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Rewrite status checks with macros

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This also forces the result of operations to be considered purely as
8-bit results in _some_ cases, but not in others. We were missing some
times when an overflow is the expected behavior; because SET_RESULT()
and mos6502_modify_status() use ints, this overflow was not properly
observed.
This commit is contained in:
Peter Evans 2018-02-28 21:16:39 -06:00
parent 4baec33e24
commit 49199eac84
4 changed files with 110 additions and 76 deletions
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31
include/mos6502.h
View File

@ -53,6 +53,37 @@
#define DECL_INST(x) \ #define DECL_INST(x) \
extern void mos6502_handle_##x (mos6502 *, vm_8bit) 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 { typedef struct {
/* /*
* There are two different segment pointers for reading and writing, * There are two different segment pointers for reading and writing,

57
src/mos6502.arith.c
View File

@ -21,11 +21,19 @@ DEFINE_INST(adc)
} }
MOS_CARRY_BIT(); MOS_CARRY_BIT();
SET_RESULT(cpu->A + oper + carry);
mos6502_modify_status(cpu, MOS_NVZC, cpu->A, result); vm_8bit result = cpu->A + oper + carry;
MOS_CHECK_NVZ(cpu->A, result);
cpu->A = result & 0xff; // Carry has different meanings in different contexts... in ADC,
// carry is set if the result requires a ninth bit (the carry bit!)
// to be set.
cpu->P &= ~MOS_CARRY;
if ((cpu->A + oper + carry) > 0xff) {
cpu->P |= MOS_CARRY;
}
cpu->A = result;
} }
/* /*
@ -65,17 +73,16 @@ DEFINE_INST(adc_dec)
// And the final result has to be ported back into a "hexadecimal" // And the final result has to be ported back into a "hexadecimal"
// number; you see, BCD values are not just literally decimal, they // number; you see, BCD values are not just literally decimal, they
// are decimal in hexadecimal form. // are decimal in hexadecimal form.
SET_RESULT(((modsum / 10) << 4) | (modsum % 10)); vm_8bit result = ((modsum / 10) << 4) | (modsum % 10);
// Because the rules for carry is a bit different, we'll handle it // As you can see, decimal comports a different meaning for the
// here. // carry bit than its binary version
cpu->P &= ~MOS_CARRY; cpu->P &= ~MOS_CARRY;
if (sum > 100) { if (sum > 100) {
cpu->P |= MOS_CARRY; cpu->P |= MOS_CARRY;
} }
// We'll check zero, but not negative or overflow. MOS_CHECK_Z(result);
mos6502_modify_status(cpu, MOS_ZERO, cpu->A, sum);
cpu->A = result; cpu->A = result;
} }
@ -89,10 +96,10 @@ DEFINE_INST(adc_dec)
*/ */
DEFINE_INST(cmp) DEFINE_INST(cmp)
{ {
mos6502_modify_status(cpu, MOS_NZ, cpu->A, cpu->A - oper); MOS_CHECK_NZ(cpu->A - oper);
// Carry works slightly different with the cmp-style instructions; // With CMP, carry is set if the difference between A and oper is
// it's set if A >= oper. // not zero.
cpu->P &= ~MOS_CARRY; cpu->P &= ~MOS_CARRY;
if (cpu->A >= oper) { if (cpu->A >= oper) {
cpu->P |= MOS_CARRY; cpu->P |= MOS_CARRY;
@ -105,7 +112,7 @@ DEFINE_INST(cmp)
*/ */
DEFINE_INST(cpx) DEFINE_INST(cpx)
