#include #include #include #include "gb.h" typedef struct { bool has_bank; uint16_t bank:9; uint16_t value; } value_t; typedef struct { enum { LVALUE_MEMORY, LVALUE_MEMORY16, LVALUE_REG16, LVALUE_REG_H, LVALUE_REG_L, } kind; union { uint16_t *register_address; value_t memory_address; }; } lvalue_t; #define VALUE_16(x) ((value_t){false, 0, (x)}) struct GB_breakpoint_s { union { struct { uint16_t addr; uint16_t bank; /* -1 = any bank*/ }; uint32_t key; /* For sorting and comparing */ }; char *condition; bool is_jump_to; }; #define BP_KEY(x) (((struct GB_breakpoint_s){.addr = ((x).value), .bank = (x).has_bank? (x).bank : -1 }).key) #define GB_WATCHPOINT_R (1) #define GB_WATCHPOINT_W (2) struct GB_watchpoint_s { union { struct { uint16_t addr; uint16_t bank; /* -1 = any bank*/ }; uint32_t key; /* For sorting and comparing */ }; char *condition; uint8_t flags; }; #define WP_KEY(x) (((struct GB_watchpoint_s){.addr = ((x).value), .bank = (x).has_bank? (x).bank : -1 }).key) static uint16_t bank_for_addr(GB_gameboy_t *gb, uint16_t addr) { if (addr < 0x4000) { return gb->mbc_rom0_bank; } if (addr < 0x8000) { return gb->mbc_rom_bank; } if (addr < 0xD000) { return 0; } if (addr < 0xE000) { return gb->cgb_ram_bank; } return 0; } typedef struct { uint16_t rom0_bank; uint16_t rom_bank; uint8_t mbc_ram_bank; bool mbc_ram_enable; uint8_t ram_bank; uint8_t vram_bank; } banking_state_t; static inline void save_banking_state(GB_gameboy_t *gb, banking_state_t *state) { state->rom0_bank = gb->mbc_rom0_bank; state->rom_bank = gb->mbc_rom_bank; state->mbc_ram_bank = gb->mbc_ram_bank; state->mbc_ram_enable = gb->mbc_ram_enable; state->ram_bank = gb->cgb_ram_bank; state->vram_bank = gb->cgb_vram_bank; } static inline void restore_banking_state(GB_gameboy_t *gb, banking_state_t *state) { gb->mbc_rom0_bank = state->rom0_bank; gb->mbc_rom_bank = state->rom_bank; gb->mbc_ram_bank = state->mbc_ram_bank; gb->mbc_ram_enable = state->mbc_ram_enable; gb->cgb_ram_bank = state->ram_bank; gb->cgb_vram_bank = state->vram_bank; } static inline void switch_banking_state(GB_gameboy_t *gb, uint16_t bank) { gb->mbc_rom0_bank = bank; gb->mbc_rom_bank = bank; gb->mbc_ram_bank = bank; gb->mbc_ram_enable = true; if (GB_is_cgb(gb)) { gb->cgb_ram_bank = bank & 7; gb->cgb_vram_bank = bank & 1; if (gb->cgb_ram_bank == 0) { gb->cgb_ram_bank = 1; } } } static const char *value_to_string(GB_gameboy_t *gb, uint16_t value, bool prefer_name) { static __thread char output[256]; const GB_bank_symbol_t *symbol = GB_debugger_find_symbol(gb, value); if (symbol && (value - symbol->addr > 0x1000 || symbol->addr == 0) ) { symbol = NULL; } if (!symbol) { snprintf(output, sizeof(output), "$%04x", value); } else if (symbol->addr == value) { if (prefer_name) { snprintf(output, sizeof(output), "%s ($%04x)", symbol->name, value); } else { snprintf(output, sizeof(output), "$%04x (%s)", value, symbol->name); } } else { if (prefer_name) { snprintf(output, sizeof(output), "%s+$%03x ($%04x)", symbol->name, value - symbol->addr, value); } else { snprintf(output, sizeof(output), "$%04x (%s+$%03x)", value, symbol->name, value - symbol->addr); } } return output; } static GB_symbol_map_t *get_symbol_map(GB_gameboy_t *gb, uint16_t bank) { if (bank >= gb->n_symbol_maps) { return NULL; } return gb->bank_symbols[bank]; } static const char *debugger_value_to_string(GB_gameboy_t *gb, value_t value, bool prefer_name) { if (!value.has_bank) return value_to_string(gb, value.value, prefer_name); static __thread char output[256]; const GB_bank_symbol_t *symbol = GB_map_find_symbol(get_symbol_map(gb, value.bank), value.value); if (symbol && (value.value - symbol->addr > 0x1000 || symbol->addr == 0) ) { symbol = NULL; } if (!symbol) { snprintf(output, sizeof(output), "$%02x:$%04x", value.bank, value.value); } else if (symbol->addr == value.value) { if (prefer_name) { snprintf(output, sizeof(output), "%s ($%02x:$%04x)", symbol->name, value.bank, value.value); } else { snprintf(output, sizeof(output), "$%02x:$%04x (%s)", value.bank, value.value, symbol->name); } } else { if (prefer_name) { snprintf(output, sizeof(output), "%s+$%03x ($%02x:$%04x)", symbol->name, value.value - symbol->addr, value.bank, value.value); } else { snprintf(output, sizeof(output), "$%02x:$%04x (%s+$%03x)", value.bank, value.value, symbol->name, value.value - symbol->addr); } } return output; } static value_t read_lvalue(GB_gameboy_t *gb, lvalue_t lvalue) { /* Not used until we add support for operators like += */ switch (lvalue.kind) { case LVALUE_MEMORY: if (lvalue.memory_address.has_bank) { banking_state_t state; save_banking_state(gb, &state); switch_banking_state(gb, lvalue.memory_address.bank); value_t r = VALUE_16(GB_read_memory(gb, lvalue.memory_address.value)); restore_banking_state(gb, &state); return r; } return VALUE_16(GB_read_memory(gb, lvalue.memory_address.value)); case LVALUE_MEMORY16: if (lvalue.memory_address.has_bank) { banking_state_t state; save_banking_state(gb, &state); switch_banking_state(gb, lvalue.memory_address.bank); value_t r = VALUE_16(GB_read_memory(gb, lvalue.memory_address.value) | (GB_read_memory(gb, lvalue.memory_address.value + 1) * 0x100)); restore_banking_state(gb, &state); return r; } return VALUE_16(GB_read_memory(gb, lvalue.memory_address.value) | (GB_read_memory(gb, lvalue.memory_address.value + 1) * 0x100)); case LVALUE_REG16: return VALUE_16(*lvalue.register_address); case LVALUE_REG_L: return VALUE_16(*lvalue.register_address & 0x00FF); case LVALUE_REG_H: return VALUE_16(*lvalue.register_address >> 8); } return VALUE_16(0); } static void write_lvalue(GB_gameboy_t *gb, lvalue_t lvalue, uint16_t value) { switch (lvalue.kind) { case LVALUE_MEMORY: if (lvalue.memory_address.has_bank) { banking_state_t state; save_banking_state(gb, &state); switch_banking_state(gb, lvalue.memory_address.bank); GB_write_memory(gb, lvalue.memory_address.value, value); restore_banking_state(gb, &state); return; } GB_write_memory(gb, lvalue.memory_address.value, value); return; case LVALUE_MEMORY16: if (lvalue.memory_address.has_bank) { banking_state_t state; save_banking_state(gb, &state); switch_banking_state(gb, lvalue.memory_address.bank); GB_write_memory(gb, lvalue.memory_address.value, value); GB_write_memory(gb, lvalue.memory_address.value + 1, value >> 8); restore_banking_state(gb, &state); return; } GB_write_memory(gb, lvalue.memory_address.value, value); GB_write_memory(gb, lvalue.memory_address.value + 1, value >> 8); return; case LVALUE_REG16: *lvalue.register_address = value; return; case LVALUE_REG_L: *lvalue.register_address &= 0xFF00; *lvalue.register_address |= value & 0xFF; return; case LVALUE_REG_H: *lvalue.register_address &= 0x00FF; *lvalue.register_address |= value << 8; return; } } /* 16 bit value 16 bit value = 16 bit value 25 bit address 16 bit value = 25 bit address 16 bit value 25 bit address = 25 bit address 25 bit address 25 bit address = 16 bit value (since adding pointers, for examples, makes no sense) Boolean operators always return a 16-bit value */ #define FIX_BANK(x) ((value_t){a.has_bank ^ b.has_bank, a.has_bank? a.bank : b.bank, (x)}) static value_t add(value_t a, value_t b) {return FIX_BANK(a.value + b.value);} static value_t sub(value_t a, value_t b) {return FIX_BANK(a.value - b.value);} static value_t mul(value_t a, value_t b) {return FIX_BANK(a.value * b.value);} static value_t _div(value_t a, value_t b) { if (b.value == 0) { return FIX_BANK(0); } return FIX_BANK(a.value / b.value); }; static value_t mod(value_t a, value_t b) { if (b.value == 0) { return FIX_BANK(0); } return FIX_BANK(a.value % b.value); }; static value_t and(value_t a, value_t b) {return FIX_BANK(a.value & b.value);} static value_t or(value_t a, value_t b) {return FIX_BANK(a.value | b.value);} static value_t xor(value_t a, value_t b) {return FIX_BANK(a.value ^ b.value);} static value_t shleft(value_t a, value_t b) {return FIX_BANK(a.value << b.value);} static value_t shright(value_t a, value_t b) {return FIX_BANK(a.value >> b.value);} static value_t assign(GB_gameboy_t *gb, lvalue_t a, uint16_t b) { write_lvalue(gb, a, b); return read_lvalue(gb, a); } static value_t bool_and(value_t a, value_t b) {return VALUE_16(a.value && b.value);} static value_t bool_or(value_t a, value_t b) {return VALUE_16(a.value || b.value);} static value_t equals(value_t a, value_t b) {return VALUE_16(a.value == b.value);} static value_t different(value_t a, value_t b) {return VALUE_16(a.value != b.value);} static value_t lower(value_t a, value_t b) {return VALUE_16(a.value < b.value);} static value_t greater(value_t a, value_t b) {return VALUE_16(a.value > b.value);} static value_t lower_equals(value_t a, value_t b) {return VALUE_16(a.value <= b.value);} static value_t greater_equals(value_t a, value_t b) {return VALUE_16(a.value >= b.value);} static value_t bank(value_t a, value_t b) {return (value_t) {true, a.value, b.value};} static struct { const char *string; int8_t priority; value_t (*operator)(value_t, value_t); value_t (*lvalue_operator)(GB_gameboy_t *, lvalue_t, uint16_t); } operators[] = { // Yes. This is not C-like. But it makes much more sense. // Deal with it. {"+", 0, add}, {"-", 0, sub}, {"||", 0, bool_or}, {"|", 0, or}, {"*", 1, mul}, {"/", 1, _div}, {"%", 1, mod}, {"&&", 1, bool_and}, {"&", 1, and}, {"^", 1, xor}, {"<<", 2, shleft}, {"<=", 3, lower_equals}, {"<", 3, lower}, {">>", 2, shright}, {">=", 3, greater_equals}, {">", 3, greater}, {"==", 3, equals}, {"=", -1, NULL, assign}, {"!