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CLK/OSBindings/Mac/Clock SignalTests/Z80MemptrTests.swift

652 lines
16 KiB
Swift

//
// Z80MemptrTests.swift
// Clock Signal
//
// Created by Thomas Harte on 21/07/2017.
// Copyright 2017 Thomas Harte. All rights reserved.
//
import XCTest
class Z80MemptrTester: XCTestCase {
let machine = CSTestMachineZ80()
private func test(program : [UInt8], initialValue : UInt16) -> UInt16 {
// Create a machine and install the supplied program at address 0, setting the PC to run from there
machine.setValue(0x0000, for: .programCounter)
machine.setData(Data(_: program), atAddress: 0x0000)
// Set the initial value of memptr, run for the requested number of cycles,
// return the new value
machine.setValue(initialValue, for: .memPtr)
machine.runForInstruction()
return machine.value(for: .memPtr)
}
private func testPage(_ prefix: UInt8, exclusions: [Int]) {
for opcode in 0 ..< 256 {
if exclusions.contains(opcode) {
continue
}
var program: [UInt8] = [
(prefix != 0) ? prefix : UInt8(opcode), UInt8(opcode), 0, 0
]
let argumentPosition = (prefix != 0) ? 2 : 1
for _ in 0 ..< 10 {
let random = arc4random_uniform(65536)
program[argumentPosition + 0] = UInt8(random & 0x00ff)
program[argumentPosition + 1] = UInt8(random >> 8)
let expectedResult = UInt16(arc4random_uniform(65536))
let result = test(program: program, initialValue: expectedResult)
XCTAssertEqual(result, expectedResult, "Failed for opcode \(String(opcode, radix:16))")
// One failure per opcode will do.
if result != expectedResult {
break
}
}
}
}
private func insert16(program: inout [UInt8], address: Int, offset: size_t) {
program[offset] = UInt8(address & 0x00ff)
program[offset + 1] = UInt8(address >> 8)
}
/// Tests that everything not listed in the documentation has no effect upon MEMPTR.
func testStandardPageOthers() {
testPage(0, exclusions: [
0x02, // LD (BC), A
0x09, // ADD HL, BC
0x0a, // LD A, (BC)
0x10, // DJNZ
0x12, // LD (DE), A
0x18, // JR
0x19, // ADD HL, DE
0x1a, // LD A, (DE)
0x20, // JR NZ
0x22, // LD (nn), HL
0x28, // JR Z
0x29, // ADD HL, HL
0x2a, // LD HL, (nn)
0x30, // JR NC
0x32, // LD (nn), A
0x38, // JR C
0x39, // ADD HL, SP
0x3a, // LD A, (nn)
0xcb, // CB page
0xdd, // DD page
0xed, // ED page
0xfd, // FD page
])
}
func testEDPageOthers() {
testPage(0xed, exclusions: [
0x40, // IN B, (C)
0x41, // OUT (C), B
0x42, // SBC HL, BC
0x43, // LD (nn), HL
0x45, // RETN (??)
0x48, // IN C, (C)
0x49, // OUT (C), C
0x4a, // ADC HL, BC
0x4b, // LD BC, (nn)
0x4d, // RETI
0x50, // IN D, (C)
0x51, // OUT (C), D
0x52, // SBC HL, DE
0x53, // LD (nn), DE
0x55, // RETN (??)
0x58, // IN E, (C)
0x59, // OUT (C), E
0x5a, // ADC HL, DE
0x5b, // LD DE, (nn)
0x5d, // RETN (??)
0x60, // IN H, (C)
0x61, // OUT (C), H
0x62, // SBC HL, HL
0x63, // LD (nn), HL
0x65, // RETN (??)
0x67, // RRD
0x68, // IN L, (C)
0x69, // OUT (C), L
0x6a, // ADC HL, HL
0x6b, // LD HL, (nn)
0x6d, // RETN (??)
0x6f, // RLD
0x70, // IN (C)
0x71, // OUT (C), 0
0x72, // SBC HL, SP
0x73, // LD (nn), SP
0x75, // RETN (??)
0x78, // IN A, (C)
0x79, // OUT (C), A
0x7a, // ADC HL, SP
0x7b, // LD SP, (nn)
0x7d, // RETN (??)
