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erc-c/tests/mos6502.c
Peter Evans 2f777ce881 Several core changes to status, soft switches 
Regarding soft switches, we had several we should have been listening
for on both reads and writes, but were only doing so on writes; this is
now fixed.

Regarding statuses, we were incorrectly calculating both carry and
overflow. This should now be fixed, although some quick examinations of
disassembly output suggest there is something else amiss. Debugging will
continue shortly.
2018-01-20 21:01:26 -06:00

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#include <criterion/criterion.h>
#include "mos6502.h"
#include "mos6502.enums.h"
#include "mos6502.tests.h"
TestSuite(mos6502, .init = setup, .fini = teardown);
/* Test(mos6502, free) */
Test(mos6502, create)
{
cr_assert_neq(cpu, NULL);
cr_assert_eq(cpu->rmem->size, MOS6502_MEMSIZE);
cr_assert_eq(cpu->wmem->size, MOS6502_MEMSIZE);
cr_assert_eq(cpu->PC, 0);
cr_assert_eq(cpu->A, 0);
cr_assert_eq(cpu->X, 0);
cr_assert_eq(cpu->Y, 0);
cr_assert_eq(cpu->P, 0);
cr_assert_eq(cpu->S, 0);
}
Test(mos6502, push_stack)
{
mos6502_push_stack(cpu, 0x1234);
cr_assert_eq(mos6502_get(cpu, 0x0100), 0x34);
cr_assert_eq(mos6502_get(cpu, 0x0101), 0x12);
}
Test(mos6502, pop_stack)
{
mos6502_push_stack(cpu, 0x1234);
cr_assert_eq(mos6502_pop_stack(cpu), 0x1234);
}
Test(mos6502, modify_status)
{
mos6502_modify_status(cpu, MOS_NEGATIVE, 130, 130);
cr_assert_eq(cpu->P & MOS_NEGATIVE, MOS_NEGATIVE);
mos6502_modify_status(cpu, MOS_NEGATIVE, 123, 123);
cr_assert_neq(cpu->P & MOS_NEGATIVE, MOS_NEGATIVE);
mos6502_modify_status(cpu, MOS_OVERFLOW, 123, 133);
cr_assert_eq(cpu->P & MOS_OVERFLOW, MOS_OVERFLOW);
mos6502_modify_status(cpu, MOS_OVERFLOW, 44, 44);
cr_assert_neq(cpu->P & MOS_OVERFLOW, MOS_OVERFLOW);
mos6502_modify_status(cpu, MOS_CARRY, 230, 230);
cr_assert_eq(cpu->P & MOS_CARRY, MOS_CARRY);
mos6502_modify_status(cpu, MOS_CARRY, 30, 190);
cr_assert_neq(cpu->P & MOS_CARRY, MOS_CARRY);
mos6502_modify_status(cpu, MOS_ZERO, 0, 0);
cr_assert_eq(cpu->P & MOS_ZERO, MOS_ZERO);
mos6502_modify_status(cpu, MOS_ZERO, 1, 1);
cr_assert_neq(cpu->P & MOS_ZERO, MOS_ZERO);
}
Test(mos6502, set_status)
{
mos6502_set_status(cpu, MOS_BREAK | MOS_INTERRUPT | MOS_DECIMAL);
cr_assert_eq(cpu->P & (MOS_BREAK | MOS_INTERRUPT | MOS_DECIMAL), MOS_BREAK | MOS_INTERRUPT | MOS_DECIMAL);
}
Test(mos6502, instruction)
{
cr_assert_eq(mos6502_instruction(0x1D), ORA);
cr_assert_eq(mos6502_instruction(0xD8), CLD);
cr_assert_eq(mos6502_instruction(0x98), TYA);
}
Test(mos6502, cycles)
{
cr_assert_eq(mos6502_cycles(cpu, 0x76), 6);
cr_assert_eq(mos6502_cycles(cpu, 0xBA), 2);
// In this case, we aren't cross a page boundary, and the number of
// cycles should stay at 4
cpu->eff_addr = 0x5070;
cpu->X = 23;
cr_assert_eq(mos6502_cycles(cpu, 0x1D), 4);
// Testing that crossing a page boundary adds one to the number of
