#include "BMPParser.h"
#include <cassert>
using namespace std;
using namespace BMPParser;
#define MAX_IMG_SIZE 10000
#define E(cond, msg) if(cond) return setErr(msg)
#define EU(cond, msg) if(cond) return setErrUnsupported(msg)
#define EX(cond, msg) if(cond) return setErrUnknown(msg)
#define I1() get<char>()
#define U1() get<uint8_t>()
#define I2() get<int16_t>()
#define U2() get<uint16_t>()
#define I4() get<int32_t>()
#define U4() get<uint32_t>()
#define I1UC() get<char, false>()
#define U1UC() get<uint8_t, false>()
#define I2UC() get<int16_t, false>()
#define U2UC() get<uint16_t, false>()
#define I4UC() get<int32_t, false>()
#define U4UC() get<uint32_t, false>()
#define CHECK_OVERRUN(ptr, size, type) \
if((ptr) + (size) - data > len){ \
setErr("unexpected end of file"); \
return type(); \
}
Parser::~Parser(){
data = nullptr;
ptr = nullptr;
if(imgd){
delete[] imgd;
imgd = nullptr;
}
}
void Parser::parse(uint8_t *buf, int bufSize, uint8_t *format){
assert(status == Status::EMPTY);
data = ptr = buf;
len = bufSize;
// Start parsing file header
setOp("file header");
// File header signature
string fhSig = getStr(2);
string temp = "file header signature";
EU(fhSig == "BA", temp + " \"BA\"");
EU(fhSig == "CI", temp + " \"CI\"");
EU(fhSig == "CP", temp + " \"CP\"");
EU(fhSig == "IC", temp + " \"IC\"");
EU(fhSig == "PT", temp + " \"PT\"");
EX(fhSig != "BM", temp); // BM
// Length of the file should not be larger than `len`
E(U4() > static_cast<uint32_t>(len), "inconsistent file size");
// Skip unused values
skip(4);
// Offset where the pixel array (bitmap data) can be found
auto imgdOffset = U4();
// Start parsing DIB header
setOp("DIB header");
// Prepare some variables in case they are needed
uint32_t compr = 0;
uint32_t redShift = 0, greenShift = 0, blueShift = 0, alphaShift = 0;
uint32_t redMask = 0, greenMask = 0, blueMask = 0, alphaMask = 0;
double redMultp = 0, greenMultp = 0, blueMultp = 0, alphaMultp = 0;
/**
* Type of the DIB (device-independent bitmap) header
* is determined by its size. Most BMP files use BITMAPINFOHEADER.
*/
auto dibSize = U4();
temp = "DIB header";
EU(dibSize == 64, temp + " \"OS22XBITMAPHEADER\"");
EU(dibSize == 16, temp + " \"OS22XBITMAPHEADER\"");
uint32_t infoHeader = dibSize == 40 ? 1 :
dibSize == 52 ? 2 :
dibSize == 56 ? 3 :
dibSize == 108 ? 4 :
dibSize == 124 ? 5 : 0;
// BITMAPCOREHEADER, BITMAP*INFOHEADER, BITMAP*HEADER
auto isDibValid = dibSize == 12 || infoHeader;
EX(!isDibValid, temp);
// Image width
w = dibSize == 12 ? U2() : I4();
E(!w, "image width is 0");
E(w < 0, "negative image width");
E(w > MAX_IMG_SIZE, "too large image width");
// Image height (specification allows negative values)
h = dibSize == 12 ? U2() : I4();
E(!h, "image height is 0");
E(h > MAX_IMG_SIZE, "too large image height");
bool isHeightNegative = h < 0;
if(isHeightNegative) h = -h;
// Number of color planes (must be 1)
E(U2() != 1, "number of color planes must be 1");
// Bits per pixel (color depth)
auto bpp = U2();
auto isBppValid = bpp == 1 || bpp == 4 || bpp == 8 || bpp == 16 || bpp == 24 || bpp == 32;
EU(!isBppValid, "color depth");
// Calculate image data size and padding
uint32_t expectedImgdSize = (((w * bpp + 31) >> 5) << 2) * h;
uint32_t rowPadding = (-w * bpp & 31) >> 3;
uint32_t imgdSize = 0;
// Color palette data
uint8_t* paletteStart = nullptr;
uint32_t palColNum = 0;
if(infoHeader){
// Compression type
compr = U4();
temp = "compression type";
EU(compr == 1, temp + " \"BI_RLE8\"");
