591 lines
26 KiB
C
591 lines
26 KiB
C
#define WIN32_MEAN_AND_LEAN
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#define NOMINMAX
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#include <Windows.h>
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#include <stdint.h>
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#include <stdio.h>
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#include <stdarg.h>
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#include <stdbool.h>
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// NOTE: Macros
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// ============================================================================
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#define S86_STRINGIFY2(token) #token
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#define S86_STRINGIFY(token) S86_STRINGIFY2(token)
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#define S86_ASSERT(expr) \
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if (!(expr)) { \
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S86_PrintLnFmt("Assertion triggered [file=\"" __FILE__ ":" S86_STRINGIFY(__LINE__) "\", expr=\"" #expr "\"]"); \
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__debugbreak(); \
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} \
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#define S86_ARRAY_UCOUNT(array) sizeof((array)) / sizeof((array)[0])
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#define S86_CAST(Type) (Type)
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// NOTE: Globals
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// ============================================================================
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typedef struct S86_Globals {
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HANDLE stdout_handle;
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bool write_to_console;
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} S86_Globals;
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S86_Globals s86_globals;
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// NOTE: Strings
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// ============================================================================
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typedef struct S86_Str8 {
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char *data;
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size_t size;
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} S86_Str8;
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#define S86_STR8(string) (S86_Str8){.data = (string), .size = S86_ARRAY_UCOUNT(string) - 1 }
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#define S86_STR8_FMT(string) (int)((string).size), (string).data
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// NOTE: Buffer
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// ============================================================================
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typedef struct S86_Buffer {
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char *data;
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size_t size;
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} S86_Buffer;
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typedef struct S86_BufferIterator {
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S86_Buffer buffer;
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size_t index;
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} S86_BufferIterator;
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bool S86_BufferIsValid(S86_Buffer buffer);
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S86_BufferIterator S86_BufferIteratorInit(S86_Buffer buffer);
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bool S86_BufferIteratorHasMoreBytes(S86_BufferIterator it);
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uint8_t S86_BufferIteratorPeekByte(S86_BufferIterator it);
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uint8_t S86_BufferIteratorNextByte(S86_BufferIterator *it);
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// NOTE: File
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// ============================================================================
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S86_Buffer S86_FileRead(char const *file_path);
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void S86_FileFree(S86_Buffer buffer);
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// NOTE: Print
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// ============================================================================
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void S86_PrintLn(S86_Str8 string);
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void S86_PrintLnFmt(char const *fmt, ...);
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// NOTE: Sim8086
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// ============================================================================
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typedef enum S86_InstructionType {
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S86_InstructionType_MOVRegOrMemToOrFromReg,
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S86_InstructionType_MOVImmediateToRegOrMem,
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S86_InstructionType_MOVImmediateToReg,
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S86_InstructionType_MOVMemToAccum,
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S86_InstructionType_MOVAccumToMem,
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S86_InstructionType_MOVRegOrMemToSegReg,
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S86_InstructionType_MOVSegRegToRegOrMem,
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S86_InstructionType_Count,
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} S86_InstructionType;
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/// Bit patterns and masks for decoding 8086 assembly. 8086 opcodes can be up
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/// to 2 bytes long and mixed with instruction specific control bits. These
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/// masks isolate the opcode bits from the bits can be checked after masking
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/// the binary instruction stream.
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///
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/// Instructions that do not have opcode bits in the 2nd byte will have the mask
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/// set to 0.
