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https://github.com/TomHarte/CLK.git
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Merge pull request #837 from TomHarte/Vic20Tests
Further improves 6522 emulation.
This commit is contained in:
commit
94dba70bbe
@ -128,13 +128,14 @@ template <class T> class MOS6522: public MOS6522Storage {
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void access(int address);
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uint8_t get_port_input(Port port, uint8_t output_mask, uint8_t output);
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uint8_t get_port_input(Port port, uint8_t output_mask, uint8_t output, uint8_t timer_mask);
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inline void reevaluate_interrupts();
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/// Sets the current intended output value for the port and line;
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/// if this affects the visible output, it will be passed to the handler.
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void set_control_line_output(Port port, Line line, LineState value);
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void evaluate_cb2_output();
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void evaluate_port_b_output();
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};
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}
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@ -43,7 +43,7 @@ template <typename T> void MOS6522<T>::write(int address, uint8_t value) {
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registers_.output[1] = value;
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bus_handler_.run_for(time_since_bus_handler_call_.flush<HalfCycles>());
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bus_handler_.set_port_output(Port::B, value, registers_.data_direction[1]);
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evaluate_port_b_output();
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registers_.interrupt_flags &= ~(InterruptFlag::CB1ActiveEdge | ((registers_.peripheral_control&0x20) ? 0 : InterruptFlag::CB2ActiveEdge));
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reevaluate_interrupts();
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@ -85,6 +85,12 @@ template <typename T> void MOS6522<T>::write(int address, uint8_t value) {
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registers_.next_timer[0] = registers_.timer_latch[0];
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timer_is_running_[0] = true;
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// If PB7 output mode is active, set it low.
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if(registers_.auxiliary_control & 0x80) {
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registers_.timer_port_b_output &= 0x7f;
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evaluate_port_b_output();
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}
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// Clear existing interrupt flag.
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registers_.interrupt_flags &= ~InterruptFlag::Timer1;
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reevaluate_interrupts();
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@ -113,6 +119,13 @@ template <typename T> void MOS6522<T>::write(int address, uint8_t value) {
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case 0xb: // Auxiliary control ('ACR').
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registers_.auxiliary_control = value;
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evaluate_cb2_output();
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// This is a bit of a guess: reset the timer-based PB7 output to its default high level
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// any timer that timer-linked PB7 output is disabled.
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if(!(registers_.auxiliary_control & 0x80)) {
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registers_.timer_port_b_output |= 0x80;
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}
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evaluate_port_b_output();
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break;
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case 0xc: { // Peripheral control ('PCR').
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// const auto old_peripheral_control = registers_.peripheral_control;
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@ -176,12 +189,12 @@ template <typename T> uint8_t MOS6522<T>::read(int address) {
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case 0x0: // Read Port B ('IRB').
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registers_.interrupt_flags &= ~(InterruptFlag::CB1ActiveEdge | InterruptFlag::CB2ActiveEdge);
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reevaluate_interrupts();
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return get_port_input(Port::B, registers_.data_direction[1], registers_.output[1]);
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return get_port_input(Port::B, registers_.data_direction[1], registers_.output[1], registers_.auxiliary_control & 0x80);
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case 0xf:
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case 0x1: // Read Port A ('IRA').
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registers_.interrupt_flags &= ~(InterruptFlag::CA1ActiveEdge | InterruptFlag::CA2ActiveEdge);
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reevaluate_interrupts();
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return get_port_input(Port::A, registers_.data_direction[0], registers_.output[0]);
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return get_port_input(Port::A, registers_.data_direction[0], registers_.output[0], 0);
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case 0x2: return registers_.data_direction[1]; // Port B direction ('DDRB').
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case 0x3: return registers_.data_direction[0]; // Port A direction ('DDRA').
