fluxengine/arch/c64/encoder.cc

#include "globals.h"
#include "decoders/decoders.h"
#include "encoders/encoders.h"
#include "c64.h"
#include "crc.h"
#include "sector.h"
#include "writer.h"
#include "image.h"
#include "fmt/format.h"
#include "arch/c64/c64.pb.h"
#include "lib/encoders/encoders.pb.h"
#include <ctype.h>
#include "bytes.h"

static bool lastBit;

static double clockRateUsForTrack(unsigned track)
{
    /*
     * Track   # Sectors/Track Speed Zone  bits/rotation       
     * 1 – 17          21          3       61,538.4
     * 18 – 24         19          2       57,142.8
     * 25 – 30         18          1       53,333.4
     * 31 – 35         17          0       50,000.0
    */
    if (track < 17)
        return 200000.0/61538.4;
    if (track < 24)
        return 200000.0/57142.8;
    if (track < 30)
        return 200000.0/53333.4;
    return 200000.0/50000.0;

}

static unsigned sectorsForTrack(unsigned track)
{
    /*
     * Track   Sectors/track   # Sectors   Storage in Bytes
     *   -----   -------------   ---------   ----------------
     *    1-17        21            357           7820
     *   18-24        19            133           7170
     *   25-30        18            108           6300
     *   31-40(*)     17             85           6020
     *                              ---
     *                              683 (for a 35 track image)
     */
    if (track < 17)
        return 21;
    if (track < 24)
        return 19;
    if (track < 30)
        return 18;
    return 17;
}

static int encode_data_gcr(uint8_t data)
{
    switch (data)
    {
        #define GCR_ENTRY(gcr, data) \
            case data: return gcr;
        #include "data_gcr.h"
        #undef GCR_ENTRY
    }
    return -1;
}

static void write_bits(std::vector<bool>& bits, unsigned& cursor, const std::vector<bool>& src)
{
    for (bool bit : src)  //Range-based for loop
    {
        if (cursor < bits.size())
            bits[cursor++] = bit;
    }
}

static void write_bits(std::vector<bool>& bits, unsigned& cursor, uint64_t data, int width)
{
    cursor += width;
    for (int i=0; i<width; i++)
    {
        unsigned pos = cursor - i - 1;              
        if (pos < bits.size())
            bits[pos] = data & 1;
        data >>= 1;
    }
}

void bindump(std::ostream& stream, std::vector<bool>& buffer)
{
    size_t pos = 0;

    while ((pos < buffer.size()) and (pos <520))
    {
        stream << fmt::format("{:5d} : ", pos);
        for (int i=0; i<40; i++)
        {
            if ((pos+i) < buffer.size())
                stream << fmt::format("{:01b}", (buffer[pos+i]));
            else
                stream << "-- ";
            if ((((pos + i + 1) % 8) == 0) and i != 0)
                stream << "  ";

        }
        stream << std::endl;
        pos += 40;
    }
}
static std::vector<bool> encode_data(uint8_t input)
{
    /*
    * Four 8-bit data bytes are converted to four 10-bit GCR bytes at a time by
    * the 1541 DOS.  RAM is only an 8-bit storage device though. This hardware
    * limitation prevents a 10-bit GCR byte from being stored in a single
    * memory location. Four 10-bit GCR bytes total 40 bits - a number evenly
    * divisible by our overriding 8-bit constraint. Commodore sub- divides the
    * 40 GCR bits into five 8-bit bytes to solve this dilemma. This explains
    * why four 8-bit data bytes are converted to GCR form at a time. The
    * following step by step example demonstrates how this bit manipulation is
    * performed by the DOS.
    *
    * STEP 1. Four 8-bit Data Bytes
    * $08 $10 $00 $12
    *
    * STEP 2. Hexadecimal to Binary Conversion
    * 1. Binary Equivalents
    * $08       $10         $00         $12
    * 00001000  00010000    00000000    00010010
    *
    * STEP 3. Binary to GCR Conversion
    * 1. Four 8-bit Data Bytes
    * 00001000 00010000 00000000 00010010
    * 2. High and Low Nybbles
    * 0000 1000 0001 0000 0000 0000 0001 0010
    * 3. High and Low Nybble GCR Equivalents
    * 01010 01001 01011 01010 01010 01010 01011 10010
    * 4. Four 10-bit GCR Bytes
    * 0101001001 0101101010 0101001010 0101110010
    *
    * STEP 4. 10-bit GCR to 8-bit GCR Conversion
    *   1. Concatenate Four 10-bit GCR Bytes
    *   0101001001010110101001010010100101110010
    *   2. Five 8-bit Subdivisions
    *   01010010 01010110 10100101 00101001 01110010
    *
    * STEP 5. Binary to Hexadecimal Conversion
    * 1. Hexadecimal Equivalents
    *   01010010    01010110    10100101    00101001    01110010
    *   $52         $56         $A5         $29         $72
    *
    * STEP 6. Four 8-bit Data Bytes are Recorded as Five 8-bit GCR Bytes
    *   $08 $10 $00 $12
    *
    * are recorded as
    *   $52 $56 $A5 $29 $72
    */

    std::vector<bool> output(10, false);
    uint8_t hi = 0;
    uint8_t lo = 0;
    uint8_t lo_GCR = 0;
    uint8_t hi_GCR = 0;

