#if defined(_MSC_VER) && (_MSC_VER >= 1400)
#define _CRT_SECURE_NO_DEPRECATE 1
#endif
#include <memory>
#include "tmachine.h"
#include "texception.h"
#include "tfilepath.h"
#include "tiio_png.h"
#include "tiio.h"
#include "../compatibility/tfile_io.h"
#include "png.h"
#include "tpixel.h"
#include "tpixelutils.h"
using namespace std;
//------------------------------------------------------------
extern "C" {
static void tnz_abort(jmp_buf, int) {}
static void tnz_error_fun(png_structp pngPtr, png_const_charp error_message) {
*(int *)png_get_error_ptr(pngPtr) = 0;
}
}
#if !defined(TNZ_LITTLE_ENDIAN)
#error "TNZ_LITTLE_ENDIAN undefined !!"
#endif
//=========================================================
/* Check for the older version of libpng */
#if defined(PNG_LIBPNG_VER)
#if (PNG_LIBPNG_VER < 10527)
extern "C" {
static png_uint_32 png_get_current_row_number(const png_structp png_ptr) {
/* See the comments in png.h - this is the sub-image row when reading and
* interlaced image.
*/
if (png_ptr != NULL) return png_ptr->row_number;
return PNG_UINT_32_MAX; /* help the app not to fail silently */
}
static png_byte png_get_current_pass_number(const png_structp png_ptr) {
if (png_ptr != NULL) return png_ptr->pass;
return 8; /* invalid */
}
}
#endif
#else
#error "PNG_LIBPNG_VER undefined, libpng too old?"
#endif
//=========================================================
inline USHORT mySwap(USHORT val) {
#if TNZ_LITTLE_ENDIAN
return ((val) |
((val & 0xff) << 8)); //((val>>8)|((val&0xff)<<8)); (vecchio codice)
#else
return val;
#endif
}
//=========================================================
class PngReader final : public Tiio::Reader {
FILE *m_chan;
png_structp m_png_ptr;
png_infop m_info_ptr, m_end_info_ptr;
int m_bit_depth, m_color_type, m_interlace_type;
int m_compression_type, m_filter_type;
unsigned int m_sig_read;
int m_y;
bool m_is16bitEnabled;
std::unique_ptr<unsigned char[]> m_rowBuffer;
std::unique_ptr<unsigned char[]> m_tempBuffer; // Buffer temporaneo
int m_canDelete;
public:
PngReader()
: m_chan(0)
, m_png_ptr(0)
, m_info_ptr(0)
, m_end_info_ptr(0)
, m_bit_depth(0)
, m_color_type(0)
, m_interlace_type(0)
, m_compression_type(0)
, m_filter_type(0)
, m_sig_read(0)
, m_y(0)
, m_is16bitEnabled(true)
, m_canDelete(0) {}
~PngReader() {
if (m_canDelete == 1) {
png_destroy_read_struct(&m_png_ptr, &m_info_ptr, &m_end_info_ptr);
}
}
bool read16BitIsEnabled() const override { return m_is16bitEnabled; }
void enable16BitRead(bool enabled) override { m_is16bitEnabled = enabled; }
void readLineInterlace(char *buffer) {
readLineInterlace(buffer, 0, m_info.m_lx - 1, 1);
}
void readLineInterlace(short *buffer) {
readLineInterlace(buffer, 0, m_info.m_lx - 1, 1);
}
void open(FILE *file) override {
try {
m_chan = file;
} catch (...) {
perror("uffa");
return;
}
unsigned char signature[8]; // da 1 a 8 bytes
fread(signature, 1, sizeof signature, m_chan);
bool isPng = !png_sig_cmp(signature, 0, sizeof signature);
if (!isPng) return;
