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CLK/Storage/Tape/Parsers/Oric.cpp
2024-01-22 21:22:56 -05:00

169 lines
4.7 KiB
C++

//
// Oric.cpp
// Clock Signal
//
// Created by Thomas Harte on 06/11/2016.
// Copyright 2016 Thomas Harte. All rights reserved.
//
#include "Oric.hpp"
using namespace Storage::Tape::Oric;
int Parser::get_next_byte(const std::shared_ptr<Storage::Tape::Tape> &tape, bool use_fast_encoding) {
detection_mode_ = use_fast_encoding ? FastZero : SlowZero;
cycle_length_ = 0.0f;
int result = 0;
int bit_count = 0;
while(bit_count < 11 && !tape->is_at_end()) {
SymbolType symbol = get_next_symbol(tape);
if(!bit_count && symbol != SymbolType::Zero) continue;
detection_mode_ = use_fast_encoding ? FastData : SlowData;
result |= ((symbol == SymbolType::One) ? 1 : 0) << bit_count;
bit_count++;
}
// TODO: check parity?
return tape->is_at_end() ? -1 : ((result >> 1)&0xff);
}
bool Parser::sync_and_get_encoding_speed(const std::shared_ptr<Storage::Tape::Tape> &tape) {
detection_mode_ = Sync;
while(!tape->is_at_end()) {
const SymbolType symbol = get_next_symbol(tape);
switch(symbol) {
case SymbolType::FoundSlow: return false;
case SymbolType::FoundFast: return true;
default: break;
}
}
return false;
}
void Parser::process_pulse(const Storage::Tape::Tape::Pulse &pulse) {
constexpr float maximum_short_length = 0.000512f;
constexpr float maximum_medium_length = 0.000728f;
constexpr float maximum_long_length = 0.001456f;
const bool wave_is_high = pulse.type == Storage::Tape::Tape::Pulse::High;
if(!wave_was_high_ && wave_is_high != wave_was_high_) {
if(cycle_length_ < maximum_short_length) push_wave(WaveType::Short);
else if(cycle_length_ < maximum_medium_length) push_wave(WaveType::Medium);
else if(cycle_length_ < maximum_long_length) push_wave(WaveType::Long);
else push_wave(WaveType::Unrecognised);
cycle_length_ = 0.0f;
}
wave_was_high_ = wave_is_high;
cycle_length_ += pulse.length.get<float>();
}
void Parser::inspect_waves(const std::vector<WaveType> &waves) {
switch(detection_mode_) {
case FastZero:
if(waves.empty()) return;
if(waves[0] == WaveType::Medium) {
push_symbol(SymbolType::Zero, 1);
return;
}
break;
case FastData:
if(waves.empty()) return;
if(waves[0] == WaveType::Medium) {
push_symbol(SymbolType::Zero, 1);
return;
}
if(waves[0] == WaveType::Short) {
push_symbol(SymbolType::One, 1);
return;
}
break;
case SlowZero:
if(waves.size() < 4) return;
if(waves[0] == WaveType::Long && waves[1] == WaveType::Long && waves[2] == WaveType::Long && waves[3] == WaveType::Long) {
push_symbol(SymbolType::Zero, 4);
return;
}
break;
case SlowData: {
const auto check_run = [&](std::size_t length, WaveType type, SymbolType symbol) -> bool {
if(waves.size() >= length) {
std::size_t c;
for(c = 0; c < length; c++) if(waves[c] != type) break;
if(c == length) {
push_symbol(symbol, int(length));
return true;
}
}
return false;
};
if(check_run(4, WaveType::Long, SymbolType::Zero)) return;
if(check_run(8, WaveType::Short, SymbolType::One)) return;
if(waves.size() < 16) return; // TODO, maybe: if there are any inconsistencies in the first 8, don't return
} break;
case Sync: {
// Sync is 0x16, either encoded fast or slow; i.e. 0 0110 1000 1
const Pattern slow_sync[] = {
{WaveType::Long, 8},
{WaveType::Short, 16},
{WaveType::Long, 4},
{WaveType::Short, 8},
{WaveType::Long, 12},
{WaveType::Short, 8},
{WaveType::Unrecognised}
};
const Pattern fast_sync[] = {
{WaveType::Medium, 2},
{WaveType::Short, 2},
{WaveType::Medium, 1},
{WaveType::Short, 1},
{WaveType::Medium, 3},
{WaveType::Short, 1},
{WaveType::Unrecognised}
};
std::size_t slow_sync_matching_depth = pattern_matching_depth(waves, slow_sync);
std::size_t fast_sync_matching_depth = pattern_matching_depth(waves, fast_sync);
if(slow_sync_matching_depth == 52) {
push_symbol(SymbolType::FoundSlow, 52);
return;
}
if(fast_sync_matching_depth == 10) {
push_symbol(SymbolType::FoundFast, 10);
return;
}
if(slow_sync_matching_depth < waves.size() && fast_sync_matching_depth < waves.size()) {
int least_depth = int(std::min(slow_sync_matching_depth, fast_sync_matching_depth));
remove_waves(least_depth ? least_depth : 1);
}
return;
}
break;
}
remove_waves(1);
}
std::size_t Parser::pattern_matching_depth(const std::vector<WaveType> &waves, const Pattern *pattern) {
std::size_t depth = 0;
int pattern_depth = 0;
while(depth < waves.size() && pattern->type != WaveType::Unrecognised) {
if(waves[depth] != pattern->type) break;
depth++;
pattern_depth++;
if(pattern_depth == pattern->count) {
pattern_depth = 0;
pattern++;
}
}
return depth;
}