1
0
mirror of https://github.com/TomHarte/CLK.git synced 2024-11-30 04:50:08 +00:00
CLK/Storage/Tape/Formats/TapePRG.cpp

240 lines
6.2 KiB
C++
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

//
// TapePRG.cpp
// Clock Signal
//
// Created by Thomas Harte on 14/08/2016.
// Copyright © 2016 Thomas Harte. All rights reserved.
//
#include "TapePRG.hpp"
/*
My interpretation of Commodore's tape format is such that a PRG is encoded as:
[long block of lead-in tone]
[short block of lead-in tone]
[count down][header; 192 bytes fixed length]
[short block of lead-in tone]
[count down][copy of header; 192 bytes fixed length]
[gap]
[short block of lead-in tone]
[count down][data; length as in file]
[short block of lead-in tone]
[count down][copy of data]
... and repeat ...
Individual bytes are composed of:
word marker
least significant bit
...
most significant bit
parity bit
Both the header and data blocks additionally end with an end-of-block marker.
Encoding is via square-wave cycles of four lengths, in ascending order: lead-in, zero, one, marker.
Lead-in tone is always just repetitions of the lead-in wave.
A word marker is a marker wave followed by a one wave.
An end-of-block marker is a marker wave followed by a zero wave.
A zero bit is a zero wave followed by a one wave.
A one bit is a one wave followed by a zero wave.
Parity is 1 if there are an even number of bits in the byte; 0 otherwise.
*/
#include <sys/stat.h>
using namespace Storage::Tape;
PRG::PRG(const char *file_name) :
bit_phase_(3),
file_phase_(FilePhaseLeadIn),
phase_offset_(0),
copy_mask_(0x80),
Storage::FileHolder(file_name)
{
// There's really no way to validate other than that if this file is larger than 64kb,
// of if load address + length > 65536 then it's broken.
if(file_stats_.st_size >= 65538 || file_stats_.st_size < 3)
throw ErrorBadFormat;
load_address_ = fgetc16le();
length_ = (uint16_t)(file_stats_.st_size - 2);
if (load_address_ + length_ >= 65536)
throw ErrorBadFormat;
}
Storage::Tape::Tape::Pulse PRG::virtual_get_next_pulse()
{
// these are all microseconds per pole
static const unsigned int leader_zero_length = 179;
static const unsigned int zero_length = 169;
static const unsigned int one_length = 247;
static const unsigned int marker_length = 328;
bit_phase_ = (bit_phase_+1)&3;
if(!bit_phase_) get_next_output_token();
Tape::Pulse pulse;
pulse.length.clock_rate = 1000000;
pulse.type = (bit_phase_&1) ? Tape::Pulse::High : Tape::Pulse::Low;
switch(output_token_)
{
case Leader: pulse.length.length = leader_zero_length; break;
case Zero: pulse.length.length = (bit_phase_&2) ? one_length : zero_length; break;
case One: pulse.length.length = (bit_phase_&2) ? zero_length : one_length; break;
case WordMarker: pulse.length.length = (bit_phase_&2) ? one_length : marker_length; break;
case EndOfBlock: pulse.length.length = (bit_phase_&2) ? zero_length : marker_length; break;
case Silence: pulse.type = Tape::Pulse::Zero; pulse.length.length = 5000; break;
}
return pulse;
}
void PRG::virtual_reset()
{
bit_phase_ = 3;
fseek(file_, 2, SEEK_SET);
file_phase_ = FilePhaseLeadIn;
phase_offset_ = 0;
copy_mask_ = 0x80;
}
bool PRG::is_at_end()
{
return file_phase_ == FilePhaseAtEnd;
}
void PRG::get_next_output_token()
{
static const int block_length = 192; // not counting the checksum
static const int countdown_bytes = 9;
static const int leadin_length = 20000;
static const int block_leadin_length = 5000;
if(file_phase_ == FilePhaseHeaderDataGap || file_phase_ == FilePhaseAtEnd)
{
output_token_ = Silence;
if(file_phase_ != FilePhaseAtEnd) file_phase_ = FilePhaseData;
return;
}
// the lead-in is 20,000 instances of the lead-in pair; every other phase begins with 5000
// before doing whatever it should be doing
if(file_phase_ == FilePhaseLeadIn || phase_offset_ < block_leadin_length)
{
output_token_ = Leader;
phase_offset_++;
if(file_phase_ == FilePhaseLeadIn && phase_offset_ == leadin_length)
{
phase_offset_ = 0;
file_phase_ = (file_phase_ == FilePhaseLeadIn) ? FilePhaseHeader : FilePhaseData;
}
return;
}
// determine whether a new byte needs to be queued up
int block_offset = phase_offset_ - block_leadin_length;
int bit_offset = block_offset % 10;
int byte_offset = block_offset / 10;
phase_offset_++;
if(!bit_offset &&
(
(file_phase_ == FilePhaseHeader && byte_offset == block_length + countdown_bytes + 1) ||
feof(file_)
)
)
{
output_token_ = EndOfBlock;
phase_offset_ = 0;
switch(file_phase_)
{
default: break;
case FilePhaseHeader:
copy_mask_ ^= 0x80;
if(copy_mask_) file_phase_ = FilePhaseHeaderDataGap;
break;
case FilePhaseData:
copy_mask_ ^= 0x80;
fseek(file_, 2, SEEK_SET);
if(copy_mask_) file_phase_ = FilePhaseAtEnd;
break;
}
return;
}
if(bit_offset == 0)
{
// the first nine bytes are countdown; the high bit is set if this is a header
if(byte_offset < countdown_bytes)
{
output_byte_ = (uint8_t)(countdown_bytes - byte_offset) | copy_mask_;
}
else
{
if(file_phase_ == FilePhaseHeader)
{
if(byte_offset == countdown_bytes + block_length)
{
output_byte_ = check_digit_;
}
else
{
if(byte_offset == countdown_bytes) check_digit_ = 0;
if(file_phase_ == FilePhaseHeader)
{
switch(byte_offset - countdown_bytes)
{
case 0: output_byte_ = 0x03; break;
case 1: output_byte_ = load_address_ & 0xff; break;
case 2: output_byte_ = (load_address_ >> 8)&0xff; break;
case 3: output_byte_ = (load_address_ + length_) & 0xff; break;
case 4: output_byte_ = ((load_address_ + length_) >> 8) & 0xff; break;
case 5: output_byte_ = 0x50; break; // P
case 6: output_byte_ = 0x52; break; // R
case 7: output_byte_ = 0x47; break; // G
default:
output_byte_ = 0x20;
break;
}
}
}
}
else
{
output_byte_ = (uint8_t)fgetc(file_);
if(feof(file_))
{
output_byte_ = check_digit_;
}
}
check_digit_ ^= output_byte_;
}
}
switch(bit_offset)
{
case 0:
output_token_ = WordMarker;
break;
default: // i.e. 18
output_token_ = (output_byte_ & (1 << (bit_offset - 1))) ? One : Zero;
break;
case 9:
{
uint8_t parity = output_byte_;
parity ^= (parity >> 4);
parity ^= (parity >> 2);
parity ^= (parity >> 1);
output_token_ = (parity&1) ? Zero : One;
}
break;
}
}