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png.d
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png.d
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/++
PNG file read and write. Leverages [arsd.color|color.d]'s [MemoryImage] interfaces for interop.
The main high-level functions you want are [readPng], [readPngFromBytes], [writePng], and maybe [writeImageToPngFile] or [writePngLazy] for some circumstances.
The other functions are low-level implementations and helpers for dissecting the png file format.
History:
Originally written in 2009. This is why some of it is still written in a C-like style!
See_Also:
$(LIST
* [arsd.image] has generic load interfaces that can handle multiple file formats, including png.
* [arsd.apng] handles the animated png extensions.
)
+/
module arsd.png;
import core.memory;
/++
Easily reads a png file into a [MemoryImage]
Returns:
Please note this function doesn't return null right now, but you should still check for null anyway as that might change.
The returned [MemoryImage] is either a [IndexedImage] or a [TrueColorImage], depending on the file's color mode. You can cast it to one or the other, or just call [MemoryImage.getAsTrueColorImage] which will cast and return or convert as needed automatically.
Greyscale pngs and bit depths other than 8 are converted for the ease of the MemoryImage interface. If you need more detail, try [PNG] and [getDatastream] etc.
+/
MemoryImage readPng(string filename) {
import std.file;
return imageFromPng(readPng(cast(ubyte[]) read(filename)));
}
/++
Easily reads a png from a data array into a MemoryImage.
History:
Added December 29, 2021 (dub v10.5)
+/
MemoryImage readPngFromBytes(const(ubyte)[] bytes) {
return imageFromPng(readPng(bytes));
}
/++
Saves a MemoryImage to a png file. See also: [writeImageToPngFile] which uses memory a little more efficiently
See_Also:
[writePngToArray]
+/
void writePng(string filename, MemoryImage mi) {
// FIXME: it would be nice to write the file lazily so we don't have so many intermediate buffers here
import std.file;
std.file.write(filename, writePngToArray(mi));
}
/++
Creates an in-memory png file from the given memory image, returning it.
History:
Added April 21, 2023 (dub v11.0)
See_Also:
[writePng]
+/
ubyte[] writePngToArray(MemoryImage mi) {
PNG* png;
if(auto p = cast(IndexedImage) mi)
png = pngFromImage(p);
else if(auto p = cast(TrueColorImage) mi)
png = pngFromImage(p);
else assert(0);
return writePng(png);
}
/++
Represents the different types of png files, with numbers matching what the spec gives for filevalues.
+/
enum PngType {
greyscale = 0, /// The data must be `depth` bits per pixel
truecolor = 2, /// The data will be RGB triples, so `depth * 3` bits per pixel. Depth must be 8 or 16.
indexed = 3, /// The data must be `depth` bits per pixel, with a palette attached. Use [writePng] with [IndexedImage] for this mode. Depth must be <= 8.
greyscale_with_alpha = 4, /// The data must be (grey, alpha) byte pairs for each pixel. Thus `depth * 2` bits per pixel. Depth must be 8 or 16.
truecolor_with_alpha = 6 /// The data must be RGBA quads for each pixel. Thus, `depth * 4` bits per pixel. Depth must be 8 or 16.
}
/++
Saves an image from an existing array of pixel data. Note that depth other than 8 may not be implemented yet. Also note depth of 16 must be stored big endian
+/
void writePng(string filename, const ubyte[] data, int width, int height, PngType type, ubyte depth = 8) {
PngHeader h;
h.width = width;
h.height = height;
h.type = cast(ubyte) type;
h.depth = depth;
auto png = blankPNG(h);
addImageDatastreamToPng(data, png);
import std.file;
std.file.write(filename, writePng(png));
}
/*
//Here's a simple test program that shows how to write a quick image viewer with simpledisplay:
import arsd.png;
import arsd.simpledisplay;
import std.file;
void main(string[] args) {
// older api, the individual functions give you more control if you need it
//auto img = imageFromPng(readPng(cast(ubyte[]) read(args[1])));
// newer api, simpler but less control
auto img = readPng(args[1]);
// displayImage is from simpledisplay and just pops up a window to show the image
// simpledisplay's Images are a little different than MemoryImages that this loads,
// but conversion is easy
displayImage(Image.fromMemoryImage(img));
}
*/
// By Adam D. Ruppe, 2009-2010, released into the public domain
//import std.file;
//import std.zlib;
public import arsd.color;
/**
The return value should be casted to indexed or truecolor depending on what the file is. You can
also use getAsTrueColorImage to forcibly convert it if needed.