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@ -218,9 +231,10 @@ template <typename T> uint8_t MOS6522<T>::read(int address) {
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return 0xff;
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}
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template <typename T> uint8_t MOS6522<T>::get_port_input(Port port, uint8_t output_mask, uint8_t output) {
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template <typename T> uint8_t MOS6522<T>::get_port_input(Port port, uint8_t output_mask, uint8_t output, uint8_t timer_mask) {
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bus_handler_.run_for(time_since_bus_handler_call_.flush<HalfCycles>());
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const uint8_t input = bus_handler_.get_port_input(port);
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output = (output & ~timer_mask) | (registers_.timer_port_b_output & timer_mask);
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return (input & ~output_mask) | (output & output_mask);
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}
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@ -354,13 +368,22 @@ template <typename T> void MOS6522<T>::do_phase1() {
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// Determine whether to toggle PB7.
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if(registers_.auxiliary_control&0x80) {
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registers_.output[1] ^= 0x80;
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registers_.timer_port_b_output ^= 0x80;
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bus_handler_.run_for(time_since_bus_handler_call_.flush<HalfCycles>());
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bus_handler_.set_port_output(Port::B, registers_.output[1], registers_.data_direction[1]);
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evaluate_port_b_output();
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}
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}
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}
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template <typename T> void MOS6522<T>::evaluate_port_b_output() {
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// Apply current timer-linked PB7 output if any atop the stated output.
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const uint8_t timer_control_bit = registers_.auxiliary_control & 0x80;
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bus_handler_.set_port_output(
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Port::B,
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(registers_.output[1] & (0xff ^ timer_control_bit)) | timer_control_bit,
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registers_.data_direction[1] | timer_control_bit);
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}
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/*! Runs for a specified number of half cycles. */
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template <typename T> void MOS6522<T>::run_for(const HalfCycles half_cycles) {
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auto number_of_half_cycles = half_cycles.as_integral();
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@ -34,7 +34,9 @@ class MOS6522Storage {
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uint8_t peripheral_control = 0;
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uint8_t interrupt_flags = 0;
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uint8_t interrupt_enable = 0;
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bool timer_needs_reload = false;
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uint8_t timer_port_b_output = 0xff;
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} registers_;
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// Control state.
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@ -860,6 +860,7 @@
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4BEF6AAC1D35D1C400E73575 /* DPLLTests.swift in Sources */ = {isa = PBXBuildFile; fileRef = 4BEF6AAB1D35D1C400E73575 /* DPLLTests.swift */; };
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4BF437EE209D0F7E008CBD6B /* SegmentParser.cpp in Sources */ = {isa = PBXBuildFile; fileRef = 4BF437EC209D0F7E008CBD6B /* SegmentParser.cpp */; };
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4BF437EF209D0F7E008CBD6B /* SegmentParser.cpp in Sources */ = {isa = PBXBuildFile; fileRef = 4BF437EC209D0F7E008CBD6B /* SegmentParser.cpp */; };
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4BF8D4C82516E27A00BBE21B /* Accelerate.framework in Frameworks */ = {isa = PBXBuildFile; fileRef = 4BB8617024E22F4900A00E03 /* Accelerate.framework */; };
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4BFCA1241ECBDCB400AC40C1 /* AllRAMProcessor.cpp in Sources */ = {isa = PBXBuildFile; fileRef = 4BFCA1211ECBDCAF00AC40C1 /* AllRAMProcessor.cpp */; };
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4BFCA1271ECBE33200AC40C1 /* TestMachineZ80.mm in Sources */ = {isa = PBXBuildFile; fileRef = 4BFCA1261ECBE33200AC40C1 /* TestMachineZ80.mm */; };
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4BFCA1291ECBE7A700AC40C1 /* zexall.com in Resources */ = {isa = PBXBuildFile; fileRef = 4BFCA1281ECBE7A700AC40C1 /* zexall.com */; };
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@ -1830,6 +1831,7 @@
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buildActionMask = 2147483647;
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files = (
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4B9F11CA2272433900701480 /* libz.tbd in Frameworks */,
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4BF8D4C82516E27A00BBE21B /* Accelerate.framework in Frameworks */,
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);
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runOnlyForDeploymentPostprocessing = 0;
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};
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@ -101,6 +101,116 @@ class MOS6522Tests: XCTestCase {
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}
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// MARK: PB7 timer 1 tests
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// These follow the same logic and check for the same results as the VICE VIC-20 via_pb7 tests.