=", 3, different}, {":", 4, bank}, }; value_t debugger_evaluate(GB_gameboy_t *gb, const char *string, size_t length, bool *error, uint16_t *watchpoint_address, uint8_t *watchpoint_new_value); static lvalue_t debugger_evaluate_lvalue(GB_gameboy_t *gb, const char *string, size_t length, bool *error, uint16_t *watchpoint_address, uint8_t *watchpoint_new_value) { *error = false; // Strip whitespace while (length && (string[0] == ' ' || string[0] == '\n' || string[0] == '\r' || string[0] == '\t')) { string++; length--; } while (length && (string[length-1] == ' ' || string[length-1] == '\n' || string[length-1] == '\r' || string[length-1] == '\t')) { length--; } if (length == 0) { GB_log(gb, "Expected expression.\n"); *error = true; return (lvalue_t){0,}; } if (string[0] == '(' && string[length - 1] == ')') { // Attempt to strip parentheses signed depth = 0; for (unsigned i = 0; i < length; i++) { if (string[i] == '(') depth++; if (depth == 0) { // First and last are not matching depth = 1; break; } if (string[i] == ')') depth--; } if (depth == 0) return debugger_evaluate_lvalue(gb, string + 1, length - 2, error, watchpoint_address, watchpoint_new_value); } else if (string[0] == '[' && string[length - 1] == ']') { // Attempt to strip square parentheses (memory dereference) signed depth = 0; for (unsigned i = 0; i < length; i++) { if (string[i] == '[') depth++; if (depth == 0) { // First and last are not matching depth = 1; break; } if (string[i] == ']') depth--; } if (depth == 0) { return (lvalue_t){LVALUE_MEMORY, .memory_address = debugger_evaluate(gb, string + 1, length - 2, error, watchpoint_address, watchpoint_new_value)}; } } else if (string[0] == '{' && string[length - 1] == '}') { // Attempt to strip curly parentheses (memory dereference) signed depth = 0; for (unsigned i = 0; i < length; i++) { if (string[i] == '{') depth++; if (depth == 0) { // First and last are not matching depth = 1; break; } if (string[i] == '}') depth--; } if (depth == 0) { return (lvalue_t){LVALUE_MEMORY16, .memory_address = debugger_evaluate(gb, string + 1, length - 2, error, watchpoint_address, watchpoint_new_value)}; } } // Registers if (string[0] != '$' && (string[0] < '0' || string[0] > '9')) { if (length == 1) { switch (string[0]) { case 'a': return (lvalue_t){LVALUE_REG_H, .register_address = &gb->af}; case 'f': return (lvalue_t){LVALUE_REG_L, .register_address = &gb->af}; case 'b': return (lvalue_t){LVALUE_REG_H, .register_address = &gb->bc}; case 'c': return (lvalue_t){LVALUE_REG_L, .register_address = &gb->bc}; case 'd': return (lvalue_t){LVALUE_REG_H, .register_address = &gb->de}; case 'e': return (lvalue_t){LVALUE_REG_L, .register_address = &gb->de}; case 'h': return (lvalue_t){LVALUE_REG_H, .register_address = &gb->hl}; case 'l': return (lvalue_t){LVALUE_REG_L, .register_address = &gb->hl}; } } else if (length == 2) { switch (string[0]) { case 'a': if (string[1] == 'f') return (lvalue_t){LVALUE_REG16, .register_address = &gb->af}; case 'b': if (string[1] == 'c') return (lvalue_t){LVALUE_REG16, .register_address = &gb->bc}; case 'd': if (string[1] == 'e') return (lvalue_t){LVALUE_REG16, .register_address = &gb->de}; case 'h': if (string[1] == 'l') return (lvalue_t){LVALUE_REG16, .register_address = &gb->hl}; case 's': if (string[1] == 'p') return (lvalue_t){LVALUE_REG16, .register_address = &gb->sp}; case 'p': if (string[1] == 'c') return (lvalue_t){LVALUE_REG16, .register_address = &gb->pc}; } } GB_log(gb, "Unknown register: %.*s\n", (unsigned) length, string); *error = true; return (lvalue_t){0,}; } GB_log(gb, "Expression is not an lvalue: %.*s\n", (unsigned) length, string); *error = true; return (lvalue_t){0,}; } #define ERROR ((value_t){0,}) value_t debugger_evaluate(GB_gameboy_t *gb, const char *string, size_t length, bool *error, uint16_t *watchpoint_address, uint8_t *watchpoint_new_value) { /* Disable watchpoints while evaluating expressions */ uint16_t n_watchpoints = gb->n_watchpoints; gb->n_watchpoints = 0; value_t ret = ERROR; *error = false; // Strip whitespace while (length && (string[0] == ' ' || string[0] == '\n' || string[0] == '\r' || string[0] == '\t')) { string++; length--; } while (length && (string[length-1] == ' ' || string[length-1] == '\n' || string[length-1] == '\r' || string[length-1] == '\t')) { length--; } if (length == 0) { GB_log(gb, "Expected expression.\n"); *error = true; goto exit; } if (string[0] == '(' && string[length - 1] == ')') { // Attempt to strip parentheses signed depth = 0; for (unsigned i = 0; i < length; i++) { if (string[i] == '(') depth++; if (depth == 0) { // First and last are not matching depth = 1; break; } if (string[i] == ')') depth--; } if (depth == 0) { ret = debugger_evaluate(gb, string + 1, length - 2, error, watchpoint_address, watchpoint_new_value); goto exit; } } else if (string[0] == '[' && string[length - 1] == ']') { // Attempt to strip square parentheses (memory dereference) signed depth = 0; for (unsigned i = 0; i < length; i++) { if (string[i] == '[') depth++; if (depth == 0) { // First and last are not matching depth = 1; break; } if (string[i] == ']') depth--; } if (depth == 0) { value_t addr = debugger_evaluate(gb, string + 1, length - 2, error, watchpoint_address, watchpoint_new_value); banking_state_t state; if (addr.bank) { save_banking_state(gb, &state); switch_banking_state(gb, addr.bank); } ret = VALUE_16(GB_read_memory(gb, addr.value)); if (addr.bank) { restore_banking_state(gb, &state); } goto exit; } } else if (string[0] == '{' && string[length - 1] == '}') { // Attempt to strip curly parentheses (memory dereference) signed depth = 0; for (unsigned i = 0; i < length; i++) { if (string[i] == '{') depth++; if (depth == 0) { // First and last are not matching depth = 1; break; } if (string[i] == '}') depth--; } if (depth == 0) { value_t addr = debugger_evaluate(gb, string + 1, length - 2, error, watchpoint_address, watchpoint_new_value); banking_state_t state; if (addr.bank) { save_banking_state(gb, &state); switch_banking_state(gb, addr.bank); } ret = VALUE_16(GB_read_memory(gb, addr.value) | (GB_read_memory(gb, addr.value + 1) * 0x100)); if (addr.bank) { restore_banking_state(gb, &state); } goto exit; } } // Search for lowest priority operator signed depth = 0; unsigned operator_index = -1; unsigned operator_pos = 0; for (unsigned i = 0; i < length; i++) { if (string[i] == '(') depth++; else if (string[i] == ')') depth--; else if (string[i] == '[') depth++; else if (string[i] == ']') depth--; else if (depth == 0) { for (unsigned j = 0; j < sizeof(operators) / sizeof(operators[0]); j++) { unsigned operator_length = strlen(operators[j].string); if (operator_length > length - i) continue; // Operator too long if (memcmp(string + i, operators[j].string, operator_length) == 0) { if (operator_index != -1 && operators[operator_index].priority < operators[j].priority) { /* for supporting = vs ==, etc*/ i += operator_length - 1; break; } // Found an operator! operator_pos = i; operator_index = j; /* for supporting = vs ==, etc*/ i += operator_length - 1; break; } } } } if (operator_index != -1) { unsigned right_start = (unsigned)(operator_pos + strlen(operators[operator_index].string)); value_t right = debugger_evaluate(gb, string + right_start, length - right_start, error, watchpoint_address, watchpoint_new_value); if (*error) goto exit; if (operators[operator_index].lvalue_operator) { lvalue_t left = debugger_evaluate_lvalue(gb, string, operator_pos, error, watchpoint_address, watchpoint_new_value); if (*error) goto exit; ret = operators[operator_index].lvalue_operator(gb, left, right.value); goto exit; } value_t left = debugger_evaluate(gb, string, operator_pos, error, watchpoint_address, watchpoint_new_value); if (*error) goto exit; ret = operators[operator_index].operator(left, right); goto exit; } // Not an expression - must be a register or a literal // Registers if (string[0] != '$' && (string[0] < '0' || string[0] > '9')) { if (length == 1) { switch (string[0]) { case 'a': ret = VALUE_16(gb->af >> 8); goto exit; case 'f': ret = VALUE_16(gb->af & 0xFF); goto exit; case 'b': ret = VALUE_16(gb->bc >> 8); goto exit; case 'c': ret = VALUE_16(gb->bc & 0xFF); goto exit; case 'd': ret = VALUE_16(gb->de >> 8); goto exit; case 'e': ret = VALUE_16(gb->de & 0xFF); goto exit; case 'h': ret = VALUE_16(gb->hl >> 8); goto exit; case 'l': ret = VALUE_16(gb->hl & 0xFF); goto exit; } } else if (length == 2) { switch (string[0]) { case 'a': if (string[1] == 'f') {ret = VALUE_16(gb->af); goto exit;} case 'b': if (string[1] == 'c') {ret = VALUE_16(gb->bc); goto exit;} case 'd': if (string[1] == 'e') {ret = VALUE_16(gb->de); goto exit;} case 'h': if (string[1] == 'l') {ret = VALUE_16(gb->hl); goto exit;} case 's': if (string[1] == 'p') {ret = VALUE_16(gb->sp); goto exit;} case 'p': if (string[1] == 'c') {ret = (value_t){true, bank_for_addr(gb, gb->pc), gb->pc}; goto exit;} } } else if (length == 3) { if (watchpoint_address && memcmp(string, "old", 3) == 0) { ret = VALUE_16(GB_read_memory(gb, *watchpoint_address)); goto exit; } if (watchpoint_new_value && memcmp(string, "new", 3) == 0) { ret = VALUE_16(*watchpoint_new_value); goto exit; } /* $new is identical to $old in read conditions */ if (watchpoint_address && memcmp(string, "new", 3) == 0) { ret = VALUE_16(GB_read_memory(gb, *watchpoint_address)); goto exit; } } char symbol_name[length + 1]; memcpy(symbol_name, string, length); symbol_name[length] = 0; const GB_symbol_t *symbol = GB_reversed_map_find_symbol(&gb->reversed_symbol_map, symbol_name); if (symbol) { ret = (value_t){true, symbol->bank, symbol->addr}; goto exit; } GB_log(gb, "Unknown register or symbol: %.*s\n", (unsigned) length, string); *error = true; goto exit; } char *end; unsigned base = 10; if (string[0] == '$') { string++; base = 16; length--; } uint16_t literal = (uint16_t) (strtol(string, &end, base)); if (end != string + length) { GB_log(gb, "Failed to parse: %.