To get an image from a png file, do something like this:
auto i = cast(TrueColorImage) imageFromPng(readPng(cast(ubyte)[]) std.file.read("file.png")));
*/
MemoryImage imageFromPng(PNG* png) {
PngHeader h = getHeader(png);
/** Types from the PNG spec:
0 - greyscale
2 - truecolor
3 - indexed color
4 - grey with alpha
6 - true with alpha
1, 5, and 7 are invalid.
There's a kind of bitmask going on here:
If type&1, it has a palette.
If type&2, it is in color.
If type&4, it has an alpha channel in the datastream.
*/
MemoryImage i;
ubyte[] idata;
// FIXME: some duplication with the lazy reader below in the module
switch(h.type) {
case 0: // greyscale
case 4: // greyscale with alpha
// this might be a different class eventually...
auto a = new TrueColorImage(h.width, h.height);
idata = a.imageData.bytes;
i = a;
break;
case 2: // truecolor
case 6: // truecolor with alpha
auto a = new TrueColorImage(h.width, h.height);
idata = a.imageData.bytes;
i = a;
break;
case 3: // indexed
auto a = new IndexedImage(h.width, h.height);
a.palette = fetchPalette(png);
a.hasAlpha = true; // FIXME: don't be so conservative here
idata = a.data;
i = a;
break;
default:
assert(0, "invalid png");
}
size_t idataIdx = 0;
auto file = LazyPngFile!(Chunk[])(png.chunks);
immutable(ubyte)[] previousLine;
auto bpp = bytesPerPixel(h);
foreach(line; file.rawDatastreamByChunk()) {
auto filter = line[0];
auto data = unfilter(filter, line[1 .. $], previousLine, bpp);
previousLine = data;
convertPngData(h.type, h.depth, data, h.width, idata, idataIdx);
}
assert(idataIdx == idata.length, "not all filled, wtf");
assert(i !is null);
return i;
}
/+
This is used by the load MemoryImage functions to convert the png'd datastream into the format MemoryImage's implementations expect.
idata needs to be already sized for the image! width * height if indexed, width*height*4 if not.
+/
void convertPngData(ubyte type, ubyte depth, const(ubyte)[] data, int width, ubyte[] idata, ref size_t idataIdx) {
ubyte consumeOne() {
ubyte ret = data[0];
data = data[1 .. $];
return ret;
}
import std.conv;
loop: for(int pixel = 0; pixel < width; pixel++)
switch(type) {
case 0: // greyscale
case 4: // greyscale with alpha
case 3: // indexed
void acceptPixel(ubyte p) {
if(type == 3) {
idata[idataIdx++] = p;
} else {
if(depth == 1) {
p = p ? 0xff : 0;
} else if (depth == 2) {
p |= p << 2;
p |= p << 4;
}
else if (depth == 4) {
p |= p << 4;
}
idata[idataIdx++] = p;
idata[idataIdx++] = p;
idata[idataIdx++] = p;
if(type == 0)
idata[idataIdx++] = 255;
else if(type == 4)
idata[idataIdx++] = consumeOne();
}
}
auto b = consumeOne();
switch(depth) {
case 1:
acceptPixel((b >> 7) & 0x01);
pixel++; if(pixel == width) break loop;
acceptPixel((b >> 6) & 0x01);
pixel++; if(pixel == width) break loop;
acceptPixel((b >> 5) & 0x01);
pixel++; if(pixel == width) break loop;
acceptPixel((b >> 4) & 0x01);
pixel++; if(pixel == width) break loop;
acceptPixel((b >> 3) & 0x01);
pixel++; if(pixel == width) break loop;
acceptPixel((b >> 2) & 0x01);
pixel++; if(pixel == width) break loop;
acceptPixel((b >> 1) & 0x01);
pixel++; if(pixel == width) break loop;
acceptPixel(b & 0x01);
break;
case 2:
acceptPixel((b >> 6) & 0x03);
pixel++; if(pixel == width) break loop;
acceptPixel((b >> 4) & 0x03);
pixel++; if(pixel == width) break loop;
acceptPixel((b >> 2) & 0x03);
pixel++; if(pixel == width) break loop;
acceptPixel(b & 0x03);
break;
case 4:
acceptPixel((b >> 4) & 0x0f);
pixel++; if(pixel == width) break loop;
acceptPixel(b & 0x0f);
break;
case 8:
acceptPixel(b);
break;
case 16:
assert(type != 3); // 16 bit indexed isn't supported per png spec
acceptPixel(b);
consumeOne(); // discarding the least significant byte as we can't store it anyway
break;
default:
assert(0, "bit depth not implemented");