    //Convert the byte in high and low nibble
    lo = input >> 4; //get the lo nibble shift the bits 4 to the right          
    hi = input & 15; //get the hi nibble bij masking the lo bits (00001111)     


    lo_GCR = encode_data_gcr(lo);   //example value: 0000   GCR = 01010
    hi_GCR = encode_data_gcr(hi);   //example value: 1000   GCR = 01001
    //output = [0,1,2,3,4,5,6,7,8,9]
    //value  = [0,1,0,1,0,0,1,0,0,1]
    //          01010 01001

    int b = 4;
    for (int i = 0; i < 10; i++)
    {
        if (i < 5) //01234
        {       //i = 0 op 
            output[4-i] = (lo_GCR & 1); //01010

            //01010 -> & 00001 -> 00000 output[4] = 0
            //00101 -> & 00001 -> 00001 output[3] = 1
            //00010 -> & 00001 -> 00000 output[2] = 0
            //00001 -> & 00001 -> 00001 output[1] = 1
            //00000 -> & 00001 -> 00000 output[0] = 0
            lo_GCR >>= 1;
        } else  
        {
            output[i+b] = (hi_GCR & 1); //01001
            //01001 -> & 00001 -> 00001 output[9] = 1
            //00100 -> & 00001 -> 00000 output[8] = 0
            //00010 -> & 00001 -> 00000 output[7] = 0
            //00001 -> & 00001 -> 00001 output[6] = 1
            //00000 -> & 00001 -> 00000 output[5] = 0
            hi_GCR >>= 1;
            b = b-2;
        }
    }
    return output;
}

class Commodore64Encoder : public AbstractEncoder
{
public:
	Commodore64Encoder(const EncoderProto& config):
        AbstractEncoder(config),
		_config(config.c64())
	{}

public:
	std::vector<std::shared_ptr<const Sector>> collectSectors(const Location& location, const Image& image) override
	{
		std::vector<std::shared_ptr<const Sector>> sectors;

        if (location.head == 0)
        {
            unsigned numSectors = sectorsForTrack(location.logicalTrack);
            for (int sectorId=0; sectorId<numSectors; sectorId++)
            {
                const auto& sector = image.get(location.logicalTrack, 0, sectorId);
                if (sector)
                    sectors.push_back(sector);
            }
        }

		return sectors;
	}

    std::unique_ptr<Fluxmap> encode(const Location& location,
            const std::vector<std::shared_ptr<const Sector>>& sectors, const Image& image) override
    {
        /* The format ID Character # 1 and # 2 are in the .d64 image only present
         * in track 18 sector zero which contains the BAM info in byte 162 and 163.
         * it is written in every header of every sector and track. headers are not
         * stored in a d64 disk image so we have to get it from track 18 which
         * contains the BAM.
        */

        const auto& sectorData = image.get(C64_BAM_TRACK*2, 0, 0); //Read de BAM to get the DISK ID bytes
        if (sectorData)
        {
            ByteReader br(sectorData->data);
            br.seek(162); //goto position of the first Disk ID Byte
            _formatByte1 = br.read_8();
            _formatByte2 = br.read_8();
        }
        else
            _formatByte1 = _formatByte2 = 0;
        
        double clockRateUs = clockRateUsForTrack(location.logicalTrack) * _config.clock_compensation_factor();

        int bitsPerRevolution = 200000.0 / clockRateUs;

        std::vector<bool> bits(bitsPerRevolution);
        unsigned cursor = 0;

        fillBitmapTo(bits, cursor, _config.post_index_gap_us() / clockRateUs, { true, false });
        lastBit = false;

        for (const auto& sector : sectors)
            writeSector(bits, cursor, sector);

        if (cursor >= bits.size())
            Error() << fmt::format("track data overrun by {} bits", cursor - bits.size());
        fillBitmapTo(bits, cursor, bits.size(), { true, false });

        std::unique_ptr<Fluxmap> fluxmap(new Fluxmap);
        fluxmap->appendBits(bits, clockRateUs*1e3);
        return fluxmap;
    }