m_png_ptr = png_create_read_struct(PNG_LIBPNG_VER_STRING, &m_canDelete,
tnz_error_fun, 0);
if (!m_png_ptr) return;
#if defined(PNG_LIBPNG_VER)
#if (PNG_LIBPNG_VER >= 10527)
png_set_longjmp_fn(m_png_ptr, tnz_abort,
sizeof(jmp_buf)); /* ignore all fatal errors */
#endif // (PNG_LIBPNG_VER >= 10527)
#endif // defined(PNG_LIBPNG_VER)
m_canDelete = 1;
m_info_ptr = png_create_info_struct(m_png_ptr);
if (!m_info_ptr) {
png_destroy_read_struct(&m_png_ptr, (png_infopp)0, (png_infopp)0);
return;
}
m_end_info_ptr = png_create_info_struct(m_png_ptr);
if (!m_end_info_ptr) {
png_destroy_read_struct(&m_png_ptr, &m_info_ptr, (png_infopp)0);
return;
}
png_init_io(m_png_ptr, m_chan);
png_set_sig_bytes(m_png_ptr, sizeof signature);
#if defined(TNZ_MACHINE_CHANNEL_ORDER_MBGR)
png_set_bgr(m_png_ptr);
png_set_swap_alpha(m_png_ptr);
#elif defined(TNZ_MACHINE_CHANNEL_ORDER_BGRM)
png_set_bgr(m_png_ptr);
#elif defined(TNZ_MACHINE_CHANNEL_ORDER_MRGB)
png_set_swap_alpha(m_png_ptr);
#elif !defined(TNZ_MACHINE_CHANNEL_ORDER_RGBM)
#error "unknown channel order"
#endif
png_read_info(m_png_ptr, m_info_ptr);
if (png_get_valid(m_png_ptr, m_info_ptr, PNG_INFO_pHYs)) {
png_uint_32 xdpi = png_get_x_pixels_per_meter(m_png_ptr, m_info_ptr);
png_uint_32 ydpi = png_get_y_pixels_per_meter(m_png_ptr, m_info_ptr);
m_info.m_dpix = tround(xdpi * 0.0254);
m_info.m_dpiy = tround(ydpi * 0.0254);
}
int rowBytes = png_get_rowbytes(m_png_ptr, m_info_ptr);
png_uint_32 lx = 0, ly = 0;
png_get_IHDR(m_png_ptr, m_info_ptr, &lx, &ly, &m_bit_depth, &m_color_type,
&m_interlace_type, &m_compression_type, &m_filter_type);
m_info.m_lx = lx;
m_info.m_ly = ly;
m_info.m_bitsPerSample = m_bit_depth;
int channels = png_get_channels(m_png_ptr, m_info_ptr);
m_info.m_samplePerPixel = channels;
if (channels == 1 || channels == 2) {
if (m_bit_depth <
8) // (m_bit_depth == 1 || m_bit_depth == 2 || m_bit_depth == 4)
m_rowBuffer.reset(new unsigned char[lx * 3]);
else
m_rowBuffer.reset(new unsigned char[rowBytes * 4]);
} else {
m_rowBuffer.reset(new unsigned char[rowBytes]);
}
if (m_color_type == PNG_COLOR_TYPE_PALETTE) {
m_info.m_valid = true;
png_set_palette_to_rgb(m_png_ptr);
// treat the image as RGBA from now on
m_info.m_samplePerPixel =
4; // there are 4 channels per pixel (R, G, B, and A)
// if there is no alpha channel, then fill it with "255" (full opacity)
png_set_filler(m_png_ptr, 0xFF, PNG_FILLER_AFTER);
}
if (m_color_type == PNG_COLOR_TYPE_GRAY && m_bit_depth < 8) {
png_set_expand_gray_1_2_4_to_8(m_png_ptr);
}
if (png_get_valid(m_png_ptr, m_info_ptr, PNG_INFO_tRNS)) {
png_set_tRNS_to_alpha(m_png_ptr);
}
if (m_bit_depth == 16 && !m_is16bitEnabled) {
png_set_strip_16(m_png_ptr);
}
#if defined(TNZ_MACHINE_CHANNEL_ORDER_BGRM)
if (m_color_type == PNG_COLOR_TYPE_RGB ||
m_color_type == PNG_COLOR_TYPE_RGB_ALPHA) {
png_set_bgr(m_png_ptr);
}
#elif defined(TNZ_MACHINE_CHANNEL_ORDER_MBGR)
if (m_color_type == PNG_COLOR_TYPE_RGB_ALPHA) {
png_set_swap_alpha(m_png_ptr);
}
#elif !defined(TNZ_MACHINE_CHANNEL_ORDER_RGBM) && \
