CLK/OSBindings/Mac/Clock SignalTests/68000ComparativeTests.mm

//
//  68000ComparativeTests.cpp
//  Clock SignalTests
//
//  Created by Thomas Harte on 14/12/2019.
//  Copyright © 2019 Thomas Harte. All rights reserved.
//

#import <XCTest/XCTest.h>

#include "../../../Processors/68000/68000.hpp"
#include "../../../InstructionSets/M68k/Executor.hpp"
#include "../../../InstructionSets/M68k/Decoder.hpp"

#include <array>
#include <memory>
#include <functional>

//#define USE_EXECUTOR
//#define MAKE_SUGGESTIONS
//#define LOG_UNTESTED

namespace {

/// Binds a 68000 executor to 16mb of RAM.
struct TestExecutor {
	uint8_t *const ram;
	InstructionSet::M68k::Executor<InstructionSet::M68k::Model::M68000, TestExecutor> processor;

	TestExecutor(uint8_t *ram) : ram(ram), processor(*this) {}

	void run_for_instructions(int instructions) {
		processor.run_for_instructions(instructions);
	}

	// Initial test-case implementation:
	// do a very sedate read and write.

	template <typename IntT> IntT read(uint32_t address, InstructionSet::M68k::FunctionCode) {
		if constexpr (sizeof(IntT) == 1) {
			return IntT(ram[address & 0xffffff]);
		}

		if constexpr (sizeof(IntT) == 2) {
			return IntT(
				(ram[address & 0xffffff] << 8) |
				ram[(address+1) & 0xffffff]
			);
		}

		if constexpr (sizeof(IntT) == 4) {
			return IntT(
				(ram[address & 0xffffff] << 24) |
				(ram[(address+1) & 0xffffff] << 16) |
				(ram[(address+2) & 0xffffff] << 8) |
				ram[(address+3) & 0xffffff]
			);
		}
		return 0;
	}

	template <typename IntT> void write(uint32_t address, IntT value, InstructionSet::M68k::FunctionCode) {
		if constexpr (sizeof(IntT) == 1) {
			ram[address & 0xffffff] = uint8_t(value);
		}

		if constexpr (sizeof(IntT) == 2) {
			ram[address & 0xffffff] = uint8_t(value >> 8);
			ram[(address+1) & 0xffffff] = uint8_t(value);
		}

		if constexpr (sizeof(IntT) == 4) {
			ram[address & 0xffffff] = uint8_t(value >> 24);
			ram[(address+1) & 0xffffff] = uint8_t(value >> 16);
			ram[(address+2) & 0xffffff] = uint8_t(value >> 8);
			ram[(address+3) & 0xffffff] = uint8_t(value);
		}
	}

	void reset() {}
	int acknowlege_interrupt(int) {
		return -1;
	}
};

/// Binds a bus-accurate 68000 to 16mb of RAM.
struct TestProcessor: public CPU::MC68000::BusHandler {
	uint8_t *const ram;
	CPU::MC68000::Processor<TestProcessor, true, true, true> processor;
	std::function<void(void)> comparitor;

	TestProcessor(uint8_t *ram) : ram(ram), processor(*this) {}

	void will_perform(uint32_t, uint16_t) {
		--instructions_remaining_;
		if(!instructions_remaining_) comparitor();
	}


	template <typename Microcycle> HalfCycles perform_bus_operation(const Microcycle &cycle, int) {
		if(cycle.data_select_active()) {
			cycle.apply(&ram[cycle.host_endian_byte_address()]);
		}
		return HalfCycles(0);
	}

	void run_for_instructions(int instructions, const std::function<void(void)> &compare) {
		instructions_remaining_ = instructions + 1;	// i.e. run up to the will_perform of the instruction after.
		comparitor = std::move(compare);
		while(instructions_remaining_) {
			processor.run_for(HalfCycles(2));
		}
	}

	private:
		int instructions_remaining_;
};

}

@interface M68000ComparativeTests : XCTestCase
@end

@implementation M68000ComparativeTests {
	NSSet<NSString *> *_fileSet;
	NSSet<NSString *> *_testSet;

	NSMutableSet<NSString *> *_failures;
	NSMutableArray<NSNumber *> *_failingOpcodes;
	NSMutableDictionary<NSNumber *, NSMutableArray<NSString *> *> *_suggestedCorrections;
	NSMutableSet<NSNumber *> *_testedOpcodes;

	InstructionSet::M68k::Predecoder<InstructionSet::M68k::Model::M68000> _decoder;

	std::array<uint16_t, 8*1024*1024> _ram;
	std::unique_ptr<TestExecutor> _testExecutor;
}

- (void)setUp {
	// Definitively erase any prior memory contents;
	// 0xce is arbitrary but hopefully easier to spot
	// in potential errors than e.g. 0x00 or 0xff.
	_ram.fill(0xcece);

	// TODO: possibly, worry about resetting RAM to 0xce after tests have completed.

