bsnes/ananke/nall/png.hpp

#ifndef NALL_PNG_HPP
#define NALL_PNG_HPP

//PNG image decoder
//author: byuu

#include <nall/inflate.hpp>
#include <nall/string.hpp>

namespace nall {

struct png {
  //colorType:
  //0 = L
  //2 = R,G,B
  //3 = P
  //4 = L,A
  //6 = R,G,B,A
  struct Info {
    unsigned width;
    unsigned height;
    unsigned bitDepth;
    unsigned colorType;
    unsigned compressionMethod;
    unsigned filterType;
    unsigned interlaceMethod;

    unsigned bytesPerPixel;
    unsigned pitch;

    uint8_t palette[256][3];
  } info;

  uint8_t *data;
  unsigned size;

  inline bool decode(const string &filename);
  inline bool decode(const uint8_t *sourceData, unsigned sourceSize);
  inline unsigned readbits(const uint8_t *&data);
  unsigned bitpos;

  inline png();
  inline ~png();

protected:
  enum class FourCC : unsigned {
    IHDR = 0x49484452,
    PLTE = 0x504c5445,
    IDAT = 0x49444154,
    IEND = 0x49454e44,
  };

  inline unsigned interlace(unsigned pass, unsigned index);
  inline unsigned inflateSize();
  inline bool deinterlace(const uint8_t *&inputData, unsigned pass);
  inline bool filter(uint8_t *outputData, const uint8_t *inputData, unsigned width, unsigned height);
  inline unsigned read(const uint8_t *data, unsigned length);
};

bool png::decode(const string &filename) {
  if(auto memory = file::read(filename)) {
    return decode(memory.data(), memory.size());
  }
  return false;
}

bool png::decode(const uint8_t *sourceData, unsigned sourceSize) {
  if(sourceSize < 8) return false;
  if(read(sourceData + 0, 4) != 0x89504e47) return false;
  if(read(sourceData + 4, 4) != 0x0d0a1a0a) return false;

  uint8_t *compressedData = 0;
  unsigned compressedSize = 0;

  unsigned offset = 8;
  while(offset < sourceSize) {
    unsigned length   = read(sourceData + offset + 0, 4);
    unsigned fourCC   = read(sourceData + offset + 4, 4);
    unsigned checksum = read(sourceData + offset + 8 + length, 4);

    if(fourCC == (unsigned)FourCC::IHDR) {
      info.width             = read(sourceData + offset +  8, 4);
      info.height            = read(sourceData + offset + 12, 4);
      info.bitDepth          = read(sourceData + offset + 16, 1);
      info.colorType         = read(sourceData + offset + 17, 1);
      info.compressionMethod = read(sourceData + offset + 18, 1);
      info.filterType        = read(sourceData + offset + 19, 1);
      info.interlaceMethod   = read(sourceData + offset + 20, 1);

      if(info.bitDepth == 0 || info.bitDepth > 16) return false;
      if(info.bitDepth & (info.bitDepth - 1)) return false;  //not a power of two
      if(info.compressionMethod != 0) return false;
      if(info.filterType != 0) return false;
      if(info.interlaceMethod != 0 && info.interlaceMethod != 1) return false;

      switch(info.colorType) {
      case 0: info.bytesPerPixel = info.bitDepth * 1; break;  //L
      case 2: info.bytesPerPixel = info.bitDepth * 3; break;  //R,G,B
      case 3: info.bytesPerPixel = info.bitDepth * 1; break;  //P
      case 4: info.bytesPerPixel = info.bitDepth * 2; break;  //L,A
      case 6: info.bytesPerPixel = info.bitDepth * 4; break;  //R,G,B,A
      default: return false;
      }

      if(info.colorType == 2 || info.colorType == 4 || info.colorType == 6)
        if(info.bitDepth != 8 && info.bitDepth != 16) return false;
      if(info.colorType == 3 && info.bitDepth == 16) return false;

      info.bytesPerPixel = (info.bytesPerPixel + 7) / 8;
      info.pitch = (int)info.width * info.bytesPerPixel;
    }