{ {
mos6502_modify_status(cpu, MOS_NZ, cpu->X, cpu->X - oper); MOS_CHECK_NZ(cpu->X - oper);
cpu->P &= ~MOS_CARRY; cpu->P &= ~MOS_CARRY;
if (cpu->X >= oper) { if (cpu->X >= oper) {
@ -119,7 +126,7 @@ DEFINE_INST(cpx)
*/ */
DEFINE_INST(cpy) DEFINE_INST(cpy)
{ {
mos6502_modify_status(cpu, MOS_NZ, cpu->Y, cpu->Y - oper); MOS_CHECK_NZ(cpu->Y - oper);
cpu->P &= ~MOS_CARRY; cpu->P &= ~MOS_CARRY;
if (cpu->Y >= oper) { if (cpu->Y >= oper) {
@ -134,7 +141,7 @@ DEFINE_INST(cpy)
DEFINE_INST(dec) DEFINE_INST(dec)
{ {
if (cpu->eff_addr) { if (cpu->eff_addr) {
mos6502_modify_status(cpu, MOS_NZ, oper, oper - 1); MOS_CHECK_NZ(oper - 1);
mos6502_set(cpu, cpu->eff_addr, oper - 1); mos6502_set(cpu, cpu->eff_addr, oper - 1);
return; return;
} }
@ -149,7 +156,7 @@ DEFINE_INST(dec)
*/ */
DEFINE_INST(dex) DEFINE_INST(dex)
{ {
mos6502_modify_status(cpu, MOS_NZ, cpu->X, cpu->X - 1); MOS_CHECK_NZ(cpu->X - 1);
cpu->X--; cpu->X--;
} }
@ -158,7 +165,7 @@ DEFINE_INST(dex)
*/ */
DEFINE_INST(dey) DEFINE_INST(dey)
{ {
mos6502_modify_status(cpu, MOS_NZ, cpu->Y, cpu->Y - 1); MOS_CHECK_NZ(cpu->Y - 1);
cpu->Y--; cpu->Y--;
} }
@ -168,7 +175,7 @@ DEFINE_INST(dey)
DEFINE_INST(inc) DEFINE_INST(inc)
{ {
if (cpu->eff_addr) { if (cpu->eff_addr) {
mos6502_modify_status(cpu, MOS_NZ, oper, oper + 1); MOS_CHECK_NZ(oper + 1);
mos6502_set(cpu, cpu->eff_addr, oper + 1); mos6502_set(cpu, cpu->eff_addr, oper + 1);
return; return;
} }
@ -181,7 +188,7 @@ DEFINE_INST(inc)
*/ */
DEFINE_INST(inx) DEFINE_INST(inx)
{ {
mos6502_modify_status(cpu, MOS_NZ, cpu->X, cpu->X + 1); MOS_CHECK_NZ(cpu->X + 1);
cpu->X++; cpu->X++;
} }
@ -190,7 +197,7 @@ DEFINE_INST(inx)
*/ */
DEFINE_INST(iny) DEFINE_INST(iny)
{ {
mos6502_modify_status(cpu, MOS_NZ, cpu->Y, cpu->Y + 1); MOS_CHECK_NZ(cpu->Y + 1);
cpu->Y++; cpu->Y++;
} }
@ -209,7 +216,9 @@ DEFINE_INST(sbc)
} }
MOS_CARRY_BIT(); MOS_CARRY_BIT();
SET_RESULT(cpu->A - oper - (carry ? 0 : 1));
vm_8bit result = cpu->A - oper - (carry ? 0 : 1);
MOS_CHECK_NVZ(cpu->A, result);
// Carry is handled slightly differently in SBC; it's set if the // Carry is handled slightly differently in SBC; it's set if the
// value is non-negative, and unset if negative. (It's essentially a // value is non-negative, and unset if negative. (It's essentially a
@ -219,8 +228,7 @@ DEFINE_INST(sbc)
cpu->P &= ~MOS_CARRY; cpu->P &= ~MOS_CARRY;
} }
mos6502_modify_status(cpu, MOS_NVZ, cpu->A, result); cpu->A = result;
cpu->A = result & 0xff;
} }
/* /*
@ -267,9 +275,8 @@ DEFINE_INST(sbc_dec)
// And the final result has to be ported back into a "hexadecimal" // And the final result has to be ported back into a "hexadecimal"
// number; you see, BCD values are not just literally decimal, they // number; you see, BCD values are not just literally decimal, they
// are decimal in hexadecimal form. // are decimal in hexadecimal form.
SET_RESULT(((diff / 10) << 4) | (diff % 10)); vm_8bit result = ((diff / 10) << 4) | (diff % 10);
MOS_CHECK_Z(result);
mos6502_modify_status(cpu, MOS_ZERO, cpu->A, result);
cpu->A = result; cpu->A = result;
} }