EU(compr == 2, temp + " \"BI_RLE4\"");
EU(compr == 4, temp + " \"BI_JPEG\"");
EU(compr == 5, temp + " \"BI_PNG\"");
EU(compr == 6, temp + " \"BI_ALPHABITFIELDS\"");
EU(compr == 11, temp + " \"BI_CMYK\"");
EU(compr == 12, temp + " \"BI_CMYKRLE8\"");
EU(compr == 13, temp + " \"BI_CMYKRLE4\"");
// BI_RGB and BI_BITFIELDS
auto isComprValid = compr == 0 || compr == 3;
EX(!isComprValid, temp);
// Ensure that BI_BITFIELDS appears only with 16-bit or 32-bit color
E(compr == 3 && !(bpp == 16 || bpp == 32), "compression BI_BITFIELDS can be used only with 16-bit and 32-bit color depth");
// Size of the image data
imgdSize = U4();
// Horizontal and vertical resolution (ignored)
skip(8);
// Number of colors in the palette or 0 if no palette is present
palColNum = U4();
EU(palColNum && bpp > 8, "color palette and bit depth combination");
if(palColNum) paletteStart = data + dibSize + 14;
// Number of important colors used or 0 if all colors are important (generally ignored)
skip(4);
if(infoHeader >= 2){
// If BI_BITFIELDS are used, calculate masks, otherwise ignore them
if(compr == 3){
calcMaskShift(redShift, redMask, redMultp);
calcMaskShift(greenShift, greenMask, greenMultp);
calcMaskShift(blueShift, blueMask, blueMultp);
if(infoHeader >= 3) calcMaskShift(alphaShift, alphaMask, alphaMultp);
if(status == Status::ERROR) return;
}else{
skip(16);
}
// Ensure that the color space is LCS_WINDOWS_COLOR_SPACE or sRGB
if(infoHeader >= 4 && !palColNum){
string colSpace = getStr(4, 1);
EU(colSpace != "Win " && colSpace != "sRGB", "color space \"" + colSpace + "\"");
}
}
}
// Skip to the image data (there may be other chunks between, but they are optional)
E(ptr - data > imgdOffset, "image data overlaps with another structure");
ptr = data + imgdOffset;
// Start parsing image data
setOp("image data");
if(!imgdSize){
// Value 0 is allowed only for BI_RGB compression type
E(compr != 0, "missing image data size");
imgdSize = expectedImgdSize;
}else{
E(imgdSize < expectedImgdSize, "invalid image data size");
}
// Ensure that all image data is present
E(ptr - data + imgdSize > len, "not enough image data");
// Direction of reading rows
int yStart = h - 1;
int yEnd = -1;
int dy = isHeightNegative ? 1 : -1;
// In case of negative height, read rows backward
if(isHeightNegative){
yStart = 0;
yEnd = h;
}
// Allocate output image data array
int buffLen = w * h << 2;
imgd = new (nothrow) uint8_t[buffLen];
E(!imgd, "unable to allocate memory");
// Prepare color values
uint8_t color[4] = {0};
uint8_t &red = color[0];
uint8_t &green = color[1];
uint8_t &blue = color[2];
uint8_t &alpha = color[3];
// Check if pre-multiplied alpha is used
bool premul = format ? format[4] : 0;
// Main loop
for(int y = yStart; y != yEnd; y += dy){
// Use in-byte offset for bpp < 8
uint8_t colOffset = 0;
uint8_t cval = 0;
uint32_t val = 0;
for(int x = 0; x != w; x++){
// Index in the output image data
int i = (x + y * w) << 2;
switch(compr){
case 0: // BI_RGB
switch(bpp){
case 1:
if(colOffset) ptr--;
cval = (U1UC() >> (7 - colOffset)) & 1;
if(palColNum){
uint8_t* entry = paletteStart + (cval << 2);
blue = get<uint8_t>(entry);
green = get<uint8_t>(entry + 1);
red = get<uint8_t>(entry + 2);
if(status == Status::ERROR) return;
}else{
red = green = blue = cval ? 255 : 0;
}
alpha = 255;
colOffset = (colOffset + 1) & 7;
break;
case 4:
if(colOffset) ptr--;
cval = (U1UC() >> (4 - colOffset)) & 15;
if(palColNum){
uint8_t* entry = paletteStart + (cval << 2);