*s\n", (unsigned) length, string); *error = true; goto exit; } ret = VALUE_16(literal); exit: gb->n_watchpoints = n_watchpoints; return ret; } struct debugger_command_s; typedef bool debugger_command_imp_t(GB_gameboy_t *gb, char *arguments, char *modifiers, const struct debugger_command_s *command); typedef char *debugger_completer_imp_t(GB_gameboy_t *gb, const char *string, uintptr_t *context); typedef struct debugger_command_s { const char *command; uint8_t min_length; debugger_command_imp_t *implementation; const char *help_string; // Null if should not appear in help const char *arguments_format; // For usage message const char *modifiers_format; // For usage message debugger_completer_imp_t *argument_completer; debugger_completer_imp_t *modifiers_completer; } debugger_command_t; static const char *lstrip(const char *str) { while (*str == ' ' || *str == '\t') { str++; } return str; } #define STOPPED_ONLY \ if (!gb->debug_stopped) { \ GB_log(gb, "Program is running. \n"); \ return false; \ } #define NO_MODIFIERS \ if (modifiers) { \ print_usage(gb, command); \ return true; \ } static void print_usage(GB_gameboy_t *gb, const debugger_command_t *command) { GB_log(gb, "Usage: %s", command->command); if (command->modifiers_format) { GB_log(gb, "[/%s]", command->modifiers_format); } if (command->arguments_format) { GB_log(gb, " %s", command->arguments_format); } GB_log(gb, "\n"); } static bool cont(GB_gameboy_t *gb, char *arguments, char *modifiers, const debugger_command_t *command) { NO_MODIFIERS STOPPED_ONLY if (strlen(lstrip(arguments))) { print_usage(gb, command); return true; } gb->debug_stopped = false; return false; } static bool next(GB_gameboy_t *gb, char *arguments, char *modifiers, const debugger_command_t *command) { NO_MODIFIERS STOPPED_ONLY if (strlen(lstrip(arguments))) { print_usage(gb, command); return true; } gb->debug_stopped = false; gb->debug_next_command = true; gb->debug_call_depth = 0; return false; } static bool step(GB_gameboy_t *gb, char *arguments, char *modifiers, const debugger_command_t *command) { NO_MODIFIERS STOPPED_ONLY if (strlen(lstrip(arguments))) { print_usage(gb, command); return true; } return false; } static bool finish(GB_gameboy_t *gb, char *arguments, char *modifiers, const debugger_command_t *command) { NO_MODIFIERS STOPPED_ONLY if (strlen(lstrip(arguments))) { print_usage(gb, command); return true; } gb->debug_stopped = false; gb->debug_fin_command = true; gb->debug_call_depth = 0; return false; } static bool stack_leak_detection(GB_gameboy_t *gb, char *arguments, char *modifiers, const debugger_command_t *command) { NO_MODIFIERS STOPPED_ONLY if (strlen(lstrip(arguments))) { print_usage(gb, command); return true; } gb->debug_stopped = false; gb->stack_leak_detection = true; gb->debug_call_depth = 0; return false; } static bool registers(GB_gameboy_t *gb, char *arguments, char *modifiers, const debugger_command_t *command) { NO_MODIFIERS if (strlen(lstrip(arguments))) { print_usage(gb, command); return true; } GB_log(gb, "AF = $%04x (%c%c%c%c)\n", gb->af, /* AF can't really be an address */ (gb->f & GB_CARRY_FLAG)? 'C' : '-', (gb->f & GB_HALF_CARRY_FLAG)? 'H' : '-', (gb->f & GB_SUBTRACT_FLAG)? 'N' : '-', (gb->f & GB_ZERO_FLAG)? 'Z' : '-'); GB_log(gb, "BC = %s\n", value_to_string(gb, gb->bc, false)); GB_log(gb, "DE = %s\n", value_to_string(gb, gb->de, false)); GB_log(gb, "HL = %s\n", value_to_string(gb, gb->hl, false)); GB_log(gb, "SP = %s\n", value_to_string(gb, gb->sp, false)); GB_log(gb, "PC = %s\n", value_to_string(gb, gb->pc, false)); GB_log(gb, "IME = %s\n", gb->ime? "Enabled" : "Disabled"); return true; } static char *on_off_completer(GB_gameboy_t *gb, const char *string, uintptr_t *context) { size_t length = strlen(string); const char *suggestions[] = {"on", "off"}; while (*context < sizeof(suggestions) / sizeof(suggestions[0])) { if (memcmp(string, suggestions[*context], length) == 0) { return strdup(suggestions[(*context)++] + length); } (*context)++; } return NULL; } /* Enable or disable software breakpoints */ static bool softbreak(GB_gameboy_t *gb, char *arguments, char *modifiers, const debugger_command_t *command) { NO_MODIFIERS if (strcmp(lstrip(arguments), "on") == 0 || !strlen(lstrip(arguments))) { gb->has_software_breakpoints = true; } else if (strcmp(lstrip(arguments), "off") == 0) { gb->has_software_breakpoints = false; } else { print_usage(gb, command); } return true; } /* Find the index of the closest breakpoint equal or greater to addr */ static uint16_t find_breakpoint(GB_gameboy_t *gb, value_t addr) { if (!gb->breakpoints) { return 0; } uint32_t key = BP_KEY(addr); unsigned min = 0; unsigned max = gb->n_breakpoints; while (min < max) { uint16_t pivot = (min + max) / 2; if (gb->breakpoints[pivot].key == key) return pivot; if (gb->breakpoints[pivot].key > key) { max = pivot; } else { min = pivot + 1; } } return (uint16_t) min; } static inline bool is_legal_symbol_char(char c) { if (c >= '0' && c <= '9') return true; if (c >= 'A' && c <= 'Z') return true; if (c >= 'a' && c <= 'z') return true; if (c == '_') return true; if (c == '.') return true; return false; } static char *symbol_completer(GB_gameboy_t *gb, const char *string, uintptr_t *_context) { const char *symbol_prefix = string; while (*string) { if (!is_legal_symbol_char(*string)) { symbol_prefix = string + 1; } string++; } if (*symbol_prefix == '$') { return NULL; } struct { uint16_t bank; uint32_t symbol; } *context = (void *)_context; size_t length = strlen(symbol_prefix); while (context->bank < 0x200) { GB_symbol_map_t *map = get_symbol_map(gb, context->bank); if (map == NULL || context->symbol >= map->n_symbols) { context->bank++; context->symbol = 0; continue; } const char *candidate = map->symbols[context->symbol++].name; if (memcmp(symbol_prefix, candidate, length) == 0) { return strdup(candidate + length); } } return NULL; } static char *j_completer(GB_gameboy_t *gb, const char *string, uintptr_t *context) { size_t length = strlen(string); const char *suggestions[] = {"j"}; while (*context < sizeof(suggestions) / sizeof(suggestions[0])) { if (memcmp(string, suggestions[*context], length) == 0) { return strdup(suggestions[(*context)++] + length); } (*context)++; } return NULL; } static bool breakpoint(GB_gameboy_t *gb, char *arguments, char *modifiers, const debugger_command_t *command) { bool is_jump_to = true; if (!modifiers) { is_jump_to = false; } else if (strcmp(modifiers, "j") != 0) { print_usage(gb, command); return true; } if (strlen(lstrip(arguments)) == 0) { print_usage(gb, command); return true; } if (gb->n_breakpoints == (typeof(gb->n_breakpoints)) -1) { GB_log(gb, "Too many breakpoints set\n"); return true; } char *condition = NULL; if ((condition = strstr(arguments, " if "))) { *condition = 0; condition += strlen(" if "); /* Verify condition is sane (Todo: This might have side effects!) */ bool error; debugger_evaluate(gb, condition, (unsigned)strlen(condition), &error, NULL, NULL); if (error) return true; } bool error; value_t result = debugger_evaluate(gb, arguments, (unsigned)strlen(arguments), &error, NULL, NULL); uint32_t key = BP_KEY(result); if (error) return true; uint16_t index = find_breakpoint(gb, result); if (index < gb->n_breakpoints && gb->breakpoints[index].key == key) { GB_log(gb, "Breakpoint already set at %s\n", debugger_value_to_string(gb, result, true)); if (!gb->breakpoints[index].condition && condition) { GB_log(gb, "Added condition to breakpoint\n"); gb->breakpoints[index].condition = strdup(condition); } else if (gb->breakpoints[index].condition && condition) { GB_log(gb, "Replaced breakpoint condition\n"); free(gb->breakpoints[index].condition); gb->breakpoints[index].condition = strdup(condition); } else if (gb->breakpoints[index].condition && !condition) { GB_log(gb, "Removed breakpoint condition\n"); free(gb->breakpoints[index].condition); gb->breakpoints[index].condition = NULL; } return true; } gb->breakpoints = realloc(gb->breakpoints, (gb->n_breakpoints + 1) * sizeof(gb->breakpoints[0])); memmove(&gb->breakpoints[index + 1], &gb->breakpoints[index], (gb->n_breakpoints - index) * sizeof(gb->breakpoints[0])); gb->breakpoints[index].key = key; if (condition) { gb->breakpoints[index].condition = strdup(condition); } else { gb->breakpoints[index].condition = NULL; } gb->n_breakpoints++; gb->breakpoints[index].is_jump_to = is_jump_to; if (is_jump_to) { gb->has_jump_to_breakpoints = true; } GB_log(gb, "Breakpoint set at %s\n", debugger_value_to_string(gb, result, true)); return true; } static bool delete(GB_gameboy_t *gb, char *arguments, char *modifiers, const debugger_command_t *command) { NO_MODIFIERS if (strlen(lstrip(arguments)) == 0) { for (unsigned i = gb->n_breakpoints; i--;) { if (gb->breakpoints[i].condition) { free(gb->breakpoints[i].condition); } } free(gb->breakpoints); gb->breakpoints = NULL; gb->n_breakpoints = 0; return true; } bool error; value_t result = debugger_evaluate(gb, arguments, (unsigned)strlen(arguments), &error, NULL, NULL); uint32_t key = BP_KEY(result); if (error) return true; uint16_t index = 0; for (unsigned i = 0; i < gb->n_breakpoints; i++) { if (gb->breakpoints[i].key == key) { /* Full match */ index = i; break; } if (gb->breakpoints[i].addr == result.value && result.has_bank != (gb->breakpoints[i].bank != (uint16_t) -1)) { /* Partial match */ index = i; } } if (index >= gb->n_breakpoints) { GB_log(gb, "No breakpoint set at %s\n", debugger_value_to_string(gb, result, true)); return true; } result.bank = gb->breakpoints[index].bank; result.has_bank = gb->breakpoints[index].bank != (uint16_t) -1; if (gb->breakpoints[index].condition) { free(gb->breakpoints[index].condition); } if (gb->breakpoints[index].is_jump_to) { gb->has_jump_to_breakpoints = false; for (unsigned i = 0; i < gb->n_breakpoints; i++) { if (i == index) continue; if (gb->breakpoints[i].is_jump_to) { gb->has_jump_to_breakpoints = true; break; } } } memmove(&gb->breakpoints[index], &gb->breakpoints[index + 1], (gb->n_breakpoints - index - 1) * sizeof(gb->breakpoints[0])); gb->n_breakpoints--; gb->breakpoints = realloc(gb->breakpoints, gb->n_breakpoints * sizeof(gb->breakpoints[0])); GB_log(gb, "Breakpoint removed from %s\n", debugger_value_to_string(gb, result, true)); return true; } /* Find the index of the closest watchpoint equal or greater to addr */ static uint16_t find_watchpoint(GB_gameboy_t *gb, value_t addr) { if (!gb->watchpoints) { return 0; } uint32_t key = WP_KEY(addr); unsigned min = 0; unsigned max = gb->n_watchpoints; while (min < max) { uint16_t pivot = (min + max) / 2; if (gb->watchpoints[pivot].key == key) return pivot; if (gb->watchpoints[pivot].key > key) { max = pivot; } else { min = pivot + 1; } } return (uint16_t) min; } static char *rw_completer(GB_gameboy_t *gb, const char *string, uintptr_t *context) { size_t length = strlen(string); const char *suggestions[] = {"r", "rw", "w"}; while (*context < sizeof(suggestions) / sizeof(suggestions[0])) { if (memcmp(string, suggestions[*context], length) == 0) { return strdup(suggestions[(*context)++] + length); } (*context)++; } return NULL; } static bool watch(GB_gameboy_t *gb, char *arguments, char *modifiers, const debugger_command_t *command) { if (strlen(lstrip(arguments)) == 0) { print_usage: print_usage(gb, command); return true; } if (gb->n_watchpoints == (typeof(gb->n_watchpoints)) -1) { GB_log(gb, "Too many watchpoints set\n"); return true; } if (!modifiers) { modifiers = "w"; } uint8_t flags = 0; while (*modifiers) { switch (*modifiers) { case 'r': flags |= GB_WATCHPOINT_R; break; case 'w': flags |= GB_WATCHPOINT_W; break; default: goto print_usage; } modifiers++; } if (!flags) { goto print_usage; } char *condition = NULL; if ((condition = strstr(arguments, " if "))) { *condition = 0; condition += strlen(" if "); /* Verify condition is sane (Todo: This might have side effects!) */ bool error; /* To make $new and $old legal */ uint16_t dummy = 0; uint8_t dummy2 = 0; debugger_evaluate(gb, condition, (unsigned)strlen(condition), &error, &dummy, &dummy2); if (error) return true; } bool error; value_t result = debugger_evaluate(gb, arguments, (unsigned)strlen(arguments), &error, NULL, NULL); uint32_t key = WP_KEY(result); if (error) return true; uint16_t index = find_watchpoint(gb, result); if (index < gb->n_watchpoints && gb->watchpoints[index].key == key) { GB_log(gb, "Watchpoint already set at %s\n", debugger_value_to_string(gb, result, true)); if (gb->watchpoints[index].flags != flags) { GB_log(gb, "Modified watchpoint type\n"); gb->watchpoints[index].flags = flags; } if (!gb->watchpoints[index].condition && condition) { GB_log(gb, "Added condition to watchpoint\n"); gb->watchpoints[index].condition = strdup(condition); } else if (gb->watchpoints[index].condition && condition) { GB_log(gb, "Replaced watchpoint condition\n"); free(gb->watchpoints[index].condition); gb->watchpoints[index].condition = strdup(condition); } else if (gb->watchpoints[index].condition && !condition) { GB_log(gb, "Removed watchpoint condition\n"); free(gb->watchpoints[index].condition); gb->watchpoints[index].condition = NULL; } return true; } gb->watchpoints = realloc(gb->watchpoints, (gb->n_watchpoints + 1) * sizeof(gb->watchpoints[0])); memmove(&gb->watchpoints[index + 1], &gb->watchpoints[index], (gb->n_watchpoints - index) * sizeof(gb->watchpoints[0])); gb->watchpoints[index].key = key; gb->watchpoints[index].flags = flags; if (condition) { gb->watchpoints[index].condition = strdup(condition); } else { gb->watchpoints[index].condition = NULL; } gb->n_watchpoints++; GB_log(gb, "Watchpoint set at %s\n", debugger_value_to_string(gb, result, true)); return true; } static bool unwatch(GB_gameboy_t *gb, char *arguments, char *modifiers, const debugger_command_t *command) { NO_MODIFIERS if (strlen(lstrip(arguments)) == 0) { for (unsigned i = gb->n_watchpoints; i--;) { if (gb->watchpoints[i].condition) { free(gb->watchpoints[i].condition); } } free(gb->watchpoints); gb->watchpoints = NULL; gb->n_watchpoints = 0; return true; } bool error; value_t result = debugger_evaluate(gb, arguments, (unsigned)strlen(arguments), &error, NULL, NULL); uint32_t key = WP_KEY(result); if (error) return true; uint16_t index = 0; for (unsigned i = 0; i < gb->n_watchpoints; i++) { if (gb->watchpoints[i].key == key) { /* Full match */ index = i; break; } if (gb->watchpoints[i].addr == result.value && result.has_bank != (gb->watchpoints[i].bank != (uint16_t) -1)) { /* Partial match */ index = i; } } if (index >= gb->n_watchpoints) { GB_log(gb, "No watchpoint set at %s\n", debugger_value_to_string(gb, result, true)); return true; } result.bank = gb->watchpoints[index].bank; result.has_bank = gb->watchpoints[index].bank != (uint16_t) -1; if (gb->watchpoints[index].condition) { free(gb->watchpoints[index].condition); } memmove(&gb->watchpoints[index], &gb->watchpoints[index + 1], (gb->n_watchpoints - index - 1) * sizeof(gb->watchpoints[0])); gb->n_watchpoints--; gb->watchpoints = realloc(gb->watchpoints, gb->n_watchpoints *sizeof(gb->watchpoints[0])); GB_log(gb, "Watchpoint removed from %s\n", debugger_value_to_string(gb, result, true)); return true; } static bool list(GB_gameboy_t *gb, char *arguments, char *modifiers, const debugger_command_t *command) { NO_MODIFIERS if (strlen(lstrip(arguments))) { print_usage(gb, command); return true; } if (gb->n_breakpoints == 0) { GB_log(gb, "No breakpoints set.\n"); } else { GB_log(gb, "%d breakpoint(s) set:\n", gb->n_breakpoints); for (uint16_t i = 0; i < gb->n_breakpoints; i++) { value_t addr = (value_t){gb->breakpoints[i].bank != (uint16_t)-1, gb->breakpoints[i].bank, gb->breakpoints[i].addr}; if (gb->breakpoints[i].condition) { GB_log(gb, " %d. %s (%sCondition: %s)\n", i + 1, debugger_value_to_string(gb, addr, addr.has_bank), gb->breakpoints[i].is_jump_to? "Jump to, ": "", gb->breakpoints[i].condition); } else { GB_log(gb, " %d. %s%s\n", i + 1, debugger_value_to_string(gb, addr, addr.has_bank), gb->breakpoints[i].is_jump_to? " (Jump to)" : ""); } } } if (gb->n_watchpoints == 0) { GB_log(gb, "No watchpoints set.\n"); } else { GB_log(gb, "%d watchpoint(s) set:\n", gb->n_watchpoints); for (uint16_t i = 0; i < gb->n_watchpoints; i++) { value_t addr = (value_t){gb->watchpoints[i].bank != (uint16_t)-1, gb->watchpoints[i].bank, gb->watchpoints[i].addr}; if (gb->watchpoints[i].condition) { GB_log(gb, " %d. %s (%c%c, Condition: %s)\n", i + 1, debugger_value_to_string(gb, addr, addr.has_bank), (gb->watchpoints[i].flags & GB_WATCHPOINT_R)? 'r' : '-', (gb->watchpoints[i].flags & GB_WATCHPOINT_W)? 'w' : '-', gb->watchpoints[i].condition); } else { GB_log(gb, " %d. %s (%c%c)\n", i + 1, debugger_value_to_string(gb, addr, addr.has_bank), (gb->watchpoints[i].flags & GB_WATCHPOINT_R)? 'r' : '-', (gb->watchpoints[i].flags & GB_WATCHPOINT_W)? 'w' : '-'); } } } return true; } static bool _should_break(GB_gameboy_t *gb, value_t addr, bool jump_to) { uint16_t index = find_breakpoint(gb, addr); uint32_t key = BP_KEY(addr); if (index < gb->n_breakpoints && gb->breakpoints[index].key == key && gb->breakpoints[index].is_jump_to == jump_to) { if (!gb->breakpoints[index].condition) { return true; } bool error; bool condition = debugger_evaluate(gb, gb->breakpoints[index].condition, (unsigned)strlen(gb->breakpoints[index].condition), &error, NULL, NULL).value; if (error) { /* Should never happen */ GB_log(gb, "An internal error has occured\n"); return true; } return condition; } return false; } static bool should_break(GB_gameboy_t *gb, uint16_t addr, bool jump_to) { /* Try any-bank breakpoint */ value_t full_addr = (VALUE_16(addr)); if (_should_break(gb, full_addr, jump_to)) return true; /* Try bank-specific breakpoint */ full_addr.has_bank = true; full_addr.bank = bank_for_addr(gb, addr); return _should_break(gb, full_addr, jump_to); } static char *format_completer(GB_gameboy_t *gb, const char *string, uintptr_t *context) { size_t length = strlen(string); const char *suggestions[] = {"a", "b", "d", "o", "x"}; while (*context < sizeof(suggestions) / sizeof(suggestions[0])) { if (memcmp(string, suggestions[*context], length) == 0) { return strdup(suggestions[(*context)++] + length); } (*context)++; } return NULL; } static bool print(GB_gameboy_t *gb, char *arguments, char *modifiers, const debugger_command_t *command) { if (strlen(lstrip(arguments)) == 0) { print_usage(gb, command); return true; } if (!modifiers || !modifiers[0]) { modifiers = "a"; } else if (modifiers[1]) { print_usage(gb, command); return true; } bool error; value_t result = debugger_evaluate(gb, arguments, (unsigned)strlen(arguments), &error, NULL, NULL); if (!error) { switch (modifiers[0]) { case 'a': GB_log(gb, "=%s\n", debugger_value_to_string(gb, result, false)); break; case 'd': GB_log(gb, "=%d\n", result.value); break; case 'x': GB_log(gb, "=$%x\n", result.value); break; case 'o': GB_log(gb, "=0%o\n", result.value); break; case 'b': { if (!result.value) { GB_log(gb, "=%%0\n"); break; } char binary[17]; binary[16] = 0; char *ptr = &binary[16]; while (result.value) { *(--ptr) = (result.value & 1)? '1' : '0'; result.value >>= 1; } GB_log(gb, "=%%%s\n", ptr); break; } default: break; } } return true; } static bool examine(GB_gameboy_t *gb, char *arguments, char *modifiers, const debugger_command_t *command) { if (strlen(lstrip(arguments)) == 0) { print_usage(gb, command); return true; } bool error; value_t addr = debugger_evaluate(gb, arguments, (unsigned)strlen(arguments), &error, NULL, NULL); uint16_t count = 32; if (modifiers) { char *end; count = (uint16_t) (strtol(modifiers, &end, 10)); if (*end) { print_usage(gb, command); return true; } } if (!error) { if (addr.has_bank) { banking_state_t old_state; save_banking_state(gb, &old_state); switch_banking_state(gb, addr.bank); while (count) { GB_log(gb, "%02x:%04x: ", addr.bank, addr.value); for (unsigned i = 0; i < 16 && count; i++) { GB_log(gb, "%02x ", GB_safe_read_memory(gb, addr.value + i)); count--; } addr.value += 16; GB_log(gb, "\n"); } restore_banking_state(gb, &old_state); } else { while (count) { GB_log(gb, "%04x: ", addr.value); for (unsigned i = 0; i < 16 && count; i++) { GB_log(gb, "%02x ", GB_safe_read_memory(gb, addr.value + i)); count--; } addr.value += 16; GB_log(gb, "\n"); } } } return true; } static bool disassemble(GB_gameboy_t *gb, char *arguments, char *modifiers, const debugger_command_t *command) { if (strlen(lstrip(arguments)) == 0) { arguments = "pc"; } bool error; value_t addr = debugger_evaluate(gb, arguments, (unsigned)strlen(arguments), &error, NULL, NULL); uint16_t count = 5; if (modifiers) { char *end; count = (uint16_t) (strtol(modifiers, &end, 10)); if (*end) { print_usage(gb, command); return true; } } if (!error) { if (addr.has_bank) { banking_state_t old_state; save_banking_state(gb, &old_state); switch_banking_state(gb, addr.bank); GB_cpu_disassemble(gb, addr.value, count); restore_banking_state(gb, &old_state); } else { GB_cpu_disassemble(gb, addr.value, count); } } return true; } static bool mbc(GB_gameboy_t *gb, char *arguments, char *modifiers, const debugger_command_t *command) { NO_MODIFIERS if (strlen(lstrip(arguments))) { print_usage(gb, command); return true; } const GB_cartridge_t *cartridge = gb->cartridge_type; if (cartridge->has_ram) { bool has_battery = gb->cartridge_type->has_battery && (gb->cartridge_type->mbc_type != GB_TPP1 || (gb->rom[0x153] & 8)); GB_log(gb, "Cartridge includes%s RAM: $%x bytes\n", has_battery? " battery-backed": "", gb->mbc_ram_size); } else { GB_log(gb, "No cartridge RAM\n"); } if (cartridge->mbc_type) { if (gb->is_mbc30) { GB_log(gb, "MBC30\n"); } else { static const char *const mapper_names[] = { [GB_MBC1] = "MBC1", [GB_MBC2] = "MBC2", [GB_MBC3] = "MBC3", [GB_MBC5] = "MBC5", [GB_MBC7] = "MBC7", [GB_MMM01] = "MMM01", [GB_HUC1] = "HUC-1", [GB_HUC3] = "HUC-3", [GB_CAMERA] = "MAC-GBD", }; GB_log(gb, "%s\n", mapper_names[cartridge->mbc_type]); } if (cartridge->mbc_type == GB_MMM01 || cartridge->mbc_type == GB_MBC1) { GB_log(gb, "Current mapped ROM0 bank: %x\n", gb->mbc_rom0_bank); } GB_log(gb, "Current mapped ROM bank: %x\n", gb->mbc_rom_bank); if (cartridge->has_ram) { GB_log(gb, "Current mapped RAM bank: %x\n", gb->mbc_ram_bank); if (gb->cartridge_type->mbc_type != GB_HUC1) { GB_log(gb, "RAM is currently %s\n", gb->mbc_ram_enable? "enabled" : "disabled"); } } if (cartridge->mbc_type == GB_MBC1 && gb->mbc1_wiring == GB_STANDARD_MBC1_WIRING) { GB_log(gb, "MBC1 banking mode is %s\n", gb->mbc1.mode == 1 ? "RAM" : "ROM"); } if (cartridge->mbc_type == GB_MBC1 && gb->mbc1_wiring == GB_MBC1M_WIRING) { GB_log(gb, "MBC1 uses MBC1M wiring. \n"); GB_log(gb, "Current mapped ROM0 bank: %x\n", gb->mbc_rom0_bank); GB_log(gb, "MBC1 multicart banking mode is %s\n", gb->mbc1.mode == 1 ? "enabled" : "disabled"); } } else { GB_log(gb, "No MBC\n"); } if (gb->cartridge_type->has_rumble && (gb->cartridge_type->mbc_type != GB_TPP1 || (gb->rom[0x153] & 1))) { GB_log(gb, "Cart contains a Rumble Pak\n"); } if (cartridge->has_rtc) { GB_log(gb, "Cart contains a real time clock\n"); } return true; } static bool backtrace(GB_gameboy_t *gb, char *arguments, char *modifiers, const debugger_command_t *command) { NO_MODIFIERS if (strlen(lstrip(arguments))) { print_usage(gb, command); return true; } GB_log(gb, " 1. %s\n", debugger_value_to_string(gb, (value_t){true, bank_for_addr(gb, gb->pc), gb->pc}, true)); for (unsigned i = gb->backtrace_size; i--;) { GB_log(gb, "%3d. %s\n", gb->backtrace_size - i + 1, debugger_value_to_string(gb, (value_t){true, gb->backtrace_returns[i].bank, gb->backtrace_returns[i].addr}, true)); } return true; } static bool ticks(GB_gameboy_t *gb, char *arguments, char *modifiers, const debugger_command_t *command) { NO_MODIFIERS STOPPED_ONLY if (strlen(lstrip(arguments))) { print_usage(gb, command); return true; } GB_log(gb, "T-cycles: %llu\n", (unsigned long long)gb->debugger_ticks); GB_log(gb, "M-cycles: %llu\n", (unsigned long long)gb->debugger_ticks / 4); GB_log(gb, "Absolute 8MHz ticks: %llu\n", (unsigned long long)gb->absolute_debugger_ticks); GB_log(gb, "Tick count reset.\n"); gb->debugger_ticks = 0; gb->absolute_debugger_ticks = 0; return true; } static bool palettes(GB_gameboy_t *gb, char *arguments, char *modifiers, const debugger_command_t *command) { NO_MODIFIERS if (strlen(lstrip(arguments))) { print_usage(gb, command); return true; } if (!GB_is_cgb(gb)) { GB_log(gb, "Not available on a DMG.\n"); return true; } GB_log(gb, "Background palettes: \n"); for (unsigned i = 0; i < 32; i++) { GB_log(gb, "%04x ", ((uint16_t *)&gb->background_palettes_data)[i]); if (i % 4 == 3) { GB_log(gb, "\n"); } } GB_log(gb, "Object palettes: \n"); for (unsigned i = 0; i < 32; i++) { GB_log(gb, "%04x ", ((uint16_t *)&gb->object_palettes_data)[i]); if (i % 4 == 3) { GB_log(gb, "\n"); } } return true; } static bool dma(GB_gameboy_t *gb, char *arguments, char *modifiers, const debugger_command_t *command) { NO_MODIFIERS if (strlen(lstrip(arguments))) { print_usage(gb, command); return true; } if (!GB_is_dma_active(gb)) { GB_log(gb, "DMA is inactive\n"); return true; } if (gb->dma_current_dest == 0xFF) { GB_log(gb, "DMA warming up\n"); // Shouldn't actually happen, as it only lasts 2 T-cycles return true; } GB_log(gb, "Next DMA write: [$FE%02X] = [$%04X]\n", gb->dma_current_dest, gb->dma_current_src); return true; } static bool lcd(GB_gameboy_t *gb, char *arguments, char *modifiers, const debugger_command_t *command) { NO_MODIFIERS if (strlen(lstrip(arguments))) { print_usage(gb, command); return true; } GB_log(gb, "LCDC:\n"); GB_log(gb, " LCD enabled: %s\n",(gb->io_registers[GB_IO_LCDC] & 128)? "Enabled" : "Disabled"); GB_log(gb, " %s: %s\n", (gb->cgb_mode? "Object priority flags" : "Background and Window"), (gb->io_registers[GB_IO_LCDC] & 1)? "Enabled" : "Disabled"); GB_log(gb, " Objects: %s\n", (gb->io_registers[GB_IO_LCDC] & 2)? "Enabled" : "Disabled"); GB_log(gb, " Object size: %s\n", (gb->io_registers[GB_IO_LCDC] & 4)? "8x16" : "8x8"); GB_log(gb, " Background tilemap: %s\n", (gb->io_registers[GB_IO_LCDC] & 8)? "$9C00" : "$9800"); GB_log(gb, " Background and Window Tileset: %s\n", (gb->io_registers[GB_IO_LCDC] & 16)? "$8000" : "$8800"); GB_log(gb, " Window: %s\n", (gb->io_registers[GB_IO_LCDC] & 32)? "Enabled" : "Disabled"); GB_log(gb, " Window tilemap: %s\n", (gb->io_registers[GB_IO_LCDC] & 64)? "$9C00" : "$9800"); GB_log(gb, "\nSTAT:\n"); static const char *modes[] = {"Mode 0, H-Blank", "Mode 1, V-Blank", "Mode 2, OAM", "Mode 3, Rendering"}; GB_log(gb, " Current mode: %s\n", modes[gb->io_registers[GB_IO_STAT] & 3]); GB_log(gb, " LYC flag: %s\n", (gb->io_registers[GB_IO_STAT] & 4)? "On" : "Off"); GB_log(gb, " H-Blank interrupt: %s\n", (gb->io_registers[GB_IO_STAT] & 8)? "Enabled" : "Disabled"); GB_log(gb, " V-Blank interrupt: %s\n", (gb->io_registers[GB_IO_STAT] & 16)? "Enabled" : "Disabled"); GB_log(gb, " OAM interrupt: %s\n", (gb->io_registers[GB_IO_STAT] & 32)? "Enabled" : "Disabled"); GB_log(gb, " LYC interrupt: %s\n", (gb->io_registers[GB_IO_STAT] & 64)? "Enabled" : "Disabled"); GB_log(gb, "\nCurrent line: %d\n", gb->current_line); GB_log(gb, "Current state: "); if (!(gb->io_registers[GB_IO_LCDC] & 0x80)) { GB_log(gb, "Off\n"); } else if (gb->display_state == 7 || gb->display_state == 8) { GB_log(gb, "Reading OAM data (%d/40)\n", gb->display_state == 8? gb->oam_search_index : 0); } else if (gb->display_state <= 3 || gb->display_state == 24 || gb->display_state == 31) { GB_log(gb, "Glitched line 0 OAM mode (%d cycles to next event)\n", -gb->display_cycles / 2); } else if (gb->mode_for_interrupt == 3) { if (((uint8_t)(gb->position_in_line + 16) < 8)) { GB_log(gb, "Adjusting for scrolling (%d/%d)\n", gb->position_in_line & 7, gb->io_registers[GB_IO_SCX] & 7); } else { signed pixel = gb->position_in_line > 160? (int8_t) gb->position_in_line : gb->position_in_line; GB_log(gb, "Rendering pixel (%d/160)\n", pixel); } } else { GB_log(gb, "Sleeping (%d cycles to next event)\n", -gb->display_cycles / 2); } GB_log(gb, "LY: %d\n", gb->io_registers[GB_IO_LY]); GB_log(gb, "LYC: %d\n", gb->io_registers[GB_IO_LYC]); GB_log(gb, "Window position: %d, %d\n", (signed) gb->io_registers[GB_IO_WX] - 7, gb->io_registers[GB_IO_WY]); GB_log(gb, "Interrupt line: %s\n", gb->stat_interrupt_line? "On" : "Off"); return true; } static bool apu(GB_gameboy_t *gb, char *arguments, char *modifiers, const debugger_command_t *command) { NO_MODIFIERS const char *stripped = lstrip(arguments); if (strlen(stripped)) { if (stripped[0] != 0 && (stripped[0] < '1' || stripped[0] > '5')) { print_usage(gb, command); return true; } } if (stripped[0] == 0 || stripped[0] == '5') { GB_log(gb, "Current state: "); if (!gb->apu.global_enable) { GB_log(gb, "Disabled\n"); } else { GB_log(gb, "Enabled\n"); for (uint8_t channel = 0; channel < GB_N_CHANNELS; channel++) { GB_log(gb, "CH%u is %s, DAC %s; current sample = 0x%x\n", channel + 1, gb->apu.is_active[channel] ? "active " : "inactive", GB_apu_is_DAC_enabled(gb, channel) ? "active " : "inactive", gb->apu.samples[channel]); } } GB_log(gb, "SO1 (left output): volume %u,", gb->io_registers[GB_IO_NR50] & 0x07); if (gb->io_registers[GB_IO_NR51] & 0x0F) { for (uint8_t channel = 0, mask = 0x01; channel < GB_N_CHANNELS; channel++, mask <<= 1) { if (gb->io_registers[GB_IO_NR51] & mask) { GB_log(gb, " CH%u", channel + 1); } } } else { GB_log(gb, " no channels"); } GB_log(gb, "%s\n", gb->io_registers[GB_IO_NR50] & 0x80 ? " VIN": ""); GB_log(gb, "SO2 (right output): volume %u,", gb->io_registers[GB_IO_NR50] & 0x70 >> 4); if (gb->io_registers[GB_IO_NR51] & 0xF0) { for (uint8_t channel = 0, mask = 0x10; channel < GB_N_CHANNELS; channel++, mask <<= 1) { if (gb->io_registers[GB_IO_NR51] & mask) { GB_log(gb, " CH%u", channel + 1); } } } else { GB_log(gb, " no channels"); } GB_log(gb, "%s\n", gb->io_registers[GB_IO_NR50] & 0x80 ? " VIN": ""); } for (uint8_t channel = GB_SQUARE_1; channel <= GB_SQUARE_2; channel++) { if (stripped[0] != 0 && stripped[0] != ('1') + channel) continue; GB_log(gb, "\nCH%u:\n", channel + 1); GB_log(gb, " Current volume: %u, current sample length: %u APU ticks (next in %u ticks)\n", gb->apu.square_channels[channel].current_volume, (gb->apu.square_channels[channel].sample_length ^ 0x7FF) * 2 + 1, gb->apu.square_channels[channel].sample_countdown); uint8_t nrx2 = gb->io_registers[channel == GB_SQUARE_1? GB_IO_NR12 : GB_IO_NR22]; GB_log(gb, " %u 256 Hz ticks till next volume %screase (out of %u)\n", gb->apu.square_channels[channel].volume_countdown, nrx2 & 8 ? "in" : "de", nrx2 & 7); uint8_t duty = gb->io_registers[channel == GB_SQUARE_1? GB_IO_NR11 :GB_IO_NR21] >> 6; GB_log(gb, " Duty cycle %s%% (%s), current index %u/8%s\n", duty > 3? "" : (const char *[]){"12.5", " 25", " 50", " 75"}[duty], duty > 3? "" : (const char *[]){"_______-", "-______-", "-____---", "_------_"}[duty], gb->apu.square_channels[channel].current_sample_index, gb->apu.square_channels[channel].sample_surpressed ? " (suppressed)" : ""); if (channel == GB_SQUARE_1) { GB_log(gb, " Frequency sweep %s and %s\n", ((gb->io_registers[GB_IO_NR10] & 0x7) && (gb->io_registers[GB_IO_NR10] & 0x70))? "active" : "inactive", (gb->io_registers[GB_IO_NR10] & 0x8) ? "decreasing" : "increasing"); if (gb->apu.square_sweep_calculate_countdown) { GB_log(gb, " On going frequency calculation will be ready in %u APU ticks\n", gb->apu.square_sweep_calculate_countdown); } else { GB_log(gb, " Shadow frequency register: 0x%03x\n", gb->apu.shadow_sweep_sample_length); GB_log(gb, " Sweep addend register: 0x%03x\n", gb->apu.sweep_length_addend); } } if (gb->apu.square_channels[channel].length_enabled) { GB_log(gb, " Channel will end in %u 256 Hz ticks\n", gb->apu.square_channels[channel].pulse_length); } } if (stripped[0] == 0 || stripped[0] == '3') { GB_log(gb, "\nCH3:\n"); GB_log(gb, " Wave:"); for (uint8_t i = 0; i < 16; i++) { GB_log(gb, "%s%X", i % 2? "" : " ", gb->io_registers[GB_IO_WAV_START + i] >> 4); GB_log(gb, "%X", gb->io_registers[GB_IO_WAV_START + i] & 0xF); } GB_log(gb, "\n"); GB_log(gb, " Current position: %u\n", gb->apu.wave_channel.current_sample_index); GB_log(gb, " Volume %s (right-shifted %u times)\n", gb->apu.wave_channel.shift > 4? "" : (const char *[]){"100%", "50%", "25%", "", "muted"}[gb->apu.wave_channel.shift], gb->apu.wave_channel.shift); GB_log(gb, " Current sample length: %u APU ticks (next in %u ticks)\n", gb->apu.wave_channel.sample_length ^ 0x7FF, gb->apu.wave_channel.sample_countdown); if (gb->apu.wave_channel.length_enabled) { GB_log(gb, " Channel will end in %u 256 Hz ticks\n", gb->apu.wave_channel.pulse_length); } } if (stripped[0] == 0 || stripped[0] == '4') { GB_log(gb, "\nCH4:\n"); GB_log(gb, " Current volume: %u, current internal counter: 0x%04x (next increase in %u ticks)\n", gb->apu.noise_channel.current_volume, gb->apu.noise_channel.counter, gb->apu.noise_channel.counter_countdown); GB_log(gb, " %u 256 Hz ticks till next volume %screase (out of %u)\n", gb->apu.noise_channel.volume_countdown, gb->io_registers[GB_IO_NR42] & 8 ? "in" : "de", gb->io_registers[GB_IO_NR42] & 7); GB_log(gb, " LFSR in %u-step mode, current value ", gb->apu.noise_channel.narrow? 7 : 15); for (uint16_t lfsr = gb->apu.noise_channel.lfsr, i = 15; i--; lfsr <<= 1) { GB_log(gb, "%u%s", (lfsr >> 14) & 1, i%4 ? "" : " "); } if (gb->apu.noise_channel.length_enabled) { GB_log(gb, " Channel will end in %u 256 Hz ticks\n", gb->apu.noise_channel.pulse_length); } } GB_log(gb, "\n\nReminder: APU ticks are @ 2 MiHz\n"); return true; } static char *wave_completer(GB_gameboy_t *gb, const char *string, uintptr_t *context) { size_t length = strlen(string); const char *suggestions[] = {"c", "f", "l"}; while (*context < sizeof(suggestions) / sizeof(suggestions[0])) { if (memcmp(string, suggestions[*context], length) == 0) { return strdup(suggestions[(*context)++] + length); } (*context)++; } return NULL; } static bool wave(GB_gameboy_t *gb, char *arguments, char *modifiers, const debugger_command_t *command) { if (strlen(lstrip(arguments)) || (modifiers && !strchr("fcl", modifiers[0]))) { print_usage(gb, command); return true; } uint8_t shift_amount = 1, mask; if (modifiers) { switch (modifiers[0]) { case 'c': shift_amount = 2; break; case 'l': shift_amount = 8; break; } } mask = (0xF << (shift_amount - 1)) & 0xF; for (int8_t cur_val = 0xF & mask; cur_val >= 0; cur_val -= shift_amount) { for (uint8_t i = 0; i < 32; i++) { uint8_t sample = i & 1? (gb->io_registers[GB_IO_WAV_START + i / 2] & 0xF) : (gb->io_registers[GB_IO_WAV_START + i / 2] >> 4); if ((sample & mask) == cur_val) { GB_log(gb, "%X", sample); } else { GB_log(gb, "%c", i % 4 == 2 ? '-' : ' '); } } GB_log(gb, "\n"); } return true; } static bool undo(GB_gameboy_t *gb, char *arguments, char *modifiers, const debugger_command_t *command) { NO_MODIFIERS STOPPED_ONLY if (strlen(lstrip(arguments))) { print_usage(gb, command); return true; } if (!gb->undo_label) { GB_log(gb, "No undo state available\n"); return true; } uint16_t pc = gb->pc; GB_load_state_from_buffer(gb, gb->undo_state, GB_get_save_state_size_no_bess(gb)); GB_log(gb, "Reverted a \"%s\" command.\n", gb->undo_label); if (pc != gb->pc) { GB_cpu_disassemble(gb, gb->pc, 5); } gb->undo_label = NULL; return true; } static bool help(GB_gameboy_t *gb, char *arguments, char *modifiers, const debugger_command_t *command); #define HELP_NEWLINE "\n " /* Commands without implementations are aliases of the previous non-alias commands */ static const debugger_command_t commands[] = { {"continue", 1, cont, "Continue running until next stop"}, {"next", 1, next, "Run the next instruction, skipping over function calls"}, {"step", 1, step, "Run the next instruction, stepping into function calls"}, {"finish", 1, finish, "Run until the current function returns"}, {"undo", 1, undo, "Revert the last command"}, {"backtrace", 2, backtrace, "Display the current call stack"}, {"bt", 2, }, /* Alias */ {"sld", 3, stack_leak_detection, "Like finish, but stops if a stack leak is detected"}, {"ticks", 2, ticks, "Display the number of CPU ticks since the last time 'ticks' was" HELP_NEWLINE "used"}, {"registers", 1, registers, "Print values of processor registers and other important registers"}, {"cartridge", 2, mbc, "Display information about the MBC and cartridge"}, {"mbc", 3, }, /* Alias */ {"apu", 3, apu, "Display information about the current state of the audio processing unit", "[channel (1-4, 5 for NR5x)]"}, {"wave", 3, wave, "Print a visual representation of the wave RAM." HELP_NEWLINE "Modifiers can be used for a (f)ull print (the default)," HELP_NEWLINE "a more (c)ompact one, or a one-(l)iner", "", "(f|c|l)", .modifiers_completer = wave_completer}, {"lcd", 3, lcd, "Display information about the current state of the LCD controller"}, {"palettes", 3, palettes, "Display the current CGB palettes"}, {"dma", 3, dma, "Display the current OAM DMA status"}, {"softbreak", 2, softbreak, "Enable or disable software breakpoints", "(on|off)", .argument_completer = on_off_completer}, {"breakpoint", 1, breakpoint, "Add a new breakpoint at the specified address/expression" HELP_NEWLINE "Can also modify the condition of existing breakpoints." HELP_NEWLINE "If the j modifier is used, the breakpoint will occur just before" HELP_NEWLINE "jumping to the target.", "[ if ]", "j", .argument_completer = symbol_completer, .modifiers_completer = j_completer}, {"delete", 2, delete, "Delete a breakpoint by its address, or all breakpoints", "[]", .argument_completer = symbol_completer}, {"watch", 1, watch, "Add a new watchpoint at the specified address/expression." HELP_NEWLINE "Can also modify the condition and type of existing watchpoints." HELP_NEWLINE "Default watchpoint type is write-only.", "[ if ]", "(r|w|rw)", .argument_completer = symbol_completer, .modifiers_completer = rw_completer }, {"unwatch", 3, unwatch, "Delete a watchpoint by its address, or all watchpoints", "[]", .argument_completer = symbol_completer}, {"list", 1, list, "List all set breakpoints and watchpoints"}, {"print", 1, print, "Evaluate and print an expression" HELP_NEWLINE "Use modifier to format as an address (a, default) or as a number in" HELP_NEWLINE "decimal (d), hexadecimal (x), octal (o) or binary (b).", "", "format", .argument_completer = symbol_completer, .modifiers_completer = format_completer}, {"eval", 2, }, /* Alias */ {"examine", 2, examine, "Examine values at address", "", "count", .argument_completer = symbol_completer}, {"x", 1, }, /* Alias */ {"disassemble", 1, disassemble, "Disassemble instructions at address", "", "count", .argument_completer = symbol_completer}, {"help", 1, help, "List available commands or show help for the specified command", "[]"}, {NULL,}, /* Null terminator */ }; static const debugger_command_t *find_command(const char *string) { size_t length = strlen(string); for (const debugger_command_t *command = commands; command->command; command++) { if (command->min_length > length) continue; if (memcmp(command->command, string, length) == 0) { /* Is a substring? */ /* Aliases */ while (!command->implementation) { command--; } return command; } } return NULL; } static void print_command_shortcut(GB_gameboy_t *gb, const debugger_command_t *command) { GB_attributed_log(gb, GB_LOG_BOLD | GB_LOG_UNDERLINE, "%.