Only unconditional branches can end the block. */ \ if(type##_opcode_unconditional_branch) \ { \ /* Check to see if any prior block exits branch after here, \ if so don't end the block. Starts from the top and works \ down because the most recent branch is most likely to \ join after the end (if/then form) */ \ for(i = block_exit_position - 2; i >= 0; i--) \ { \ if(block_exits[i].branch_target == block_end_pc) \ break; \ } \ \ if(i < 0) \ break; \ } \ if(block_exit_position == MAX_EXITS) \ break; \ } \ else \ { \ type##_set_condition(condition); \ } \ \ for(i = 0; i < translation_gate_targets; i++) \ { \ if(block_end_pc == translation_gate_target_pc[i]) \ goto block_end; \ } \ \ block_data[block_data_position].update_cycles = 0; \ block_data_position++; \ if((block_data_position == MAX_BLOCK_SIZE) || \ (block_end_pc == 0x3007FF0) || (block_end_pc == 0x203FFFF0)) \ { \ break; \ } \ } while(1); \ \ block_end:; \ } \ #define arm_fix_pc() \ pc &= ~0x03 \ #define thumb_fix_pc() \ pc &= ~0x01 \ #define update_pc_limits() \ if (ram_region) { \ if (pc >= 0x3000000) { \ iwram_code_min = MIN(pc & 0x7FFF, iwram_code_min); \ iwram_code_max = MAX(pc & 0x7FFF, iwram_code_max); \ } else { \ ewram_code_min = MIN(pc & 0x3FFFF, ewram_code_min); \ ewram_code_max = MAX(pc & 0x3FFFF, ewram_code_max); \ } \ } \ bool translate_block_arm(u32 pc, bool ram_region) { u32 opcode = 0; u32 last_opcode; u32 condition; u32 last_condition; u32 pc_region = (pc >> 15); u32 new_pc_region; u8 *pc_address_block = memory_map_read[pc_region]; u32 block_start_pc = pc; u32 block_end_pc = pc; u32 block_exit_position = 0; s32 block_data_position = 0; u32 external_block_exit_position = 0; u32 branch_target; u32 cycle_count = 0; u8 *translation_target; u8 *backpatch_address = NULL; u8 *translation_ptr = NULL; u8 *translation_cache_limit = NULL; s32 i; u32 flag_status; block_exit_type external_block_exits[MAX_EXITS]; generate_block_extra_vars_arm(); arm_fix_pc(); if(!pc_address_block) pc_address_block = load_gamepak_page(pc_region & 0x3FF); if (ram_region) { translation_ptr = ram_translation_ptr; translation_cache_limit = &ram_translation_cache[ RAM_TRANSLATION_CACHE_SIZE - TRANSLATION_CACHE_LIMIT_THRESHOLD - (0x10000 - ram_block_tag) / 2 * sizeof(ramtag_type)]; } else { translation_ptr = rom_translation_ptr; translation_cache_limit = rom_translation_cache + ROM_TRANSLATION_CACHE_SIZE - TRANSLATION_CACHE_LIMIT_THRESHOLD; } generate_block_prologue(); /* This is a function because it's used a lot more than it might seem (all of the data processing functions can access it), and its expansion was massacreing the compiler. */ if(ram_region) { scan_block(arm, yes); } else { scan_block(arm, no); } for(i = 0; i < block_exit_position; i++) { branch_target = block_exits[i].branch_target; if((branch_target > block_start_pc) && (branch_target < block_end_pc)) { block_data[(branch_target - block_start_pc) / arm_instruction_width].update_cycles = 1; } } arm_dead_flag_eliminate(); block_exit_position = 0; block_data_position = 0; last_condition = 0x0E; while(pc != block_end_pc) { block_data[block_data_position].block_offset = translation_ptr; arm_base_cycles(); if (pc == cheat_master_hook) { arm_process_cheats(); } update_pc_limits(); translate_arm_instruction(); block_data_position++; /* If it went too far the cache needs to be flushed and the process restarted. Because we might already be nested several stages in a simple recursive call here won't work, it has to pedal out to the beginning. */ if(translation_ptr > translation_cache_limit) { if (ram_region) flush_translation_cache_ram(); else flush_translation_cache_rom(); return false; } /* If the next instruction is a block entry point update the cycle counter and update */ if (pc != block_end_pc && block_data[block_data_position].update_cycles) { generate_cycle_update(); } } /* This can happen if the last instruction is *not* inconditional */ if ((last_condition & 0x0F) != 0x0E) { generate_branch_patch_conditional(backpatch_address, translation_ptr); } /* Unconditionally generate translation targets. In case we hit one or in the unlikely case that block was too big (and not finalized) */ generate_translation_gate(arm); for(i = 0; i < block_exit_position; i++) { branch_target = block_exits[i].branch_target; if((branch_target >= block_start_pc) && (branch_target < block_end_pc)) { /* Internal branch, patch to recorded address */ translation_target = block_data[(branch_target - block_start_pc) / arm_instruction_width].block_offset; generate_branch_patch_unconditional(block_exits[i].branch_source, translation_target); } else { /* External branch, save for later */ external_block_exits[external_block_exit_position].branch_target = branch_target; external_block_exits[external_block_exit_position].branch_source = block_exits[i].branch_source; external_block_exit_position++; } } if (ram_region) ram_translation_ptr = translation_ptr; else rom_translation_ptr = translation_ptr; for(i = 0; i < external_block_exit_position; i++) { branch_target = external_block_exits[i].branch_target; if(branch_target == 0x00000008) translation_target = bios_swi_entrypoint; else translation_target = block_lookup_translate_arm(branch_target); if (!translation_target) return false; generate_branch_patch_unconditional( external_block_exits[i].branch_source, translation_target); } return true; } bool translate_block_thumb(u32 pc, bool ram_region) { u32 opcode = 0; u32 last_opcode; u32 condition; u32 pc_region = (pc >> 15); u32 new_pc_region; u8 *pc_address_block = memory_map_read[pc_region]; u32 block_start_pc = pc; u32 block_end_pc = pc; u32 block_exit_position = 0; s32 block_data_position = 0; u32 external_block_exit_position = 0; u32 branch_target; u32 cycle_count = 0; u8 *translation_target; u8 *backpatch_address = NULL; u8 *translation_ptr = NULL; u8 *translation_cache_limit = NULL; s32 i; u32 flag_status; block_exit_type external_block_exits[MAX_EXITS]; generate_block_extra_vars_thumb(); thumb_fix_pc(); if(!pc_address_block) pc_address_block = load_gamepak_page(pc_region & 0x3FF); if (ram_region) { translation_ptr = ram_translation_ptr; translation_cache_limit = &ram_translation_cache[ RAM_TRANSLATION_CACHE_SIZE - TRANSLATION_CACHE_LIMIT_THRESHOLD - (0x10000 - ram_block_tag) / 2 * sizeof(ramtag_type)]; } else { translation_ptr = rom_translation_ptr; translation_cache_limit = &rom_translation_cache[ ROM_TRANSLATION_CACHE_SIZE - TRANSLATION_CACHE_LIMIT_THRESHOLD]; } generate_block_prologue(); /* This is a function because it's used a lot more than it might seem (all of the data processing functions can access it), and its expansion was massacreing the compiler. */ if(ram_region) { scan_block(thumb, yes); } else { scan_block(thumb, no); } for(i = 0; i < block_exit_position; i++) { branch_target = block_exits[i].branch_target; if((branch_target > block_start_pc) && (branch_target < block_end_pc)) { block_data[(branch_target - block_start_pc) / thumb_instruction_width].update_cycles = 1; } } thumb_dead_flag_eliminate(); block_exit_position = 0; block_data_position = 0; while(pc != block_end_pc) { block_data[block_data_position].block_offset = translation_ptr; thumb_base_cycles(); if (pc == cheat_master_hook) { thumb_process_cheats(); } update_pc_limits(); translate_thumb_instruction(); block_data_position++; /* If it went too far the cache needs to be flushed and the process restarted. Because we might already be nested several stages in a simple recursive call here won't work, it has to pedal out to the beginning. */ if(translation_ptr > translation_cache_limit) { if (ram_region) flush_translation_cache_ram(); else flush_translation_cache_rom(); return false; } /* If the next instruction is a block entry point update the cycle counter and update */ if (pc != block_end_pc && block_data[block_data_position].update_cycles) { generate_cycle_update(); } } /* Unconditionally generate translation targets. In case we hit one or in the unlikely case that block was too big (and not finalized) */ generate_translation_gate(thumb); for(i = 0; i < block_exit_position; i++) { branch_target = block_exits[i].branch_target; if((branch_target >= block_start_pc) && (branch_target < block_end_pc)) { /* Internal branch, patch to recorded address */ translation_target = block_data[(branch_target - block_start_pc) / thumb_instruction_width].block_offset; generate_branch_patch_unconditional(block_exits[i].branch_source, translation_target); } else { /* External branch, save for later */ external_block_exits[external_block_exit_position].branch_target = branch_target; external_block_exits[external_block_exit_position].branch_source = block_exits[i].branch_source; external_block_exit_position++; } } if (ram_region) ram_translation_ptr = translation_ptr; else rom_translation_ptr = translation_ptr; for(i = 0; i < external_block_exit_position; i++) { branch_target = external_block_exits[i].branch_target; if(branch_target == 0x00000008) translation_target = bios_swi_entrypoint; else translation_target = block_lookup_translate_thumb(branch_target); if (!translation_target) return false; generate_branch_patch_unconditional( external_block_exits[i].branch_source, translation_target); } return true; } void init_bios_hooks(void) { // Pre-generate this entry point so that we can safely invoke fast // SWI calls from ROM and RAM regardless of cache flushes. rom_translation_ptr = &rom_translation_cache[rom_cache_watermark]; last_rom_translation_ptr = rom_translation_ptr; bios_swi_entrypoint = block_lookup_address_arm(0x8); rom_cache_watermark = (u32)(rom_translation_ptr - rom_translation_cache); } void flush_translation_cache_ram(void) { /* Flushes RAM caches avoiding doing too much work (ie. wiping unused memory) */ flush_ram_count++; /*printf("ram flush %d (pc %x), %x to %x, %x to %x\n", flush_ram_count, reg[REG_PC], iwram_code_min, iwram_code_max, ewram_code_min, ewram_code_max);*/ last_ram_translation_ptr = ram_translation_cache; ram_translation_ptr = ram_translation_cache; // Proceed to clean the SMC area if needed // (also try to memset as little as possible for performance) if (iwram_code_max) { if(iwram_code_max > iwram_code_min) { iwram_code_min &= ~15U; iwram_code_max = MIN(iwram_code_max + 8, 0x8000); memset(&iwram[iwram_code_min], 0, iwram_code_max - iwram_code_min); } else memset(iwram, 0, 0x8000); } if (ewram_code_max) { if(ewram_code_max > ewram_code_min) { ewram_code_min &= ~15U; ewram_code_max = MIN(ewram_code_max + 8, 0x40000); memset(&ewram[0x40000 + ewram_code_min], 0, ewram_code_max - ewram_code_min); } else memset(&ewram[0x40000], 0, 0x40000); } iwram_code_min = ~0U; iwram_code_max = 0U; ewram_code_min = ~0U; ewram_code_max = 0U; ram_block_tag = INITIAL_TOP_TAG; } void flush_translation_cache_rom(void) { /* We flush the generated code except for everything below the watermark. */ last_rom_translation_ptr = &rom_translation_cache[rom_cache_watermark]; rom_translation_ptr = &rom_translation_cache[rom_cache_watermark]; memset(rom_branch_hash, 0, sizeof(rom_branch_hash)); } void init_dynarec_caches(void) { /* Initialize caches so that we can start initalizing the emitter. */ rom_translation_ptr = last_rom_translation_ptr = &rom_translation_cache[0]; memset(rom_branch_hash, 0, sizeof(rom_branch_hash)); ram_translation_ptr = last_ram_translation_ptr = &ram_translation_cache[0]; memset(iwram, 0, 0x8000); memset(&ewram[0x40000], 0, 0x40000); ewram_code_min = 0; ewram_code_max = 0x40000; iwram_code_min = 0; iwram_code_max = 0x8000; } void flush_dynarec_caches(void) { /* Flush ROM and RAM caches. */ flush_translation_cache_rom(); ewram_code_min = 0; ewram_code_max = 0x40000; iwram_code_min = 0; iwram_code_max = 0x8000; flush_translation_cache_ram(); }