0xa1, // CPI
0xa2, // INI
0xa3, // OUTI
0xa9, // CPD
0xaa, // IND
0xab, // OUTD
0xb0, // LDIR
0xb1, // CPIR
0xb2, // INIR
0xb3, // OUIR
0xb8, // LDDR
0xb9, // CPDR
0xba, // INDR
0xbb, // OTDR
])
// testPage(0xcb, exclusions: [])
// testPage(0xdd, exclusions: [])
// testPage(0xfd, exclusions: [])
}
/*
Re: comments below:
All the CPU chips tested give the same results except KP1858BM1 and T34BM1 slices noted as "BM1".
*/
// LD A, (addr)
func testLDAnn() {
// MEMPTR = addr+1
var program: [UInt8] = [
0x3a, 0x00, 0x00
]
for addr in 0 ..< 65536 {
program[1] = UInt8(addr & 0x00ff)
program[2] = UInt8(addr >> 8)
let expectedResult = UInt16((addr + 1) & 0xffff)
let result = test(program: program, initialValue: 0xffff)
XCTAssertEqual(result, expectedResult)
}
}
// LD (bc/de),A, and LD (nn),A
func testLDrpA() {
// MEMPTR_low = (addr + 1) & #FF, MEMPTR_hi = A
// Note for *BM1: MEMPTR_low = (addr + 1) & #FF, MEMPTR_hi = 0
let bcProgram: [UInt8] = [
0x02
]
let deProgram: [UInt8] = [
0x12
]
var nnProgram: [UInt8] = [
0x32, 0x00, 0x00
]
for addr in 0 ..< 256 {
machine.setValue(UInt16(addr), for: .BC)
machine.setValue(UInt16(addr), for: .DE)
insert16(program: &nnProgram, address: addr, offset: 1)
for a in 0 ..< 256 {
machine.setValue(UInt16(a), for: .A)
let expectedResult = UInt16(((addr + 1) & 0xff) + (a << 8))
let bcResult = test(program: bcProgram, initialValue: 0xffff)
let deResult = test(program: deProgram, initialValue: 0xffff)
let nnResult = test(program: nnProgram, initialValue: 0xffff)
XCTAssertEqual(bcResult, expectedResult)
XCTAssertEqual(deResult, expectedResult)
XCTAssertEqual(nnResult, expectedResult)
}
}
}
// LD A, (rp)
func testLDArp() {
// MEMPTR = rp+1
let bcProgram: [UInt8] = [
0x0a
]
let deProgram: [UInt8] = [
0x1a
]
for addr in 0 ..< 65536 {
machine.setValue(UInt16(addr), for: .BC)
machine.setValue(UInt16(addr), for: .DE)
let expectedResult = UInt16((addr + 1) & 0xffff)
let bcResult = test(program: bcProgram, initialValue: 0xffff)
let deResult = test(program: deProgram, initialValue: 0xffff)
XCTAssertEqual(bcResult, expectedResult)
XCTAssertEqual(deResult, expectedResult)
}
}
// LD (addr), rp
func testLDnnrp() {
// MEMPTR = addr + 1
var ldnnhlBaseProgram: [UInt8] = [
0x22, 0x00, 0x00
]
var ldnnbcEDProgram: [UInt8] = [
0xed, 0x43, 0x00, 0x00
]
var ldnndeEDProgram: [UInt8] = [
0xed, 0x53, 0x00, 0x00
]
var ldnnhlEDProgram: [UInt8] = [
0xed, 0x63, 0x00, 0x00
]
var ldnnspEDProgram: [UInt8] = [
0xed, 0x73, 0x00, 0x00
]
for addr in 0 ..< 65536 {
insert16(program: &ldnnhlBaseProgram, address: addr, offset: 1)
insert16(program: &ldnnbcEDProgram, address: addr, offset: 2)
insert16(program: &ldnndeEDProgram, address: addr, offset: 2)
insert16(program: &ldnnhlEDProgram, address: addr, offset: 2)
insert16(program: &ldnnspEDProgram, address: addr, offset: 2)
let expectedResult = UInt16((addr + 1) & 0xffff)
XCTAssertEqual(test(program: ldnnhlBaseProgram, initialValue: expectedResult ^ 1), expectedResult)