    if(fourCC == (unsigned)FourCC::PLTE) {
      if(length % 3) return false;
      for(unsigned n = 0, p = offset + 8; n < length / 3; n++) {
        info.palette[n][0] = sourceData[p++];
        info.palette[n][1] = sourceData[p++];
        info.palette[n][2] = sourceData[p++];
      }
    }

    if(fourCC == (unsigned)FourCC::IDAT) {
      compressedData = (uint8_t*)realloc(compressedData, compressedSize + length);
      memcpy(compressedData + compressedSize, sourceData + offset + 8, length);
      compressedSize += length;
    }

    if(fourCC == (unsigned)FourCC::IEND) {
      break;
    }

    offset += 4 + 4 + length + 4;
  }

  unsigned interlacedSize = inflateSize();
  uint8_t *interlacedData = new uint8_t[interlacedSize];

  bool result = inflate(interlacedData, interlacedSize, compressedData + 2, compressedSize - 6);
  delete[] compressedData;

  if(result == false) {
    delete[] interlacedData;
    return false;
  }

  size = info.width * info.height * info.bytesPerPixel;
  data = new uint8_t[size];

  if(info.interlaceMethod == 0) {
    if(filter(data, interlacedData, info.width, info.height) == false) {
      delete[] interlacedData;
      delete[] data;
      data = 0;
      return false;
    }
  } else {
    const uint8_t *passData = interlacedData;
    for(unsigned pass = 0; pass < 7; pass++) {
      if(deinterlace(passData, pass) == false) {
        delete[] interlacedData;
        delete[] data;
        data = 0;
        return false;
      }
    }
  }

  delete[] interlacedData;
  return true;
}

unsigned png::interlace(unsigned pass, unsigned index) {
  static const unsigned data[7][4] = {
    //x-distance, y-distance, x-origin, y-origin
    { 8, 8, 0, 0 },
    { 8, 8, 4, 0 },
    { 4, 8, 0, 4 },
    { 4, 4, 2, 0 },
    { 2, 4, 0, 2 },
    { 2, 2, 1, 0 },
    { 1, 2, 0, 1 },
  };
  return data[pass][index];
}

unsigned png::inflateSize() {
  if(info.interlaceMethod == 0) {
    return info.width * info.height * info.bytesPerPixel + info.height;
  }

  unsigned size = 0;
  for(unsigned pass = 0; pass < 7; pass++) {
    unsigned xd = interlace(pass, 0), yd = interlace(pass, 1);
    unsigned xo = interlace(pass, 2), yo = interlace(pass, 3);
    unsigned width  = (info.width  + (xd - xo - 1)) / xd;
    unsigned height = (info.height + (yd - yo - 1)) / yd;
    if(width == 0 || height == 0) continue;
    size += width * height * info.bytesPerPixel + height;
  }
  return size;
}

bool png::deinterlace(const uint8_t *&inputData, unsigned pass) {
  unsigned xd = interlace(pass, 0), yd = interlace(pass, 1);
  unsigned xo = interlace(pass, 2), yo = interlace(pass, 3);
  unsigned width  = (info.width  + (xd - xo - 1)) / xd;
  unsigned height = (info.height + (yd - yo - 1)) / yd;
  if(width == 0 || height == 0) return true;

  unsigned outputSize = width * height * info.bytesPerPixel;
  uint8_t *outputData = new uint8_t[outputSize];
  bool result = filter(outputData, inputData, width, height);

  const uint8_t *rd = outputData;
  for(unsigned y = yo; y < info.height; y += yd) {
    uint8_t *wr = data + y * info.pitch;
    for(unsigned x = xo; x < info.width; x += xd) {
      for(unsigned b = 0; b < info.bytesPerPixel; b++) {
        wr[x * info.bytesPerPixel + b] = *rd++;
      }
    }
  }

  inputData += outputSize + height;
  delete[] outputData;
  return result;
}

bool png::filter(uint8_t *outputData, const uint8_t *inputData, unsigned width, unsigned height) {
  uint8_t *wr = outputData;
  const uint8_t *rd = inputData;
  int bpp = info.bytesPerPixel, pitch = width * bpp;
  for(int y = 0; y < height; y++) {
    uint8_t filter = *rd++;