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typedef struct S86_Instruction {
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uint8_t op_mask0;
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uint8_t op_bits0;
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uint8_t op_mask1;
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uint8_t op_bits1;
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} S86_Instruction;
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S86_Instruction const S86_INSTRUCTIONS[S86_InstructionType_Count] = {
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[S86_InstructionType_MOVRegOrMemToOrFromReg] = {.op_mask0 = 0b1111'1100,
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.op_bits0 = 0b1000'1000,
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.op_mask1 = 0b0000'0000,
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.op_bits1 = 0b0000'0000},
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[S86_InstructionType_MOVImmediateToRegOrMem] = {.op_mask0 = 0b1111'1110,
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.op_bits0 = 0b1100'0110,
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.op_mask1 = 0b0011'1000,
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.op_bits1 = 0b0000'0000},
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[S86_InstructionType_MOVImmediateToReg] = {.op_mask0 = 0b1111'0000,
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.op_bits0 = 0b1011'0000,
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.op_mask1 = 0b0000'0000,
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.op_bits1 = 0b0000'0000},
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[S86_InstructionType_MOVMemToAccum] = {.op_mask0 = 0b1111'1110,
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.op_bits0 = 0b1010'0000,
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.op_mask1 = 0b0000'0000,
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.op_bits1 = 0b0000'0000},
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[S86_InstructionType_MOVAccumToMem] = {.op_mask0 = 0b1111'1110,
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.op_bits0 = 0b1010'0010,
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.op_mask1 = 0b0000'0000,
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.op_bits1 = 0b0000'0000},
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[S86_InstructionType_MOVRegOrMemToSegReg] = {.op_mask0 = 0b1111'1111,
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.op_bits0 = 0b1000'1110,
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.op_mask1 = 0b0010'0000,
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.op_bits1 = 0b0000'0000},
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[S86_InstructionType_MOVSegRegToRegOrMem] = {.op_mask0 = 0b1111'1111,
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.op_bits0 = 0b1000'1100,
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.op_mask1 = 0b0010'0000,
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.op_bits1 = 0b0000'0000},
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};
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// NOTE: Implementation
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// ============================================================================
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bool S86_BufferIsValid(S86_Buffer buffer)
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{
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bool result = buffer.data && buffer.size;
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return result;
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}
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S86_BufferIterator S86_BufferIteratorInit(S86_Buffer buffer)
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{
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S86_BufferIterator result = {0};
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result.buffer = buffer;
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return result;
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}
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bool S86_BufferIteratorHasMoreBytes(S86_BufferIterator it)
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{
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bool result = S86_BufferIsValid(it.buffer) && it.index < it.buffer.size;
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return result;
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}
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uint8_t S86_BufferIteratorPeekByte(S86_BufferIterator it)
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{
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S86_ASSERT(S86_BufferIsValid(it.buffer));
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S86_ASSERT(it.index < it.buffer.size);
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uint8_t result = it.buffer.data[it.index];
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return result;
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}
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uint8_t S86_BufferIteratorNextByte(S86_BufferIterator *it)
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{
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S86_ASSERT(it);
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S86_ASSERT(S86_BufferIsValid(it->buffer));
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S86_ASSERT(it->index < it->buffer.size);
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uint8_t result = it->buffer.data[it->index++];
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return result;
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}
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S86_Buffer S86_FileRead(char const *file_path)
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{
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S86_Buffer result = {0};
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// NOTE: Determine file size
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// =========================================================================
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WIN32_FILE_ATTRIBUTE_DATA file_attrib_data = {0};
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if (GetFileAttributesEx(file_path, GetFileExInfoStandard, &file_attrib_data) == 0)
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return result;
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// NOTE: Open file
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// =========================================================================
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HANDLE file_handle = CreateFile(
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/*LPCSTR lpFileName*/ file_path,
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/*DWORD dwDesiredAccess*/ GENERIC_READ,
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/*DWORD dwShareMode*/ 0,
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/*LPSECURITY_ATTRIBUTES lpSecurityAttributes*/ NULL,
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/*DWORD dwCreationDisposition*/ OPEN_EXISTING,
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/*DWORD dwFlagsAndAttributes*/ 0,
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/*HANDLE hTemplateFile*/ NULL
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);
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if (file_handle == INVALID_HANDLE_VALUE)
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return result;
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// NOTE: Allocate buffer
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// =========================================================================