}
break;
case 2: // truecolor
case 6: // true with alpha
if(depth == 8) {
idata[idataIdx++] = consumeOne();
idata[idataIdx++] = consumeOne();
idata[idataIdx++] = consumeOne();
idata[idataIdx++] = (type == 6) ? consumeOne() : 255;
} else if(depth == 16) {
idata[idataIdx++] = consumeOne();
consumeOne();
idata[idataIdx++] = consumeOne();
consumeOne();
idata[idataIdx++] = consumeOne();
consumeOne();
idata[idataIdx++] = (type == 6) ? consumeOne() : 255;
if(type == 6)
consumeOne();
} else assert(0, "unsupported truecolor bit depth " ~ to!string(depth));
break;
default: assert(0);
}
assert(data.length == 0, "not all consumed, wtf " ~ to!string(data));
}
/*
struct PngHeader {
uint width;
uint height;
ubyte depth = 8;
ubyte type = 6; // 0 - greyscale, 2 - truecolor, 3 - indexed color, 4 - grey with alpha, 6 - true with alpha
ubyte compressionMethod = 0; // should be zero
ubyte filterMethod = 0; // should be zero
ubyte interlaceMethod = 0; // bool
}
*/
/++
Creates the [PNG] data structure out of an [IndexedImage]. This structure will have the minimum number of colors
needed to represent the image faithfully in the file and will be ready for writing to a file.
This is called by [writePng].
+/
PNG* pngFromImage(IndexedImage i) {
PngHeader h;
h.width = i.width;
h.height = i.height;
h.type = 3;
if(i.numColors() <= 2)
h.depth = 1;
else if(i.numColors() <= 4)
h.depth = 2;
else if(i.numColors() <= 16)
h.depth = 4;
else if(i.numColors() <= 256)
h.depth = 8;
else throw new Exception("can't save this as an indexed png");
auto png = blankPNG(h);
// do palette and alpha
// FIXME: if there is only one transparent color, set it as the special chunk for that
// FIXME: we'd get a smaller file size if the transparent pixels were arranged first
Chunk palette;
palette.type = ['P', 'L', 'T', 'E'];
palette.size = cast(int) i.palette.length * 3;
palette.payload.length = palette.size;
Chunk alpha;
if(i.hasAlpha) {
alpha.type = ['t', 'R', 'N', 'S'];
alpha.size = cast(uint) i.palette.length;
alpha.payload.length = alpha.size;
}
for(int a = 0; a < i.palette.length; a++) {
palette.payload[a*3+0] = i.palette[a].r;
palette.payload[a*3+1] = i.palette[a].g;
palette.payload[a*3+2] = i.palette[a].b;
if(i.hasAlpha)
alpha.payload[a] = i.palette[a].a;
}
palette.checksum = crc("PLTE", palette.payload);
png.chunks ~= palette;
if(i.hasAlpha) {
alpha.checksum = crc("tRNS", alpha.payload);
png.chunks ~= alpha;
}
// do the datastream
if(h.depth == 8) {
addImageDatastreamToPng(i.data, png);
} else {
// gotta convert it
auto bitsPerLine = i.width * h.depth;
if(bitsPerLine % 8 != 0)
bitsPerLine = bitsPerLine / 8 + 1;
else
bitsPerLine = bitsPerLine / 8;
ubyte[] datastream = new ubyte[bitsPerLine * i.height];
int shift = 0;
switch(h.depth) {
default: assert(0);
case 1: shift = 7; break;
case 2: shift = 6; break;
case 4: shift = 4; break;
case 8: shift = 0; break;
}
size_t dsp = 0;
size_t dpos = 0;
bool justAdvanced;
for(int y = 0; y < i.height; y++) {
for(int x = 0; x < i.width; x++) {
datastream[dsp] |= i.data[dpos++] << shift;
switch(h.depth) {
default: assert(0);
case 1: shift-= 1; break;
case 2: shift-= 2; break;
case 4: shift-= 4; break;
case 8: shift-= 8; break;
}
justAdvanced = shift < 0;
if(shift < 0) {
dsp++;
switch(h.depth) {
default: assert(0);
case 1: shift = 7; break;
case 2: shift = 6; break;
case 4: shift = 4; break;
case 8: shift = 0; break;
}
}
}
if(!justAdvanced)
dsp++;
switch(h.depth) {
default: assert(0);
case 1: shift = 7; break;
case 2: shift = 6; break;
case 4: shift = 4; break;
case 8: shift = 0; break;
}
}
addImageDatastreamToPng(datastream, png);
}
return png;
}
/++
Creates the [PNG] data structure out of a [TrueColorImage]. This implementation currently always make
the file a true color with alpha png type.
