CLK/OSBindings/Mac/Clock SignalTests/EmuTOSTests.mm

//
//  EmuTOSTests.m
//  Clock SignalTests
//
//  Created by Thomas Harte on 10/03/2019.
//  Copyright © 2019 Thomas Harte. All rights reserved.
//

#import <XCTest/XCTest.h>

#include <array>
#include <cassert>

#include "68000.hpp"
#include "CSROMFetcher.hpp"

class EmuTOS: public CPU::MC68000::BusHandler {
	public:
		EmuTOS(const std::vector<uint8_t> &emuTOS) : m68000_(*this) {
			assert(!(emuTOS.size() & 1));
			emuTOS_.resize(emuTOS.size() / 2);

			for(size_t c = 0; c < emuTOS_.size(); ++c) {
				emuTOS_[c] = (emuTOS[c << 1] << 8) | emuTOS[(c << 1) + 1];
			}
		}

		void run_for(HalfCycles cycles) {
			m68000_.run_for(cycles);
		}

		HalfCycles perform_bus_operation(const CPU::MC68000::Microcycle &cycle, int is_supervisor) {
			const uint32_t address = cycle.word_address();
			uint32_t word_address = address;

			// As much about the Atari ST's memory map as is relevant here: the ROM begins
			// at 0xfc0000, and the first eight bytes are mirrored to the first four memory
			// addresses in order for /RESET to work properly. RAM otherwise fills the first
			// 512kb of the address space. Trying to write to ROM raises a bus error.

			const bool is_peripheral = word_address > (0xff0000 >> 1);
			const bool is_rom = word_address > (0xfc0000 >> 1) || word_address < 4;
			uint16_t *const base = is_rom ? emuTOS_.data() : ram_.data();
			if(is_rom) {
				word_address &= 0xffff;
			} else {
				word_address &= 0x3ffff;
			}

			using Microcycle = CPU::MC68000::Microcycle;
			if(cycle.data_select_active()) {
				uint16_t peripheral_result = 0xffff;
				if(is_peripheral) {
					switch(address & 0x7ff) {
						// A hard-coded value for TIMER B.
						case (0xa21 >> 1):
							peripheral_result = 0x00000001;
						break;
					}
//					printf("Peripheral: %c %08x", (cycle.operation & Microcycle::Read) ? 'r' : 'w', *cycle.address);
//					if(!(cycle.operation & Microcycle::Read)) {
//						if(cycle.operation & Microcycle::SelectByte)
//							printf(" %02x", cycle.value->halves.low);
//						else
//							printf(" %04x", cycle.value->full);
//					}
//					printf("\n");
				}

				switch(cycle.operation & (Microcycle::SelectWord | Microcycle::SelectByte | Microcycle::Read)) {
					default: break;

					case Microcycle::SelectWord | Microcycle::Read:
						cycle.value->full = is_peripheral ? peripheral_result : base[word_address];
//						if(!(cycle.operation & Microcycle::IsProgram)) printf("[word r %08x -> %04x] ", *cycle.address, cycle.value->full);
					break;
					case Microcycle::SelectByte | Microcycle::Read:
						cycle.value->halves.low = (is_peripheral ? peripheral_result : base[word_address]) >> cycle.byte_shift();
//						if(!(cycle.operation & Microcycle::IsProgram)) printf("[byte r %08x -> %02x] ", *cycle.address, cycle.value->halves.low);
					break;
					case Microcycle::SelectWord:
						assert(!(is_rom && !is_peripheral));
//						if(!(cycle.operation & Microcycle::IsProgram)) printf("[word w %04x -> %08x] ", cycle.value->full, *cycle.address);
						base[word_address] = cycle.value->full;
					break;
					case Microcycle::SelectByte:
						assert(!(is_rom && !is_peripheral));
//						if(!(cycle.operation & Microcycle::IsProgram)) printf("[byte w %02x -> %08x] ", cycle.value->halves.low, *cycle.address);
						base[word_address] = (cycle.value->halves.low << cycle.byte_shift()) | (base[word_address] & (0xffff ^ cycle.byte_mask()));
					break;
				}
			}

			return HalfCycles(0);
		}

	private:
		CPU::MC68000::Processor<EmuTOS, true> m68000_;

		std::vector<uint16_t> emuTOS_;
		std::array<uint16_t, 256*1024> ram_;
};