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uint64_t file_size = (uint64_t)file_attrib_data.nFileSizeHigh << 32 | (uint64_t)file_attrib_data.nFileSizeLow << 0;
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S86_ASSERT(file_size < (DWORD)-1);
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char *buffer = VirtualAlloc(
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/*LPVOID lpAddress*/ NULL,
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/*SIZE_T dwSize*/ file_size,
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/*DWORD flAllocationType*/ MEM_COMMIT | MEM_RESERVE,
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/*DWORD flProtect*/ PAGE_READWRITE
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);
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if (!buffer)
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goto end;
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// NOTE: Read file to buffer
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// =========================================================================
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DWORD bytes_read = 0;
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BOOL read_file_result = ReadFile(
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/*HANDLE hFile*/ file_handle,
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/*LPVOID lpBuffer*/ buffer,
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/*DWORD nNumberOfBytesToRead*/ S86_CAST(DWORD)file_size,
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/*LPDWORD lpNumberOfBytesRead*/ &bytes_read,
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/*LPOVERLAPPED lpOverlapped*/ NULL
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);
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// NOTE: Handle read result
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// =========================================================================
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if (read_file_result == 0) {
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VirtualFree(buffer, 0, MEM_RELEASE);
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} else {
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result.data = buffer;
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result.size = file_size;
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}
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end:
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CloseHandle(file_handle);
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return result;
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};
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void S86_FileFree(S86_Buffer buffer)
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{
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if (S86_BufferIsValid(buffer))
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VirtualFree(buffer.data, 0, MEM_RELEASE);
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}
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void S86_PrintLn(S86_Str8 string)
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{
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if (s86_globals.stdout_handle == NULL) {
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s86_globals.stdout_handle = GetStdHandle(STD_OUTPUT_HANDLE);
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DWORD mode = 0;
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BOOL get_console_mode_result = GetConsoleMode(
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/*HANDLE hConsoleHandle*/ s86_globals.stdout_handle,
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/*LPDWORD lpMode*/ &mode
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);
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s86_globals.write_to_console = get_console_mode_result != 0;
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}
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S86_ASSERT(string.size < S86_CAST(DWORD)-1);
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if (s86_globals.write_to_console) {
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DWORD chars_written = 0;
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WriteConsoleA(s86_globals.stdout_handle, string.data, (DWORD)string.size, &chars_written, NULL);
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WriteConsoleA(s86_globals.stdout_handle, "\n", 1, &chars_written, NULL);
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} else {
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DWORD bytes_written = 0;
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WriteFile(s86_globals.stdout_handle, string.data, (DWORD)string.size, &bytes_written, NULL);
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WriteFile(s86_globals.stdout_handle, "\n", 1, &bytes_written, NULL);
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}
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}
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void S86_PrintLnFmt(char const *fmt, ...)
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{
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va_list args, args_copy;
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va_start(args, fmt);
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va_copy(args_copy, args);
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int string_size = vsnprintf(NULL, 0, fmt, args_copy);
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va_end(args_copy);
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char buffer[8192];
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S86_ASSERT(string_size >= 0 && string_size < S86_ARRAY_UCOUNT(buffer));
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if (string_size) {
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vsnprintf(buffer, sizeof(buffer), fmt, args);
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S86_Str8 string = {.data = buffer, .size = string_size};
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S86_PrintLn(string);
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}
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va_end(args);
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}
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int main(int argc, char **argv)
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{
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// NOTE: Argument handling
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// =========================================================================
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if (argc != 2) {
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S86_PrintLn(S86_STR8("usage: sim8086.exe <binary asm file>"));
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return -1;
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}
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char const *file_path = argv[1];
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S86_Buffer buffer = S86_FileRead(file_path);
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if (!S86_BufferIsValid(buffer)) {
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S86_PrintLnFmt("File read failed [path=\"%s\"]", argv[1], buffer.size);
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return -1;
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}
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// NOTE: Sim8086
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// =========================================================================
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// Mapping from a 'reg' encoding to the register name.