!defined(TNZ_MACHINE_CHANNEL_ORDER_MRGB)
#error "unknown channel order"
#endif
if (m_color_type == PNG_COLOR_TYPE_GRAY ||
m_color_type == PNG_COLOR_TYPE_GRAY_ALPHA) {
png_set_gray_to_rgb(m_png_ptr);
}
}
void readLine(char *buffer, int x0, int x1, int shrink) override {
int ly = m_info.m_ly;
if (!m_tempBuffer) {
int lx = m_info.m_lx;
int channels = png_get_channels(m_png_ptr, m_info_ptr);
int rowBytes = png_get_rowbytes(m_png_ptr, m_info_ptr);
if (m_interlace_type == 1) {
if (channels == 1 || channels == 2) {
if (m_bit_depth < 8)
m_tempBuffer.reset(new unsigned char[ly * lx * 3]);
else
m_tempBuffer.reset(new unsigned char[ly * rowBytes * 4]);
} else {
m_tempBuffer.reset(new unsigned char[ly * rowBytes]);
}
}
}
int lx = m_info.m_lx;
if (m_interlace_type == 1 && lx > 4) {
readLineInterlace(&buffer[0], x0, x1, shrink);
m_y++;
if (m_tempBuffer && m_y == ly) {
m_tempBuffer.reset();
}
return;
}
int y = m_info.m_ly - 1 - m_y;
if (y < 0) return;
m_y++;
png_bytep row_pointer = m_rowBuffer.get();
png_read_row(m_png_ptr, row_pointer, NULL);
writeRow(buffer, x0, x1);
if (m_tempBuffer && m_y == ly) {
m_tempBuffer.reset();
}
}
void readLine(short *buffer, int x0, int x1, int shrink) override {
int ly = m_info.m_ly;
if (!m_tempBuffer) {
int lx = m_info.m_lx;
int channels = png_get_channels(m_png_ptr, m_info_ptr);
int rowBytes = png_get_rowbytes(m_png_ptr, m_info_ptr);
if (m_interlace_type == 1) {
if (channels == 1 || channels == 2) {
if (m_bit_depth <
8) // (m_bit_depth == 1 || m_bit_depth == 2 || m_bit_depth == 4)
m_tempBuffer.reset(new unsigned char[ly * lx * 3]);
else
m_tempBuffer.reset(new unsigned char[ly * rowBytes * 4]);
} else {
m_tempBuffer.reset(new unsigned char[ly * rowBytes]);
}
}
}
if (png_get_interlace_type(m_png_ptr, m_info_ptr) == PNG_INTERLACE_ADAM7) {
readLineInterlace(&buffer[0], x0, x1, shrink);
m_y++;
if (m_tempBuffer && m_y == ly) {
m_tempBuffer.reset();
}
return;
}
int y = m_info.m_ly - 1 - m_y;
if (y < 0) return;
m_y++;
png_bytep row_pointer = m_rowBuffer.get();
png_read_row(m_png_ptr, row_pointer, NULL);
writeRow(buffer, x0, x1);
if (m_tempBuffer && m_y == ly) {
m_tempBuffer.reset();
}
}
int skipLines(int lineCount) override {
for (int i = 0; i < lineCount; i++) {
if (m_interlace_type == 1 &&
m_info.m_lx > 4) // pezza. Studiare il codice
{
int channels = png_get_channels(m_png_ptr, m_info_ptr);
char *lineBuffer = (char *)malloc(4 * m_info.m_lx * sizeof(char));
readLine(lineBuffer, 0, m_info.m_lx - 1, 1);
free(lineBuffer);
} else {
m_y++;
png_bytep row_pointer = m_rowBuffer.get();
png_read_row(m_png_ptr, row_pointer, NULL);
}
}
return lineCount;
}
Tiio::RowOrder getRowOrder() const override { return Tiio::TOP2BOTTOM; }
void writeRow(char *buffer, int x0, int x1) {
if (m_color_type == PNG_COLOR_TYPE_RGB_ALPHA ||
m_color_type == PNG_COLOR_TYPE_GRAY_ALPHA ||
m_color_type == PNG_COLOR_TYPE_PALETTE) { // PNG_COLOR_TYPE_PALETTE is
// expanded to RGBA
if (m_bit_depth == 16) {
TPixel32 *pix = (TPixel32 *)buffer;
int i = -2;
i += x0 * 2 * 4;