// cycles
cpu->X = 200;
cr_assert_eq(mos6502_cycles(cpu, 0x1D), 5);
}
Test(mos6502, get_instruction_handler)
{
cr_assert_eq(mos6502_get_instruction_handler(0x00), mos6502_handle_brk);
cr_assert_eq(mos6502_get_instruction_handler(0x1D), mos6502_handle_ora);
cr_assert_eq(mos6502_get_instruction_handler(0x20), mos6502_handle_jsr);
}
Test(mos6502, execute)
{
mos6502_set(cpu, 11, 34);
mos6502_set(cpu, 10, 0x69);
cpu->PC = 10;
mos6502_execute(cpu);
cr_assert_eq(cpu->A, 34);
}
Test(mos6502, would_jump)
{
bool expect;
for (int inst = 0; inst <= TYA; inst++) {
switch (inst) {
case BCC:
case BCS:
case BEQ:
case BMI:
case BNE:
case BPL:
case BRK:
case BVC:
case BVS:
case JMP:
case JSR:
case RTS:
case RTI:
expect = true;
break;
default:
expect = false;
break;
}
cr_assert_eq(mos6502_would_jump(inst), expect);
}
}
Test(mos6502, get_address_resolver)
{
cr_assert_eq(mos6502_get_address_resolver(0x0A), mos6502_resolve_acc);
cr_assert_eq(mos6502_get_address_resolver(0x20), mos6502_resolve_abs);
cr_assert_eq(mos6502_get_address_resolver(0xBC), mos6502_resolve_abx);
cr_assert_eq(mos6502_get_address_resolver(0x19), mos6502_resolve_aby);
cr_assert_eq(mos6502_get_address_resolver(0xA0), mos6502_resolve_imm);
cr_assert_eq(mos6502_get_address_resolver(0x6C), mos6502_resolve_ind);
cr_assert_eq(mos6502_get_address_resolver(0x01), mos6502_resolve_idx);
cr_assert_eq(mos6502_get_address_resolver(0x11), mos6502_resolve_idy);
cr_assert_eq(mos6502_get_address_resolver(0x10), mos6502_resolve_rel);
cr_assert_eq(mos6502_get_address_resolver(0x05), mos6502_resolve_zpg);
cr_assert_eq(mos6502_get_address_resolver(0x15), mos6502_resolve_zpx);
cr_assert_eq(mos6502_get_address_resolver(0x96), mos6502_resolve_zpy);
}
Test(mos6502, get)
{
vm_segment_set(cpu->wmem, 0, 123);
cr_assert_eq(mos6502_get(cpu, 0), 123);
}
Test(mos6502, get16)
{
vm_segment_set16(cpu->wmem, 0, 0x3344);
cr_assert_eq(mos6502_get16(cpu, 0), 0x3344);
}
Test(mos6502, set)
{
mos6502_set(cpu, 0, 111);
cr_assert_eq(vm_segment_get(cpu->rmem, 0), 111);
}
Test(mos6502, set16)
{
mos6502_set16(cpu, 0, 0x2255);
cr_assert_eq(vm_segment_get16(cpu->rmem, 0), 0x2255);
}
Test(mos6502, set_memory)
{
vm_segment *rmem, *wmem;
rmem = (vm_segment *)111;
wmem = (vm_segment *)222;
mos6502_set_memory(cpu, rmem, wmem);
cr_assert_eq(cpu->rmem, rmem);
cr_assert_eq(cpu->wmem, wmem);
}
Test(mos6502, last_executed)
{
vm_8bit opcode, operand;
vm_16bit addr;
mos6502_set(cpu, 0, 0xA9); // LDA #$EE
mos6502_set(cpu, 1, 0xEE);
mos6502_set(cpu, 2, 0x8D); // STA $1234
mos6502_set16(cpu, 3, 0x1234);
mos6502_execute(cpu);
mos6502_last_executed(cpu, &opcode, &operand, NULL);
cr_assert_eq(opcode, 0xA9);
cr_assert_eq(operand, 0xEE);
mos6502_execute(cpu);
mos6502_last_executed(cpu, &opcode, NULL, &addr);
cr_assert_eq(opcode, 0x8D);
cr_assert_eq(addr, 0x1234);
}
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