This is called by [writePng].
+/
PNG* pngFromImage(TrueColorImage i) {
PngHeader h;
h.width = i.width;
h.height = i.height;
// FIXME: optimize it if it is greyscale or doesn't use alpha alpha
auto png = blankPNG(h);
addImageDatastreamToPng(i.imageData.bytes, png);
return png;
}
/*
void main(string[] args) {
auto a = readPng(cast(ubyte[]) read(args[1]));
auto f = getDatastream(a);
foreach(i; f) {
writef("%d ", i);
}
writefln("\n\n%d", f.length);
}
*/
/++
Represents the PNG file's data. This struct is intended to be passed around by pointer.
+/
struct PNG {
/++
The length of the file.
+/
uint length;
/++
The PNG file magic number header. Please note the image data header is a IHDR chunk, not this (see [getHeader] for that). This just a static identifier
History:
Prior to October 10, 2022, this was called `header`.
+/
ubyte[8] magic;// = [0x89, 0x50, 0x4e, 0x47, 0x0d, 0x0a, 0x1a, 0x0a]; // this is the only valid value but idk if it is worth changing here since the ctor sets it regardless.
/// ditto
deprecated("use `magic` instead") alias header = magic;
/++
The array of chunks that make up the file contents. See [getChunkNullable], [getChunk], [insertChunk], and [replaceChunk] for functions to access and manipulate this array.
+/
Chunk[] chunks;
/++
Gets the chunk with the given name, or throws if it cannot be found.
Returns:
A non-null pointer to the chunk in the [chunks] array.
Throws:
an exception if the chunk can not be found. The type of this exception is subject to change at this time.
See_Also:
[getChunkNullable], which returns a null pointer instead of throwing.
+/
pure @trusted /* see note on getChunkNullable */
Chunk* getChunk(string what) {
foreach(ref c; chunks) {
if(c.stype == what)
return &c;
}
throw new Exception("no such chunk " ~ what);
}
/++
Gets the chunk with the given name, return `null` if it is not found.
See_Also:
[getChunk], which throws if the chunk cannot be found.
+/
nothrow @nogc pure @trusted /* trusted because &c i know is referring to the dynamic array, not actually a local. That has lifetime at least as much of the parent PNG object. */
Chunk* getChunkNullable(string what) {
foreach(ref c; chunks) {
if(c.stype == what)
return &c;
}
return null;
}
/++
Insert chunk before IDAT. PNG specs allows to drop all chunks after IDAT,
so we have to insert our custom chunks right before it.
Use `Chunk.create()` to create new chunk, and then `insertChunk()` to add it.
Return `true` if we did replacement.
+/
nothrow pure @trusted /* the chunks.ptr here fails safe, but it does that for performance and again I control that data so can be reasonably assured */
bool insertChunk (Chunk* chk, bool replaceExisting=false) {
if (chk is null) return false; // just in case
// use reversed loop, as "IDAT" is usually present, and it is usually the last,
// so we will somewhat amortize painter's algorithm here.
foreach_reverse (immutable idx, ref cc; chunks) {
if (replaceExisting && cc.type == chk.type) {
// replace existing chunk, the easiest case
chunks[idx] = *chk;
return true;
}
if (cc.stype == "IDAT") {
// ok, insert it; and don't use phobos
chunks.length += 1;
foreach_reverse (immutable c; idx+1..chunks.length) chunks.ptr[c] = chunks.ptr[c-1];
chunks.ptr[idx] = *chk;
return false;
}
}
chunks ~= *chk;
return false;
}
/++
Convenient wrapper for `insertChunk()`.