XCTAssertEqual(test(program: ldnnbcEDProgram, initialValue: expectedResult ^ 1), expectedResult)
XCTAssertEqual(test(program: ldnndeEDProgram, initialValue: expectedResult ^ 1), expectedResult)
XCTAssertEqual(test(program: ldnnhlEDProgram, initialValue: expectedResult ^ 1), expectedResult)
XCTAssertEqual(test(program: ldnnspEDProgram, initialValue: expectedResult ^ 1), expectedResult)
}
}
// LD rp, (addr)
func testLDrpnn() {
// MEMPTR = addr+1
var hlBaseProgram: [UInt8] = [
0x22, 0x00, 0x00
]
var bcEDProgram: [UInt8] = [
0xed, 0x43, 0x00, 0x00
]
var deEDProgram: [UInt8] = [
0xed, 0x53, 0x00, 0x00
]
var hlEDProgram: [UInt8] = [
0xed, 0x63, 0x00, 0x00
]
var spEDProgram: [UInt8] = [
0xed, 0x73, 0x00, 0x00
]
var ixProgram: [UInt8] = [
0xdd, 0x22, 0x00, 0x00
]
var iyProgram: [UInt8] = [
0xfd, 0x22, 0x00, 0x00
]
for addr in 0 ..< 65536 {
hlBaseProgram[1] = UInt8(addr & 0x00ff)
hlBaseProgram[2] = UInt8(addr >> 8)
bcEDProgram[2] = UInt8(addr & 0x00ff)
bcEDProgram[3] = UInt8(addr >> 8)
deEDProgram[2] = UInt8(addr & 0x00ff)
deEDProgram[3] = UInt8(addr >> 8)
hlEDProgram[2] = UInt8(addr & 0x00ff)
hlEDProgram[3] = UInt8(addr >> 8)
spEDProgram[2] = UInt8(addr & 0x00ff)
spEDProgram[3] = UInt8(addr >> 8)
ixProgram[2] = UInt8(addr & 0x00ff)
ixProgram[3] = UInt8(addr >> 8)
iyProgram[2] = UInt8(addr & 0x00ff)
iyProgram[3] = UInt8(addr >> 8)
let expectedResult = UInt16((addr + 1) & 0xffff)
XCTAssertEqual(test(program: hlBaseProgram, initialValue: 0xffff), expectedResult)
XCTAssertEqual(test(program: bcEDProgram, initialValue: 0xffff), expectedResult)
XCTAssertEqual(test(program: deEDProgram, initialValue: 0xffff), expectedResult)
XCTAssertEqual(test(program: hlEDProgram, initialValue: 0xffff), expectedResult)
XCTAssertEqual(test(program: spEDProgram, initialValue: 0xffff), expectedResult)
XCTAssertEqual(test(program: ixProgram, initialValue: 0xffff), expectedResult)
XCTAssertEqual(test(program: iyProgram, initialValue: 0xffff), expectedResult)
}
}
// EX (SP), rp
func testEXSPrp() {
// MEMPTR = rp at end
var hlProgram: [UInt8] = [
0xe3, 0x00, 0x00, 0x00
]
var ixProgram: [UInt8] = [
0xdd, 0xe3, 0x00, 0x00
]
var iyProgram: [UInt8] = [
0xfd, 0xe3, 0x00, 0x00
]
machine.setValue(2, for: .stackPointer)
for addr in 0 ..< 65536 {
hlProgram[2] = UInt8(addr & 0x00ff)
hlProgram[3] = UInt8(addr >> 8)
ixProgram[2] = UInt8(addr & 0x00ff)
ixProgram[3] = UInt8(addr >> 8)
iyProgram[2] = UInt8(addr & 0x00ff)
iyProgram[3] = UInt8(addr >> 8)
XCTAssertEqual(test(program: hlProgram, initialValue: 0xffff), UInt16(addr))
XCTAssertEqual(test(program: ixProgram, initialValue: 0xffff), UInt16(addr))
XCTAssertEqual(test(program: iyProgram, initialValue: 0xffff), UInt16(addr))
}
}
// ADD/ADC/SBC dest, src
func testADDADCSBCrr() {
// MEMPTR = dest prior to modification + 1
let addProgram: [UInt8] = [
0x09
]
let adcProgram: [UInt8] = [
0xed, 0x4a
]
let sbcProgram: [UInt8] = [
0xed, 0x42
]
