perfaware/part1: Implement mem<->accum ops

2023-03-09 22:38:51 +11:00 · 2023-03-09 22:38:51 +11:00 · c4e2be3926
commit c4e2be3926
parent 68486e8855
3 changed files with 121 additions and 27 deletions
--- a/part1/build.bat
+++ b/part1/build.bat
@ -34,3 +34,8 @@ set listing_0039=%build_dir%\listing_0039_more_movs
 %build_dir%\sim8086.exe %listing_0039% > %listing_0039%_disassembled.asm
 nasm %listing_0039%_disassembled.asm
 fc %listing_0039% %listing_0039%_disassembled || exit /b 1
 set listing_0040=%build_dir%\listing_0040_challenge_movs
 %build_dir%\sim8086.exe %listing_0040% > %listing_0040%_disassembled.asm
 nasm %listing_0040%_disassembled.asm
 fc %listing_0040% %listing_0040%_disassembled || exit /b 1
--- a/part1/sim8086.c
+++ b/part1/sim8086.c
@ -403,17 +403,16 @@ int main(int argc, char **argv)
                } else {
                    // NOTE: Memory mode w/ effective address calculation
                    // =========================================================
                    bool direct_address = mod == 0b00 && rm == 0b110;
                    uint16_t displacement = 0;
-                    if (mod == 0b01) { // Mem mode 8 bit displacement
+                    if (mod == 0b10 || direct_address) { // Mem mode 16 bit displacement
                        displacement = S86_BufferIteratorNextByte(&buffer_it);
                    } else if (mod == 0b10 || (mod == 0b00 && rm == 0b110)) { // Mem mode 16 bit displacement
                        uint8_t disp_lo = S86_BufferIteratorNextByte(&buffer_it);
                        uint8_t disp_hi = S86_BufferIteratorNextByte(&buffer_it);
                        displacement    = (uint16_t)disp_lo << 0 | (uint16_t)disp_hi << 8;
                    } else if (mod == 0b01) { // Mem mode 8 bit displacement
                        displacement = S86_BufferIteratorNextByte(&buffer_it);
                    } else {
                        S86_ASSERT(mod == 0b00 /*Mem mode (no displacement)*/);
                        if (mod == 0b00)
                            S86_ASSERT(rm != 0b110 && "16 bit displacement should be handled in (mod == 0b10) branch");
                    }
                    // NOTE: Generate the effective address calculation string
@ -422,6 +421,12 @@ int main(int argc, char **argv)
                    int  effective_addr_size       = 0;
                    effective_addr_buffer[effective_addr_size++] = '[';
                    if (direct_address) {
                        effective_addr_size += snprintf(effective_addr_buffer + effective_addr_size,
                                                        sizeof(effective_addr_buffer) - effective_addr_size,
                                                        "%u",
                                                        displacement);
                    } else {
                        if (rm == 0b110) {
                            effective_addr_buffer[effective_addr_size++] = 'b';
                            effective_addr_buffer[effective_addr_size++] = 'p';
@ -454,6 +459,7 @@ int main(int argc, char **argv)
                                                                displacement);
                            }
                        }
                    }
                    effective_addr_buffer[effective_addr_size++] = ']';
                    // NOTE: Disassemble
@ -468,12 +474,86 @@ int main(int argc, char **argv)
            case S86_InstructionType_MOVImmediateToRegOrMem: {
                S86_ASSERT(op_code_size == 2);
                #if 0
                uint8_t w   = (op_code_bytes[0] & 0b0000'0001) >> 0;
                uint8_t mod = (op_code_bytes[1] & 0b1100'0000) >> 6;
                uint8_t rm  = (op_code_bytes[1] & 0b0000'0111) >> 0;
-                #endif
+                S86_ASSERT(w   < 2);
-                S86_ASSERT(!"Unhandled instruction");
+                S86_ASSERT(mod < 4);
                S86_ASSERT(rm  < 8);
                S86_ASSERT(mod != 0b11); // NOTE: Op is IMM->Reg, register-to-register not permitted
                // NOTE: Memory mode w/ effective address calculation
                // =========================================================
                bool direct_address = mod == 0b00 && rm == 0b110;
                uint16_t displacement = 0;
                if (mod == 0b10 || direct_address) { // Mem mode 16 bit displacement
                    uint8_t disp_lo = S86_BufferIteratorNextByte(&buffer_it);
                    uint8_t disp_hi = S86_BufferIteratorNextByte(&buffer_it);
                    displacement    = (uint16_t)disp_lo << 0 | (uint16_t)disp_hi << 8;
                } else if (mod == 0b01) { // Mem mode 8 bit displacement
                    displacement = S86_BufferIteratorNextByte(&buffer_it);
                } else {
                    S86_ASSERT(mod == 0b00 /*Mem mode (no displacement)*/);
