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erc-c/include/mos6502.h
Peter Evans f8bda4ebd3 Remove modify_status() function
Also rewrite tests to use macros
2018-02-28 21:40:52 -06:00

279 lines
7.1 KiB
C

#ifndef _MOS6502_H_
#define _MOS6502_H_
#include <stdbool.h>
#include "vm_bits.h"
#include "vm_segment.h"
/*
* The size of memory that the MOS 6502 supports is 64k (the limit of
* values that a 16-bit address could possibly map to).
*/
#define MOS6502_MEMSIZE 65536
/*
* This is a small macro to make it a bit simpler to set bytes ahead of
* the PC register position; useful in testing.
*/
#define SET_PC_BYTE(cpu, off, byte) \
mos6502_set(cpu, cpu->PC + off, byte)
/*
* This macro is used to define new instruction handler functions.
*/
#define DEFINE_INST(inst) \
void mos6502_handle_##inst (mos6502 *cpu, vm_8bit oper)
/*
* In some address mode resolution, we must factor the carry bit into
* the arithmetic we perform. In all those cases, if the carry bit is
* set, we must only add 1 to the addition. The carry variable is,
* therefore, the literal value we are adding, rather than a boolean
* signifier.
*/
#define MOS_CARRY_BIT() \
vm_8bit carry = 0; \
if (cpu->P & MOS_CARRY) carry = 1
#define SET_RESULT(op) \
int result = op
/*
* A uniform way of declaring resolve functions for address modes, which
* is useful in the event that we need to change the function signature.
*/
#define DECL_ADDR_MODE(x) \
extern vm_8bit mos6502_resolve_##x (mos6502 *)
/*
* Similarly, a uniform way of declaring instruction handler functions,
* for the same reasons.
*/
#define DECL_INST(x) \
extern void mos6502_handle_##x (mos6502 *, vm_8bit)
#define MOS_CHECK_Z(result) \
cpu->P &= ~MOS_ZERO; \
if ((vm_8bit)(result) == 0) cpu->P |= MOS_ZERO
#define MOS_CHECK_N(result) \
cpu->P &= ~MOS_NEGATIVE; \
if ((vm_8bit)(result) & 0x80) cpu->P |= MOS_NEGATIVE
#define MOS_CHECK_V(orig, result) \
cpu->P &= ~MOS_OVERFLOW; \
do { \
vm_8bit r = result; \
vm_8bit o = orig; \
if ((o & 0x80) ^ (r & 0x80)) { \
cpu->P |= MOS_OVERFLOW; \
} \
} while (0)
#define MOS_CHECK_NV(orig, result) \
MOS_CHECK_N(result); \
MOS_CHECK_V(orig, result)
#define MOS_CHECK_NZ(result) \
MOS_CHECK_N(result); \
MOS_CHECK_Z(result)
#define MOS_CHECK_NVZ(orig, result) \
MOS_CHECK_N(result); \
MOS_CHECK_V(orig, result); \
MOS_CHECK_Z(result)
typedef struct {
/*
* There are two different segment pointers for reading and writing,
* because it's possible for there to be two different banks in
* which an action occurs. These memory segments must be injected at
* creation time, and can be changed later.
*/
vm_segment *rmem;
vm_segment *wmem;
/*
* This contains the _effective_ address we've resolved in one
* of our address modes. In absolute mode, this would be the literal
* operand we read from memory; in indirect mode, this will be the
* address we _find_ after dereferencing the operand we read from
* memory. Another way of thinking of this is, this address is where
* we found the value we care about.
*/
vm_16bit eff_addr;
/*
* These are the last opcode and last effective address that was
* used in the instruction previous to the one currently being
* executed. Some things (notably soft switches) may need to
* the last opcode.
*/
vm_8bit last_opcode;
vm_8bit last_operand;
vm_16bit last_addr;
/*
* Our program counter register; this is what we'll use to determine
* where we're "at" in memory while executing opcodes. We use a
* 16-bit register because our memory is 64k large.
*/
vm_16bit PC;
/*
* This is the accumulator register. It's used in most arithmetic
* operations, and anything like that which you need to do will end
* up storing the value here.
*/
vm_8bit A;
/*
* The X and Y registers are our index registers. They're provided
* to aid looping over tables, but they can also be used for other
* purposes.
*/
vm_8bit X, Y;
/*
* The P register is our status flag register. (I presume 'P' means
* 'predicate'.) Each bit stands for some kind of status.
