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CLK/Storage/Tape/Formats/TapeUEF.cpp

377 lines
7.6 KiB
C++

//
// TapeUEF.cpp
// Clock Signal
//
// Created by Thomas Harte on 18/01/2016.
// Copyright © 2016 Thomas Harte. All rights reserved.
//
#include "TapeUEF.hpp"
#include <cstring>
#include <cstdio>
#include <cstdlib>
#include <cmath>
#pragma mark - ZLib extensions
static float gzgetfloat(gzFile file)
{
uint8_t bytes[4];
gzread(file, bytes, 4);
/* assume a four byte array named Float exists, where Float[0]
was the first byte read from the UEF, Float[1] the second, etc */
/* decode mantissa */
int mantissa;
mantissa = bytes[0] | (bytes[1] << 8) | ((bytes[2]&0x7f)|0x80) << 16;
float result = (float)mantissa;
result = (float)ldexp(result, -23);
/* decode exponent */
int exponent;
exponent = ((bytes[2]&0x80) >> 7) | (bytes[3]&0x7f) << 1;
exponent -= 127;
result = (float)ldexp(result, exponent);
/* flip sign if necessary */
if(bytes[3]&0x80)
result = -result;
return result;
}
static uint8_t gzget8(gzFile file)
{
// This is a workaround for gzgetc, which seems to be broken in ZLib 1.2.8.
uint8_t result;
gzread(file, &result, 1);
return result;
}
static int gzget16(gzFile file)
{
uint8_t bytes[2];
gzread(file, bytes, 2);
return bytes[0] | (bytes[1] << 8);
}
static int gzget24(gzFile file)
{
uint8_t bytes[3];
gzread(file, bytes, 3);
return bytes[0] | (bytes[1] << 8) | (bytes[2] << 16);
}
static int gzget32(gzFile file)
{
uint8_t bytes[4];
gzread(file, bytes, 4);
return bytes[0] | (bytes[1] << 8) | (bytes[2] << 16) | (bytes[3] << 24);
}
using namespace Storage::Tape;
UEF::UEF(const char *file_name) :
time_base_(1200),
is_at_end_(false),
pulse_pointer_(0),
is_300_baud_(false)
{
file_ = gzopen(file_name, "rb");
char identifier[10];
int bytes_read = gzread(file_, identifier, 10);
if(bytes_read < 10 || strcmp(identifier, "UEF File!"))
{
throw ErrorNotUEF;
}
uint8_t version[2];
gzread(file_, version, 2);
if(version[1] > 0 || version[0] > 10)
{
throw ErrorNotUEF;
}
parse_next_tape_chunk();
}
UEF::~UEF()
{
gzclose(file_);
}
#pragma mark - Public methods
void UEF::virtual_reset()
{
gzseek(file_, 12, SEEK_SET);
is_at_end_ = false;
parse_next_tape_chunk();
}
bool UEF::is_at_end()
{
return is_at_end_;
}
Storage::Tape::Tape::Pulse UEF::virtual_get_next_pulse()
{
Pulse next_pulse;
if(is_at_end_)
{
next_pulse.type = Pulse::Zero;
next_pulse.length.length = time_base_ * 4;
next_pulse.length.clock_rate = time_base_ * 4;
return next_pulse;
}
next_pulse = queued_pulses_[pulse_pointer_];
pulse_pointer_++;
if(pulse_pointer_ == queued_pulses_.size())
{
queued_pulses_.clear();
pulse_pointer_ = 0;
parse_next_tape_chunk();
}
return next_pulse;
}
#pragma mark - Chunk navigator
void UEF::parse_next_tape_chunk()
{
while(queued_pulses_.empty())
{
// read chunk details
uint16_t chunk_id = (uint16_t)gzget16(file_);
uint32_t chunk_length = (uint32_t)gzget32(file_);
// figure out where the next chunk will start
z_off_t start_of_next_chunk = gztell(file_) + chunk_length;
if(gzeof(file_))
{
is_at_end_ = true;
return;
}
switch(chunk_id)
{
case 0x0100: queue_implicit_bit_pattern(chunk_length); break;
case 0x0102: queue_explicit_bit_pattern(chunk_length); break;
case 0x0112: queue_integer_gap(); break;
case 0x0116: queue_floating_point_gap(); break;
case 0x0110: queue_carrier_tone(); break;
case 0x0111: queue_carrier_tone_with_dummy(); break;
case 0x0114: queue_security_cycles(); break;
case 0x0104: queue_defined_data(chunk_length); break;
case 0x0113: // change of base rate
{
// TODO: something smarter than just converting this to an int
float new_time_base = gzgetfloat(file_);
time_base_ = (unsigned int)roundf(new_time_base);
}
break;
case 0x0117:
{
int baud_rate = gzget16(file_);