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// Perfoms:
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//
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// (1) establish initial ACR and port B output value, and grab port B input value.
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// (2) start timer 1, grab port B input value.
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// (3) set final ACR, grab port B input value.
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// (4) allow timer 1 to expire, grab port B input value.
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private func runTest(startACR: UInt8, endACR: UInt8, portBOutput: UInt8) -> [UInt8] {
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var result: [UInt8] = []
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// Clear all register values.
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for n: UInt in 0...15 {
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m6522.setValue(0, forRegister: n)
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}
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m6522.run(forHalfCycles: 2)
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// Set data direction and current port B value.
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m6522.setValue(0xff, forRegister: 2)
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m6522.run(forHalfCycles: 2)
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m6522.setValue(portBOutput, forRegister: 0)
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m6522.run(forHalfCycles: 2)
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// Set initial ACR and grab the current port B value.
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m6522.setValue(startACR, forRegister: 0xb)
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m6522.run(forHalfCycles: 2)
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result.append(m6522.value(forRegister: 0))
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m6522.run(forHalfCycles: 2)
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// Start timer 1 and grab the value.
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m6522.setValue(1, forRegister: 0x5)
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m6522.run(forHalfCycles: 2)
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result.append(m6522.value(forRegister: 0))
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m6522.run(forHalfCycles: 2)
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// Set the final ACR value and grab value.
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m6522.setValue(endACR, forRegister: 0xb)
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m6522.run(forHalfCycles: 2)
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result.append(m6522.value(forRegister: 0))
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m6522.run(forHalfCycles: 2)
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// Make sure timer 1 has expired.
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m6522.run(forHalfCycles: 512)
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// Grab the final value.
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result.append(m6522.value(forRegister: 0))
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return result
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}
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func testTimer1PB7() {
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// Original top row. [original Vic-20 screen output in comments on the right]
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XCTAssertEqual(runTest(startACR: 0x00, endACR: 0x00, portBOutput: 0x00), [0x00, 0x00, 0x00, 0x00]) // @@@@ (i.e. 0, 0, 0, 0)
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XCTAssertEqual(runTest(startACR: 0x00, endACR: 0x40, portBOutput: 0x00), [0x00, 0x00, 0x00, 0x00]) // @@@@ (i.e. 0, 0, 0, 0)
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XCTAssertEqual(runTest(startACR: 0x00, endACR: 0x80, portBOutput: 0x00), [0x00, 0x00, 0x80, 0x00]) // @@b@ (i.e. 0, 0, 1, 0)
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XCTAssertEqual(runTest(startACR: 0x00, endACR: 0xc0, portBOutput: 0x00), [0x00, 0x00, 0x80, 0x00]) // @@b@ (i.e. 0, 0, 1, 0)
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XCTAssertEqual(runTest(startACR: 0x00, endACR: 0x00, portBOutput: 0xff), [0xff, 0xff, 0xff, 0xff]) // cccc (i.e. 1, 1, 1, 1)
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XCTAssertEqual(runTest(startACR: 0x00, endACR: 0x40, portBOutput: 0xff), [0xff, 0xff, 0xff, 0xff]) // cccc (i.e. 1, 1, 1, 1)
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XCTAssertEqual(runTest(startACR: 0x00, endACR: 0x80, portBOutput: 0xff), [0xff, 0xff, 0xff, 0x7f]) // ccca (i.e. 1, 1, 1, 0)
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XCTAssertEqual(runTest(startACR: 0x00, endACR: 0xc0, portBOutput: 0xff), [0xff, 0xff, 0xff, 0x7f]) // ccca (i.e. 1, 1, 1, 0)