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S86_Str8 const REGISTER_FIELD_ENCODING[2][8] = {
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[0b0] =
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{
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S86_STR8("al"),
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S86_STR8("cl"),
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S86_STR8("dl"),
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S86_STR8("bl"),
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S86_STR8("ah"),
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S86_STR8("ch"),
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S86_STR8("dh"),
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S86_STR8("bh"),
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},
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[0b1] =
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{
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S86_STR8("ax"),
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S86_STR8("cx"),
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S86_STR8("dx"),
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S86_STR8("bx"),
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S86_STR8("sp"),
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S86_STR8("bp"),
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S86_STR8("si"),
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S86_STR8("di"),
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},
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};
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// NOTE: Decode assembly
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// =========================================================================
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S86_PrintLn(S86_STR8("bits 16"));
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S86_BufferIterator buffer_it = S86_BufferIteratorInit(buffer);
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while (S86_BufferIteratorHasMoreBytes(buffer_it)) {
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char op_code_bytes[2] = {0};
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size_t op_code_size = 0;
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op_code_bytes[op_code_size++] = S86_BufferIteratorNextByte(&buffer_it);
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// NOTE: Match the assembly bytes to the desired instruction
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// =====================================================================
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S86_InstructionType instruction_type = S86_InstructionType_Count;
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S86_Instruction const *instruction = NULL;
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for (size_t instruction_index = 0;
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instruction_type == S86_InstructionType_Count && instruction_index < S86_ARRAY_UCOUNT(S86_INSTRUCTIONS);
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instruction_index++)
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{
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S86_Instruction const *item = S86_INSTRUCTIONS + instruction_index;
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// NOTE: Check first instruction byte
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// =================================================================
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if ((op_code_bytes[0] & item->op_mask0) != item->op_bits0)
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continue;
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// NOTE Check multi-byte instruction
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// =================================================================
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// If the matched instruction has a bit mask for the 2nd byte, this
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// is a multi-byte instruction. Check if the 2nd byte checks out.
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bool instruction_matched = true;
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if (item->op_mask1) {
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// TODO: This assumes the iterator is valid
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op_code_bytes[op_code_size++] = S86_BufferIteratorNextByte(&buffer_it);
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instruction_matched = (op_code_bytes[op_code_size - 1] & item->op_mask1) == item->op_bits1;
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}
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if (instruction_matched) {
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instruction_type = instruction_index;
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instruction = item;
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}
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}
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// NOTE: Disassemble bytes to assembly mnemonics
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// =================================================================
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S86_ASSERT(op_code_size > 0 && op_code_size <= S86_ARRAY_UCOUNT(op_code_bytes));
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S86_ASSERT(instruction_type != S86_InstructionType_Count && "Unknown instruction");
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switch (instruction_type) {
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case S86_InstructionType_MOVRegOrMemToOrFromReg: {
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// NOTE: Instruction does not have opcode bits in the 2nd byte
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S86_ASSERT(op_code_size == 1);
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op_code_bytes[op_code_size++] = S86_BufferIteratorNextByte(&buffer_it);
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uint8_t d = (op_code_bytes[0] & 0b0000'0010) >> 1;
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uint8_t w = (op_code_bytes[0] & 0b0000'0001) >> 0;
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uint8_t mod = (op_code_bytes[1] & 0b1100'0000) >> 6;
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uint8_t reg = (op_code_bytes[1] & 0b0011'1000) >> 3;
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uint8_t rm = (op_code_bytes[1] & 0b0000'0111) >> 0;
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S86_ASSERT(d < 2);
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S86_ASSERT(w < 2);
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S86_ASSERT(mod < 4);
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S86_ASSERT(reg < 8);
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S86_ASSERT(rm < 8);
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if (mod == 0b11) {
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// NOTE: Register-to-register move
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// =========================================================
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S86_Str8 src_op = REGISTER_FIELD_ENCODING[w][d ? rm : reg];
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S86_Str8 dest_op = REGISTER_FIELD_ENCODING[w][d ? reg : rm];
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S86_PrintLnFmt("mov %.*s, %.*s", S86_STR8_FMT(dest_op), S86_STR8_FMT(src_op));