blue = get<uint8_t>(entry);
green = get<uint8_t>(entry + 1);
red = get<uint8_t>(entry + 2);
if(status == Status::ERROR) return;
}else{
red = green = blue = cval << 4;
}
alpha = 255;
colOffset = (colOffset + 4) & 7;
break;
case 8:
cval = U1UC();
if(palColNum){
uint8_t* entry = paletteStart + (cval << 2);
blue = get<uint8_t>(entry);
green = get<uint8_t>(entry + 1);
red = get<uint8_t>(entry + 2);
if(status == Status::ERROR) return;
}else{
red = green = blue = cval;
}
alpha = 255;
break;
case 16:
// RGB555
val = U1UC();
val |= U1UC() << 8;
red = (val >> 10) << 3;
green = (val >> 5) << 3;
blue = val << 3;
alpha = 255;
break;
case 24:
blue = U1UC();
green = U1UC();
red = U1UC();
alpha = 255;
break;
case 32:
blue = U1UC();
green = U1UC();
red = U1UC();
if(infoHeader >= 3){
alpha = U1UC();
}else{
alpha = 255;
skip(1);
}
break;
}
break;
case 3: // BI_BITFIELDS
uint32_t col = bpp == 16 ? U2UC() : U4UC();
red = ((col >> redShift) & redMask) * redMultp + .5;
green = ((col >> greenShift) & greenMask) * greenMultp + .5;
blue = ((col >> blueShift) & blueMask) * blueMultp + .5;
alpha = alphaMask ? ((col >> alphaShift) & alphaMask) * alphaMultp + .5 : 255;
break;
}
/**
* Pixel format:
* red,
* green,
* blue,
* alpha,
* is alpha pre-multiplied
* Default is [0, 1, 2, 3, 0]
*/
if(premul && alpha != 255){
double a = alpha / 255.;
red = static_cast<uint8_t>(red * a + .5);
green = static_cast<uint8_t>(green * a + .5);
blue = static_cast<uint8_t>(blue * a + .5);
}
if(format){
imgd[i] = color[format[0]];
imgd[i + 1] = color[format[1]];
imgd[i + 2] = color[format[2]];
imgd[i + 3] = color[format[3]];
}else{
imgd[i] = red;
imgd[i + 1] = green;
imgd[i + 2] = blue;
imgd[i + 3] = alpha;
}
}
// Skip unused bytes in the current row
skip(rowPadding);
}
if(status == Status::ERROR) return;
status = Status::OK;
};
void Parser::clearImgd(){ imgd = nullptr; }
int32_t Parser::getWidth() const{ return w; }
int32_t Parser::getHeight() const{ return h; }
uint8_t *Parser::getImgd() const{ return imgd; }
Status Parser::getStatus() const{ return status; }
string Parser::getErrMsg() const{
return "Error while processing " + getOp() + " - " + err;
}
template <typename T, bool check> inline T Parser::get(){
if(check)
CHECK_OVERRUN(ptr, sizeof(T), T);
T val = *(T*)ptr;
ptr += sizeof(T);
return val;
}
template <typename T, bool check> inline T Parser::get(uint8_t* pointer){
if(check)
CHECK_OVERRUN(pointer, sizeof(T), T);
T val = *(T*)pointer;
return val;
}
string Parser::getStr(int size, bool reverse){
CHECK_OVERRUN(ptr, size, string);
string val = "";
while(size--){
if(reverse) val = string(1, static_cast<char>(*ptr++)) + val;
else val += static_cast<char>(*ptr++);
}
return val;
}
inline void Parser::skip(int size){
CHECK_OVERRUN(ptr, size, void);
ptr += size;
}
void Parser::calcMaskShift(uint32_t& shift, uint32_t& mask, double& multp){
mask = U4();
shift = 0;
if(mask == 0) return;
while(~mask & 1){
mask >>= 1;
shift++;
}
E(mask & (mask + 1), "invalid color mask");
multp = 255. / mask;
}
void Parser::setOp(string val){
if(status != Status::EMPTY) return;
op = val;
}
string Parser::getOp() const{
return op;
}
void Parser::setErrUnsupported(string msg){
setErr("unsupported " + msg);
}
void Parser::setErrUnknown(string msg){
setErr("unknown " + msg);
}
void Parser::setErr(string msg){
if(status != Status::EMPTY) return;
err = msg;
status = Status::ERROR;
}
string Parser::getErr() const{
return err;
}
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