Mercurial > repos > blastem
view backend_x86.c @ 1489:637fbc3b5063 nuklear_ui
Added code to persist config back to a file
| author | Michael Pavone <pavone@retrodev.com> |
|---|---|
| date | Wed, 29 Nov 2017 08:41:37 -0800 |
| parents | 5d41d0574863 |
| children | 2a5649a767e7 |
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#include "backend.h" #include "gen_x86.h" #include <string.h> void cycles(cpu_options *opts, uint32_t num) { if (opts->limit < 0) { sub_ir(&opts->code, num*opts->clock_divider, opts->cycles, SZ_D); } else { add_ir(&opts->code, num*opts->clock_divider, opts->cycles, SZ_D); } } void check_cycles_int(cpu_options *opts, uint32_t address) { code_info *code = &opts->code; uint8_t cc; if (opts->limit < 0) { cmp_ir(code, 1, opts->cycles, SZ_D); cc = CC_NS; } else { cmp_rr(code, opts->cycles, opts->limit, SZ_D); cc = CC_A; } code_ptr jmp_off = code->cur+1; jcc(code, cc, jmp_off+1); mov_ir(code, address, opts->scratch1, SZ_D); call(code, opts->handle_cycle_limit_int); *jmp_off = code->cur - (jmp_off+1); } void retranslate_calc(cpu_options *opts) { code_info *code = &opts->code; code_info tmp = *code; uint8_t cc; if (opts->limit < 0) { cmp_ir(code, 1, opts->cycles, SZ_D); cc = CC_NS; } else { cmp_rr(code, opts->cycles, opts->limit, SZ_D); cc = CC_A; } jcc(code, cc, code->cur+2); opts->move_pc_off = code->cur - tmp.cur; mov_ir(code, 0x1234, opts->scratch1, SZ_D); opts->move_pc_size = code->cur - tmp.cur - opts->move_pc_off; *code = tmp; } void patch_for_retranslate(cpu_options *opts, code_ptr native_address, code_ptr handler) { if (!is_mov_ir(native_address)) { //instruction is not already patched for either retranslation or a breakpoint //copy original mov_ir instruction containing PC to beginning of native code area memmove(native_address, native_address + opts->move_pc_off, opts->move_pc_size); } //jump to the retranslation handler code_info tmp = { .cur = native_address + opts->move_pc_size, .last = native_address + 256, .stack_off = 0 }; jmp(&tmp, handler); } void check_cycles(cpu_options * opts) { code_info *code = &opts->code; uint8_t cc; if (opts->limit < 0) { cmp_ir(code, 1, opts->cycles, SZ_D); cc = CC_NS; } else { cmp_rr(code, opts->cycles, opts->limit, SZ_D); cc = CC_A; } check_alloc_code(code, MAX_INST_LEN*2); code_ptr jmp_off = code->cur+1; jcc(code, cc, jmp_off+1); call(code, opts->handle_cycle_limit); *jmp_off = code->cur - (jmp_off+1); } void log_address(cpu_options *opts, uint32_t address, char * format) { code_info *code = &opts->code; call(code, opts->save_context); push_r(code, opts->context_reg); mov_rr(code, opts->cycles, RDX, SZ_D); mov_ir(code, (int64_t)format, RDI, SZ_PTR); mov_ir(code, address, RSI, SZ_D); call_args_abi(code, (code_ptr)printf, 3, RDI, RSI, RDX); pop_r(code, opts->context_reg); call(code, opts->load_context); } void check_code_prologue(code_info *code) { check_alloc_code(code, MAX_INST_LEN*4); } code_ptr gen_mem_fun(cpu_options * opts, memmap_chunk const * memmap, uint32_t num_chunks, ftype fun_type, code_ptr *after_inc) { code_info *code = &opts->code; code_ptr start = code->cur; check_cycles(opts); uint8_t is_write = fun_type == WRITE_16 || fun_type == WRITE_8; uint8_t adr_reg = is_write ? opts->scratch2 : opts->scratch1; uint8_t size = (fun_type == READ_16 || fun_type == WRITE_16) ? SZ_W : SZ_B; if (size != SZ_B && opts->align_error_mask) { test_ir(code, opts->align_error_mask, adr_reg, SZ_D); jcc(code, CC_NZ, is_write ? opts->handle_align_error_write : opts->handle_align_error_read); } cycles(opts, opts->bus_cycles); if (after_inc) { *after_inc = code->cur; } if (opts->address_size == SZ_D && opts->address_mask != 0xFFFFFFFF) { and_ir(code, opts->address_mask, adr_reg, SZ_D); } else if (opts->address_size == SZ_W && opts->address_mask != 0xFFFF) { and_ir(code, opts->address_mask, adr_reg, SZ_W); } code_ptr lb_jcc = NULL, ub_jcc = NULL; uint16_t access_flag = is_write ? MMAP_WRITE : MMAP_READ; uint32_t ram_flags_off = opts->ram_flags_off; uint32_t min_address = 0; uint32_t max_address = opts->max_address; for (uint32_t chunk = 0; chunk < num_chunks; chunk++) { if (memmap[chunk].start > min_address) { cmp_ir(code, memmap[chunk].start, adr_reg, opts->address_size); lb_jcc = code->cur + 1; jcc(code, CC_C, code->cur + 2); } else { min_address = memmap[chunk].end; } if (memmap[chunk].end < max_address) { cmp_ir(code, memmap[chunk].end, adr_reg, opts->address_size); ub_jcc = code->cur + 1; jcc(code, CC_NC, code->cur + 2); } else { max_address = memmap[chunk].start; } if (memmap[chunk].mask != opts->address_mask) { and_ir(code, memmap[chunk].mask, adr_reg, opts->address_size); } void * cfun; switch (fun_type) { case READ_16: cfun = memmap[chunk].read_16; break; case READ_8: cfun = memmap[chunk].read_8; break; case WRITE_16: cfun = memmap[chunk].write_16; break; case WRITE_8: cfun = memmap[chunk].write_8; break; default: cfun = NULL; } if(memmap[chunk].flags & access_flag) { if (memmap[chunk].flags & MMAP_PTR_IDX) { if (memmap[chunk].flags & MMAP_FUNC_NULL) { cmp_irdisp(code, 0, opts->context_reg, opts->mem_ptr_off + sizeof(void*) * memmap[chunk].ptr_index, SZ_PTR); code_ptr not_null = code->cur + 1; jcc(code, CC_NZ, code->cur + 2); call(code, opts->save_context); if (is_write) { call_args_abi(code, cfun, 3, opts->scratch2, opts->context_reg, opts->scratch1); mov_rr(code, RAX, opts->context_reg, SZ_PTR); } else { push_r(code, opts->context_reg); call_args_abi(code, cfun, 2, opts->scratch1, opts->context_reg); pop_r(code, opts->context_reg); mov_rr(code, RAX, opts->scratch1, size); } jmp(code, opts->load_context); *not_null = code->cur - (not_null + 1); } if ((opts->byte_swap || memmap[chunk].flags & MMAP_BYTESWAP) && size == SZ_B) { xor_ir(code, 1, adr_reg, opts->address_size); } if (opts->address_size != SZ_D) { movzx_rr(code, adr_reg, adr_reg, opts->address_size, SZ_D); } if (is_write && (memmap[chunk].flags & MMAP_CODE)) { push_r(code, adr_reg); } add_rdispr(code, opts->context_reg, opts->mem_ptr_off + sizeof(void*) * memmap[chunk].ptr_index, adr_reg, SZ_PTR); if (is_write) { mov_rrind(code, opts->scratch1, opts->scratch2, size); if (memmap[chunk].flags & MMAP_CODE) { pop_r(code, adr_reg); } } else { mov_rindr(code, opts->scratch1, opts->scratch1, size); } } else { uint8_t tmp_size = size; if (size == SZ_B) { if ((memmap[chunk].flags & MMAP_ONLY_ODD) || (memmap[chunk].flags & MMAP_ONLY_EVEN)) { bt_ir(code, 0, adr_reg, opts->address_size); code_ptr good_addr = code->cur + 1; jcc(code, (memmap[chunk].flags & MMAP_ONLY_ODD) ? CC_C : CC_NC, code->cur + 2); if (!is_write) { mov_ir(code, 0xFF, opts->scratch1, SZ_B); } retn(code); *good_addr = code->cur - (good_addr + 1); shr_ir(code, 1, adr_reg, opts->address_size); } else if (opts->byte_swap || memmap[chunk].flags & MMAP_BYTESWAP) { xor_ir(code, 1, adr_reg, opts->address_size); } } else if ((memmap[chunk].flags & MMAP_ONLY_ODD) || (memmap[chunk].flags & MMAP_ONLY_EVEN)) { tmp_size = SZ_B; shr_ir(code, 1, adr_reg, opts->address_size); if ((memmap[chunk].flags & MMAP_ONLY_EVEN) && is_write) { shr_ir(code, 8, opts->scratch1, SZ_W); } } if (opts->address_size != SZ_D) { movzx_rr(code, adr_reg, adr_reg, opts->address_size, SZ_D); } if ((intptr_t)memmap[chunk].buffer <= 0x7FFFFFFF && (intptr_t)memmap[chunk].buffer >= -2147483648) { if (is_write) { mov_rrdisp(code, opts->scratch1, opts->scratch2, (intptr_t)memmap[chunk].buffer, tmp_size); } else { mov_rdispr(code, opts->scratch1, (intptr_t)memmap[chunk].buffer, opts->scratch1, tmp_size); } } else { if (is_write) { push_r(code, opts->scratch2); mov_ir(code, (intptr_t)memmap[chunk].buffer, opts->scratch2, SZ_PTR); add_rdispr(code, RSP, 0, opts->scratch2, SZ_PTR); mov_rrind(code, opts->scratch1, opts->scratch2, tmp_size); if (is_write && (memmap[chunk].flags & MMAP_CODE)) { pop_r(code, opts->scratch2); } else { add_ir(code, sizeof(void*), RSP, SZ_D); code->stack_off -= sizeof(void *); } } else { push_r(code, opts->scratch2); mov_ir(code, (intptr_t)memmap[chunk].buffer, opts->scratch2, SZ_PTR); mov_rindexr(code, opts->scratch2, opts->scratch1, 1, opts->scratch1, tmp_size); pop_r(code, opts->scratch2); } } if (size != tmp_size && !is_write) { if (memmap[chunk].flags & MMAP_ONLY_EVEN) { shl_ir(code, 8, opts->scratch1, SZ_W); mov_ir(code, 0xFF, opts->scratch1, SZ_B); } else { or_ir(code, 0xFF00, opts->scratch1, SZ_W); } } } if (is_write && (memmap[chunk].flags & MMAP_CODE)) { mov_rr(code, opts->scratch2, opts->scratch1, opts->address_size); shr_ir(code, opts->ram_flags_shift, opts->scratch1, opts->address_size); bt_rrdisp(code, opts->scratch1, opts->context_reg, ram_flags_off, opts->address_size); code_ptr not_code = code->cur + 1; jcc(code, CC_NC, code->cur + 2); if (memmap[chunk].mask != opts->address_mask) { or_ir(code, memmap[chunk].start, opts->scratch2, opts->address_size); } call(code, opts->save_context); call_args(code, opts->handle_code_write, 2, opts->scratch2, opts->context_reg); mov_rr(code, RAX, opts->context_reg, SZ_PTR); jmp(code, opts->load_context); *not_code = code->cur - (not_code+1); } retn(code); } else if (cfun) { call(code, opts->save_context); if (is_write) { call_args_abi(code, cfun, 3, opts->scratch2, opts->context_reg, opts->scratch1); mov_rr(code, RAX, opts->context_reg, SZ_PTR); } else { push_r(code, opts->context_reg); call_args_abi(code, cfun, 2, opts->scratch1, opts->context_reg); pop_r(code, opts->context_reg); mov_rr(code, RAX, opts->scratch1, size); } jmp(code, opts->load_context); } else { //Not sure the best course of action here if (!is_write) { mov_ir(code, size == SZ_B ? 0xFF : 0xFFFF, opts->scratch1, size); } retn(code); } if (memmap[chunk].flags & MMAP_CODE) { if (memmap[chunk].mask == opts->address_mask) { ram_flags_off += (memmap[chunk].end - memmap[chunk].start) / (1 << opts->ram_flags_shift) / 8; ; } else { ram_flags_off += (memmap[chunk].mask + 1) / (1 << opts->ram_flags_shift) / 8;; } } if (lb_jcc) { *lb_jcc = code->cur - (lb_jcc+1); lb_jcc = NULL; } if (ub_jcc) { *ub_jcc = code->cur - (ub_jcc+1); ub_jcc = NULL; } } if (!is_write) { mov_ir(code, size == SZ_B ? 0xFF : 0xFFFF, opts->scratch1, size); } retn(code); return start; }