    switch(filter) {
    case 0x00:  //None
      for(int x = 0; x < pitch; x++) {
        wr[x] = rd[x];
      }
      break;

    case 0x01:  //Subtract
      for(int x = 0; x < pitch; x++) {
        wr[x] = rd[x] + (x - bpp < 0 ? 0 : wr[x - bpp]);
      }
      break;

    case 0x02:  //Above
      for(int x = 0; x < pitch; x++) {
        wr[x] = rd[x] + (y - 1 < 0 ? 0 : wr[x - pitch]);
      }
      break;

    case 0x03:  //Average
      for(int x = 0; x < pitch; x++) {
        short a = x - bpp < 0 ? 0 : wr[x - bpp];
        short b = y - 1 < 0 ? 0 : wr[x - pitch];

        wr[x] = rd[x] + (uint8_t)((a + b) / 2);
      }
      break;

    case 0x04:  //Paeth
      for(int x = 0; x < pitch; x++) {
        short a = x - bpp < 0 ? 0 : wr[x - bpp];
        short b = y - 1 < 0 ? 0 : wr[x - pitch];
        short c = x - bpp < 0 || y - 1 < 0 ? 0 : wr[x - pitch - bpp];

        short p = a + b - c;
        short pa = p > a ? p - a : a - p;
        short pb = p > b ? p - b : b - p;
        short pc = p > c ? p - c : c - p;

        uint8_t paeth = (uint8_t)((pa <= pb && pa <= pc) ? a : (pb <= pc) ? b : c);

        wr[x] = rd[x] + paeth;
      }
      break;

    default:  //Invalid
      return false;
    }

    rd += pitch;
    wr += pitch;
  }

  return true;
}

unsigned png::read(const uint8_t *data, unsigned length) {
  unsigned result = 0;
  while(length--) result = (result << 8) | (*data++);
  return result;
}

unsigned png::readbits(const uint8_t *&data) {
  unsigned result = 0;
  switch(info.bitDepth) {
  case 1:
    result = (*data >> bitpos) & 1;
    bitpos++;
    if(bitpos == 8) { data++; bitpos = 0; }
    break;
  case 2:
    result = (*data >> bitpos) & 3;
    bitpos += 2;
    if(bitpos == 8) { data++; bitpos = 0; }
    break;
  case 4:
    result = (*data >> bitpos) & 15;
    bitpos += 4;
    if(bitpos == 8) { data++; bitpos = 0; }
    break;
  case 8:
    result = *data++;
    break;
  case 16:
    result = (data[0] << 8) | (data[1] << 0);
    data += 2;
    break;
  }
  return result;
}

png::png() : data(nullptr) {
  bitpos = 0;
}

png::~png() {
  if(data) delete[] data;
}

}

#endif
Update to v091r11 release. byuu says: This release refines HSU1 support as a bidirectional protocol, nests SFC manifests as "release/cartridge" and "release/information" (but release/ is not guaranteed to be finalized just yet), removes the database integration, and adds support for ananke. ananke represents inevitability. It's a library that, when installed, higan can use to load files from the command-line, and also from a new File -> Load Game menu option. I need to change the build rules a bit for it to work on Windows (need to make phoenix a DLL, basically), but it works now on Linux. Right now, it only takes .sfc file names, looks them up in the included database, converts them to game folders, and returns the game folder path for higan to load. The idea is to continue expanding it to support everything we can that I don't want in the higan core: - load .sfc, .smc, .swc, .fig files - remove SNES copier headers - split apart merged firmware files - pull in external firmware files (eg dsp1b.rom - these are staying merged, just as SPC7110 prg+dat are merged) - load .zip and *.7z archives - prompt for selection on multi-file archives - generate manifest files based on heuristics - apply BPS patches The "Load" menu option has been renamed to "Library", to represent games in your library. I'm going to add some sort of suffix to indicate unverified games, and use a different folder icon for those (eg manifests built on heuristics rather than from the database.) So basically, to future end users: File -> Load Game will be how they play games. Library -> (specific system) can be thought of as an infinitely-sized recent games list. purify will likely become a simple stub that invokes ananke's functions. No reason to duplicate all that code. 2012-11-05 08:22:50 +00:00			`#ifndef NALL_PNG_HPP`
			`#define NALL_PNG_HPP`