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} else {
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// NOTE: Memory mode w/ effective address calculation
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// =========================================================
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bool direct_address = mod == 0b00 && rm == 0b110;
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int16_t displacement = 0;
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if (mod == 0b10 || direct_address) { // Mem mode 16 bit displacement
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uint8_t disp_lo = S86_BufferIteratorNextByte(&buffer_it);
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uint8_t disp_hi = S86_BufferIteratorNextByte(&buffer_it);
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displacement = (int16_t)((uint16_t)disp_hi << 8 | (uint16_t)disp_lo << 0);
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} else if (mod == 0b01) { // Mem mode 8 bit displacement
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displacement = (int8_t)S86_BufferIteratorNextByte(&buffer_it);
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} else {
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S86_ASSERT(mod == 0b00 /*Mem mode (no displacement)*/);
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}
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// NOTE: Generate the effective address calculation string
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// =========================================================
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char effective_addr_buffer[64] = {0};
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int effective_addr_size = 0;
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effective_addr_buffer[effective_addr_size++] = '[';
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if (direct_address) {
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effective_addr_size += snprintf(effective_addr_buffer + effective_addr_size,
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sizeof(effective_addr_buffer) - effective_addr_size,
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"%s%d",
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displacement >= 0 ? "" : "-", displacement >= 0 ? displacement : -displacement);
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} else {
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S86_Str8 base_calc = {0};
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switch (rm) {
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case 0b000: base_calc = S86_STR8("bx + si"); break;
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case 0b001: base_calc = S86_STR8("bx + di"); break;
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case 0b010: base_calc = S86_STR8("bp + si"); break;
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case 0b011: base_calc = S86_STR8("bp + di"); break;
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case 0b100: base_calc = S86_STR8("si"); break;
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case 0b101: base_calc = S86_STR8("di"); break;
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case 0b110: base_calc = S86_STR8("bp"); break;
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case 0b111: base_calc = S86_STR8("bx"); break;
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default: S86_ASSERT(!"Invalid rm value, must be 3 bits"); break;
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}
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memcpy(effective_addr_buffer + effective_addr_size, base_calc.data, base_calc.size);
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effective_addr_size += S86_CAST(int)base_calc.size;
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if ((mod == 0b01 || mod == 0b10) && displacement) {
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effective_addr_size += snprintf(effective_addr_buffer + effective_addr_size,
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sizeof(effective_addr_buffer) - effective_addr_size,
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" %c %d",
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displacement >= 0 ? '+' : '-', displacement >= 0 ? displacement : -displacement);
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}
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}
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effective_addr_buffer[effective_addr_size++] = ']';
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// NOTE: Disassemble
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// =========================================================
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S86_Str8 effective_addr = { .data = effective_addr_buffer, .size = effective_addr_size };
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S86_Str8 dest_op = d ? REGISTER_FIELD_ENCODING[w][reg] : effective_addr;
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S86_Str8 src_op = d ? effective_addr : REGISTER_FIELD_ENCODING[w][reg];
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S86_PrintLnFmt("mov %.*s, %.*s", S86_STR8_FMT(dest_op), S86_STR8_FMT(src_op));
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}
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} break;
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case S86_InstructionType_MOVImmediateToRegOrMem: {
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S86_ASSERT(op_code_size == 2);
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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;
|
|
S86_ASSERT(w < 2);
|
|
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;
|
|
int16_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 = (int16_t)((uint16_t)disp_lo << 0 | (uint16_t)disp_hi << 8);
|
|
} else if (mod == 0b01) { // Mem mode 8 bit displacement
|
|
displacement = (int8_t)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,
|
|
"%s%d",
|
|
displacement >= 0 ? "" : "-", displacement >= 0 ? displacement : -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 0b110: base_calc = S86_STR8("bp"); 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) && displacement) {
|
|
effective_addr_size += snprintf(effective_addr_buffer + effective_addr_size,
|
|
sizeof(effective_addr_buffer) - effective_addr_size,
|
|
" %c %d",
|
|
displacement >= 0 ? '+' : '-', displacement >= 0 ? displacement : -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: {
|
|
// NOTE: Parse opcode control bits
|
|
// =============================================================
|
|
S86_ASSERT(op_code_size == 1);
|
|
uint8_t w = (op_code_bytes[0] & 0b0000'1000) >> 3;
|
|
uint8_t reg = (op_code_bytes[0] & 0b0000'0111) >> 0;
|
|
|
|
// 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: Disassemble
|
|
// =============================================================
|
|
S86_Str8 dest_register = REGISTER_FIELD_ENCODING[w][reg];
|
|
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(op_code_size == 1);
|
|
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);
|
|
|
|
S86_Str8 fmt = {0};
|
|
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: {
|
|
S86_ASSERT(!"Unhandled instruction");
|
|
} break;
|
|
|
|
case S86_InstructionType_MOVSegRegToRegOrMem: {
|
|
S86_ASSERT(!"Unhandled instruction");
|
|
} break;
|
|
|
|
default: {
|
|
S86_ASSERT(!"Unknown instruction");
|
|
} break;
|
|
}
|
|
}
|
|
}
|