@interface EmuTOSTests : XCTestCase
@end

@implementation EmuTOSTests {
	std::unique_ptr<EmuTOS> _machine;
}

- (void)setUp {
    // Put setup code here. This method is called before the invocation of each test method in the class.
    const auto roms = CSROMFetcher()("AtariST", {"tos100.img"});
    _machine.reset(new EmuTOS(*roms[0]));
}

- (void)tearDown {
    // Put teardown code here. This method is called after the invocation of each test method in the class.
}

- (void)testStartup {
    // This is an example of a functional test case.
    // Use XCTAssert and related functions to verify your tests produce the correct results.
    _machine->run_for(HalfCycles(8000000));
}

@end
Introduces EmuTOS, and starts constructing test cases around it. 2019-03-10 22:40:12 +00:00			`//`
			`// EmuTOSTests.m`
			`// Clock SignalTests`
			`//`
			`// Created by Thomas Harte on 10/03/2019.`
			`// Copyright © 2019 Thomas Harte. All rights reserved.`
			`//`

			`#import <XCTest/XCTest.h>`

Implements as much as I currently care about of the Atari ST memory map. 2019-03-12 02:47:37 +00:00			`#include <array>`
Introduces EmuTOS, and starts constructing test cases around it. 2019-03-10 22:40:12 +00:00			`#include <cassert>`
Implements as much as I currently care about of the Atari ST memory map. 2019-03-12 02:47:37 +00:00
Introduces EmuTOS, and starts constructing test cases around it. 2019-03-10 22:40:12 +00:00			`#include "68000.hpp"`
			`#include "CSROMFetcher.hpp"`

			`class EmuTOS: public CPU::MC68000::BusHandler {`
			`public:`
			`EmuTOS(const std::vector<uint8_t> &emuTOS) : m68000_(*this) {`
			`assert(!(emuTOS.size() & 1));`
			`emuTOS_.resize(emuTOS.size() / 2);`

			`for(size_t c = 0; c < emuTOS_.size(); ++c) {`
			`emuTOS_[c] = (emuTOS[c << 1] << 8) \| emuTOS[(c << 1) + 1];`
			`}`
			`}`

			`void run_for(HalfCycles cycles) {`
			`m68000_.run_for(cycles);`
			`}`

			`HalfCycles perform_bus_operation(const CPU::MC68000::Microcycle &cycle, int is_supervisor) {`
Adds a hard-coded value sufficient to advance in TOS startup. 2019-04-07 00:00:34 +00:00			`const uint32_t address = cycle.word_address();`
			`uint32_t word_address = address;`
Implements as much as I currently care about of the Atari ST memory map. 2019-03-12 02:47:37 +00:00
			`// As much about the Atari ST's memory map as is relevant here: the ROM begins`
			`// at 0xfc0000, and the first eight bytes are mirrored to the first four memory`
			`// addresses in order for /RESET to work properly. RAM otherwise fills the first`
			`// 512kb of the address space. Trying to write to ROM raises a bus error.`