for (int j = x0; j <= x1; j++) {
#if defined(TNZ_MACHINE_CHANNEL_ORDER_MRGB)
pix[j].m = m_rowBuffer[i = i + 2];
pix[j].r = m_rowBuffer[i = i + 2];
pix[j].g = m_rowBuffer[i = i + 2];
pix[j].b = m_rowBuffer[i = i + 2];
#elif defined(TNZ_MACHINE_CHANNEL_ORDER_RGBM)
pix[j].r = m_rowBuffer[i = i + 2];
pix[j].g = m_rowBuffer[i = i + 2];
pix[j].b = m_rowBuffer[i = i + 2];
pix[j].m = m_rowBuffer[i = i + 2];
#elif defined(TNZ_MACHINE_CHANNEL_ORDER_BGRM)
pix[j].b = m_rowBuffer[i = i + 2];
pix[j].g = m_rowBuffer[i = i + 2];
pix[j].r = m_rowBuffer[i = i + 2];
pix[j].m = m_rowBuffer[i = i + 2];
#elif defined(TNZ_MACHINE_CHANNEL_ORDER_MBGR)
pix[j].m = m_rowBuffer[i = i + 2];
pix[j].b = m_rowBuffer[i = i + 2];
pix[j].g = m_rowBuffer[i = i + 2];
pix[j].r = m_rowBuffer[i = i + 2];
#else
#error "unknown channel order"
#endif
// premultiply here
premult(pix[j]);
}
} else {
TPixel32 *pix = (TPixel32 *)buffer;
int i = 0;
i += x0 * 4;
for (int j = x0; j <= x1; j++) {
#if defined(TNZ_MACHINE_CHANNEL_ORDER_MRGB)
pix[j].m = m_rowBuffer[i++];
pix[j].r = m_rowBuffer[i++];
pix[j].g = m_rowBuffer[i++];
pix[j].b = m_rowBuffer[i++];
#elif defined(TNZ_MACHINE_CHANNEL_ORDER_RGBM)
pix[j].r = m_rowBuffer[i++];
pix[j].g = m_rowBuffer[i++];
pix[j].b = m_rowBuffer[i++];
pix[j].m = m_rowBuffer[i++];
#elif defined(TNZ_MACHINE_CHANNEL_ORDER_BGRM)
pix[j].b = m_rowBuffer[i++];
pix[j].g = m_rowBuffer[i++];
pix[j].r = m_rowBuffer[i++];
pix[j].m = m_rowBuffer[i++];
#elif defined(TNZ_MACHINE_CHANNEL_ORDER_MBGR)
pix[j].m = m_rowBuffer[i++];
pix[j].b = m_rowBuffer[i++];
pix[j].g = m_rowBuffer[i++];
pix[j].r = m_rowBuffer[i++];
#else
#error "unknown channel order"
#endif
// premultiply here
premult(pix[j]);
}
}
} else // qui gestisce RGB senza alpha.
{ // grayscale e' gestito come RGB perche' si usa png_set_gray_to_rgb
if (m_bit_depth == 16) {
TPixel32 *pix = (TPixel32 *)buffer;
int i = -2;
i += x0 * 2 * 3;
for (int j = x0; j <= x1; j++) {
#if defined(TNZ_MACHINE_CHANNEL_ORDER_MRGB) || \
defined(TNZ_MACHINE_CHANNEL_ORDER_RGBM)
pix[j].r = m_rowBuffer[i = i + 2];
pix[j].g = m_rowBuffer[i = i + 2];
pix[j].b = m_rowBuffer[i = i + 2];
#elif defined(TNZ_MACHINE_CHANNEL_ORDER_MBGR) || \
defined(TNZ_MACHINE_CHANNEL_ORDER_BGRM)
pix[j].b = m_rowBuffer[i = i + 2];
pix[j].g = m_rowBuffer[i = i + 2];
pix[j].r = m_rowBuffer[i = i + 2];
#else
#error "unknown channel order"
#endif
pix[j].m = 255;
}
} else {
TPixel32 *pix = (TPixel32 *)buffer;
int i = 0;
i += x0 * 3;
for (int j = x0; j <= x1; j++) {
#if defined(TNZ_MACHINE_CHANNEL_ORDER_MRGB) || \
defined(TNZ_MACHINE_CHANNEL_ORDER_RGBM)
pix[j].r = m_rowBuffer[i++];
pix[j].g = m_rowBuffer[i++];
pix[j].b = m_rowBuffer[i++];
#elif defined(TNZ_MACHINE_CHANNEL_ORDER_MBGR) || \
defined(TNZ_MACHINE_CHANNEL_ORDER_BGRM)
pix[j].b = m_rowBuffer[i++];
pix[j].g = m_rowBuffer[i++];
pix[j].r = m_rowBuffer[i++];
#else
#error "unknown channel order"
#endif
pix[j].m = 255;
}
}
}
}
void writeRow(short *buffer, int x0, int x1) {
if (m_color_type == PNG_COLOR_TYPE_RGB_ALPHA ||