for addr in 0 ..< 65536 {
let expectedResult = UInt16((addr + 1) & 0xffff)
machine.setValue(UInt16(addr), for: .HL)
XCTAssertEqual(test(program: addProgram, initialValue: 0xffff), expectedResult)
XCTAssertEqual(test(program: adcProgram, initialValue: 0xffff), expectedResult)
XCTAssertEqual(test(program: sbcProgram, initialValue: 0xffff), expectedResult)
}
}
// RLD/RRD
func testRLDRRD() {
// MEMPTR = HL + 1
let rldProgram: [UInt8] = [
0xed, 0x6f
]
let rrdProgram: [UInt8] = [
0xed, 0x67
]
for addr in 0 ..< 65536 {
let expectedResult = UInt16((addr + 1) & 0xffff)
machine.setValue(UInt16(addr), for: .HL)
XCTAssertEqual(test(program: rldProgram, initialValue: 0xffff), expectedResult)
XCTAssertEqual(test(program: rrdProgram, initialValue: 0xffff), expectedResult)
}
}
/* TODO:
JR/DJNZ/RET/RETI/RST (jumping to addr)
MEMPTR = addr
(implemented in principle)
*/
func testJR() {
var jrProgram: [UInt8] = [
0x18, 0x00
]
for offset in 0 ..< 256 {
jrProgram[1] = UInt8(offset)
let result = test(program: jrProgram, initialValue: 0xffff)
XCTAssertEqual(result, machine.value(for: .programCounter))
}
}
func testJRcc() {
func testJR(instruction: UInt8, shouldPass: Bool) {
var program: [UInt8] = [
instruction, 0x00
]
for offset in 0 ..< 256 {
program[1] = UInt8(offset)
let result = test(program: program, initialValue: 0xffff)
XCTAssertEqual(result, shouldPass ? machine.value(for: .programCounter) : 0xffff)
}
}
// JR NZ.
machine.setValue(0x00, for: .AF)
testJR(instruction: 0x20, shouldPass: true)
machine.setValue(0xff, for: .AF)
testJR(instruction: 0x20, shouldPass: false)
// JR NC
machine.setValue(0x00, for: .AF)
testJR(instruction: 0x30, shouldPass: true)
machine.setValue(0xff, for: .AF)
testJR(instruction: 0x30, shouldPass: false)
// JR Z
machine.setValue(0x00, for: .AF)
testJR(instruction: 0x28, shouldPass: false)
machine.setValue(0xff, for: .AF)
testJR(instruction: 0x28, shouldPass: true)
// JR C
machine.setValue(0x00, for: .AF)
testJR(instruction: 0x38, shouldPass: false)
machine.setValue(0xff, for: .AF)
testJR(instruction: 0x38, shouldPass: true)
}
func testRST() {
var rstProgram: [UInt8] = [
0x00
]
for offset in 0 ..< 8 {
rstProgram[0] = UInt8(offset << 3) + 0xc7
let result = test(program: rstProgram, initialValue: 0xffff)
XCTAssertEqual(result, machine.value(for: .programCounter))
}
}
func testRET() {
let retProgram: [UInt8] = [
0xc9
]
for addr in 0 ..< 65536 {
let stackContents: [UInt8] = [
UInt8(addr & 0xff), UInt8(addr >> 8)
]
machine.setData(Data(stackContents), atAddress: 0xf001)
machine.setValue(0xf000, for: .stackPointer)
let result = test(program: retProgram, initialValue: 0xffff)
XCTAssertEqual(result, machine.value(for: .programCounter))
}
}
func testRETI() {
let retiProgram: [UInt8] = [
0xed, 0x4d
]
for addr in 0 ..< 65536 {
let stackContents: [UInt8] = [
UInt8(addr & 0xff), UInt8(addr >> 8)
]
machine.setData(Data(stackContents), atAddress: 0xf001)
machine.setValue(0xf000, for: .stackPointer)