is_300_baud_ = (baud_rate == 300);
}
break;
default:
printf("!!! Skipping %04x\n", chunk_id);
break;
}
gzseek(file_, start_of_next_chunk, SEEK_SET);
}
}
#pragma mark - Chunk parsers
void UEF::queue_implicit_bit_pattern(uint32_t length)
{
while(length--)
{
queue_implicit_byte(gzget8(file_));
}
}
void UEF::queue_explicit_bit_pattern(uint32_t length)
{
size_t length_in_bits = (length << 3) - (size_t)gzget8(file_);
uint8_t current_byte = 0;
for(size_t bit = 0; bit < length_in_bits; bit++)
{
if(!(bit&7)) current_byte = gzget8(file_);
queue_bit(current_byte&1);
current_byte >>= 1;
}
}
void UEF::queue_integer_gap()
{
Time duration;
duration.length = (unsigned int)gzget16(file_);
duration.clock_rate = time_base_;
queued_pulses_.emplace_back(Pulse::Zero, duration);
}
void UEF::queue_floating_point_gap()
{
float length = gzgetfloat(file_);
Time duration;
duration.length = (unsigned int)(length * 4000000);
duration.clock_rate = 4000000;
queued_pulses_.emplace_back(Pulse::Zero, duration);
}
void UEF::queue_carrier_tone()
{
unsigned int number_of_cycles = (unsigned int)gzget16(file_);
while(number_of_cycles--) queue_bit(1);
}
void UEF::queue_carrier_tone_with_dummy()
{
unsigned int pre_cycles = (unsigned int)gzget16(file_);
unsigned int post_cycles = (unsigned int)gzget16(file_);
while(pre_cycles--) queue_bit(1);
queue_implicit_byte(0xaa);
while(post_cycles--) queue_bit(1);
}
void UEF::queue_security_cycles()
{
int number_of_cycles = gzget24(file_);
bool first_is_pulse = gzget8(file_) == 'P';
bool last_is_pulse = gzget8(file_) == 'P';
uint8_t current_byte = 0;
for(int cycle = 0; cycle < number_of_cycles; cycle++)
{
if(!(cycle&7)) current_byte = gzget8(file_);
int bit = (current_byte >> 7);
current_byte <<= 1;
Time duration;
duration.length = bit ? 1 : 2;
duration.clock_rate = time_base_ * 4;
if(!cycle && first_is_pulse)
{
queued_pulses_.emplace_back(Pulse::High, duration);
}
else if(cycle == number_of_cycles-1 && last_is_pulse)
{
queued_pulses_.emplace_back(Pulse::Low, duration);
}
else
{
queued_pulses_.emplace_back(Pulse::Low, duration);
queued_pulses_.emplace_back(Pulse::High, duration);
}
}
}
void UEF::queue_defined_data(uint32_t length)
{
if(length < 3) return;
int bits_per_packet = gzget8(file_);
char parity_type = (char)gzget8(file_);
int number_of_stop_bits = gzget8(file_);
bool has_extra_stop_wave = (number_of_stop_bits < 0);
number_of_stop_bits = abs(number_of_stop_bits);
length -= 3;
while(length--)
{
uint8_t byte = gzget8(file_);
uint8_t parity_value = byte;
parity_value ^= (parity_value >> 4);
parity_value ^= (parity_value >> 2);
parity_value ^= (parity_value >> 1);
queue_bit(0);
int c = bits_per_packet;
while(c--)
{
queue_bit(byte&1);
byte >>= 1;
}
switch(parity_type)
{
default: break;
case 'E': queue_bit(parity_value&1); break;
case 'O': queue_bit((parity_value&1) ^ 1); break;
}
int stop_bits = number_of_stop_bits;
while(stop_bits--) queue_bit(1);
if(has_extra_stop_wave)
{
Time duration;
duration.length = 1;
duration.clock_rate = time_base_ * 4;
queued_pulses_.emplace_back(Pulse::Low, duration);
queued_pulses_.emplace_back(Pulse::High, duration);
}
}
}
#pragma mark - Queuing helpers
void UEF::queue_implicit_byte(uint8_t byte)
{
queue_bit(0);
int c = 8;
while(c--)
{
queue_bit(byte&1);
byte >>= 1;
}
queue_bit(1);
}
void UEF::queue_bit(int bit)
{
int number_of_cycles;
Time duration;
duration.clock_rate = time_base_ * 4;
if(bit)
{
// encode high-frequency waves
duration.length = 1;
number_of_cycles = 2;
}
else
{
// encode low-frequency waves
duration.length = 2;
number_of_cycles = 1;
}
if(is_300_baud_) number_of_cycles *= 4;
while(number_of_cycles--)
{
queued_pulses_.emplace_back(Pulse::Low, duration);
queued_pulses_.emplace_back(Pulse::High, duration);
}
}