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CLK/Storage/Tape/Formats/OricTAP.cpp
2021-04-29 18:00:02 -04:00

164 lines
3.6 KiB
C++

//
// OricTAP.cpp
// Clock Signal
//
// Created by Thomas Harte on 10/10/2016.
// Copyright 2016 Thomas Harte. All rights reserved.
//
#include "OricTAP.hpp"
#include <sys/stat.h>
using namespace Storage::Tape;
OricTAP::OricTAP(const std::string &file_name) :
file_(file_name)
{
// Check for a sequence of at least three 0x16s followed by a 0x24.
while(true) {
const uint8_t next = file_.get8();
if(next != 0x16 && next != 0x24) {
throw ErrorNotOricTAP;
}
if(next == 0x24) {
if(file_.tell() < 4) {
throw ErrorNotOricTAP;
}
break;
}
}
// then rewind and start again
virtual_reset();
}
void OricTAP::virtual_reset() {
file_.seek(0, SEEK_SET);
bit_count_ = 13;
phase_ = next_phase_ = LeadIn;
phase_counter_ = 0;
pulse_counter_ = 0;
}
Tape::Pulse OricTAP::virtual_get_next_pulse() {
// Each byte byte is written as 13 bits: 0, eight bits of data, parity, three 1s.
if(bit_count_ == 13) {
if(next_phase_ != phase_) {
phase_ = next_phase_;
phase_counter_ = 0;
}
bit_count_ = 0;
uint8_t next_byte = 0;
switch(phase_) {
case LeadIn:
next_byte = phase_counter_ < 258 ? 0x16 : 0x24;
phase_counter_++;
if(phase_counter_ == 259) { // 256 artificial bytes plus the three in the file = 259
while(1) {
if(file_.get8() != 0x16) break;
}
next_phase_ = Header;
}
break;
case Header:
// Counts are relative to:
// [0, 1]: "two bytes unused" (on the Oric 1)
// 2: program type
// 3: auto indicator
// [4, 5]: end address of data
// [6, 7]: start address of data
// 8: "unused" (on the Oric 1)
// [9...]: filename, up to NULL byte
next_byte = file_.get8();
if(phase_counter_ == 4) data_end_address_ = uint16_t(next_byte << 8);
if(phase_counter_ == 5) data_end_address_ |= next_byte;
if(phase_counter_ == 6) data_start_address_ = uint16_t(next_byte << 8);
if(phase_counter_ == 7) data_start_address_ |= next_byte;
if(phase_counter_ >= 9 && !next_byte) { // advance after the filename-ending NULL byte
next_phase_ = Gap;
}
if(file_.eof()) {
next_phase_ = End;
}
phase_counter_++;
break;
case Gap:
phase_counter_++;
if(phase_counter_ == 8) {
next_phase_ = Data;
}
break;
case Data:
next_byte = file_.get8();
phase_counter_++;
if(phase_counter_ >= (data_end_address_ - data_start_address_)+1) {
if(next_byte == 0x16) {
next_phase_ = LeadIn;
}
else if(file_.eof()) {
next_phase_ = End;
}
}
break;
case End:
break;
}
uint8_t parity = next_byte;
parity ^= (parity >> 4);
parity ^= (parity >> 2);
parity ^= (parity >> 1);
current_value_ = uint16_t((uint16_t(next_byte) << 1) | ((parity&1) << 9) | (7 << 10));
}
// In slow mode, a 0 is 4 periods of 1200 Hz, a 1 is 8 periods at 2400 Hz.
// In fast mode, a 1 is a single period of 2400 Hz, a 0 is a 2400 Hz pulse followed by a 1200 Hz pulse.
// This code models fast mode.
Tape::Pulse pulse;
pulse.length.clock_rate = 4800;
int next_bit;
switch(phase_) {
case End:
pulse.type = Pulse::Zero;
pulse.length.length = 4800;
return pulse;
case Gap:
bit_count_ = 13;
pulse.type = (phase_counter_&1) ? Pulse::Low : Pulse::High;
pulse.length.length = 100;
return pulse;
default:
next_bit = current_value_ & 1;
break;
}
if(next_bit) {
pulse.length.length = 1;
} else {
pulse.length.length = pulse_counter_ ? 2 : 1;
}
pulse.type = pulse_counter_ ? Pulse::High : Pulse::Low; // TODO
pulse_counter_ ^= 1;
if(!pulse_counter_) {
current_value_ >>= 1;
bit_count_++;
}
return pulse;
}
bool OricTAP::is_at_end() {
return phase_ == End;
}