			`//PNG image decoder`
			`//author: byuu`

			`#include <nall/inflate.hpp>`
			`#include <nall/string.hpp>`

			`namespace nall {`

			`struct png {`
			`//colorType:`
			`//0 = L`
			`//2 = R,G,B`
			`//3 = P`
			`//4 = L,A`
			`//6 = R,G,B,A`
			`struct Info {`
			`unsigned width;`
			`unsigned height;`
			`unsigned bitDepth;`
			`unsigned colorType;`
			`unsigned compressionMethod;`
			`unsigned filterType;`
			`unsigned interlaceMethod;`

			`unsigned bytesPerPixel;`
			`unsigned pitch;`

			`uint8_t palette[256][3];`
			`} info;`

			`uint8_t *data;`
			`unsigned size;`

			`inline bool decode(const string &filename);`
			`inline bool decode(const uint8_t *sourceData, unsigned sourceSize);`
			`inline unsigned readbits(const uint8_t *&data);`
			`unsigned bitpos;`

			`inline png();`
			`inline ~png();`

			`protected:`
			`enum class FourCC : unsigned {`
			`IHDR = 0x49484452,`
			`PLTE = 0x504c5445,`
			`IDAT = 0x49444154,`
			`IEND = 0x49454e44,`
			`};`

			`inline unsigned interlace(unsigned pass, unsigned index);`
			`inline unsigned inflateSize();`
			`inline bool deinterlace(const uint8_t *&inputData, unsigned pass);`
			`inline bool filter(uint8_t outputData, const uint8_t inputData, unsigned width, unsigned height);`
			`inline unsigned read(const uint8_t *data, unsigned length);`
			`};`

			`bool png::decode(const string &filename) {`
			`if(auto memory = file::read(filename)) {`
			`return decode(memory.data(), memory.size());`
			`}`
			`return false;`
			`}`

			`bool png::decode(const uint8_t *sourceData, unsigned sourceSize) {`
			`if(sourceSize < 8) return false;`
			`if(read(sourceData + 0, 4) != 0x89504e47) return false;`
			`if(read(sourceData + 4, 4) != 0x0d0a1a0a) return false;`

			`uint8_t *compressedData = 0;`
			`unsigned compressedSize = 0;`

			`unsigned offset = 8;`
			`while(offset < sourceSize) {`
			`unsigned length = read(sourceData + offset + 0, 4);`
			`unsigned fourCC = read(sourceData + offset + 4, 4);`
			`unsigned checksum = read(sourceData + offset + 8 + length, 4);`

			`if(fourCC == (unsigned)FourCC::IHDR) {`
			`info.width = read(sourceData + offset + 8, 4);`
			`info.height = read(sourceData + offset + 12, 4);`
			`info.bitDepth = read(sourceData + offset + 16, 1);`
			`info.colorType = read(sourceData + offset + 17, 1);`
			`info.compressionMethod = read(sourceData + offset + 18, 1);`
			`info.filterType = read(sourceData + offset + 19, 1);`
			`info.interlaceMethod = read(sourceData + offset + 20, 1);`

			`if(info.bitDepth == 0 \|\| info.bitDepth > 16) return false;`
			`if(info.bitDepth & (info.bitDepth - 1)) return false; //not a power of two`
			`if(info.compressionMethod != 0) return false;`
			`if(info.filterType != 0) return false;`
			`if(info.interlaceMethod != 0 && info.interlaceMethod != 1) return false;`

			`switch(info.colorType) {`
			`case 0: info.bytesPerPixel = info.bitDepth * 1; break; //L`
			`case 2: info.bytesPerPixel = info.bitDepth * 3; break; //R,G,B`
			`case 3: info.bytesPerPixel = info.bitDepth * 1; break; //P`
			`case 4: info.bytesPerPixel = info.bitDepth * 2; break; //L,A`
			`case 6: info.bytesPerPixel = info.bitDepth * 4; break; //R,G,B,A`
			`default: return false;`
			`}`