#ifdef USE_EXECUTOR
	_testExecutor = std::make_unique<TestExecutor>(reinterpret_cast<uint8_t *>(_ram.data()));
#endif

	// These will accumulate a list of failing tests and associated opcodes.
	_failures = [[NSMutableSet alloc] init];
	_failingOpcodes = [[NSMutableArray alloc] init];

	// This will simply accumulate a list of all tested opcodes, in order to report
	// on those that are missing.
	_testedOpcodes = [[NSMutableSet alloc] init];

#ifdef MAKE_SUGGESTIONS
	_suggestedCorrections = [[NSMutableDictionary alloc] init];
#endif

	// To limit tests run to a subset of files and/or of tests, uncomment and fill in below.
//	_fileSet = [NSSet setWithArray:@[@"abcd_sbcd.json"]];
//	_testSet = [NSSet setWithArray:@[@"LINK.w 0007"]];
}

- (void)testAll {
	// Get the full list of available test files.
	NSBundle *const bundle = [NSBundle bundleForClass:[self class]];
	NSArray<NSURL *> *const tests = [bundle URLsForResourcesWithExtension:@"json" subdirectory:@"68000 Comparative Tests"];

	// Issue each test file.
	for(NSURL *url in tests) {
		// Compare against a file set if one has been supplied.
		if(_fileSet && ![_fileSet containsObject:[url lastPathComponent]]) continue;
//		NSLog(@"Testing %@", url);
		[self testJSONAtURL:url];
	}

	XCTAssert(_failures.count == 0);

	// Output a summary of failures, if any.
	if(_failures.count) {
		NSLog(@"Total failures: %@", @(_failures.count));
		NSLog(@"Failures: %@", _failures);
		NSLog(@"Failing opcodes:");

		for(NSNumber *number in _failingOpcodes) {
			const auto decoded = _decoder.decode(number.intValue);
			const std::string description = decoded.to_string(number.intValue);
			NSLog(@"%04x %s", number.intValue, description.c_str());

			for(NSString *suggestion in _suggestedCorrections[number]) {
				NSLog(@"%@", suggestion);
			}
		}
	}

#ifdef LOG_UNTESTED
	// Output a list of untested opcodes.
	NSMutableArray<NSString *> *untested = [[NSMutableArray alloc] init];
	for(int opcode = 0; opcode < 65536; opcode++) {
		const auto instruction = _decoder.decode(uint16_t(opcode));

		if(instruction.operation == InstructionSet::M68k::Operation::Undefined) {
			continue;
		}
		if([_testedOpcodes containsObject:@(opcode)]) {
			continue;
		}

		[untested addObject:[NSString stringWithFormat:@"%04x %s", opcode, instruction.to_string(uint16_t(opcode)).c_str()]];
	}

	NSLog(@"Untested: %@", untested);
#endif
}

- (void)testJSONAtURL:(NSURL *)url {
	// Read the nominated file and parse it as JSON.
	NSData *const data = [NSData dataWithContentsOfURL:url];
	NSError *error;
	NSArray *const jsonContents = [NSJSONSerialization JSONObjectWithData:data options:0 error:&error];

	XCTAssertNil(error);
	XCTAssertNotNil(jsonContents);
	XCTAssert([jsonContents isKindOfClass:[NSArray class]]);

	// Perform each dictionary in the array as a test.
	for(NSDictionary *test in jsonContents) {
		if(![test isKindOfClass:[NSDictionary class]]) continue;

		// Only entries with a name are valid.
		NSString *const name = test[@"name"];
		if(!name) continue;

		// Compare against a test set if one has been supplied.
		if(_testSet && ![_testSet containsObject:name]) continue;

		// Pull out the opcode and record it.
		NSArray<NSNumber *> *const initialMemory = test[@"initial memory"];
		uint16_t opcode = 0;
		NSEnumerator<NSNumber *> *enumerator = [initialMemory objectEnumerator];
		while(true) {
			NSNumber *const address = [enumerator nextObject];
			NSNumber *const value = [enumerator nextObject];

			if(!address || !value) break;
			if(address.integerValue == 0x100) opcode |= value.integerValue << 8;
			if(address.integerValue == 0x101) opcode |= value.integerValue;
		}
		[_testedOpcodes addObject:@(opcode)];