68
src/mos6502.bits.c
View File

@ -14,10 +14,8 @@
*/ */
DEFINE_INST(and) DEFINE_INST(and)
{ {
SET_RESULT(cpu->A & oper); MOS_CHECK_NZ(cpu->A & oper);
cpu->A &= oper;
mos6502_modify_status(cpu, MOS_NZ, cpu->A, result);
cpu->A = result & 0xff;
} }
/* /*
@ -33,14 +31,18 @@ DEFINE_INST(and)
*/ */
DEFINE_INST(asl) DEFINE_INST(asl)
{ {
SET_RESULT(oper << 1); vm_8bit result = oper << 1;
mos6502_modify_status(cpu, MOS_NZC, oper, result); MOS_CHECK_NZ(result);
cpu->P &= ~MOS_CARRY;
if ((oper << 1) > 0xff) {
cpu->P |= MOS_CARRY;
}
if (cpu->eff_addr) { if (cpu->eff_addr) {
mos6502_set(cpu, cpu->eff_addr, result & 0xff); mos6502_set(cpu, cpu->eff_addr, result);
} else { } else {
cpu->A = result & 0xff; cpu->A = result;
} }
} }
@ -96,10 +98,8 @@ DEFINE_INST(bim)
*/ */
DEFINE_INST(eor) DEFINE_INST(eor)
{ {
SET_RESULT(cpu->A ^ oper); MOS_CHECK_NZ(cpu->A ^ oper);
cpu->A ^= oper;
mos6502_modify_status(cpu, MOS_NZ, cpu->A, result);
cpu->A = result & 0xff;
} }
/* /*
@ -111,27 +111,25 @@ DEFINE_INST(eor)
*/ */
DEFINE_INST(lsr) DEFINE_INST(lsr)
{ {
SET_RESULT(oper >> 1); vm_8bit result = oper >> 1;
// Set ZERO if it should apply; also inspect the NEGATIVE flag, but // The N flag is ALWAYS cleared in LSR, because a zero is always
// note that doing so will have the effect of _always_ unsetting the // entered as bit 7
// N flag, because literally any byte value shifted right will cpu->P &= ~MOS_NEGATIVE;
// immediately lose the sign bit and be non-negative.
mos6502_modify_status(cpu, MOS_NZ, oper, result);
// However, we handle carry a bit differently here. The carry bit MOS_CHECK_Z(result);
// should be 1 if oper & 0x1; that is, when we shift right, we want
// the right-most bit to be captured in carry, in just the same way // Carry is set to the value of the bit we're "losing" in the shift
// we want the left-most bit to be captured in carry for ASL. // operation
cpu->P &= ~MOS_CARRY; cpu->P &= ~MOS_CARRY;
if (oper & 0x1) { if (oper & 0x1) {
cpu->P |= MOS_CARRY; cpu->P |= MOS_CARRY;
} }
if (cpu->eff_addr) { if (cpu->eff_addr) {
mos6502_set(cpu, cpu->eff_addr, result & 0xff); mos6502_set(cpu, cpu->eff_addr, result);
} else { } else {
cpu->A = result & 0xff; cpu->A = result;
} }
} }
@ -141,10 +139,8 @@ DEFINE_INST(lsr)
*/ */
DEFINE_INST(ora) DEFINE_INST(ora)
{ {
SET_RESULT(cpu->A | oper); MOS_CHECK_NZ(cpu->A | oper);
cpu->A |= oper;
mos6502_modify_status(cpu, MOS_NZ, cpu->A, result);
cpu->A = result & 0xff;
} }
/* /*
@ -154,7 +150,7 @@ DEFINE_INST(ora)
*/ */
DEFINE_INST(rol) DEFINE_INST(rol)
{ {
SET_RESULT(oper << 1); vm_8bit result = oper << 1;
// Rotations are effectively _9-bit_. So we aren't rotating bit 7 // Rotations are effectively _9-bit_. So we aren't rotating bit 7
// into bit 0; we're rotating bit 7 into the carry bit, and we're // into bit 0; we're rotating bit 7 into the carry bit, and we're
@ -168,12 +164,12 @@ DEFINE_INST(rol)
cpu->P |= MOS_CARRY; cpu->P |= MOS_CARRY;
} }
mos6502_modify_status(cpu, MOS_NZ, oper, result); MOS_CHECK_NZ(result);
if (cpu->eff_addr) { if (cpu->eff_addr) {
mos6502_set(cpu, cpu->eff_addr, result & 0xff); mos6502_set(cpu, cpu->eff_addr, result);
} else { } else {
cpu->A = result & 0xff; cpu->A = result;
} }
} }
@ -183,7 +179,7 @@ DEFINE_INST(rol)
*/ */
DEFINE_INST(ror) DEFINE_INST(ror)
{ {
SET_RESULT(oper >> 1); vm_8bit result = oper >> 1;
// See the code for ROL for my note on 9-bit rotation (vs. 8-bit). // See the code for ROL for my note on 9-bit rotation (vs. 8-bit).
if (cpu->P & MOS_CARRY) { if (cpu->P & MOS_CARRY) {
@ -195,12 +191,12 @@ DEFINE_INST(ror)
cpu->P |= MOS_CARRY; cpu->P |= MOS_CARRY;
} }
mos6502_modify_status(cpu, MOS_NZ, oper, result); MOS_CHECK_NZ(result);
if (cpu->eff_addr) { if (cpu->eff_addr) {
mos6502_set(cpu, cpu->eff_addr, result & 0xff); mos6502_set(cpu, cpu->eff_addr, result);
} else { } else {
cpu->A = result & 0xff; cpu->A = result;
} }
} }

