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erc-c/src/mos6502.loadstor.c
Peter Evans 90892c32e4 Add TSB (Test and Set Bits) instruction
This commit also moves the TRB code from loadstor to bits, which is
where it should have been all along.
2018-02-22 13:39:48 -06:00

194 lines
3.2 KiB
C

/*
* mos6502.loadstor.c
*
* These are all the instructions which load and store values into
* various registers and places in memory.
*/
#include "mos6502.h"
#include "mos6502.enums.h"
/*
* The LDA instruction will assign ("load") an operand into the
* accumulator.
*/
DEFINE_INST(lda)
{
mos6502_modify_status(cpu, MOS_NZ, cpu->A, oper);
cpu->A = oper;
}
/*
* Similar to LDA, except targeting X.
*/
DEFINE_INST(ldx)
{
mos6502_modify_status(cpu, MOS_NZ, cpu->X, oper);
cpu->X = oper;
}
/*
* Again similar to LDA, except with Y.
*/
DEFINE_INST(ldy)
{
mos6502_modify_status(cpu, MOS_NZ, cpu->Y, oper);
cpu->Y = oper;
}
/*
* This instruction will "push" the A register onto the stack.
*/
DEFINE_INST(pha)
{
mos6502_push_stack(cpu, cpu->A);
}
/*
* Similar to above, but will push the P register.
*/
DEFINE_INST(php)
{
mos6502_push_stack(cpu, cpu->P);
}
/*
* Push the X register onto the stack. Sadly, this does not summon a
* phoenix to assist you in hours of need.
*/
DEFINE_INST(phx)
{
mos6502_push_stack(cpu, cpu->X);
}
/*
* Push the Y register onto the stack
*/
DEFINE_INST(phy)
{
mos6502_push_stack(cpu, cpu->Y);
}
/*
* Here we pop the stack (or "pull" it), and assign to the accumulator.
*/
DEFINE_INST(pla)
{
SET_RESULT(mos6502_pop_stack(cpu));
mos6502_modify_status(cpu, MOS_NZ, cpu->A, result);
cpu->A = result;
}
/*
* Again we pop from the stack, but assign to the P register.
*/
DEFINE_INST(plp)
{
cpu->P = mos6502_pop_stack(cpu);
}
/*
* Pop from the stack and assign that byte to the X register
*/
DEFINE_INST(plx)
{
cpu->X = mos6502_pop_stack(cpu);
}
/*
* Pop from the stack and assign that byte to the Y register
*/
DEFINE_INST(ply)
{
cpu->Y = mos6502_pop_stack(cpu);
}
/*
* The STA instruction assigns the value of the accumulator to a given
* address in memory. (That is to say, it "stores" it.)
*/
DEFINE_INST(sta)
{
mos6502_set(cpu, cpu->eff_addr, cpu->A);
}
/*
* Similar to STA, but drawing from the X register.
*/
DEFINE_INST(stx)
{
mos6502_set(cpu, cpu->eff_addr, cpu->X);
}
/*
* And, again, similar to STA, but with the Y register.
*/
DEFINE_INST(sty)
{
mos6502_set(cpu, cpu->eff_addr, cpu->Y);
}
/*
* Store a zero byte into the effective address
*/
DEFINE_INST(stz)
{
mos6502_set(cpu, cpu->eff_addr, 0);
}
/*
* The TAX instruction taxes no one but your patience for my puns. What
* it does do is transfer the contents of the A register to X.
*/
DEFINE_INST(tax)
{
mos6502_modify_status(cpu, MOS_NZ, cpu->X, cpu->A);
cpu->X = cpu->A;
}
/*
* This transfers from A to Y.
*/
DEFINE_INST(tay)
{
mos6502_modify_status(cpu, MOS_NZ, cpu->Y, cpu->A);
cpu->Y = cpu->A;
}
/*
* Transfer the stack pointer (S register) to X.
*/
DEFINE_INST(tsx)
{
mos6502_modify_status(cpu, MOS_NZ, cpu->X, cpu->S);
cpu->X = cpu->S;
}
/*
* Transfer the X register to A.
*/
DEFINE_INST(txa)
{
mos6502_modify_status(cpu, MOS_NZ, cpu->A, cpu->X);
cpu->A = cpu->X;
}
/*
* Transfer the X register to S.
*/
DEFINE_INST(txs)
{
mos6502_modify_status(cpu, MOS_NZ, cpu->S, cpu->X);
cpu->S = cpu->X;
}
/*
* Transfer the Y register to A.
*/
DEFINE_INST(tya)
{
mos6502_modify_status(cpu, MOS_NZ, cpu->A, cpu->Y);
cpu->A = cpu->Y;
}