+/
nothrow pure @safe
bool replaceChunk (Chunk* chk) { return insertChunk(chk, true); }
}
/++
this is just like writePng(filename, pngFromImage(image)), but it manages
its own memory and writes straight to the file instead of using intermediate buffers that might not get gc'd right
+/
void writeImageToPngFile(in char[] filename, TrueColorImage image) {
PNG* png;
ubyte[] com;
{
import std.zlib;
PngHeader h;
h.width = image.width;
h.height = image.height;
png = blankPNG(h);
size_t bytesPerLine = cast(size_t)h.width * 4;
if(h.type == 3)
bytesPerLine = cast(size_t)h.width * 8 / h.depth;
Chunk dat;
dat.type = ['I', 'D', 'A', 'T'];
size_t pos = 0;
auto compressor = new Compress();
import core.stdc.stdlib;
auto lineBuffer = (cast(ubyte*)malloc(1 + bytesPerLine))[0 .. 1+bytesPerLine];
scope(exit) free(lineBuffer.ptr);
while(pos+bytesPerLine <= image.imageData.bytes.length) {
lineBuffer[0] = 0;
lineBuffer[1..1+bytesPerLine] = image.imageData.bytes[pos.. pos+bytesPerLine];
com ~= cast(ubyte[]) compressor.compress(lineBuffer);
pos += bytesPerLine;
}
com ~= cast(ubyte[]) compressor.flush();
assert(com.length <= uint.max);
dat.size = cast(uint) com.length;
dat.payload = com;
dat.checksum = crc("IDAT", dat.payload);
png.chunks ~= dat;
Chunk c;
c.size = 0;
c.type = ['I', 'E', 'N', 'D'];
c.checksum = crc("IEND", c.payload);
png.chunks ~= c;
}
assert(png !is null);
import core.stdc.stdio;
import std.string;
FILE* fp = fopen(toStringz(filename), "wb");
if(fp is null)
throw new Exception("Couldn't open png file for writing.");
scope(exit) fclose(fp);
fwrite(png.magic.ptr, 1, 8, fp);
foreach(c; png.chunks) {
fputc((c.size & 0xff000000) >> 24, fp);
fputc((c.size & 0x00ff0000) >> 16, fp);
fputc((c.size & 0x0000ff00) >> 8, fp);
fputc((c.size & 0x000000ff) >> 0, fp);
fwrite(c.type.ptr, 1, 4, fp);
fwrite(c.payload.ptr, 1, c.size, fp);
fputc((c.checksum & 0xff000000) >> 24, fp);
fputc((c.checksum & 0x00ff0000) >> 16, fp);
fputc((c.checksum & 0x0000ff00) >> 8, fp);
fputc((c.checksum & 0x000000ff) >> 0, fp);
}
{ import core.memory : GC; GC.free(com.ptr); } // there is a reference to this in the PNG struct, but it is going out of scope here too, so who cares
// just wanna make sure this crap doesn't stick around
}
/++
Turns a [PNG] structure into an array of bytes, ready to be written to a file.
+/
ubyte[] writePng(PNG* p) {
ubyte[] a;
if(p.length)
a.length = p.length;
else {
a.length = 8;
foreach(c; p.chunks)
a.length += c.size + 12;
}
size_t pos;
a[0..8] = p.magic[0..8];
pos = 8;
foreach(c; p.chunks) {
a[pos++] = (c.size & 0xff000000) >> 24;
a[pos++] = (c.size & 0x00ff0000) >> 16;
a[pos++] = (c.size & 0x0000ff00) >> 8;
a[pos++] = (c.size & 0x000000ff) >> 0;
a[pos..pos+4] = c.type[0..4];
pos += 4;
a[pos..pos+c.size] = c.payload[0..c.size];
pos += c.size;
a[pos++] = (c.checksum & 0xff000000) >> 24;
a[pos++] = (c.checksum & 0x00ff0000) >> 16;
a[pos++] = (c.checksum & 0x0000ff00) >> 8;
a[pos++] = (c.checksum & 0x000000ff) >> 0;
}
return a;
}
/++
Opens a file and pulls the [PngHeader] out, leaving the rest of the data alone.
This might be useful when you're only interested in getting a file's image size or
other basic metainfo without loading the whole thing.