private:
	void writeSector(std::vector<bool>& bits, unsigned& cursor, std::shared_ptr<const Sector> sector) const
    {
        /* Source: http://www.unusedino.de/ec64/technical/formats/g64.html 
         * 1. Header sync       FF FF FF FF FF (40 'on' bits, not GCR)
         * 2. Header info       52 54 B5 29 4B 7A 5E 95 55 55 (10 GCR bytes)
         * 3. Header gap        55 55 55 55 55 55 55 55 55 (9 bytes, never read)
         * 4. Data sync         FF FF FF FF FF (40 'on' bits, not GCR)
         * 5. Data block        55...4A (325 GCR bytes)
         * 6. Inter-sector gap  55 55 55 55...55 55 (4 to 12 bytes, never read)
         * 1. Header sync       (SYNC for the next sector)
        */
        if ((sector->status == Sector::OK) or (sector->status == Sector::BAD_CHECKSUM))
        {
            // There is data to encode to disk.
            if ((sector->data.size() != C64_SECTOR_LENGTH))
                Error() << fmt::format("unsupported sector size {} --- you must pick 256", sector->data.size());    

            // 1. Write header Sync (not GCR)
            for (int i=0; i<6; i++)
                write_bits(bits, cursor, C64_HEADER_DATA_SYNC, 1*8); /* sync */

            // 2. Write Header info 10 GCR bytes
            /*
             * The 10 byte header info (#2) is GCR encoded and must be decoded  to
             * it's normal 8 bytes to be understood. Once decoded, its breakdown is
             * as follows:
             * 
             * Byte $00 - header block ID           ($08)
             *   01 - header block checksum 16  (EOR of $02-$05)
             *   02 - Sector
             *   03 - Track
             *   04 - Format ID byte #2
             *   05 - Format ID byte #1
             *   06-07 - $0F ("off" bytes)
             */
            uint8_t encodedTrack = ((sector->logicalTrack) + 1); // C64 track numbering starts with 1. Fluxengine with 0.
            uint8_t encodedSector = sector->logicalSector;
            // uint8_t formatByte1 = C64_FORMAT_ID_BYTE1;
            // uint8_t formatByte2 = C64_FORMAT_ID_BYTE2;
            uint8_t headerChecksum = (encodedTrack ^ encodedSector ^ _formatByte1 ^ _formatByte2);
            write_bits(bits, cursor, encode_data(C64_HEADER_BLOCK_ID));
            write_bits(bits, cursor, encode_data(headerChecksum));
            write_bits(bits, cursor, encode_data(encodedSector));
            write_bits(bits, cursor, encode_data(encodedTrack));
            write_bits(bits, cursor, encode_data(_formatByte2));
            write_bits(bits, cursor, encode_data(_formatByte1));
            write_bits(bits, cursor, encode_data(C64_PADDING));
            write_bits(bits, cursor, encode_data(C64_PADDING));

            // 3. Write header GAP not GCR
            for (int i=0; i<9; i++)
                write_bits(bits, cursor, C64_HEADER_GAP, 1*8); /* header gap */

            // 4. Write Data sync not GCR
            for (int i=0; i<6; i++)
                write_bits(bits, cursor, C64_HEADER_DATA_SYNC, 1*8); /* sync */

            // 5. Write data block 325 GCR bytes
            /*
             * The 325 byte data block (#5) is GCR encoded and must be  decoded  to  its
             * normal 260 bytes to be understood. The data block is made up of the following:
             * 
             * Byte    $00 - data block ID ($07)
             *      01-100 - 256 bytes data
             *      101 - data block checksum (EOR of $01-100)
             *      102-103 - $00 ("off" bytes, to make the sector size a multiple of 5)
             */

            write_bits(bits, cursor, encode_data(C64_DATA_BLOCK_ID));
            uint8_t dataChecksum = xorBytes(sector->data);
            ByteReader br(sector->data);
            int i = 0;
            for (i = 0; i < C64_SECTOR_LENGTH; i++)
            {
                uint8_t val = br.read_8();
                write_bits(bits, cursor, encode_data(val));     
            }
            write_bits(bits, cursor, encode_data(dataChecksum));
            write_bits(bits, cursor, encode_data(C64_PADDING));
            write_bits(bits, cursor, encode_data(C64_PADDING));

            //6. Write inter-sector gap 9 - 12 bytes nor gcr
            for (int i=0; i<9; i++)
                write_bits(bits, cursor, C64_INTER_SECTOR_GAP, 1*8); /* sync */

        }
    }
        
private:
	const Commodore64EncoderProto& _config;
	uint8_t _formatByte1;
	uint8_t _formatByte2;
};

std::unique_ptr<AbstractEncoder> createCommodore64Encoder(const EncoderProto& config)
{
	return std::unique_ptr<AbstractEncoder>(new Commodore64Encoder(config));
}

// vim: sw=4 ts=4 et