Adds a hard-coded value sufficient to advance in TOS startup. 2019-04-07 00:00:34 +00:00			`const bool is_peripheral = word_address > (0xff0000 >> 1);`
Switches to providing UDS and LDS implicitly via address. Also makes sure that the difference between a non-data cycle that starts without the address strobe active and one that starts with it active can be discerned. 2019-03-16 21:54:58 +00:00			`const bool is_rom = word_address > (0xfc0000 >> 1) \|\| word_address < 4;`
Implements as much as I currently care about of the Atari ST memory map. 2019-03-12 02:47:37 +00:00			`uint16_t *const base = is_rom ? emuTOS_.data() : ram_.data();`
			`if(is_rom) {`
Switches to providing UDS and LDS implicitly via address. Also makes sure that the difference between a non-data cycle that starts without the address strobe active and one that starts with it active can be discerned. 2019-03-16 21:54:58 +00:00			`word_address &= 0xffff;`
Implements as much as I currently care about of the Atari ST memory map. 2019-03-12 02:47:37 +00:00			`} else {`
Switches to providing UDS and LDS implicitly via address. Also makes sure that the difference between a non-data cycle that starts without the address strobe active and one that starts with it active can be discerned. 2019-03-16 21:54:58 +00:00			`word_address &= 0x3ffff;`
Implements as much as I currently care about of the Atari ST memory map. 2019-03-12 02:47:37 +00:00			`}`

Switches to providing UDS and LDS implicitly via address. Also makes sure that the difference between a non-data cycle that starts without the address strobe active and one that starts with it active can be discerned. 2019-03-16 21:54:58 +00:00			`using Microcycle = CPU::MC68000::Microcycle;`
			`if(cycle.data_select_active()) {`
Adds a hard-coded value sufficient to advance in TOS startup. 2019-04-07 00:00:34 +00:00			`uint16_t peripheral_result = 0xffff;`
			`if(is_peripheral) {`
			`switch(address & 0x7ff) {`
			`// A hard-coded value for TIMER B.`
			`case (0xa21 >> 1):`
			`peripheral_result = 0x00000001;`
			`break;`
			`}`
Ensures that MOVE.b #, (xxx).l writes only a byte. Also rearranges some of the temporary logging functionality. 2019-04-23 23:01:58 +00:00			`// printf("Peripheral: %c %08x", (cycle.operation & Microcycle::Read) ? 'r' : 'w', *cycle.address);`
			`// if(!(cycle.operation & Microcycle::Read)) {`
			`// if(cycle.operation & Microcycle::SelectByte)`
			`// printf(" %02x", cycle.value->halves.low);`
			`// else`
			`// printf(" %04x", cycle.value->full);`
			`// }`
			`// printf("\n");`
Adds a hard-coded value sufficient to advance in TOS startup. 2019-04-07 00:00:34 +00:00			`}`

Switches to providing UDS and LDS implicitly via address. Also makes sure that the difference between a non-data cycle that starts without the address strobe active and one that starts with it active can be discerned. 2019-03-16 21:54:58 +00:00			`switch(cycle.operation & (Microcycle::SelectWord \| Microcycle::SelectByte \| Microcycle::Read)) {`
			`default: break;`