+/
PngHeader getHeaderFromFile(string filename) {
import std.stdio;
auto file = File(filename, "rb");
ubyte[12] initialBuffer; // file header + size of first chunk (should be IHDR)
auto data = file.rawRead(initialBuffer[]);
if(data.length != 12)
throw new Exception("couldn't get png file header off " ~ filename);
if(data[0..8] != [0x89, 0x50, 0x4e, 0x47, 0x0d, 0x0a, 0x1a, 0x0a])
throw new Exception("file " ~ filename ~ " is not a png");
size_t pos = 8;
size_t size;
size |= data[pos++] << 24;
size |= data[pos++] << 16;
size |= data[pos++] << 8;
size |= data[pos++] << 0;
size += 4; // chunk type
size += 4; // checksum
ubyte[] more;
more.length = size;
auto chunk = file.rawRead(more);
if(chunk.length != size)
throw new Exception("couldn't get png image header off " ~ filename);
more = data ~ chunk;
auto png = readPng(more);
return getHeader(png);
}
/++
Given an in-memory array of bytes from a PNG file, returns the parsed out [PNG] object.
You might want the other [readPng] overload instead, which returns an even more processed [MemoryImage] object.
+/
PNG* readPng(in ubyte[] data) {
auto p = new PNG;
p.length = cast(int) data.length;
p.magic[0..8] = data[0..8];
if(p.magic != [0x89, 0x50, 0x4e, 0x47, 0x0d, 0x0a, 0x1a, 0x0a])
throw new Exception("not a png, header wrong");
size_t pos = 8;
while(pos < data.length) {
Chunk n;
n.size |= data[pos++] << 24;
n.size |= data[pos++] << 16;
n.size |= data[pos++] << 8;
n.size |= data[pos++] << 0;
n.type[0..4] = data[pos..pos+4];
pos += 4;
n.payload.length = n.size;
if(pos + n.size > data.length)
throw new Exception(format("malformed png, chunk '%s' %d @ %d longer than data %d", n.type, n.size, pos, data.length));
if(pos + n.size < pos)
throw new Exception("uint overflow: chunk too large");
n.payload[0..n.size] = data[pos..pos+n.size];
pos += n.size;
n.checksum |= data[pos++] << 24;
n.checksum |= data[pos++] << 16;
n.checksum |= data[pos++] << 8;
n.checksum |= data[pos++] << 0;
p.chunks ~= n;
}
return p;
}
/++
Creates a new [PNG] object from the given header parameters, ready to receive data.
+/
PNG* blankPNG(PngHeader h) {
auto p = new PNG;
p.magic = [0x89, 0x50, 0x4e, 0x47, 0x0d, 0x0a, 0x1a, 0x0a];
Chunk c;
c.size = 13;
c.type = ['I', 'H', 'D', 'R'];
c.payload.length = 13;
size_t pos = 0;
c.payload[pos++] = h.width >> 24;
c.payload[pos++] = (h.width >> 16) & 0xff;
c.payload[pos++] = (h.width >> 8) & 0xff;
c.payload[pos++] = h.width & 0xff;
c.payload[pos++] = h.height >> 24;
c.payload[pos++] = (h.height >> 16) & 0xff;
c.payload[pos++] = (h.height >> 8) & 0xff;
c.payload[pos++] = h.height & 0xff;
c.payload[pos++] = h.depth;
c.payload[pos++] = h.type;
c.payload[pos++] = h.compressionMethod;
c.payload[pos++] = h.filterMethod;
c.payload[pos++] = h.interlaceMethod;
c.checksum = crc("IHDR", c.payload);
p.chunks ~= c;
return p;
}
/+
Implementation helper for creating png files.
Its API is subject to change; it would be private except it might be useful to you.
+/
// should NOT have any idata already.