			`if(info.colorType == 2 \|\| info.colorType == 4 \|\| info.colorType == 6)`
			`if(info.bitDepth != 8 && info.bitDepth != 16) return false;`
			`if(info.colorType == 3 && info.bitDepth == 16) return false;`

			`info.bytesPerPixel = (info.bytesPerPixel + 7) / 8;`
			`info.pitch = (int)info.width * info.bytesPerPixel;`
			`}`

			`if(fourCC == (unsigned)FourCC::PLTE) {`
			`if(length % 3) return false;`
			`for(unsigned n = 0, p = offset + 8; n < length / 3; n++) {`
			`info.palette[n][0] = sourceData[p++];`
			`info.palette[n][1] = sourceData[p++];`
			`info.palette[n][2] = sourceData[p++];`
			`}`
			`}`

			`if(fourCC == (unsigned)FourCC::IDAT) {`
			`compressedData = (uint8_t*)realloc(compressedData, compressedSize + length);`
			`memcpy(compressedData + compressedSize, sourceData + offset + 8, length);`
			`compressedSize += length;`
			`}`

			`if(fourCC == (unsigned)FourCC::IEND) {`
			`break;`
			`}`

			`offset += 4 + 4 + length + 4;`
			`}`

			`unsigned interlacedSize = inflateSize();`
			`uint8_t *interlacedData = new uint8_t[interlacedSize];`

			`bool result = inflate(interlacedData, interlacedSize, compressedData + 2, compressedSize - 6);`
			`delete[] compressedData;`

			`if(result == false) {`
			`delete[] interlacedData;`
			`return false;`
			`}`

			`size = info.width * info.height * info.bytesPerPixel;`
			`data = new uint8_t[size];`

			`if(info.interlaceMethod == 0) {`
			`if(filter(data, interlacedData, info.width, info.height) == false) {`
			`delete[] interlacedData;`
			`delete[] data;`
			`data = 0;`
			`return false;`
			`}`
			`} else {`
			`const uint8_t *passData = interlacedData;`
			`for(unsigned pass = 0; pass < 7; pass++) {`
			`if(deinterlace(passData, pass) == false) {`
			`delete[] interlacedData;`
			`delete[] data;`
			`data = 0;`
			`return false;`
			`}`
			`}`
			`}`

			`delete[] interlacedData;`
			`return true;`
			`}`

			`unsigned png::interlace(unsigned pass, unsigned index) {`
			`static const unsigned data[7][4] = {`
			`//x-distance, y-distance, x-origin, y-origin`
			`{ 8, 8, 0, 0 },`
			`{ 8, 8, 4, 0 },`
			`{ 4, 8, 0, 4 },`
			`{ 4, 4, 2, 0 },`
			`{ 2, 4, 0, 2 },`
			`{ 2, 2, 1, 0 },`
			`{ 1, 2, 0, 1 },`
			`};`
			`return data[pass][index];`
			`}`

			`unsigned png::inflateSize() {`
			`if(info.interlaceMethod == 0) {`
			`return info.width * info.height * info.bytesPerPixel + info.height;`
			`}`

			`unsigned size = 0;`
			`for(unsigned pass = 0; pass < 7; pass++) {`
			`unsigned xd = interlace(pass, 0), yd = interlace(pass, 1);`
			`unsigned xo = interlace(pass, 2), yo = interlace(pass, 3);`
			`unsigned width = (info.width + (xd - xo - 1)) / xd;`
			`unsigned height = (info.height + (yd - yo - 1)) / yd;`
			`if(width == 0 \|\| height == 0) continue;`
			`size += width * height * info.bytesPerPixel + height;`
			`}`
			`return size;`
			`}`

			`bool png::deinterlace(const uint8_t *&inputData, unsigned pass) {`
			`unsigned xd = interlace(pass, 0), yd = interlace(pass, 1);`
			`unsigned xo = interlace(pass, 2), yo = interlace(pass, 3);`
			`unsigned width = (info.width + (xd - xo - 1)) / xd;`
			`unsigned height = (info.height + (yd - yo - 1)) / yd;`
			`if(width == 0 \|\| height == 0) return true;`

			`unsigned outputSize = width * height * info.bytesPerPixel;`
			`uint8_t *outputData = new uint8_t[outputSize];`
			`bool result = filter(outputData, inputData, width, height);`