			`case Microcycle::SelectWord \| Microcycle::Read:`
Adds a hard-coded value sufficient to advance in TOS startup. 2019-04-07 00:00:34 +00:00			`cycle.value->full = is_peripheral ? peripheral_result : base[word_address];`
Corrects the carry and extend flags for various long-word operations. 2019-04-22 02:08:18 +00:00			`// if(!(cycle.operation & Microcycle::IsProgram)) printf("[word r %08x -> %04x] ", *cycle.address, cycle.value->full);`
Switches to providing UDS and LDS implicitly via address. Also makes sure that the difference between a non-data cycle that starts without the address strobe active and one that starts with it active can be discerned. 2019-03-16 21:54:58 +00:00			`break;`
			`case Microcycle::SelectByte \| Microcycle::Read:`
Adds a hard-coded value sufficient to advance in TOS startup. 2019-04-07 00:00:34 +00:00			`cycle.value->halves.low = (is_peripheral ? peripheral_result : base[word_address]) >> cycle.byte_shift();`
Corrects the carry and extend flags for various long-word operations. 2019-04-22 02:08:18 +00:00			`// if(!(cycle.operation & Microcycle::IsProgram)) printf("[byte r %08x -> %02x] ", *cycle.address, cycle.value->halves.low);`
Switches to providing UDS and LDS implicitly via address. Also makes sure that the difference between a non-data cycle that starts without the address strobe active and one that starts with it active can be discerned. 2019-03-16 21:54:58 +00:00			`break;`
			`case Microcycle::SelectWord:`
Corrects MOVEA, adds extra test safeguards. 2019-04-12 20:10:17 +00:00			`assert(!(is_rom && !is_peripheral));`
Corrects the carry and extend flags for various long-word operations. 2019-04-22 02:08:18 +00:00			`// if(!(cycle.operation & Microcycle::IsProgram)) printf("[word w %04x -> %08x] ", cycle.value->full, *cycle.address);`
Switches to providing UDS and LDS implicitly via address. Also makes sure that the difference between a non-data cycle that starts without the address strobe active and one that starts with it active can be discerned. 2019-03-16 21:54:58 +00:00			`base[word_address] = cycle.value->full;`
			`break;`
			`case Microcycle::SelectByte:`
Corrects MOVEA, adds extra test safeguards. 2019-04-12 20:10:17 +00:00			`assert(!(is_rom && !is_peripheral));`
Corrects the carry and extend flags for various long-word operations. 2019-04-22 02:08:18 +00:00			`// if(!(cycle.operation & Microcycle::IsProgram)) printf("[byte w %02x -> %08x] ", cycle.value->halves.low, *cycle.address);`
Corrects byte writes in both test machines. 2019-04-17 20:39:10 +00:00			`base[word_address] = (cycle.value->halves.low << cycle.byte_shift()) \| (base[word_address] & (0xffff ^ cycle.byte_mask()));`
Switches to providing UDS and LDS implicitly via address. Also makes sure that the difference between a non-data cycle that starts without the address strobe active and one that starts with it active can be discerned. 2019-03-16 21:54:58 +00:00			`break;`
			`}`
Introduces EmuTOS, and starts constructing test cases around it. 2019-03-10 22:40:12 +00:00			`}`

			`return HalfCycles(0);`
			`}`

			`private:`
			`CPU::MC68000::Processor<EmuTOS, true> m68000_;`

			`std::vector<uint16_t> emuTOS_;`
Implements as much as I currently care about of the Atari ST memory map. 2019-03-12 02:47:37 +00:00			`std::array<uint16_t, 256*1024> ram_;`
Introduces EmuTOS, and starts constructing test cases around it. 2019-03-10 22:40:12 +00:00			`};`

			`@interface EmuTOSTests : XCTestCase`
			`@end`

			`@implementation EmuTOSTests {`
			`std::unique_ptr<EmuTOS> _machine;`
			`}`

			`- (void)setUp {`
			`// Put setup code here. This method is called before the invocation of each test method in the class.`
Switches to running the real TOS, at least temporarily, and enables better testing. 2019-04-01 02:27:57 +00:00			`const auto roms = CSROMFetcher()("AtariST", {"tos100.img"});`
Introduces EmuTOS, and starts constructing test cases around it. 2019-03-10 22:40:12 +00:00			`_machine.reset(new EmuTOS(*roms[0]));`
			`}`

			`- (void)tearDown {`
			`// Put teardown code here. This method is called after the invocation of each test method in the class.`
			`}`

Corrects now-unimplemented ADD/SUB. 2019-04-03 23:43:54 +00:00			`- (void)testStartup {`
Introduces EmuTOS, and starts constructing test cases around it. 2019-03-10 22:40:12 +00:00			`// This is an example of a functional test case.`
			`// Use XCTAssert and related functions to verify your tests produce the correct results.`
Beefs up documentation and developer support. 2019-04-19 17:29:35 +00:00			`_machine->run_for(HalfCycles(8000000));`
Introduces EmuTOS, and starts constructing test cases around it. 2019-03-10 22:40:12 +00:00			`}`

			`@end`