emu_nes/cpu.c

#include <stdint.h>
#include <stdio.h>
#include <string.h>

#define STATUS_UPDATE_ZERO(r)		\
	(regs.status.zero = r == 0)
#define STATUS_UPDATE_NEGATIVE(r)	\
	(regs.status.negative = ((r & (1 << 7)) > 0))

struct cpu_flags {
	uint8_t carry : 1;
	uint8_t zero : 1;
	uint8_t interrupt_disable : 1;
	uint8_t decimal_mode : 1;
	uint8_t brk : 1;
	uint8_t unused : 1;
	uint8_t overflow : 1;
	uint8_t negative : 1;
};

struct registers {
	uint8_t a, x, y, sp;
	struct cpu_flags status;
	uint16_t pc;
};
struct registers regs;

enum addressing_mode {
	AM_ACCUMULATOR,
	AM_IMMEDIATE,
	AM_ZERO_PAGE,
	AM_ZERO_PAGE_X,
	AM_ZERO_PAGE_Y,
	AM_RELATIVE,
	AM_ABSOLUTE,
	AM_ABSOLUTE_X,
	AM_ABSOLUTE_Y,
	AM_INDIRECT,
	AM_INDIRECT_X,
	AM_INDIRECT_Y,
	AM_INDEXED_INDIRECT,
	AM_INDIRECT_INDEXED,
};

/* 64K address space, 16bit words */
uint8_t memory[0x16000];

/* example program taken from https://bugzmanov.github.io/nes_ebook/chapter_3_1.html */
uint8_t program[] = { 0xa9, 0xc0, 0xaa, 0xe8, 0x00 };

uint8_t
peek(uint16_t addr)
{
	return memory[addr];
}

uint16_t
peek16(uint16_t addr)
{
	/* bytes are stored in little-endian (low then high) */
	return (uint16_t)memory[addr] | ((uint16_t)memory[addr + 1] << 8);
}

void
brk(void)
{
	/* $00 */
	/* TODO: push regs.pc and regs.status to stack and load IRQ vector */
	regs.status.brk = 1;
	return;
}

void
tax(void)
{
	/* $AA */
	regs.x = regs.a;

	STATUS_UPDATE_ZERO(regs.x);
	STATUS_UPDATE_NEGATIVE(regs.x);
}

void
inx(void)
{
	/* $E8 */
	regs.x++;

	STATUS_UPDATE_ZERO(regs.x);
	STATUS_UPDATE_NEGATIVE(regs.x);
}

void
lda(enum addressing_mode mode)
{
	uint8_t arg, val;

	arg = peek(regs.pc++);

	switch (mode) {
	case AM_IMMEDIATE:	/* $A9 */
		val = arg;
		break;
	case AM_ZERO_PAGE:	/* $A5 */
		val = peek(arg % 256);
		break;
	case AM_ABSOLUTE:	/* $AD */
		val = peek(arg);
		break;
	case AM_ZERO_PAGE_X:	/* $B5 */
		val = peek((arg + regs.x) % 256);
		break;
	case AM_ABSOLUTE_X:	/* $BD */
		val = peek(arg + regs.x);
		break;
	case AM_ABSOLUTE_Y:	/* $B9 */
		val = peek(arg + regs.y);
		break;
	case AM_INDIRECT_X:	/* $A1 */
		val = peek(peek((arg + regs.x) % 256) + peek((arg + regs.x + 1) % 256) * 256);
		break;
	case AM_INDIRECT_Y:	/* $B1 */
		val = peek(peek(arg) + peek((arg + 1) % 256) * 256 + regs.y);
		break;
	default:
		regs.pc--;
		return;
	}

	printf("arg1 $%02X\n", arg);
	regs.a = val;