*/
vm_8bit P;
/*
* The S register is our stack counter register. It indicates how
* far into the stack we've gone.
*/
vm_8bit S;
} mos6502;
/*
* This is a small convenience so that we don't need to expose the
* somewhat regrettable syntax for function pointers to any main source
* file
*/
typedef vm_8bit (*mos6502_address_resolver)(mos6502 *);
/*
* Another convenience; this type definition is for the functions we
* write to handle instruction logic.
*/
typedef void (*mos6502_instruction_handler)(mos6502 *, vm_8bit);
extern bool mos6502_would_jump(int);
extern int mos6502_cycles(mos6502 *, vm_8bit);
extern int mos6502_instruction(vm_8bit);
extern mos6502 *mos6502_create(vm_segment *, vm_segment *);
extern mos6502_instruction_handler mos6502_get_instruction_handler(vm_8bit);
extern vm_16bit mos6502_get16(mos6502 *, size_t);
extern vm_8bit mos6502_get(mos6502 *, size_t);
extern vm_8bit mos6502_pop_stack(mos6502 *);
extern void mos6502_execute(mos6502 *);
extern void mos6502_free(mos6502 *);
extern void mos6502_last_executed(mos6502 *, vm_8bit *, vm_8bit *, vm_16bit *);
extern void mos6502_push_stack(mos6502 *, vm_8bit);
extern void mos6502_set(mos6502 *, size_t, vm_8bit);
extern void mos6502_set16(mos6502 *, size_t, vm_16bit);
extern void mos6502_set_memory(mos6502 *, vm_segment *, vm_segment *);
extern void mos6502_set_status(mos6502 *, vm_8bit);
/*
* Below are some functions that are defined in mos6502.addr.c
*/
extern int mos6502_addr_mode(vm_8bit);
extern mos6502_address_resolver mos6502_get_address_resolver(int);
/*
* All of our address modes
*/
DECL_ADDR_MODE(acc);
DECL_ADDR_MODE(abs);
DECL_ADDR_MODE(abx);
DECL_ADDR_MODE(aby);
DECL_ADDR_MODE(imm);
DECL_ADDR_MODE(ind);
DECL_ADDR_MODE(idx);
DECL_ADDR_MODE(idy);
DECL_ADDR_MODE(rel);
DECL_ADDR_MODE(zpg);
DECL_ADDR_MODE(zpx);
DECL_ADDR_MODE(zpy);
/*
* And now, our instruction handlers; held generally in mos6502.*.c
* (excepting mos6502.addr.c).
*/
DECL_INST(adc);
DECL_INST(adc_dec);
DECL_INST(and);
DECL_INST(asl);
DECL_INST(bad);
DECL_INST(bcc);
DECL_INST(bcs);
DECL_INST(beq);
DECL_INST(bit);
DECL_INST(bim);
DECL_INST(bmi);
DECL_INST(bne);
DECL_INST(bpl);
DECL_INST(bra);
DECL_INST(brk);
DECL_INST(bvc);
DECL_INST(bvs);
DECL_INST(clc);
DECL_INST(cld);
DECL_INST(cli);
DECL_INST(clv);
DECL_INST(cmp);
DECL_INST(cpx);
DECL_INST(cpy);
DECL_INST(dec);
DECL_INST(dex);
DECL_INST(dey);
DECL_INST(eor);
DECL_INST(inc);
DECL_INST(inx);
DECL_INST(iny);
DECL_INST(jmp);
DECL_INST(jsr);
DECL_INST(lda);
DECL_INST(ldx);
DECL_INST(ldy);
DECL_INST(lsr);
DECL_INST(nop);
DECL_INST(np2);
DECL_INST(np3);
DECL_INST(ora);
DECL_INST(pha);
DECL_INST(php);
DECL_INST(phx);
DECL_INST(phy);
DECL_INST(pla);
DECL_INST(plp);
DECL_INST(plx);
DECL_INST(ply);
DECL_INST(rol);
DECL_INST(ror);
DECL_INST(rti);
DECL_INST(rts);
DECL_INST(sbc);
DECL_INST(sbc_dec);
DECL_INST(sec);
DECL_INST(sed);
DECL_INST(sei);
DECL_INST(sta);
DECL_INST(stx);
DECL_INST(sty);
DECL_INST(stz);
DECL_INST(tax);
DECL_INST(tay);
DECL_INST(trb);
DECL_INST(tsb);
DECL_INST(tsx);
DECL_INST(txa);
DECL_INST(txs);
DECL_INST(tya);
#endif