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CLK/Components/9918/Implementation/ClockConverter.hpp
2023-05-19 14:22:22 -04:00

169 lines
5.6 KiB
C++

//
// ClockConverter.hpp
// Clock Signal
//
// Created by Thomas Harte on 01/01/2023.
// Copyright © 2023 Thomas Harte. All rights reserved.
//
#ifndef ClockConverter_hpp
#define ClockConverter_hpp
#include "../9918.hpp"
#include "PersonalityTraits.hpp"
#include "LineLayout.hpp"
namespace TI::TMS {
enum class Clock {
/// Whatever rate this VDP runs at, with location 0 being "the start" of the line per internal preference.
Internal,
/// A 342-cycle/line clock with the same start position as ::Internal.
TMSPixel,
/// A 171-cycle/line clock that begins at the memory window which starts straight after ::Internal = 0.
TMSMemoryWindow,
/// A fixed 1368-cycle/line clock that is used to count output to the CRT.
CRT,
/// Provides the same clock rate as ::Internal but is relocated so that 0 is the start of horizontal sync — very not coincidentally,
/// where Grauw puts 0 on his detailed TMS and Yamaha timing diagrams.
FromStartOfSync,
};
template <Personality personality, Clock clk> constexpr int clock_rate() {
static_assert(
is_classic_vdp(personality) ||
is_yamaha_vdp(personality) ||
(personality == Personality::MDVDP)
);
switch(clk) {
case Clock::TMSPixel: return 342;
case Clock::TMSMemoryWindow: return 171;
case Clock::CRT: return 1368;
case Clock::Internal:
case Clock::FromStartOfSync:
if constexpr (is_classic_vdp(personality)) {
return 342;
} else if constexpr (is_yamaha_vdp(personality)) {
return 1368;
} else if constexpr (personality == Personality::MDVDP) {
return 3420;
}
}
}
/// Statelessly converts @c length to the internal clock for @c personality; applies conversions per the list of clocks in left-to-right order.
template <Personality personality, Clock head, Clock... tail> constexpr int to_internal(int length) {
if constexpr (head == Clock::FromStartOfSync) {
length = (length + LineLayout<personality>::StartOfSync) % LineLayout<personality>::CyclesPerLine;
} else {
length = length * clock_rate<personality, Clock::Internal>() / clock_rate<personality, head>();
}
if constexpr (!sizeof...(tail)) {
return length;
} else {
return to_internal<personality, tail...>(length);
}
}
/// Statelessly converts @c length to @c clock from the the internal clock used by VDPs of @c personality throwing away any remainder.
template <Personality personality, Clock head, Clock... tail> constexpr int from_internal(int length) {
if constexpr (head == Clock::FromStartOfSync) {
length =
(length + LineLayout<personality>::CyclesPerLine - LineLayout<personality>::StartOfSync)
% LineLayout<personality>::CyclesPerLine;
} else {
length = length * clock_rate<personality, head>() / clock_rate<personality, Clock::Internal>();
}
if constexpr (!sizeof...(tail)) {
return length;
} else {
return to_internal<personality, tail...>(length);
}
}
/*!
Provides a [potentially-]stateful conversion between the external and internal clocks.
Unlike the other clock conversions, this may be non-integral, requiring that
an error term be tracked.
*/
template <Personality personality> class ClockConverter {
public:
/*!
Given that another @c source external **half-cycles** has occurred,
indicates how many complete internal **cycles** have additionally elapsed
since the last call to @c to_internal.
E.g. for the TMS, @c source will count 456 ticks per line, and the internal clock
runs at 342 ticks per line, so the proper conversion is to multiply by 3/4.
*/
int to_internal(int source) {
switch(personality) {
// Default behaviour is to apply a multiplication by 3/4;
// this is correct for the TMS and Sega VDPs other than the Mega Drive.
default: {
const int result = source * 3 + cycles_error_;
cycles_error_ = result & 3;
return result >> 2;
}
// The two Yamaha chips have an internal clock that is four times
// as fast as the TMS, therefore a stateless translation is possible.
case Personality::V9938:
case Personality::V9958:
return source * 3;
// The Mega Drive runs at 3420 master clocks per line, which is then
// divided by 4 or 5 depending on other state. That's 7 times the
// rate provided to the CPU; given that the input is in half-cycles
// the proper multiplier is therefore 3.5.
case Personality::MDVDP: {
const int result = source * 7 + cycles_error_;
cycles_error_ = result & 1;
return result >> 1;
}
}
}
/*!
Provides the number of external cycles that need to begin from now in order to
get at least @c internal_cycles into the future.
*/
HalfCycles half_cycles_before_internal_cycles(int internal_cycles) const {
// Logic here correlates with multipliers as per @c to_internal.
switch(personality) {
default:
// Relative to the external clock multiplied by 3, it will definitely take this
// many cycles to complete a further (internal_cycles - 1) after the current one.
internal_cycles = (internal_cycles - 1) << 2;
// It will also be necessary to complete the current one.
internal_cycles += 4 - cycles_error_;
// Round up to get the first external cycle after
// the number of internal_cycles has elapsed.
return HalfCycles((internal_cycles + 2) / 3);
case Personality::V9938:
case Personality::V9958:
return HalfCycles((internal_cycles + 2) / 3);
case Personality::MDVDP:
internal_cycles = (internal_cycles - 1) << 1;
internal_cycles += 2 - cycles_error_;
return HalfCycles((internal_cycles + 6) / 7);
}
}
private:
// Holds current residue in conversion from the external to
// internal clock.
int cycles_error_ = 0;
};
}
#endif /* ClockConverter_hpp */