m_color_type == PNG_COLOR_TYPE_GRAY_ALPHA ||
m_color_type == PNG_COLOR_TYPE_PALETTE) { // PNG_COLOR_TYPE_PALETTE is
// expanded to RGBA
TPixel64 *pix = (TPixel64 *)buffer;
int i = -2; // 0;
i += x0 * 2 * 4;
for (int j = x0; j <= x1; j++) {
#if defined(TNZ_MACHINE_CHANNEL_ORDER_MRGB) || \
defined(TNZ_MACHINE_CHANNEL_ORDER_RGBM)
pix[j].r = mySwap(m_rowBuffer[i = i + 2]); // i++
pix[j].g = mySwap(m_rowBuffer[i = i + 2]);
pix[j].b = mySwap(m_rowBuffer[i = i + 2]);
pix[j].m = mySwap(m_rowBuffer[i = i + 2]);
#elif defined(TNZ_MACHINE_CHANNEL_ORDER_MBGR) || \
defined(TNZ_MACHINE_CHANNEL_ORDER_BGRM)
pix[j].b = mySwap(m_rowBuffer[i = i + 2]); // i++
pix[j].g = mySwap(m_rowBuffer[i = i + 2]);
pix[j].r = mySwap(m_rowBuffer[i = i + 2]);
pix[j].m = mySwap(m_rowBuffer[i = i + 2]);
#else
#error "unknown channel order"
#endif
// pix[j].m = 255;
// premultiply here
premult(pix[j]);
}
} else // qui gestisce RGB senza alpha.
{ // grayscale e' gestito come RGB perche' si usa png_set_gray_to_rgb
TPixel64 *pix = (TPixel64 *)buffer;
int i = -2;
i += x0 * 2 * 3;
for (int j = x0; j <= x1; j++) {
#if defined(TNZ_MACHINE_CHANNEL_ORDER_MRGB) || \
defined(TNZ_MACHINE_CHANNEL_ORDER_RGBM)
pix[j].r = mySwap(m_rowBuffer[i = i + 2]);
pix[j].g = mySwap(m_rowBuffer[i = i + 2]);
pix[j].b = mySwap(m_rowBuffer[i = i + 2]);
#elif defined(TNZ_MACHINE_CHANNEL_ORDER_MBGR) || \
defined(TNZ_MACHINE_CHANNEL_ORDER_BGRM)
pix[j].b = mySwap(m_rowBuffer[i = i + 2]);
pix[j].g = mySwap(m_rowBuffer[i = i + 2]);
pix[j].r = mySwap(m_rowBuffer[i = i + 2]);
#else
#error "unknown channel order"
#endif
pix[j].m = mySwap(255);
}
}
}
void copyPixel(int count, int dstX, int dstDx, int dstY) {
int channels = png_get_channels(m_png_ptr, m_info_ptr);
int rowBytes = png_get_rowbytes(m_png_ptr, m_info_ptr);
int lx = m_info.m_lx;
if ((channels == 4 || channels == 3) && m_bit_depth == 16) {
for (int i = 0; i < count; i += 2) {
for (int j = 0; j < channels * 2; j++) {
(m_tempBuffer.get() +
(dstY * rowBytes))[(i * dstDx + dstX) * channels + j] =
m_rowBuffer[i * channels + j];
}
}
} else if (channels == 2 && m_bit_depth == 16) {
for (int i = 0; i < count; i += 2) {
for (int j = 0; j < 4 * 2; j++) {
(m_tempBuffer.get() +
(dstY * rowBytes * 4))[(i * dstDx + dstX) * 4 + j] =
m_rowBuffer[i * 4 + j];
}
}
} else if (channels == 1 && m_bit_depth == 16) {
for (int i = 0; i < count; i += 2) {
for (int j = 0; j < 3 * 2; j++) {
(m_tempBuffer.get() +
(dstY * rowBytes * 4))[(i * dstDx + dstX) * 3 + j] =
m_rowBuffer[i * 3 + j];
}
}
} else if (channels == 1 && m_bit_depth == 8) {
for (int i = 0; i < count; i++) {
for (int j = 0; j < 3; j++) {
(m_tempBuffer.get() +
(dstY * rowBytes * 4))[(i * dstDx + dstX) * 3 + j] =
m_rowBuffer[i * 3 + j];
}
}
} else if (channels == 2 && m_bit_depth == 8) {
for (int i = 0; i < count; i++) {
for (int j = 0; j < 4; j++) {
(m_tempBuffer.get() +
(dstY * rowBytes * 4))[(i * dstDx + dstX) * 4 + j] =
m_rowBuffer[i * 4 + j];
}
}
} else if ((channels == 1 || channels == 2) && m_bit_depth < 8) {