	STATUS_UPDATE_ZERO(regs.a);
	STATUS_UPDATE_NEGATIVE(regs.a);
}

void
interpret(void)
{
	uint8_t opcode;

	for (;;) {
		opcode = peek(regs.pc++);

		printf("opcode: $%02X\n", opcode);

		switch (opcode) {
		case 0x00:
			brk();
			return;
		case 0xa1:
			lda(AM_INDIRECT_X);
			break;
		case 0xa5:
			lda(AM_ZERO_PAGE);
			break;
		case 0xa9:
			lda(AM_IMMEDIATE);
			break;
		case 0xaa:
			tax();
			break;
		case 0xad:
			lda(AM_ABSOLUTE);
			break;
		case 0xb1:
			lda(AM_INDIRECT_Y);
			break;
		case 0xb5:
			lda(AM_ZERO_PAGE_X);
			break;
		case 0xb9:
			lda(AM_ABSOLUTE_Y);
			break;
		case 0xbd:
			lda(AM_ABSOLUTE_X);
			break;
		case 0xe8:
			inx();
			break;
		default:
			printf("opcode $%02X not implemented\n", opcode);
			break;
		}

		printf("status: %i%i%i%i%i%i%i%i\n", regs.status.carry,
		    regs.status.zero, regs.status.interrupt_disable,
		    regs.status.decimal_mode, regs.status.brk,
		    regs.status.unused, regs.status.overflow,
		    regs.status.negative);
		printf("A: $%02X, X: $%02X, Y: $%02X, SP: $%02X, PC: $%02X\n",
		    regs.a, regs.x, regs.y, regs.sp, regs.pc);
	}
}

/* https://www.nesdev.org/wiki/CPU_power_up_state */
void
cpu_init(void)
{
	regs.a = regs.x = regs.y = 0;
	regs.pc = 0xFFFC;
	regs.sp = 0xFD;

	memset(&regs.status, 0, sizeof(regs.status));
	regs.status.unused = 1;
}

int
main(void)
{
	cpu_init();

	if (sizeof(program) > (0x10000 - 0x8000)) {
		fprintf(stderr, "program is too big for memory\n");
		return 1;
	}
	memcpy(memory + 0x8000, program, sizeof(program));
	regs.pc = 0x8000;

	printf("Initial State:\n");
	printf("status: %i%i%i%i%i%i%i%i\n", regs.status.carry,
	    regs.status.zero, regs.status.interrupt_disable,
	    regs.status.decimal_mode, regs.status.brk,
	    regs.status.unused, regs.status.overflow,
	    regs.status.negative);
	printf("A: $%02X, X: $%02X, Y: $%02X, SP: $%02X, PC: $%02X\n",
	    regs.a, regs.x, regs.y, regs.sp, regs.pc);

	putchar('\n');

	interpret();

	return 0;
}
start working on 6502 cpu 2024-05-20 10:09:19 -04:00			`#include <stdint.h>`
implement tax and inx and print status each time 2024-05-24 02:50:04 -04:00			`#include <stdio.h>`
load program rom into proper offset in memory 2024-05-24 03:25:44 -04:00			`#include <string.h>`
implement tax and inx and print status each time 2024-05-24 02:50:04 -04:00
			`#define STATUS_UPDATE_ZERO(r) \`
			`(regs.status.zero = r == 0)`
			`#define STATUS_UPDATE_NEGATIVE(r) \`
			`(regs.status.negative = ((r & (1 << 7)) > 0))`
start working on 6502 cpu 2024-05-20 10:09:19 -04:00
			`struct cpu_flags {`
			`uint8_t carry : 1;`
			`uint8_t zero : 1;`
			`uint8_t interrupt_disable : 1;`
			`uint8_t decimal_mode : 1;`
			`uint8_t brk : 1;`
			`uint8_t unused : 1;`
			`uint8_t overflow : 1;`
			`uint8_t negative : 1;`
			`};`