#ifdef USE_EXECUTOR
		[self testOperationExecutor:test name:name];
#else
		[self testOperationClassic:test name:name];
#endif
	}
}

- (void)testOperationClassic:(NSDictionary *)test name:(NSString *)name {
	struct TerminateMarker {};

	auto uniqueTest68000 = std::make_unique<TestProcessor>(reinterpret_cast<uint8_t *>(_ram.data()));
	auto test68000 = uniqueTest68000.get();

	{
		// Apply initial memory state.
		NSArray<NSNumber *> *const initialMemory = test[@"initial memory"];
		NSEnumerator<NSNumber *> *enumerator = [initialMemory objectEnumerator];
		while(true) {
			NSNumber *const address = [enumerator nextObject];
			NSNumber *const value = [enumerator nextObject];

			if(!address || !value) break;
			test68000->ram[address.integerValue ^ 1] = value.integerValue;	// Effect a short-resolution endianness swap.
		}

		// Apply initial processor state.
		auto state = test68000->processor.get_state();
		state.registers = [self initialRegisters:test];
		test68000->processor.set_state(state);
	}

	// Check that this is a defined opcode; capture of the unrecognised instruction
	// exception doesn't work correctly with the way that this test class tries
	// to detect the gaps between operations.
	const uint16_t opcode = (test68000->ram[0x101] << 8) | test68000->ram[0x100];
	if(_decoder.decode(opcode).operation == InstructionSet::M68k::Operation::Undefined) {
		return;
	}

	// Run the thing.
	const auto comparitor = [=] {
		const auto state = test68000->processor.get_state();

		[self test:test name:name compareFinalRegisters:state.registers opcode:opcode pcOffset:-4];

		// Test final memory state.
		NSArray<NSNumber *> *const finalMemory = test[@"final memory"];
		NSEnumerator *enumerator = [finalMemory objectEnumerator];
		while(true) {
			NSNumber *const address = [enumerator nextObject];
			NSNumber *const value = [enumerator nextObject];

			if(!address || !value) break;
			XCTAssertEqual(test68000->ram[address.integerValue ^ 1], value.integerValue, @"%@: Memory at location %@ inconsistent", name, address);
			if(test68000->ram[address.integerValue ^ 1] != value.integerValue) [_failures addObject:name];
		}

		// Consider collating extra detail.
		if([_failures containsObject:name]) {
			[_failingOpcodes addObject:@(opcode)];
		}

		// Make sure nothing further occurs; keep this test isolated.
		throw TerminateMarker();
	};

	try {
		test68000->run_for_instructions(1, comparitor);
	} catch(TerminateMarker m) {}
}

- (void)setInitialState:(NSDictionary *)test {
	// Apply initial memory state.
	NSArray<NSNumber *> *const initialMemory = test[@"initial memory"];
	NSEnumerator<NSNumber *> *enumerator = [initialMemory objectEnumerator];
	while(true) {
		NSNumber *const address = [enumerator nextObject];
		NSNumber *const value = [enumerator nextObject];

		if(!address || !value) break;
		_testExecutor->ram[address.integerValue] = value.integerValue;
	}

	// Apply initial processor state.
	_testExecutor->processor.set_state([self initialRegisters:test]);
}

- (void)testOperationExecutor:(NSDictionary *)test name:(NSString *)name {
	[self setInitialState:test];

	// Run the thing.
	_testExecutor->run_for_instructions(1);

	// Test the end state.
	const auto state = _testExecutor->processor.get_state();
	const uint16_t opcode = _testExecutor->read<uint16_t>(0x100, InstructionSet::M68k::FunctionCode());
	[self test:test name:name compareFinalRegisters:state opcode:opcode pcOffset:0];

	// Test final memory state.
	NSArray<NSNumber *> *const finalMemory = test[@"final memory"];
	NSEnumerator *enumerator = [finalMemory objectEnumerator];
	while(true) {
		NSNumber *const address = [enumerator nextObject];
		NSNumber *const value = [enumerator nextObject];

		if(!address || !value) break;
		if(_testExecutor->ram[address.integerValue] != value.integerValue) [_failures addObject:name];
	}