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// Second row. [same output as first row]
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XCTAssertEqual(runTest(startACR: 0x40, endACR: 0x00, portBOutput: 0x00), [0x00, 0x00, 0x00, 0x00]) // @@@@
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XCTAssertEqual(runTest(startACR: 0x40, endACR: 0x40, portBOutput: 0x00), [0x00, 0x00, 0x00, 0x00]) // @@@@
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XCTAssertEqual(runTest(startACR: 0x40, endACR: 0x80, portBOutput: 0x00), [0x00, 0x00, 0x80, 0x00]) // @@b@
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XCTAssertEqual(runTest(startACR: 0x40, endACR: 0xc0, portBOutput: 0x00), [0x00, 0x00, 0x80, 0x00]) // @@b@
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XCTAssertEqual(runTest(startACR: 0x40, endACR: 0x00, portBOutput: 0xff), [0xff, 0xff, 0xff, 0xff]) // cccc
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XCTAssertEqual(runTest(startACR: 0x40, endACR: 0x40, portBOutput: 0xff), [0xff, 0xff, 0xff, 0xff]) // cccc
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XCTAssertEqual(runTest(startACR: 0x40, endACR: 0x80, portBOutput: 0xff), [0xff, 0xff, 0xff, 0x7f]) // ccca
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XCTAssertEqual(runTest(startACR: 0x40, endACR: 0xc0, portBOutput: 0xff), [0xff, 0xff, 0xff, 0x7f]) // ccca
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// Third row.
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XCTAssertEqual(runTest(startACR: 0x80, endACR: 0x00, portBOutput: 0x00), [0x80, 0x00, 0x00, 0x00]) // b@@@ (i.e. 1, 0, 0, 0)
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XCTAssertEqual(runTest(startACR: 0x80, endACR: 0x40, portBOutput: 0x00), [0x80, 0x00, 0x00, 0x00]) // b@@@ (i.e. 1, 0, 0, 0)
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XCTAssertEqual(runTest(startACR: 0x80, endACR: 0x80, portBOutput: 0x00), [0x80, 0x00, 0x00, 0x80]) // b@@b (i.e. 1, 0, 0, 1)
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XCTAssertEqual(runTest(startACR: 0x80, endACR: 0xc0, portBOutput: 0x00), [0x80, 0x00, 0x00, 0x80]) // b@@b (i.e. 1, 0, 0, 1)
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XCTAssertEqual(runTest(startACR: 0x80, endACR: 0x00, portBOutput: 0xff), [0xff, 0x7f, 0xff, 0xff]) // cacc (i.e. 1, 0, 1, 1)
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XCTAssertEqual(runTest(startACR: 0x80, endACR: 0x40, portBOutput: 0xff), [0xff, 0x7f, 0xff, 0xff]) // cacc (i.e. 1, 0, 1, 1)
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XCTAssertEqual(runTest(startACR: 0x80, endACR: 0x80, portBOutput: 0xff), [0xff, 0x7f, 0x7f, 0xff]) // caac (i.e. 1, 0, 0, 1)
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XCTAssertEqual(runTest(startACR: 0x80, endACR: 0xc0, portBOutput: 0xff), [0xff, 0x7f, 0x7f, 0xff]) // caac (i.e. 1, 0, 0, 1)
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// Final row. [same output as third row]
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XCTAssertEqual(runTest(startACR: 0xc0, endACR: 0x00, portBOutput: 0x00), [0x80, 0x00, 0x00, 0x00]) // b@@@
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XCTAssertEqual(runTest(startACR: 0xc0, endACR: 0x40, portBOutput: 0x00), [0x80, 0x00, 0x00, 0x00]) // b@@@
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XCTAssertEqual(runTest(startACR: 0xc0, endACR: 0x80, portBOutput: 0x00), [0x80, 0x00, 0x00, 0x80]) // b@@b
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XCTAssertEqual(runTest(startACR: 0xc0, endACR: 0xc0, portBOutput: 0x00), [0x80, 0x00, 0x00, 0x80]) // b@@b
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XCTAssertEqual(runTest(startACR: 0xc0, endACR: 0x00, portBOutput: 0xff), [0xff, 0x7f, 0xff, 0xff]) // cacc
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XCTAssertEqual(runTest(startACR: 0xc0, endACR: 0x40, portBOutput: 0xff), [0xff, 0x7f, 0xff, 0xff]) // cacc
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XCTAssertEqual(runTest(startACR: 0xc0, endACR: 0x80, portBOutput: 0xff), [0xff, 0x7f, 0x7f, 0xff]) // caac
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XCTAssertEqual(runTest(startACR: 0xc0, endACR: 0xc0, portBOutput: 0xff), [0xff, 0x7f, 0x7f, 0xff]) // caac
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// Conclusions:
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//
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// after inital ACR and port B value: [original data if not in PB7 output mode, otherwise 1]
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// after starting timer 1: [original data if not in PB7 output mode, otherwise 0]
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// after final ACR value: [original data if not in PB7 output mode, 1 if has transitioned to PB7 mode, 0 if was already in PB7 mode]
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// after timer 1 expiry: [original data if not in PB7 mode, 1 if timer has expired while in PB7 mode]
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//
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// i.e.
