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Merge pull request #926 from TomHarte/SimplifiedTiming

Attempts more cleanly to express ZX Spectrum timing.
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Thomas Harte 2021-04-21 19:46:23 -04:00 committed by GitHub
commit 5ea605ccf7
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2 changed files with 22 additions and 93 deletions

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@ -63,106 +63,34 @@ template <VideoTiming timing> class Video {
// Number of cycles after first pixel fetch at which interrupt is first signalled.
int interrupt_time;
// Contention to apply, in half-cycles, as a function of number of half cycles since
// Contention to apply, in whole cycles, as a function of number of whole cycles since
// contention began.
int delays[16];
int delays[8];
constexpr Timings(int cycles_per_line, int lines_per_frame, int contention_leadin, int contention_duration, int interrupt_offset, const int *delays) noexcept :
cycles_per_line(cycles_per_line * 2),
lines_per_frame(lines_per_frame),
contention_leadin(contention_leadin * 2),
contention_duration(contention_duration * 2),
interrupt_time((cycles_per_line * lines_per_frame - interrupt_offset - contention_leadin) * 2),
delays{ delays[0] * 2, delays[1] * 2, delays[2] * 2, delays[3] * 2, delays[4] * 2, delays[5] * 2, delays[6] * 2, delays[7] * 2}
{}
};
static constexpr Timings get_timings() {
if constexpr (timing == VideoTiming::Plus3) {
// Amstrad gate array timings, classic statement:
//
// Contention begins 14361 cycles "after interrupt" and follows the pattern [1, 0, 7, 6 5 4, 3, 2].
// The first four bytes of video are fetched at 1436514368 cycles, in the order [pixels, attribute, pixels, attribute].
//
// For my purposes:
//
// Video fetching always begins at 0. Since there are 311*228 = 70908 cycles per frame, and the interrupt
// should "occur" (I assume: begin) 14365 before that, it should actually begin at 70908 - 14365 = 56543.
//
// Contention begins four cycles before the first video fetch, so it begins at 70904. I don't currently
// know whether the four cycles is true across all models, so it's given here as convention_leadin.
//
// ... except that empirically that all seems to be two cycles off. So maybe I misunderstand what the
// contention patterns are supposed to indicate relative to MREQ? It's frustrating that all documentation
// I can find is vaguely in terms of contention patterns, and what they mean isn't well-defined in terms
// of regular Z80 signalling.
constexpr Timings result = {
.cycles_per_line = 228 * 2,
.lines_per_frame = 311,
// i.e. video fetching begins five cycles after the start of the
// contended memory pattern below; that should put a clear two
// cycles between a Z80 access and the first video fetch.
.contention_leadin = 5 * 2,
.contention_duration = 129 * 2,
// i.e. interrupt is first signalled 14368 cycles before the first video fetch.
.interrupt_time = (1 + 228*311 - 14365 - 5) * 2,
.delays = { // Should start at 14365
2, 1,
0, 0,
14, 13,
12, 11,
10, 9,
8, 7,
6, 5,
4, 3,
}
};
return result;
constexpr int delays[] = {1, 0, 7, 6, 5, 4, 3, 2};
return Timings(228, 311, 6, 129, 14365, delays);
}
if constexpr (timing == VideoTiming::OneTwoEightK) {
constexpr Timings result = {
.cycles_per_line = 228 * 2,
.lines_per_frame = 311,
.contention_leadin = 4 * 2,
.contention_duration = 128 * 2,
.interrupt_time = (1 + 228*311 - 14361 - 4) * 2,
.delays = { // Should start at 14361.
12, 11,
10, 9,
8, 7,
6, 5,
4, 3,
2, 1,
0, 0,
0, 0,
}
};
return result;
constexpr int delays[] = {6, 5, 4, 3, 2, 1, 0, 0};
return Timings(228, 311, 4, 128, 14361, delays);
}
if constexpr (timing == VideoTiming::FortyEightK) {
constexpr Timings result = {
.cycles_per_line = 224 * 2,
.lines_per_frame = 312,
.contention_leadin = 4 * 2,
.contention_duration = 128 * 2,
.interrupt_time = (1 + 224*312 - 14335 - 4) * 2,
.delays = { // Should start at 14335.
12, 11,
10, 9,
8, 7,
6, 5,
4, 3,
2, 1,
0, 0,
0, 0,
}
};
return result;
constexpr int delays[] = {6, 5, 4, 3, 2, 1, 0, 0};
return Timings(224, 312, 4, 128, 14335, delays);
}
}
@ -377,9 +305,10 @@ template <VideoTiming timing> class Video {
@returns How many cycles the [ULA/gate array] would delay the CPU for if it were to recognise that contention
needs to be applied in @c offset half-cycles from now.
*/
int access_delay(HalfCycles offset) const {
HalfCycles access_delay(HalfCycles offset) const {
constexpr auto timings = get_timings();
const int delay_time = (time_into_frame_ + offset.as<int>() + timings.contention_leadin) % (timings.cycles_per_line * timings.lines_per_frame);
assert(!(delay_time&1));
// Check for a time within the no-contention window.
if(delay_time >= (191*timings.cycles_per_line + timings.contention_duration)) {
@ -391,7 +320,7 @@ template <VideoTiming timing> class Video {
return 0;
}
return timings.delays[time_into_line & 15];
return HalfCycles(timings.delays[(time_into_line >> 1) & 7]);
}
/*!

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@ -218,7 +218,7 @@ template<Model model> class ConcreteMachine:
cycle.operation >= PartialMachineCycle::ReadOpcodeStart &&
cycle.operation <= PartialMachineCycle::WriteStart) {
const HalfCycles delay = video_.last_valid()->access_delay(video_.time_since_flush() + HalfCycles(1));
const auto delay = video_.last_valid()->access_delay(video_.time_since_flush());
advance(cycle.length + delay);
return delay;
}
@ -269,7 +269,7 @@ template<Model model> class ConcreteMachine:
// These all start by loading the address bus, then set MREQ
// half a cycle later.
if(is_contended_[address >> 14]) {
const HalfCycles delay = video_.last_valid()->access_delay(video_.time_since_flush());
const auto delay = video_.last_valid()->access_delay(video_.time_since_flush());
advance(cycle.length + delay);
return delay;