			`struct registers {`
implement tax and inx and print status each time 2024-05-24 02:50:04 -04:00			`uint8_t a, x, y, sp;`
start working on 6502 cpu 2024-05-20 10:09:19 -04:00			`struct cpu_flags status;`
			`uint16_t pc;`
			`};`
			`struct registers regs;`

			`enum addressing_mode {`
			`AM_ACCUMULATOR,`
			`AM_IMMEDIATE,`
			`AM_ZERO_PAGE,`
			`AM_ZERO_PAGE_X,`
			`AM_ZERO_PAGE_Y,`
			`AM_RELATIVE,`
			`AM_ABSOLUTE,`
			`AM_ABSOLUTE_X,`
			`AM_ABSOLUTE_Y,`
			`AM_INDIRECT,`
			`AM_INDIRECT_X,`
			`AM_INDIRECT_Y,`
			`AM_INDEXED_INDIRECT,`
			`AM_INDIRECT_INDEXED,`
			`};`

add peek(), peek16(), and finish lda() 2024-06-04 06:24:09 -04:00			`/* 64K address space, 16bit words */`
			`uint8_t memory[0x16000];`
start working on 6502 cpu 2024-05-20 10:09:19 -04:00
			`/* example program taken from https://bugzmanov.github.io/nes_ebook/chapter_3_1.html */`
			`uint8_t program[] = { 0xa9, 0xc0, 0xaa, 0xe8, 0x00 };`

add peek(), peek16(), and finish lda() 2024-06-04 06:24:09 -04:00			`uint8_t`
			`peek(uint16_t addr)`
			`{`
			`return memory[addr];`
			`}`

			`uint16_t`
			`peek16(uint16_t addr)`
			`{`
			`/* bytes are stored in little-endian (low then high) */`
			`return (uint16_t)memory[addr] \| ((uint16_t)memory[addr + 1] << 8);`
			`}`

implement tax and inx and print status each time 2024-05-24 02:50:04 -04:00			`void`
			`brk(void)`
add lda immediate and brk 2024-05-24 02:20:08 -04:00			`{`
implement tax and inx and print status each time 2024-05-24 02:50:04 -04:00			`/* $00 */`
add lda immediate and brk 2024-05-24 02:20:08 -04:00			`/* TODO: push regs.pc and regs.status to stack and load IRQ vector */`
			`regs.status.brk = 1;`
			`return;`
			`}`

implement tax and inx and print status each time 2024-05-24 02:50:04 -04:00			`void`
			`tax(void)`
			`{`
			`/* $AA */`
			`regs.x = regs.a;`

			`STATUS_UPDATE_ZERO(regs.x);`
			`STATUS_UPDATE_NEGATIVE(regs.x);`
			`}`

			`void`
			`inx(void)`
			`{`
			`/* $E8 */`
			`regs.x++;`

			`STATUS_UPDATE_ZERO(regs.x);`
			`STATUS_UPDATE_NEGATIVE(regs.x);`
			`}`

			`void`
			`lda(enum addressing_mode mode)`
add lda immediate and brk 2024-05-24 02:20:08 -04:00			`{`
add peek(), peek16(), and finish lda() 2024-06-04 06:24:09 -04:00			`uint8_t arg, val;`