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// (1) there is separate storage for the programmer-set PB7 and the timer output;
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// (2) the timer output is reset upon a timer write only if PB7 output is enabled;
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// (3) expiry toggles the output.
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}
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// MARK: Data direction tests
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func testDataDirection() {
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// set low four bits of register B as output, the top four as input
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@ -70,12 +70,9 @@
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- (void)testSeekToSecondBit {
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Storage::Disk::PCMSegmentEventSource segmentSource = self.segmentSource;
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Storage::Time target_time(1, 10);
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Storage::Time found_time = segmentSource.seek_to(target_time);
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found_time.simplify();
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XCTAssertTrue(found_time.length == 1 && found_time.clock_rate == 20, @"A request to seek to 1/10th should have seeked to 1/20th");
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const float found_time = segmentSource.seek_to(1.0f / 10.0f);
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XCTAssertTrue(fabsf(found_time - 1.0f / 20.0f) < 0.01f, @"A request to seek to 1/10th should have seeked to 1/20th");
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Storage::Disk::Track::Event next_event = segmentSource.get_next_event();
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next_event.length.simplify();
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@ -85,12 +82,9 @@
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- (void)testSeekBeyondFinalBit {
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Storage::Disk::PCMSegmentEventSource segmentSource = self.segmentSource;
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Storage::Time target_time(24, 10);
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const float found_time = segmentSource.seek_to(2.4f);
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Storage::Time found_time = segmentSource.seek_to(target_time);
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found_time.simplify();
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XCTAssertTrue(found_time.length == 47 && found_time.clock_rate == 20, @"A request to seek to 24/10ths should have seeked to 47/20ths");
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XCTAssertTrue(fabsf(found_time - 47.0f / 20.0f) < 0.01f, @"A request to seek to 24/10ths should have seeked to 47/20ths");
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Storage::Disk::Track::Event next_event = segmentSource.get_next_event();
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next_event.length.simplify();
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@ -73,16 +73,14 @@
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}
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Storage::Disk::PCMTrack track(segments);
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Storage::Time late_time(967445, 2045454);
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const float late_time = 967445.0f / 2045454.0f;
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const auto offset = track.seek_to(late_time);
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XCTAssert(offset <= late_time, "Found location should be at or before sought time");
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const auto difference = late_time - offset;
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const double difference_duration = difference.get<double>();
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XCTAssert(difference_duration >= 0.0 && difference_duration < 0.005, "Next event should occur soon");
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XCTAssert(difference >= 0.0 && difference < 0.005, "Next event should occur soon");
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const double offset_duration = offset.get<double>();
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XCTAssert(offset_duration >= 0.0 && offset_duration < 0.5, "Next event should occur soon");
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XCTAssert(offset >= 0.0 && offset < 0.5, "Next event should occur soon");
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auto next_event = track.get_next_event();
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double next_event_duration = next_event.length.get<double>();
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