			`const uint8_t *rd = outputData;`
			`for(unsigned y = yo; y < info.height; y += yd) {`
			`uint8_t wr = data + y info.pitch;`
			`for(unsigned x = xo; x < info.width; x += xd) {`
			`for(unsigned b = 0; b < info.bytesPerPixel; b++) {`
			`wr[x * info.bytesPerPixel + b] = *rd++;`
			`}`
			`}`
			`}`

			`inputData += outputSize + height;`
			`delete[] outputData;`
			`return result;`
			`}`

			`bool png::filter(uint8_t outputData, const uint8_t inputData, unsigned width, unsigned height) {`
			`uint8_t *wr = outputData;`
			`const uint8_t *rd = inputData;`
			`int bpp = info.bytesPerPixel, pitch = width * bpp;`
			`for(int y = 0; y < height; y++) {`
			`uint8_t filter = *rd++;`

			`switch(filter) {`
			`case 0x00: //None`
			`for(int x = 0; x < pitch; x++) {`
			`wr[x] = rd[x];`
			`}`
			`break;`

			`case 0x01: //Subtract`
			`for(int x = 0; x < pitch; x++) {`
			`wr[x] = rd[x] + (x - bpp < 0 ? 0 : wr[x - bpp]);`
			`}`
			`break;`

			`case 0x02: //Above`
			`for(int x = 0; x < pitch; x++) {`
			`wr[x] = rd[x] + (y - 1 < 0 ? 0 : wr[x - pitch]);`
			`}`
			`break;`

			`case 0x03: //Average`
			`for(int x = 0; x < pitch; x++) {`
			`short a = x - bpp < 0 ? 0 : wr[x - bpp];`
			`short b = y - 1 < 0 ? 0 : wr[x - pitch];`

			`wr[x] = rd[x] + (uint8_t)((a + b) / 2);`
			`}`
			`break;`

			`case 0x04: //Paeth`
			`for(int x = 0; x < pitch; x++) {`
			`short a = x - bpp < 0 ? 0 : wr[x - bpp];`
			`short b = y - 1 < 0 ? 0 : wr[x - pitch];`
			`short c = x - bpp < 0 \|\| y - 1 < 0 ? 0 : wr[x - pitch - bpp];`

			`short p = a + b - c;`
			`short pa = p > a ? p - a : a - p;`
			`short pb = p > b ? p - b : b - p;`
			`short pc = p > c ? p - c : c - p;`

			`uint8_t paeth = (uint8_t)((pa <= pb && pa <= pc) ? a : (pb <= pc) ? b : c);`

			`wr[x] = rd[x] + paeth;`
			`}`
			`break;`

			`default: //Invalid`
			`return false;`
			`}`

			`rd += pitch;`
			`wr += pitch;`
			`}`

			`return true;`
			`}`

			`unsigned png::read(const uint8_t *data, unsigned length) {`
			`unsigned result = 0;`
			`while(length--) result = (result << 8) \| (*data++);`
			`return result;`
			`}`

			`unsigned png::readbits(const uint8_t *&data) {`
			`unsigned result = 0;`
			`switch(info.bitDepth) {`
			`case 1:`
			`result = (*data >> bitpos) & 1;`
			`bitpos++;`
			`if(bitpos == 8) { data++; bitpos = 0; }`
			`break;`
			`case 2:`
			`result = (*data >> bitpos) & 3;`
			`bitpos += 2;`
			`if(bitpos == 8) { data++; bitpos = 0; }`
			`break;`
			`case 4:`
			`result = (*data >> bitpos) & 15;`
			`bitpos += 4;`
			`if(bitpos == 8) { data++; bitpos = 0; }`
			`break;`
			`case 8:`
			`result = *data++;`
			`break;`
			`case 16:`
			`result = (data[0] << 8) \| (data[1] << 0);`
			`data += 2;`
			`break;`
			`}`
			`return result;`
			`}`

			`png::png() : data(nullptr) {`
			`bitpos = 0;`
			`}`

			`png::~png() {`
			`if(data) delete[] data;`
			`}`

			`}`

			`#endif`