videochargen/frame.cpp

/**
 * @file frame.cpp
 * @author giomba@glgprograms.it
 * @brief Transform a black and white PNM image into the assembly code for the video generator.
 *
 * Takes a black/white (1bpp) PNM ASCII-armored image as input,
 * and produces the frame.S assembly code to draw it
 * as an analog video signal for this project's kernel.
 *
 * @copyright Copyright retrofficina.glgprograms.it (c) 2021-2022
 *
 */

#include <iostream>
#include <fstream>
#include <sstream>
#include <cstring>
#include <spdlog/spdlog.h>

enum ExitStatus
{
    BAD_ARGUMENT = 1,
    FILE_NOT_OPEN = 2,
    FILE_BAD_FORMAT = 3
};

int main(int argc, char **argv)
{
    // enable debug messages
    spdlog::set_level(spdlog::level::debug);

    // arguments parsing and sanity check
    if (argc < 2)
    {
        spdlog::error("Usage: {} <FILE> ...", argv[0]);
        return BAD_ARGUMENT;
    }
    const int images = argc - 1;

    // Output assembly file content.
    // Content is buffered into these stringstreams,
    // and then dumped to a file on disk.
    // Code is organized into two parts.
    std::stringstream jump_table; // Assembly jump table for images.
                                  // Each image is described by a jump table with 256 entries.
                                  // Each entry is a jump to the code to produce a particular line on the screen.
    std::stringstream asm_code;   // Assembly code to describe lines.
                                  // Each line is a sequence of a set and/or clear bit,
                                  // conveniently timed to mangle the video signal at the right moment.

    // Output file.
    std::fstream outfile;
    outfile.open("frame.S", std::ios::out);
    if (!outfile)
        return FILE_NOT_OPEN;

    // include headers
    jump_table << "#include \"macro.h\"" << std::endl;
    jump_table << "#include <avr/io.h>" << std::endl;

    // Pointer to images
    char **image = new char *[images];

    // Parse images and convert in assembly code
    for (int current_image = 0; current_image < images; ++current_image)
    {
        std::fstream infile;

        infile.open(argv[1 + current_image], std::ios::in);
        if (!infile)
            return FILE_NOT_OPEN;

        unsigned int width, height; // width and height of image
        std::string format;         // image format
        char c;                     // current pixel

        getline(infile, format);
        spdlog::debug("format: {}", format);
        if (format != "P1")
            return FILE_BAD_FORMAT;

        // skip commented line / TODO in a proper way
        getline(infile, format);
        spdlog::debug("comment: {}", format);

        // read width and height
        infile >> width >> height;
        spdlog::debug("width x height = {} x {}", width, height);

        // read full image from disk into memory
        // in an organized row by column array
        image[current_image] = new char[height * width];
        for (int y = 0; y < height;)
        {
            for (int x = 0; x < width;)
            {
                c = infile.get();

                // file is truncated
                if (!infile.good())
                    return FILE_BAD_FORMAT;

                // if current character represents a pixel, add to array...
                if (c == '0' || c == '1')
                {
                    image[current_image][y * width + x] = c;
                    x++;
                }
                else // ... else ignore current char
                    continue;
            }
            y++;
        }
        infile.close();

        // add new jump table for current image
        jump_table << ".global line_jump_table_" << current_image << std::endl;
        jump_table << "line_jump_table_" << current_image << ":" << std::endl;

        // Inspect each line one by one
        for (int y = 0; y < height; ++y)
        {
            int diff = 1;

            // Check if one of the previously inspected images has an identical line.
            // If it has an identical line, just add it in the current image jump table,
            // instead of generating again an identical assembly code.
            // This allows us to save a lot of program memory space.
            // Note: previous lines of current image are good candidates to check too!
            for (int other_image = 0; other_image <= current_image; ++other_image)
            {
                for (int other_y = 0; other_y < height && other_y < y; ++other_y)
                {
                    diff = memcmp(&(image[current_image][y * width + 0]), &(image[other_image][other_y * width + 0]), width);
                    if (diff == 0)
                    {
                        jump_table << '\t' << "jmp line_" << other_image << "_" << other_y << std::endl;
                        goto nested_loop_end;
                    }
                }
            }

        nested_loop_end:

            // Current line has already been found to be identical
            // to one of the previous ones: then skip to next one.
            if (diff == 0)
                continue;

            // Add jump in the current image table.
            jump_table << '\t' << "jmp line_" << current_image << "_" << y << std::endl;

            // Add line description.
            asm_code << "line_" << current_image << "_" << y << ":" << std::endl;

            // Line description is a sequence of assembly code conveniently built
            // in order to set/clear an output port bit at the right moment,
            // and mangle the video signal in order to display the desired image.
            // Code simulates an RLE scheme, exploting small conveniently timed loops,
            // in order to save program space.
            int count = 0;
            char last = image[current_image][y * width + 0];

            for (int x = 0; x < width; ++x)
            {
                char current = image[current_image][y * width + x];
                // If current pixel is the same as previous one,
                // then just count++
                if (current == last)
                    ++count;
                else // current pixel is different from previous one
                {
                    // Each pixel is 4 clock cycles long,
                    // because It Just Works out perfectly with the instruction set.

                    // Two clock cycles are spent to set/clear the output port.
                    if (last == '0')
                    {
                        asm_code << '\t' << "cbi IO(PORTB), 4" << std::endl; // +2
                    }
                    else if (last == '1')
                    {
                        asm_code << '\t' << "sbi IO(PORTB), 4" << std::endl; // +2
                    }

                    // Loop is entered only if RLE is needed,
                    // eg. at least 2 subsequent pixels of the same color.
                    if (count > 1)
                    {                                                              // clock cycles
                        asm_code << '\t' << "ldi r31, " << count - 1 << std::endl; // +1
                        asm_code << "1:" << std::endl;                             // +0
                        asm_code << '\t' << "dec r31" << std::endl;                // +1
                        asm_code << '\t' << "nop" << std::endl;                    // +1
                        asm_code << '\t' << "brne 1b" << std::endl;                // +2 if taken, +1 if not
                    }

                    // Add 2 more dummy clock cycles.
                    asm_code << '\t' << "rjmp 2f" << std::endl; // +2
                    asm_code << "2:" << std::endl;

                    last = current;
                    count = 1;
                }
            }
            // At the end of the line, clear output bit, and return from interrupt.
            asm_code << '\t' << "cbi IO(PORTB), 4" << std::endl;
            asm_code << '\t' << "jmp jump_table_return_address" << std::endl;
        }
    }

    delete[] image;

    // save the generated code on disk
    outfile << jump_table.str() << asm_code.str();
    outfile.close();
}