*s", command->min_length, command->command); GB_attributed_log(gb, GB_LOG_BOLD, "%s", command->command + command->min_length); } static void print_command_description(GB_gameboy_t *gb, const debugger_command_t *command) { print_command_shortcut(gb, command); GB_log(gb, ": "); GB_log(gb, (const char *)&" %s\n" + strlen(command->command), command->help_string); } static bool help(GB_gameboy_t *gb, char *arguments, char *modifiers, const debugger_command_t *ignored) { const debugger_command_t *command = find_command(arguments); if (command) { print_command_description(gb, command); GB_log(gb, "\n"); print_usage(gb, command); command++; if (command->command && !command->implementation) { /* Command has aliases*/ GB_log(gb, "\nAliases: "); do { print_command_shortcut(gb, command); GB_log(gb, " "); command++; } while (command->command && !command->implementation); GB_log(gb, "\n"); } return true; } for (command = commands; command->command; command++) { if (command->help_string) { print_command_description(gb, command); } } return true; } void GB_debugger_call_hook(GB_gameboy_t *gb, uint16_t call_addr) { /* Called just after the CPU calls a function/enters an interrupt/etc... */ if (gb->stack_leak_detection) { if (gb->debug_call_depth >= sizeof(gb->sp_for_call_depth) / sizeof(gb->sp_for_call_depth[0])) { GB_log(gb, "Potential stack overflow detected (Functions nest too much). \n"); gb->debug_stopped = true; } else { gb->sp_for_call_depth[gb->debug_call_depth] = gb->sp; gb->addr_for_call_depth[gb->debug_call_depth] = gb->pc; } } if (gb->backtrace_size < sizeof(gb->backtrace_sps) / sizeof(gb->backtrace_sps[0])) { while (gb->backtrace_size) { if (gb->backtrace_sps[gb->backtrace_size - 1] < gb->sp) { gb->backtrace_size--; } else { break; } } gb->backtrace_sps[gb->backtrace_size] = gb->sp; gb->backtrace_returns[gb->backtrace_size].bank = bank_for_addr(gb, call_addr); gb->backtrace_returns[gb->backtrace_size].addr = call_addr; gb->backtrace_size++; } gb->debug_call_depth++; } void GB_debugger_ret_hook(GB_gameboy_t *gb) { /* Called just before the CPU runs ret/reti */ gb->debug_call_depth--; if (gb->stack_leak_detection) { if (gb->debug_call_depth < 0) { GB_log(gb, "Function finished without a stack leak.\n"); gb->debug_stopped = true; } else { if (gb->sp != gb->sp_for_call_depth[gb->debug_call_depth]) { GB_log(gb, "Stack leak detected for function %s!\n", value_to_string(gb, gb->addr_for_call_depth[gb->debug_call_depth], true)); GB_log(gb, "SP is $%04x, should be $%04x.\n", gb->sp, gb->sp_for_call_depth[gb->debug_call_depth]); gb->debug_stopped = true; } } } while (gb->backtrace_size) { if (gb->backtrace_sps[gb->backtrace_size - 1] <= gb->sp) { gb->backtrace_size--; } else { break; } } } static bool _GB_debugger_test_write_watchpoint(GB_gameboy_t *gb, value_t addr, uint8_t value) { uint16_t index = find_watchpoint(gb, addr); uint32_t key = WP_KEY(addr); if (index < gb->n_watchpoints && gb->watchpoints[index].key == key) { if (!(gb->watchpoints[index].flags & GB_WATCHPOINT_W)) { return false; } if (!gb->watchpoints[index].condition) { gb->debug_stopped = true; GB_log(gb, "Watchpoint: [%s] = $%02x\n", debugger_value_to_string(gb, addr, true), value); return true; } bool error; bool condition = debugger_evaluate(gb, gb->watchpoints[index].condition, (unsigned)strlen(gb->watchpoints[index].condition), &error, &addr.value, &value).value; if (error) { /* Should never happen */ GB_log(gb, "An internal error has occured\n"); return false; } if (condition) { gb->debug_stopped = true; GB_log(gb, "Watchpoint: [%s] = $%02x\n", debugger_value_to_string(gb, addr, true), value); return true; } } return false; } void GB_debugger_test_write_watchpoint(GB_gameboy_t *gb, uint16_t addr, uint8_t value) { if (gb->debug_stopped) return; /* Try any-bank breakpoint */ value_t full_addr = (VALUE_16(addr)); if (_GB_debugger_test_write_watchpoint(gb, full_addr, value)) return; /* Try bank-specific breakpoint */ full_addr.has_bank = true; full_addr.bank = bank_for_addr(gb, addr); _GB_debugger_test_write_watchpoint(gb, full_addr, value); } static bool _GB_debugger_test_read_watchpoint(GB_gameboy_t *gb, value_t addr) { uint16_t index = find_watchpoint(gb, addr); uint32_t key = WP_KEY(addr); if (index < gb->n_watchpoints && gb->watchpoints[index].key == key) { if (!(gb->watchpoints[index].flags & GB_WATCHPOINT_R)) { return false; } if (!gb->watchpoints[index].condition) { gb->debug_stopped = true; GB_log(gb, "Watchpoint: [%s]\n", debugger_value_to_string(gb, addr, true)); return true; } bool error; bool condition = debugger_evaluate(gb, gb->watchpoints[index].condition, (unsigned)strlen(gb->watchpoints[index].condition), &error, &addr.value, NULL).value; if (error) { /* Should never happen */ GB_log(gb, "An internal error has occured\n"); return false; } if (condition) { gb->debug_stopped = true; GB_log(gb, "Watchpoint: [%s]\n", debugger_value_to_string(gb, addr, true)); return true; } } return false; } void GB_debugger_test_read_watchpoint(GB_gameboy_t *gb, uint16_t addr) { if (gb->debug_stopped) return; /* Try any-bank breakpoint */ value_t full_addr = (VALUE_16(addr)); if (_GB_debugger_test_read_watchpoint(gb, full_addr)) return; /* Try bank-specific breakpoint */ full_addr.has_bank = true; full_addr.bank = bank_for_addr(gb, addr); _GB_debugger_test_read_watchpoint(gb, full_addr); } /* Returns true if debugger waits for more commands */ bool GB_debugger_execute_command(GB_gameboy_t *gb, char *input) { if (!input[0]) { return true; } GB_display_sync(gb); GB_apu_run(gb, true); char *command_string = input; char *arguments = strchr(input, ' '); if (arguments) { /* Actually "split" the string. */ arguments[0] = 0; arguments++; } else { arguments = ""; } char *modifiers = strchr(command_string, '/'); if (modifiers) { /* Actually "split" the string. */ modifiers[0] = 0; modifiers++; } const debugger_command_t *command = find_command(command_string); if (command) { uint8_t *old_state = malloc(GB_get_save_state_size_no_bess(gb)); GB_save_state_to_buffer_no_bess(gb, old_state); bool ret = command->implementation(gb, arguments, modifiers, command); if (!ret) { // Command continues, save state in any case free(gb->undo_state); gb->undo_state = old_state; gb->undo_label = command->command; } else { uint8_t *new_state = malloc(GB_get_save_state_size_no_bess(gb)); GB_save_state_to_buffer_no_bess(gb, new_state); if (memcmp(new_state, old_state, GB_get_save_state_size_no_bess(gb)) != 0) { // State changed, save the old state as the new undo state free(gb->undo_state); gb->undo_state = old_state; gb->undo_label = command->command; } else { // Nothing changed, just free the old state free(old_state); } free(new_state); } return ret; } else { GB_log(gb, "%s: no such command.\n", command_string); return true; } } char *GB_debugger_complete_substring(GB_gameboy_t *gb, char *input, uintptr_t *context) { char *command_string = input; char *arguments = strchr(input, ' '); if (arguments) { /* Actually "split" the string. */ arguments[0] = 0; arguments++; } char *modifiers = strchr(command_string, '/'); if (modifiers) { /* Actually "split" the string. */ modifiers[0] = 0; modifiers++; } const debugger_command_t *command = find_command(command_string); if (command && command->implementation == help && arguments) { command_string = arguments; arguments = NULL; } /* No commands and no modifiers, complete the command */ if (!arguments && !modifiers) { size_t length = strlen(command_string); if (*context >= sizeof(commands) / sizeof(commands[0])) { return NULL; } for (const debugger_command_t *command = &commands[*context]; command->command; command++) { (*context)++; if (memcmp(command->command, command_string, length) == 0) { /* Is a substring? */ return strdup(command->command + length); } } return NULL; } if (command) { if (arguments) { if (command->argument_completer) { return command->argument_completer(gb, arguments, context); } return NULL; } if (modifiers) { if (command->modifiers_completer) { return command->modifiers_completer(gb, modifiers, context); } return NULL; } } return NULL; } typedef enum { JUMP_TO_NONE, JUMP_TO_BREAK, JUMP_TO_NONTRIVIAL, } jump_to_return_t; static jump_to_return_t test_jump_to_breakpoints(GB_gameboy_t *gb, uint16_t *address); void GB_debugger_run(GB_gameboy_t *gb) { if (gb->debug_disable) return; if (!gb->undo_state) { gb->undo_state = malloc(GB_get_save_state_size_no_bess(gb)); GB_save_state_to_buffer_no_bess(gb, gb->undo_state); } char *input = NULL; if (gb->debug_next_command && gb->debug_call_depth <= 0 && !gb->halted) { gb->debug_stopped = true; } if (gb->debug_fin_command && gb->debug_call_depth == -1) { gb->debug_stopped = true; } if (gb->debug_stopped) { GB_cpu_disassemble(gb, gb->pc, 5); } next_command: if (input) { free(input); } if (gb->breakpoints && !gb->debug_stopped && should_break(gb, gb->pc, false)) { gb->debug_stopped = true; GB_log(gb, "Breakpoint: PC = %s\n", value_to_string(gb, gb->pc, true)); GB_cpu_disassemble(gb, gb->pc, 5); } if (gb->breakpoints && !gb->debug_stopped) { uint16_t address = 0; jump_to_return_t jump_to_result = test_jump_to_breakpoints(gb, &address); bool should_delete_state = true; if (gb->nontrivial_jump_state && should_break(gb, gb->pc, true)) { if (gb->non_trivial_jump_breakpoint_occured) { gb->non_trivial_jump_breakpoint_occured = false; } else { gb->non_trivial_jump_breakpoint_occured = true; GB_log(gb, "Jumping to breakpoint: PC = %s\n", value_to_string(gb, gb->pc, true)); GB_cpu_disassemble(gb, gb->pc, 5); GB_load_state_from_buffer(gb, gb->nontrivial_jump_state, -1); gb->debug_stopped = true; } } else if (jump_to_result == JUMP_TO_BREAK) { gb->debug_stopped = true; GB_log(gb, "Jumping to breakpoint: PC = %s\n", value_to_string(gb, address, true)); GB_cpu_disassemble(gb, gb->pc, 5); gb->non_trivial_jump_breakpoint_occured = false; } else if (jump_to_result == JUMP_TO_NONTRIVIAL) { if (!gb->nontrivial_jump_state) { gb->nontrivial_jump_state = malloc(GB_get_save_state_size_no_bess(gb)); } GB_save_state_to_buffer_no_bess(gb, gb->nontrivial_jump_state); gb->non_trivial_jump_breakpoint_occured = false; should_delete_state = false; } else { gb->non_trivial_jump_breakpoint_occured = false; } if (should_delete_state) { if (gb->nontrivial_jump_state) { free(gb->nontrivial_jump_state); gb->nontrivial_jump_state = NULL; } } } if (gb->debug_stopped && !gb->debug_disable) { gb->debug_next_command = false; gb->debug_fin_command = false; gb->stack_leak_detection = false; input = gb->input_callback(gb); if (input == NULL) { /* Debugging is no currently available, continue running */ gb->debug_stopped = false; return; } if (GB_debugger_execute_command(gb, input)) { goto next_command; } free(input); } } void GB_debugger_handle_async_commands(GB_gameboy_t *gb) { char *input = NULL; while (gb->async_input_callback && (input = gb->async_input_callback(gb))) { GB_debugger_execute_command(gb, input); free(input); } } void GB_debugger_add_symbol(GB_gameboy_t *gb, uint16_t bank, uint16_t address, const char *symbol) { if (bank >= gb->n_symbol_maps) { gb->bank_symbols = realloc(gb->bank_symbols, (bank + 1) * sizeof(*gb->bank_symbols)); while (bank >= gb->n_symbol_maps) { gb->bank_symbols[gb->n_symbol_maps++] = NULL; } } if (!gb->bank_symbols[bank]) { gb->bank_symbols[bank] = GB_map_alloc(); } GB_bank_symbol_t *allocated_symbol = GB_map_add_symbol(gb->bank_symbols[bank], address, symbol); if (allocated_symbol) { GB_reversed_map_add_symbol(&gb->reversed_symbol_map, bank, allocated_symbol); } } void GB_debugger_load_symbol_file(GB_gameboy_t *gb, const char *path) { FILE *f = fopen(path, "r"); if (!f) return; char *line = NULL; size_t size = 0; size_t length = 0; while ((length = getline(&line, &size, f)) != -1) { for (unsigned i = 0; i < length; i++) { if (line[i] == ';' || line[i] == '\n' || line[i] == '\r') { line[i] = 0; length = i; break; } } if (length == 0) continue; unsigned bank, address; char symbol[length]; if (sscanf(line, "%x:%x %s", &bank, &address, symbol) == 3) { GB_debugger_add_symbol(gb, bank, address, symbol); } } free(line); fclose(f); } void GB_debugger_clear_symbols(GB_gameboy_t *gb) { for (unsigned i = gb->n_symbol_maps; i--;) { if (gb->bank_symbols[i]) { GB_map_free(gb->bank_symbols[i]); gb->bank_symbols[i] = 0; } } for (unsigned i = sizeof(gb->reversed_symbol_map.buckets) / sizeof(gb->reversed_symbol_map.buckets[0]); i--;) { while (gb->reversed_symbol_map.buckets[i]) { GB_symbol_t *next = gb->reversed_symbol_map.buckets[i]->next; free(gb->reversed_symbol_map.buckets[i]); gb->reversed_symbol_map.buckets[i] = next; } } gb->n_symbol_maps = 0; if (gb->bank_symbols) { free(gb->bank_symbols); gb->bank_symbols = NULL; } } const GB_bank_symbol_t *GB_debugger_find_symbol(GB_gameboy_t *gb, uint16_t addr) { uint16_t bank = bank_for_addr(gb, addr); const GB_bank_symbol_t *symbol = GB_map_find_symbol(get_symbol_map(gb, bank), addr); if (symbol) return symbol; if (bank != 0) return GB_map_find_symbol(get_symbol_map(gb, 0), addr); /* Maybe the symbol incorrectly uses bank 0? */ return NULL; } const char *GB_debugger_name_for_address(GB_gameboy_t *gb, uint16_t addr) { const GB_bank_symbol_t *symbol = GB_debugger_find_symbol(gb, addr); if (symbol && symbol->addr == addr) return symbol->name; return NULL; } /* The public version of debugger_evaluate */ bool GB_debugger_evaluate(GB_gameboy_t *gb, const char *string, uint16_t *result, uint16_t *result_bank) { bool error = false; value_t value = debugger_evaluate(gb, string, strlen(string), &error, NULL, NULL); if (result) { *result = value.value; } if (result_bank) { *result_bank = value.has_bank? value.value : -1; } return error; } void GB_debugger_break(GB_gameboy_t *gb) { gb->debug_stopped = true; } bool GB_debugger_is_stopped(GB_gameboy_t *gb) { return gb->debug_stopped; } void GB_debugger_set_disabled(GB_gameboy_t *gb, bool disabled) { gb->debug_disable = disabled; } /* Jump-to breakpoints */ static bool is_in_trivial_memory(uint16_t addr) { /* ROM */ if (addr < 0x8000) { return true; } /* HRAM */ if (addr >= 0xFF80 && addr < 0xFFFF) { return true; } /* RAM */ if (addr >= 0xC000 && addr < 0xE000) { return true; } return false; } typedef uint16_t opcode_address_getter_t(GB_gameboy_t *gb, uint8_t opcode); uint16_t trivial_1(GB_gameboy_t *gb, uint8_t opcode) { return gb->pc + 1; } uint16_t trivial_2(GB_gameboy_t *gb, uint8_t opcode) { return gb->pc + 2; } uint16_t trivial_3(GB_gameboy_t *gb, uint8_t opcode) { return gb->pc + 3; } static uint16_t jr_r8(GB_gameboy_t *gb, uint8_t opcode) { return gb->pc + 2 + (int8_t)GB_read_memory(gb, gb->pc + 1); } static bool condition_code(GB_gameboy_t *gb, uint8_t opcode) { switch ((opcode >> 3) & 0x3) { case 0: return !(gb->af & GB_ZERO_FLAG); case 1: return (gb->af & GB_ZERO_FLAG); case 2: return !(gb->af & GB_CARRY_FLAG); case 3: return (gb->af & GB_CARRY_FLAG); } return false; } static uint16_t jr_cc_r8(GB_gameboy_t *gb, uint8_t opcode) { if (!condition_code(gb, opcode)) { return gb->pc + 2; } return gb->pc + 2 + (int8_t)GB_read_memory(gb, gb->pc + 1); } static uint16_t ret(GB_gameboy_t *gb, uint8_t opcode) { return GB_read_memory(gb, gb->sp) | (GB_read_memory(gb, gb->sp + 1) << 8); } static uint16_t ret_cc(GB_gameboy_t *gb, uint8_t opcode) { if (condition_code(gb, opcode)) { return ret(gb, opcode); } else { return gb->pc + 1; } } static uint16_t jp_a16(GB_gameboy_t *gb, uint8_t opcode) { return GB_read_memory(gb, gb->pc + 1) | (GB_read_memory(gb, gb->pc + 2) << 8); } static uint16_t jp_cc_a16(GB_gameboy_t *gb, uint8_t opcode) { if (condition_code(gb, opcode)) { return jp_a16(gb, opcode); } else { return gb->pc + 3; } } static uint16_t rst(GB_gameboy_t *gb, uint8_t opcode) { return opcode ^ 0xC7; } static uint16_t jp_hl(GB_gameboy_t *gb, uint8_t opcode) { return gb->hl; } static opcode_address_getter_t *opcodes[256] = { /* X0 X1 X2 X3 X4 X5 X6 X7 */ /* X8 X9 Xa Xb Xc Xd Xe Xf */ trivial_1, trivial_3, trivial_1, trivial_1, trivial_1, trivial_1, trivial_2, trivial_1, /* 0X */ trivial_3, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_2, trivial_1, trivial_2, trivial_3, trivial_1, trivial_1, trivial_1, trivial_1, trivial_2, trivial_1, /* 1X */ jr_r8, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_2, trivial_1, jr_cc_r8, trivial_3, trivial_1, trivial_1, trivial_1, trivial_1, trivial_2, trivial_1, /* 2X */ jr_cc_r8, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_2, trivial_1, jr_cc_r8, trivial_3, trivial_1, trivial_1, trivial_1, trivial_1, trivial_2, trivial_1, /* 3X */ jr_cc_r8, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_2, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, /* 4X */ trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, /* 5X */ trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, /* 6X */ trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, NULL, trivial_1, /* 7X */ trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, /* 8X */ trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, /* 9X */ trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, /* aX */ trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, /* bX */ trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, trivial_1, ret_cc, trivial_1, jp_cc_a16, jp_a16, jp_cc_a16, trivial_1, trivial_2, rst, /* cX */ ret_cc, ret, jp_cc_a16, trivial_2, jp_cc_a16, jp_a16, trivial_2, rst, ret_cc, trivial_1, jp_cc_a16, NULL, jp_cc_a16, trivial_1, trivial_2, rst, /* dX */ ret_cc, ret, jp_cc_a16, NULL, jp_cc_a16, NULL, trivial_2, rst, trivial_2, trivial_1, trivial_1, NULL, NULL, trivial_1, trivial_2, rst, /* eX */ trivial_2, jp_hl, trivial_3, NULL, NULL, NULL, trivial_2, rst, trivial_2, trivial_1, trivial_1, trivial_1, NULL, trivial_1, trivial_2, rst, /* fX */ trivial_2, trivial_1, trivial_3, trivial_1, NULL, NULL, trivial_2, rst, }; static jump_to_return_t test_jump_to_breakpoints(GB_gameboy_t *gb, uint16_t *address) { if (!gb->has_jump_to_breakpoints) return JUMP_TO_NONE; if (!is_in_trivial_memory(gb->pc) || !is_in_trivial_memory(gb->pc + 2) || !is_in_trivial_memory(gb->sp) || !is_in_trivial_memory(gb->sp + 1)) { return JUMP_TO_NONTRIVIAL; } /* Interrupts */ if (gb->ime) { for (unsigned i = 0; i < 5; i++) { if ((gb->interrupt_enable & (1 << i)) && (gb->io_registers[GB_IO_IF] & (1 << i))) { if (should_break(gb, 0x40 + i * 8, true)) { if (address) { *address = 0x40 + i * 8; } return JUMP_TO_BREAK; } } } } uint16_t n_watchpoints = gb->n_watchpoints; gb->n_watchpoints = 0; uint8_t opcode = GB_read_memory(gb, gb->pc); if (opcode == 0x76) { gb->n_watchpoints = n_watchpoints; if (gb->ime) { /* Already handled in above */ return JUMP_TO_NONE; } if (gb->interrupt_enable & gb->io_registers[GB_IO_IF] & 0x1F) { return JUMP_TO_NONTRIVIAL; /* HALT bug could occur */ } return JUMP_TO_NONE; } opcode_address_getter_t *getter = opcodes[opcode]; if (!getter) { gb->n_watchpoints = n_watchpoints; return JUMP_TO_NONE; } uint16_t new_pc = getter(gb, opcode); gb->n_watchpoints = n_watchpoints; if (address) { *address = new_pc; } return should_break(gb, new_pc, true) ? JUMP_TO_BREAK : JUMP_TO_NONE; }