30
src/mos6502.loadstor.c
View File

@ -14,7 +14,7 @@
*/ */
DEFINE_INST(lda) DEFINE_INST(lda)
{ {
mos6502_modify_status(cpu, MOS_NZ, cpu->A, oper); MOS_CHECK_NZ(oper);
cpu->A = oper; cpu->A = oper;
} }
@ -23,7 +23,7 @@ DEFINE_INST(lda)
*/ */
DEFINE_INST(ldx) DEFINE_INST(ldx)
{ {
mos6502_modify_status(cpu, MOS_NZ, cpu->X, oper); MOS_CHECK_NZ(oper);
cpu->X = oper; cpu->X = oper;
} }
@ -32,7 +32,7 @@ DEFINE_INST(ldx)
*/ */
DEFINE_INST(ldy) DEFINE_INST(ldy)
{ {
mos6502_modify_status(cpu, MOS_NZ, cpu->Y, oper); MOS_CHECK_NZ(oper);
cpu->Y = oper; cpu->Y = oper;
} }
@ -74,9 +74,9 @@ DEFINE_INST(phy)
*/ */
DEFINE_INST(pla) DEFINE_INST(pla)
{ {
SET_RESULT(mos6502_pop_stack(cpu)); vm_8bit result = mos6502_pop_stack(cpu);
mos6502_modify_status(cpu, MOS_NZ, cpu->A, result); MOS_CHECK_NZ(result);
cpu->A = result; cpu->A = result;
} }
@ -93,9 +93,9 @@ DEFINE_INST(plp)
*/ */
DEFINE_INST(plx) DEFINE_INST(plx)
{ {
SET_RESULT(mos6502_pop_stack(cpu)); vm_8bit result = mos6502_pop_stack(cpu);
mos6502_modify_status(cpu, MOS_NZ, cpu->X, result); MOS_CHECK_NZ(result);
cpu->X = result; cpu->X = result;
} }
@ -104,9 +104,9 @@ DEFINE_INST(plx)
*/ */
DEFINE_INST(ply) DEFINE_INST(ply)
{ {
SET_RESULT(mos6502_pop_stack(cpu)); vm_8bit result = mos6502_pop_stack(cpu);
mos6502_modify_status(cpu, MOS_NZ, cpu->Y, result); MOS_CHECK_NZ(result);
cpu->Y = result; cpu->Y = result;
} }
@ -149,7 +149,7 @@ DEFINE_INST(stz)
*/ */
DEFINE_INST(tax) DEFINE_INST(tax)
{ {
mos6502_modify_status(cpu, MOS_NZ, cpu->X, cpu->A); MOS_CHECK_NZ(cpu->A);
cpu->X = cpu->A; cpu->X = cpu->A;
} }
@ -158,7 +158,7 @@ DEFINE_INST(tax)
*/ */
DEFINE_INST(tay) DEFINE_INST(tay)
{ {
mos6502_modify_status(cpu, MOS_NZ, cpu->Y, cpu->A); MOS_CHECK_NZ(cpu->A);
cpu->Y = cpu->A; cpu->Y = cpu->A;
} }
@ -167,7 +167,7 @@ DEFINE_INST(tay)
*/ */
DEFINE_INST(tsx) DEFINE_INST(tsx)
{ {
mos6502_modify_status(cpu, MOS_NZ, cpu->X, cpu->S); MOS_CHECK_NZ(cpu->S);
cpu->X = cpu->S; cpu->X = cpu->S;
} }
@ -176,7 +176,7 @@ DEFINE_INST(tsx)
*/ */
DEFINE_INST(txa) DEFINE_INST(txa)
{ {
mos6502_modify_status(cpu, MOS_NZ, cpu->A, cpu->X); MOS_CHECK_NZ(cpu->X);
cpu->A = cpu->X; cpu->A = cpu->X;
} }
@ -185,7 +185,7 @@ DEFINE_INST(txa)
*/ */
DEFINE_INST(txs) DEFINE_INST(txs)
{ {
mos6502_modify_status(cpu, MOS_NZ, cpu->S, cpu->X); MOS_CHECK_NZ(cpu->X);
cpu->S = cpu->X; cpu->S = cpu->X;
} }
@ -194,6 +194,6 @@ DEFINE_INST(txs)
*/ */
DEFINE_INST(tya) DEFINE_INST(tya)
{ {
mos6502_modify_status(cpu, MOS_NZ, cpu->A, cpu->Y); MOS_CHECK_NZ(cpu->Y);
cpu->A = cpu->Y; cpu->A = cpu->Y;
} }