for (int i = 0; i < count; i++) {
for (int j = 0; j < 3; j++) {
(m_tempBuffer.get() + (dstY * lx * 3))[(i * dstDx + dstX) * 3 + j] =
m_rowBuffer[i * 3 + j];
}
}
} else {
for (int i = 0; i < count; i++) {
for (int j = 0; j < channels; j++) {
(m_tempBuffer.get() +
(dstY * rowBytes))[(i * dstDx + dstX) * channels + j] =
m_rowBuffer[i * channels + j];
}
}
}
}
void readLineInterlace(char *buffer, int x0, int x1, int shrink) {
// m_png_ptr->row_number è l'indice di riga che scorre quando chiamo la
// png_read_row
int rowNumber = png_get_current_row_number(m_png_ptr);
// numRows è il numero di righe processate in ogni passo
int numRows = (int)png_get_image_height(m_png_ptr, m_info_ptr) / 8;
int passPng = png_get_current_pass_number(m_png_ptr);
int passRow = 5 + (m_y & 1); // passo desiderato per la riga corrente
int channels = png_get_channels(m_png_ptr, m_info_ptr);
int rowBytes = png_get_rowbytes(m_png_ptr, m_info_ptr);
png_bytep row_pointer = m_rowBuffer.get();
int lx = m_info.m_lx;
while (passPng <= passRow &&
rowNumber <=
numRows) // finchè il passo d'interlacciamento è minore o uguale
// < //del passo desiderato effettua tante volte le lettura
// della riga
// quant'è il passo desiderato per quella riga
{
rowNumber = png_get_current_row_number(m_png_ptr);
png_read_row(m_png_ptr, row_pointer, NULL);
numRows = png_get_image_height(m_png_ptr, m_info_ptr);
// devo memorizzare la riga letta nel buffer di appoggio in base al passo
// di riga
// e al blocchetto di appartenenza della riga
// copio i pixel che desidero nel buffer temporaneo
// il membro di PngReader copyPixel deve tener conto della riga processata
// e del passo che si è effettuato ( e in base a quello so quanti pixel
// copiare!)
if (m_bit_depth == 16) {
if (passPng == 0)
copyPixel(lx / 4, 0, 8, rowNumber * 8);
else if (passPng == 1)
copyPixel(lx / 4, 8, 8, rowNumber * 8);
else if (passPng == 2)
copyPixel(lx / 2, 0, 4, rowNumber * 8 + 4);
else if (passPng == 3)
copyPixel(lx / 2, 4, 4, rowNumber * 4);
else if (passPng == 4)
copyPixel(lx, 0, 2, rowNumber * 4 + 2);
else if (passPng == 5)
copyPixel(lx, 2, 2, rowNumber * 2);
else if (passPng == 6)
copyPixel(2 * lx, 0, 1, rowNumber * 2 + 1);
} else {
if (passPng == 0)
copyPixel((lx + 7) / 8, 0, 8, rowNumber * 8);
else if (passPng == 1)
copyPixel((lx + 3) / 8, 4, 8, rowNumber * 8);
else if (passPng == 2)
copyPixel((lx + 3) / 4, 0, 4, rowNumber * 8 + 4);
else if (passPng == 3)
copyPixel((lx + 1) / 4, 2, 4, rowNumber * 4);
else if (passPng == 4)
copyPixel((lx + 1) / 2, 0, 2, rowNumber * 4 + 2);
else if (passPng == 5)
copyPixel(lx / 2, 1, 2, rowNumber * 2);
else if (passPng == 6)
copyPixel(lx, 0, 1, rowNumber * 2 + 1);
}
passPng = png_get_current_pass_number(m_png_ptr);
}
// fase di copia
if (channels == 1 || channels == 2) {
if (m_bit_depth < 8)
memcpy(m_rowBuffer.get(), m_tempBuffer.get() + ((m_y)*lx * 3), lx * 3);
else
memcpy(m_rowBuffer.get(), m_tempBuffer.get() + ((m_y)*rowBytes * 4),
rowBytes * 4);
} else {
memcpy(m_rowBuffer.get(), m_tempBuffer.get() + ((m_y)*rowBytes),
