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CLK/Storage/Tape/Formats/CSW.cpp
2017-07-17 19:07:05 -04:00

137 lines
3.9 KiB
C++

//
// CSW.cpp
// Clock Signal
//
// Created by Thomas Harte on 10/07/2017.
// Copyright © 2017 Thomas Harte. All rights reserved.
//
#include "CSW.hpp"
using namespace Storage::Tape;
CSW::CSW(const char *file_name) :
Storage::FileHolder(file_name),
source_data_pointer_(0) {
if(file_stats_.st_size < 0x20) throw ErrorNotCSW;
// Check signature.
char identifier[22];
char signature[] = "Compressed Square Wave";
fread(identifier, 1, strlen(signature), file_);
if(memcmp(identifier, signature, strlen(signature))) throw ErrorNotCSW;
// Check terminating byte.
if(fgetc(file_) != 0x1a) throw ErrorNotCSW;
// Get version file number.
uint8_t major_version = (uint8_t)fgetc(file_);
uint8_t minor_version = (uint8_t)fgetc(file_);
// Reject if this is an unknown version.
if(major_version > 2 || !major_version || minor_version > 1) throw ErrorNotCSW;
// The header now diverges based on version.
uint32_t number_of_waves = 0;
if(major_version == 1) {
pulse_.length.clock_rate = fgetc16le();
if(fgetc(file_) != 1) throw ErrorNotCSW;
compression_type_ = RLE;
pulse_.type = (fgetc(file_) & 1) ? Pulse::High : Pulse::Low;
fseek(file_, 0x20, SEEK_SET);
} else {
pulse_.length.clock_rate = fgetc32le();
number_of_waves = fgetc32le();
switch(fgetc(file_)) {
case 1: compression_type_ = RLE; break;
case 2: compression_type_ = ZRLE; break;
default: throw ErrorNotCSW;
}
pulse_.type = (fgetc(file_) & 1) ? Pulse::High : Pulse::Low;
uint8_t extension_length = (uint8_t)fgetc(file_);
if(file_stats_.st_size < 0x34 + extension_length) throw ErrorNotCSW;
fseek(file_, 0x34 + extension_length, SEEK_SET);
}
if(compression_type_ == ZRLE) {
// The only clue given by CSW as to the output size in bytes is that there will be
// number_of_waves waves. Waves are usually one byte, but may be five. So this code
// is pessimistic.
source_data_.resize((size_t)number_of_waves * 5);
std::vector<uint8_t> file_data;
size_t remaining_data = (size_t)file_stats_.st_size - (size_t)ftell(file_);
file_data.resize(remaining_data);
fread(file_data.data(), sizeof(uint8_t), remaining_data, file_);
// uncompress will tell how many compressed bytes there actually were, so use its
// modification of output_length to throw away all the memory that isn't actually
// needed.
uLongf output_length = (uLongf)(number_of_waves * 5);
uncompress(source_data_.data(), &output_length, file_data.data(), file_data.size());
source_data_.resize((size_t)output_length);
} else {
rle_start_ = ftell(file_);
}
invert_pulse();
}
uint8_t CSW::get_next_byte() {
switch(compression_type_) {
case RLE: return (uint8_t)fgetc(file_);
case ZRLE: {
if(source_data_pointer_ == source_data_.size()) return 0xff;
uint8_t result = source_data_[source_data_pointer_];
source_data_pointer_++;
return result;
}
}
}
uint32_t CSW::get_next_int32le() {
switch(compression_type_) {
case RLE: return fgetc32le();
case ZRLE: {
if(source_data_pointer_ > source_data_.size() - 4) return 0xffff;
uint32_t result = (uint32_t)(
(source_data_[source_data_pointer_ + 0] << 0) |
(source_data_[source_data_pointer_ + 1] << 8) |
(source_data_[source_data_pointer_ + 2] << 16) |
(source_data_[source_data_pointer_ + 3] << 24));
source_data_pointer_ += 4;
return result;
}
}
}
void CSW::invert_pulse() {
pulse_.type = (pulse_.type == Pulse::High) ? Pulse::Low : Pulse::High;
}
bool CSW::is_at_end() {
switch(compression_type_) {
case RLE: return (bool)feof(file_);
case ZRLE: return source_data_pointer_ == source_data_.size();
}
}
void CSW::virtual_reset() {
switch(compression_type_) {
case RLE: fseek(file_, rle_start_, SEEK_SET); break;
case ZRLE: source_data_pointer_ = 0; break;
}
}
Tape::Pulse CSW::virtual_get_next_pulse() {
invert_pulse();
pulse_.length.length = get_next_byte();
if(!pulse_.length.length) pulse_.length.length = get_next_int32le();
return pulse_;
}