                }
                // NOTE: Parse data payload
                // =============================================================
                uint16_t data = S86_BufferIteratorNextByte(&buffer_it);
                if (w) { // 16 bit data
                    uint8_t data_hi = S86_BufferIteratorNextByte(&buffer_it);
                    data |= (uint16_t)(data_hi) << 8;
                }
                // NOTE: Generate the effective address calculation string
                // =========================================================
                char effective_addr_buffer[64] = {0};
                int  effective_addr_size       = 0;
                effective_addr_buffer[effective_addr_size++] = '[';
                if (direct_address) {
                    effective_addr_size += snprintf(effective_addr_buffer + effective_addr_size,
                                                    sizeof(effective_addr_buffer) - effective_addr_size,
                                                    "%u",
                                                    displacement);
                } else {
                    if (rm == 0b110) {
                        effective_addr_buffer[effective_addr_size++] = 'b';
                        effective_addr_buffer[effective_addr_size++] = 'p';
                        if (displacement) {
                            effective_addr_size += snprintf(effective_addr_buffer + effective_addr_size,
                                                            sizeof(effective_addr_buffer) - effective_addr_size,
                                                            " + %u",
                                                            displacement);
                        }
                    } else {
                        S86_Str8 base_calc = {0};
                        switch (rm) {
                            case 0b000: base_calc = S86_STR8("bx + si"); break;
                            case 0b001: base_calc = S86_STR8("bx + di"); break;
                            case 0b010: base_calc = S86_STR8("bp + si"); break;
                            case 0b011: base_calc = S86_STR8("bp + di"); break;
                            case 0b100: base_calc = S86_STR8("si");      break;
                            case 0b101: base_calc = S86_STR8("di");      break;
                            case 0b111: base_calc = S86_STR8("bx");      break;
                            default: S86_ASSERT(!"Invalid rm value, must be 3 bits"); break;
                        }
                        memcpy(effective_addr_buffer + effective_addr_size, base_calc.data, base_calc.size);
                        effective_addr_size += S86_CAST(int)base_calc.size;
                        if (mod == 0b01 || mod == 0b10) {
                            effective_addr_size += snprintf(effective_addr_buffer + effective_addr_size,
                                                            sizeof(effective_addr_buffer) - effective_addr_size,
                                                            " + %u",
                                                            displacement);
                        }
                    }
                }
                effective_addr_buffer[effective_addr_size++] = ']';
                // NOTE: Disassemble
                // =========================================================
                S86_PrintLnFmt("mov %.*s, %s %u", effective_addr_size, effective_addr_buffer, w ? "word" : "byte", data);
            } break;
            case S86_InstructionType_MOVImmediateToReg: {
@ -497,12 +577,21 @@ int main(int argc, char **argv)
                S86_PrintLnFmt("mov %.*s, %d", S86_STR8_FMT(dest_register), (int16_t)data);
            } break;
            case S86_InstructionType_MOVAccumToMem: /*FALLTHRU*/
            case S86_InstructionType_MOVMemToAccum: {
-                S86_ASSERT(!"Unhandled instruction");
+                S86_ASSERT(op_code_size == 1);
-            } break;
+                uint16_t addr_lo = S86_BufferIteratorNextByte(&buffer_it);
                uint16_t addr_hi = S86_BufferIteratorNextByte(&buffer_it);
                uint16_t addr    = (addr_hi << 8) | (addr_lo << 0);
-            case S86_InstructionType_MOVAccumToMem: {
+                S86_Str8 fmt = {0};
-                S86_ASSERT(!"Unhandled instruction");
+                if (instruction_type == S86_InstructionType_MOVAccumToMem) {
                    fmt = S86_STR8("mov [%u], ax");
                } else {
                    S86_ASSERT(instruction_type == S86_InstructionType_MOVMemToAccum);
                    fmt = S86_STR8("mov ax, [%u]");
                }
                S86_PrintLnFmt(fmt.data, addr);
            } break;
            case S86_InstructionType_MOVRegOrMemToSegReg: {
--- a/project.rdbg
+++ b/project.rdbg