// FIXME: doesn't handle palettes
void addImageDatastreamToPng(const(ubyte)[] data, PNG* png, bool addIend = true) {
// we need to go through the lines and add the filter byte
// then compress it into an IDAT chunk
// then add the IEND chunk
import std.zlib;
PngHeader h = getHeader(png);
if(h.depth == 0)
throw new Exception("depth of zero makes no sense");
if(h.width == 0)
throw new Exception("width zero?!!?!?!");
int multiplier;
size_t bytesPerLine;
switch(h.type) {
case 0:
multiplier = 1;
break;
case 2:
multiplier = 3;
break;
case 3:
multiplier = 1;
break;
case 4:
multiplier = 2;
break;
case 6:
multiplier = 4;
break;
default: assert(0);
}
bytesPerLine = h.width * multiplier * h.depth / 8;
if((h.width * multiplier * h.depth) % 8 != 0)
bytesPerLine += 1;
assert(bytesPerLine >= 1);
Chunk dat;
dat.type = ['I', 'D', 'A', 'T'];
size_t pos = 0;
const(ubyte)[] output;
while(pos+bytesPerLine <= data.length) {
output ~= 0;
output ~= data[pos..pos+bytesPerLine];
pos += bytesPerLine;
}
auto com = cast(ubyte[]) compress(output);
dat.size = cast(int) com.length;
dat.payload = com;
dat.checksum = crc("IDAT", dat.payload);
png.chunks ~= dat;
if(addIend) {
Chunk c;
c.size = 0;
c.type = ['I', 'E', 'N', 'D'];
c.checksum = crc("IEND", c.payload);
png.chunks ~= c;
}
}
deprecated alias PngHeader PNGHeader;
// bKGD - palette entry for background or the RGB (16 bits each) for that. or 16 bits of grey
/+
Uncompresses the raw datastream out of the file chunks, but does not continue processing it, so the scanlines are still filtered, etc.
+/
ubyte[] getDatastream(PNG* p) {
import std.zlib;
ubyte[] compressed;
foreach(c; p.chunks) {
if(c.stype != "IDAT")
continue;
compressed ~= c.payload;
}
return cast(ubyte[]) uncompress(compressed);
}
/+
Gets a raw datastream out of a 8 bpp png. See also [getANDMask]
+/
// FIXME: Assuming 8 bits per pixel
ubyte[] getUnfilteredDatastream(PNG* p) {
PngHeader h = getHeader(p);
assert(h.filterMethod == 0);
assert(h.type == 3); // FIXME
assert(h.depth == 8); // FIXME
ubyte[] data = getDatastream(p);
ubyte[] ufdata = new ubyte[data.length - h.height];
int bytesPerLine = cast(int) ufdata.length / h.height;
int pos = 0, pos2 = 0;
for(int a = 0; a < h.height; a++) {
assert(data[pos2] == 0);
ufdata[pos..pos+bytesPerLine] = data[pos2+1..pos2+bytesPerLine+1];
pos+= bytesPerLine;
pos2+= bytesPerLine + 1;
}
return ufdata;
}
/+
Gets the unfiltered raw datastream for conversion to Windows ico files. See also [getANDMask] and [fetchPaletteWin32].
+/
ubyte[] getFlippedUnfilteredDatastream(PNG* p) {
PngHeader h = getHeader(p);
assert(h.filterMethod == 0);
assert(h.type == 3); // FIXME
assert(h.depth == 8 || h.depth == 4); // FIXME
ubyte[] data = getDatastream(p);
ubyte[] ufdata = new ubyte[data.length - h.height];
int bytesPerLine = cast(int) ufdata.length / h.height;
int pos = cast(int) ufdata.length - bytesPerLine, pos2 = 0;
for(int a = 0; a < h.height; a++) {
assert(data[pos2] == 0);
ufdata[pos..pos+bytesPerLine] = data[pos2+1..pos2+bytesPerLine+1];
pos-= bytesPerLine;
pos2+= bytesPerLine + 1;
}
return ufdata;
}
ubyte getHighNybble(ubyte a) {
return cast(ubyte)(a >> 4); // FIXME
}
ubyte getLowNybble(ubyte a) {
return a & 0x0f;
}
/++
Takes the transparency info and returns an AND mask suitable for use in a Windows ico
+/
ubyte[] getANDMask(PNG* p) {
PngHeader h = getHeader(p);
assert(h.filterMethod == 0);
assert(h.type == 3); // FIXME
assert(h.depth == 8 || h.depth == 4); // FIXME
assert(h.width % 8 == 0); // might actually be %2
ubyte[] data = getDatastream(p);
ubyte[] ufdata = new ubyte[h.height*((((h.width+7)/8)+3)&~3)]; // gotta pad to DWORDs...
Color[] colors = fetchPalette(p);
int pos = 0, pos2 = (h.width/((h.depth == 8) ? 1 : 2)+1)*(h.height-1);
bool bits = false;
for(int a = 0; a < h.height; a++) {
assert(data[pos2++] == 0);
for(int b = 0; b < h.width; b++) {
if(h.depth == 4) {
ufdata[pos/8] |= ((colors[bits? getLowNybble(data[pos2]) : getHighNybble(data[pos2])].a <= 30) << (7-(pos%8)));
} else