	// If this test is now in the failures set, add the corresponding opcode for
	// later logging.
	if([_failures containsObject:name]) {
		// Add this opcode to the failing list.
		[_failingOpcodes addObject:@(opcode)];

		// Generate the JSON that would have satisfied this test, at least as far as registers go,
		// if those are being collected.
		if(_suggestedCorrections) {
			NSMutableDictionary *generatedTest = [test mutableCopy];
			NSMutableDictionary *generatedState = generatedTest[@"final state"] = [test[@"final state"] mutableCopy];
			for(int c = 0; c < 8; ++c) {
				const NSString *dX = [@"d" stringByAppendingFormat:@"%d", c];
				const NSString *aX = [@"a" stringByAppendingFormat:@"%d", c];
				generatedState[dX] = @(state.data[c]);
				if(c < 7) generatedState[aX] = @(state.address[c]);
			}

			generatedState[@"a7"] = @(state.supervisor_stack_pointer);
			generatedState[@"usp"] = @(state.user_stack_pointer);
			generatedState[@"sr"] = @(state.status);

			NSString *const generatedJSON =
				[[NSString alloc] initWithData:
						[NSJSONSerialization dataWithJSONObject:generatedTest options:0 error:nil]
						encoding:NSUTF8StringEncoding];

			if(_suggestedCorrections[@(opcode)]) {
				[_suggestedCorrections[@(opcode)] addObject:generatedJSON];
			} else {
				_suggestedCorrections[@(opcode)] = [NSMutableArray arrayWithObject:generatedJSON];
			}
		}
	}
}

- (InstructionSet::M68k::RegisterSet)initialRegisters:(NSDictionary *)test {
	InstructionSet::M68k::RegisterSet registers;

	NSDictionary *const initialState = test[@"initial state"];
	for(int c = 0; c < 8; ++c) {
		const NSString *dX = [@"d" stringByAppendingFormat:@"%d", c];
		const NSString *aX = [@"a" stringByAppendingFormat:@"%d", c];

		registers.data[c] = uint32_t([initialState[dX] integerValue]);
		if(c < 7)
			registers.address[c] = uint32_t([initialState[aX] integerValue]);
	}
	registers.supervisor_stack_pointer = uint32_t([initialState[@"a7"] integerValue]);
	registers.user_stack_pointer = uint32_t([initialState[@"usp"] integerValue]);
	registers.status = [initialState[@"sr"] integerValue];
	registers.program_counter = uint32_t([initialState[@"pc"] integerValue]);

	return registers;
}

- (void)test:(NSDictionary *)test name:(NSString *)name compareFinalRegisters:(InstructionSet::M68k::RegisterSet)registers opcode:(uint16_t)opcode pcOffset:(int)pcOffset {
	// Test the end state.
	NSDictionary *const finalState = test[@"final state"];
	for(int c = 0; c < 8; ++c) {
		const NSString *dX = [@"d" stringByAppendingFormat:@"%d", c];
		const NSString *aX = [@"a" stringByAppendingFormat:@"%d", c];

		if(registers.data[c] != [finalState[dX] integerValue]) [_failures addObject:name];
		if(c < 7 && registers.address[c] != [finalState[aX] integerValue]) [_failures addObject:name];
	}
	if(registers.supervisor_stack_pointer != [finalState[@"a7"] integerValue]) [_failures addObject:name];
	if(registers.user_stack_pointer != [finalState[@"usp"] integerValue]) [_failures addObject:name];
	if(registers.program_counter + pcOffset != [finalState[@"pc"] integerValue]) [_failures addObject:name];

	const uint16_t correctSR = [finalState[@"sr"] integerValue];
	if(registers.status != correctSR) {
		const auto instruction = _decoder.decode(opcode);

		// For DIVU and DIVS, for now, test only the well-defined flags.
		if(
			instruction.operation != InstructionSet::M68k::Operation::DIVSw &&
			instruction.operation != InstructionSet::M68k::Operation::DIVUw
		) {
			[_failures addObject:name];
		} else {
			uint16_t status_mask = 0xff13;	// i.e. extend, which should be unaffected, and overflow, which
											// is well-defined unless there was a divide by zero. But this
											// test set doesn't include any divide by zeroes.

			if(!(correctSR & InstructionSet::M68k::ConditionCode::Overflow)) {
				// If overflow didn't occur then negative and zero are also well-defined.
				status_mask |= 0x000c;
			}

			if((registers.status & status_mask) != (([finalState[@"sr"] integerValue]) & status_mask)) {
				[_failures addObject:name];
			}
		}
	}
}

@end