let result = test(program: retiProgram, initialValue: 0xffff)
XCTAssertEqual(result, machine.value(for: .programCounter))
}
}
/* TODO:
JP(except JP rp)/CALL addr (even in case of conditional call/jp, independently on condition satisfied or not)
MEMPTR = addr
*/
func testCALL() {
var callProgram: [UInt8] = [
0xcd, 0x00, 0x00
]
for offset in 0 ..< 65536 {
callProgram[1] = UInt8(offset & 0xff)
callProgram[2] = UInt8(offset >> 8)
let result = test(program: callProgram, initialValue: 0xffff)
XCTAssertEqual(result, machine.value(for: .programCounter))
}
}
/* TODO:
IN A,(port)
MEMPTR = (A_before_operation << 8) + port + 1
(implemented, not tested)
*/
/* TODO:
IN A,(C)
MEMPTR = BC + 1
(implemented, not tested)
*/
/* TODO:
OUT (port),A
MEMPTR_low = (port + 1) & #FF, MEMPTR_hi = A
Note for *BM1: MEMPTR_low = (port + 1) & #FF, MEMPTR_hi = 0
*/
/* TODO:
OUT (C),A
MEMPTR = BC + 1
*/
/* TODO:
LDIR/LDDR
when BC == 1: MEMPTR is not changed
when BC <> 1: MEMPTR = PC + 1, where PC = instruction address
*/
// CPI
func testCPI() {
// MEMPTR = MEMPTR + 1
let program: [UInt8] = [
0xed, 0xa1
]
machine.setData(Data(_: program), atAddress: 0x0000)
machine.setValue(0, for: .memPtr)
for c in 1 ..< 65536 {
machine.setValue(0x0000, for: .programCounter)
machine.runForNumber(ofCycles: 16)
XCTAssertEqual(UInt16(c), machine.value(for: .memPtr))
}
}
// CPD
func testCPD() {
// MEMPTR = MEMPTR - 1
let program: [UInt8] = [
0xed, 0xa9
]
machine.setData(Data(_: program), atAddress: 0x0000)
machine.setValue(0, for: .memPtr)
for c in 1 ..< 65536 {
machine.setValue(0x0000, for: .programCounter)
machine.runForNumber(ofCycles: 16)
XCTAssertEqual(UInt16(65536 - c), machine.value(for: .memPtr))
}
}
/* TODO:
CPIR
when BC=1 or A=(HL): exactly as CPI
In other cases MEMPTR = PC + 1 on each step, where PC = instruction address.
Note* since at the last execution BC=1 or A=(HL), resulting MEMPTR = PC + 1 + 1
(if there were not interrupts during the execution)
*/
/* TODO:
CPDR
when BC=1 or A=(HL): exactly as CPD
In other cases MEMPTR = PC + 1 on each step, where PC = instruction address.
Note* since at the last execution BC=1 or A=(HL), resulting MEMPTR = PC + 1 - 1
(if there were not interrupts during the execution)
*/
/* TODO:
INI
MEMPTR = BC_before_decrementing_B + 1
*/
/* TODO:
IND
MEMPTR = BC_before_decrementing_B - 1
*/
/* TODO:
INIR
exactly as INI on each execution.
I.e. resulting MEMPTR = ((1 << 8) + C) + 1
*/
/* TODO:
INDR
exactly as IND on each execution.
I.e. resulting MEMPTR = ((1 << 8) + C) - 1
*/
/* TODO:
OUTI
MEMPTR = BC_after_decrementing_B + 1
*/
/* TODO:
OUTD
MEMPTR = BC_after_decrementing_B - 1
*/
/* TODO:
OTIR
exactly as OUTI on each execution. I.e. resulting MEMPTR = C + 1
*/
/* TODO:
OTDR
exactly as OUTD on each execution. I.e. resulting MEMPTR = C - 1
*/
/* TODO:
Any instruction with (INDEX+d):
MEMPTR = INDEX+d
*/
/* TODO:
Interrupt call to addr:
As usual CALL. I.e. MEMPTR = addr
*/
}