			`arg = peek(regs.pc++);`
add lda immediate and brk 2024-05-24 02:20:08 -04:00
			`switch (mode) {`
			`case AM_IMMEDIATE: /* $A9 */`
add peek(), peek16(), and finish lda() 2024-06-04 06:24:09 -04:00			`val = arg;`
add lda immediate and brk 2024-05-24 02:20:08 -04:00			`break;`
			`case AM_ZERO_PAGE: /* $A5 */`
add peek(), peek16(), and finish lda() 2024-06-04 06:24:09 -04:00			`val = peek(arg % 256);`
implement tax and inx and print status each time 2024-05-24 02:50:04 -04:00			`break;`
add lda immediate and brk 2024-05-24 02:20:08 -04:00			`case AM_ABSOLUTE: /* $AD */`
add peek(), peek16(), and finish lda() 2024-06-04 06:24:09 -04:00			`val = peek(arg);`
			`break;`
			`case AM_ZERO_PAGE_X: /* $B5 */`
			`val = peek((arg + regs.x) % 256);`
implement tax and inx and print status each time 2024-05-24 02:50:04 -04:00			`break;`
add lda immediate and brk 2024-05-24 02:20:08 -04:00			`case AM_ABSOLUTE_X: /* $BD */`
add peek(), peek16(), and finish lda() 2024-06-04 06:24:09 -04:00			`val = peek(arg + regs.x);`
implement tax and inx and print status each time 2024-05-24 02:50:04 -04:00			`break;`
add lda immediate and brk 2024-05-24 02:20:08 -04:00			`case AM_ABSOLUTE_Y: /* $B9 */`
add peek(), peek16(), and finish lda() 2024-06-04 06:24:09 -04:00			`val = peek(arg + regs.y);`
implement tax and inx and print status each time 2024-05-24 02:50:04 -04:00			`break;`
add lda immediate and brk 2024-05-24 02:20:08 -04:00			`case AM_INDIRECT_X: /* $A1 */`
add peek(), peek16(), and finish lda() 2024-06-04 06:24:09 -04:00			`val = peek(peek((arg + regs.x) % 256) + peek((arg + regs.x + 1) % 256) * 256);`
implement tax and inx and print status each time 2024-05-24 02:50:04 -04:00			`break;`
add lda immediate and brk 2024-05-24 02:20:08 -04:00			`case AM_INDIRECT_Y: /* $B1 */`
add peek(), peek16(), and finish lda() 2024-06-04 06:24:09 -04:00			`val = peek(peek(arg) + peek((arg + 1) % 256) * 256 + regs.y);`
add lda immediate and brk 2024-05-24 02:20:08 -04:00			`break;`
			`default:`
add peek(), peek16(), and finish lda() 2024-06-04 06:24:09 -04:00			`regs.pc--;`
add lda immediate and brk 2024-05-24 02:20:08 -04:00			`return;`
			`}`

add peek(), peek16(), and finish lda() 2024-06-04 06:24:09 -04:00			`printf("arg1 $%02X\n", arg);`
			`regs.a = val;`

implement tax and inx and print status each time 2024-05-24 02:50:04 -04:00			`STATUS_UPDATE_ZERO(regs.a);`
			`STATUS_UPDATE_NEGATIVE(regs.a);`
add lda immediate and brk 2024-05-24 02:20:08 -04:00			`}`

implement tax and inx and print status each time 2024-05-24 02:50:04 -04:00			`void`
			`interpret(void)`
start working on 6502 cpu 2024-05-20 10:09:19 -04:00			`{`
			`uint8_t opcode;`

			`for (;;) {`
add peek(), peek16(), and finish lda() 2024-06-04 06:24:09 -04:00			`opcode = peek(regs.pc++);`
start working on 6502 cpu 2024-05-20 10:09:19 -04:00
implement tax and inx and print status each time 2024-05-24 02:50:04 -04:00			`printf("opcode: $%02X\n", opcode);`

start working on 6502 cpu 2024-05-20 10:09:19 -04:00			`switch (opcode) {`
add lda immediate and brk 2024-05-24 02:20:08 -04:00			`case 0x00:`
			`brk();`
			`return;`
implement tax and inx and print status each time 2024-05-24 02:50:04 -04:00			`case 0xa1:`
			`lda(AM_INDIRECT_X);`
add lda immediate and brk 2024-05-24 02:20:08 -04:00			`break;`
			`case 0xa5:`
			`lda(AM_ZERO_PAGE);`
			`break;`
implement tax and inx and print status each time 2024-05-24 02:50:04 -04:00			`case 0xa9:`
			`lda(AM_IMMEDIATE);`
			`break;`
			`case 0xaa:`
			`tax();`
add lda immediate and brk 2024-05-24 02:20:08 -04:00			`break;`
			`case 0xad:`
			`lda(AM_ABSOLUTE);`
			`break;`
implement tax and inx and print status each time 2024-05-24 02:50:04 -04:00			`case 0xb1:`
			`lda(AM_INDIRECT_Y);`
			`break;`
			`case 0xb5:`
			`lda(AM_ZERO_PAGE_X);`
add lda immediate and brk 2024-05-24 02:20:08 -04:00			`break;`
			`case 0xb9:`
			`lda(AM_ABSOLUTE_Y);`
			`break;`
implement tax and inx and print status each time 2024-05-24 02:50:04 -04:00			`case 0xbd:`
			`lda(AM_ABSOLUTE_X);`
add lda immediate and brk 2024-05-24 02:20:08 -04:00			`break;`
implement tax and inx and print status each time 2024-05-24 02:50:04 -04:00			`case 0xe8:`
			`inx();`
add lda immediate and brk 2024-05-24 02:20:08 -04:00			`break;`
start working on 6502 cpu 2024-05-20 10:09:19 -04:00			`default:`
implement tax and inx and print status each time 2024-05-24 02:50:04 -04:00			`printf("opcode $%02X not implemented\n", opcode);`
start working on 6502 cpu 2024-05-20 10:09:19 -04:00			`break;`
			`}`
implement tax and inx and print status each time 2024-05-24 02:50:04 -04:00
			`printf("status: %i%i%i%i%i%i%i%i\n", regs.status.carry,`
			`regs.status.zero, regs.status.interrupt_disable,`
			`regs.status.decimal_mode, regs.status.brk,`
			`regs.status.unused, regs.status.overflow,`
			`regs.status.negative);`
			`printf("A: $%02X, X: $%02X, Y: $%02X, SP: $%02X, PC: $%02X\n",`
			`regs.a, regs.x, regs.y, regs.sp, regs.pc);`
start working on 6502 cpu 2024-05-20 10:09:19 -04:00			`}`
			`}`
implement tax and inx and print status each time 2024-05-24 02:50:04 -04:00
add peek(), peek16(), and finish lda() 2024-06-04 06:24:09 -04:00			`/* https://www.nesdev.org/wiki/CPU_power_up_state */`
			`void`
			`cpu_init(void)`
			`{`
			`regs.a = regs.x = regs.y = 0;`
			`regs.pc = 0xFFFC;`
			`regs.sp = 0xFD;`

			`memset(&regs.status, 0, sizeof(regs.status));`
			`regs.status.unused = 1;`
			`}`

implement tax and inx and print status each time 2024-05-24 02:50:04 -04:00			`int`
			`main(void)`
			`{`
add peek(), peek16(), and finish lda() 2024-06-04 06:24:09 -04:00			`cpu_init();`

load program rom into proper offset in memory 2024-05-24 03:25:44 -04:00			`if (sizeof(program) > (0x10000 - 0x8000)) {`
			`fprintf(stderr, "program is too big for memory\n");`
			`return 1;`
			`}`
			`memcpy(memory + 0x8000, program, sizeof(program));`
			`regs.pc = 0x8000;`

			`printf("Initial State:\n");`
			`printf("status: %i%i%i%i%i%i%i%i\n", regs.status.carry,`
			`regs.status.zero, regs.status.interrupt_disable,`
			`regs.status.decimal_mode, regs.status.brk,`
			`regs.status.unused, regs.status.overflow,`
			`regs.status.negative);`
			`printf("A: $%02X, X: $%02X, Y: $%02X, SP: $%02X, PC: $%02X\n",`
			`regs.a, regs.x, regs.y, regs.sp, regs.pc);`

			`putchar('\n');`

implement tax and inx and print status each time 2024-05-24 02:50:04 -04:00			`interpret();`

			`return 0;`
			`}`