rowBytes);
}
// fase di copia vecchia
// memcpy(m_rowBuffer, m_tempBuffer+((m_y)*rowBytes), rowBytes);
// tutto quello che segue lo metto in una funzione in cui scrivo il buffer
// di restituzione della readLine
// è una funzione comune alle ReadLine
writeRow(buffer, x0, x1);
}
void readLineInterlace(short *buffer, int x0, int x1, int shrink) {
// m_png_ptr->row_number è l'indice di riga che scorre quando chiamo la
// png_read_row
int rowNumber = png_get_current_row_number(m_png_ptr);
// numRows è il numero di righe processate in ogni passo
int numRows = png_get_image_height(m_png_ptr, m_info_ptr) / 8;
int passPng = png_get_current_pass_number(
m_png_ptr); // conosco il passo d'interlacciamento
int passRow = 5 + (m_y & 1); // passo desiderato per la riga corrente
int channels = png_get_channels(m_png_ptr, m_info_ptr);
int lx = m_info.m_lx;
int rowBytes = png_get_rowbytes(m_png_ptr, m_info_ptr);
png_bytep row_pointer = m_rowBuffer.get();
while (passPng <= passRow &&
rowNumber <
numRows) // finchè il passo d'interlacciamento è minore o uguale
// del passo desiderato effettua tante volte le lettura della riga
// quant'è il passo desiderato per quella riga
{
rowNumber = png_get_current_row_number(m_png_ptr);
png_read_row(m_png_ptr, row_pointer, NULL);
numRows = png_get_image_height(m_png_ptr, m_info_ptr);
int lx = m_info.m_lx;
// devo memorizzare la riga letta nel buffer di appoggio in base al passo
// di riga
// e al blocchetto di appartenenza della riga
// copio i pixel che desidero nel buffer temporaneo
// il membro di PngReader copyPixel deve tener conto della riga processata
// e del passo che si è effettuato ( e in base a quello so quanti pixel
// copiare!)
int channels = png_get_channels(m_png_ptr, m_info_ptr);
if (passPng == 0)
copyPixel(lx / 4, 0, 8, rowNumber * 8);
else if (passPng == 1)
copyPixel(lx / 4, 8, 8, rowNumber * 8);
else if (passPng == 2)
copyPixel(lx / 2, 0, 4, rowNumber * 8 + 4);
else if (passPng == 3)
copyPixel(lx / 2, 4, 4, rowNumber * 4);
else if (passPng == 4)
copyPixel(lx, 0, 2, rowNumber * 4 + 2);
else if (passPng == 5)
copyPixel(lx, 2, 2, rowNumber * 2);
else if (passPng == 6)
copyPixel(2 * lx, 0, 1, rowNumber * 2 + 1);
passPng = png_get_current_pass_number(m_png_ptr);
}
// fase di copia
if (channels == 1 || channels == 2) {
memcpy(m_rowBuffer.get(), m_tempBuffer.get() + ((m_y)*rowBytes * 4),
rowBytes * 4);
} else {
memcpy(m_rowBuffer.get(), m_tempBuffer.get() + ((m_y)*rowBytes),
rowBytes);
}
// fase di copia
// memcpy(m_rowBuffer, m_tempBuffer+((m_y)*rowBytes), rowBytes);
// tutto quello che segue lo metto in una funzione in cui scrivo il buffer
// di restituzione della readLine
// è una funzione comune alle ReadLine
writeRow(buffer, x0, x1);
}
};
//=========================================================
Tiio::PngWriterProperties::PngWriterProperties()
: m_matte("Alpha Channel", true)
{
bind(m_matte);
}
void Tiio::PngWriterProperties::updateTranslation() {
m_matte.setQStringName(tr("Alpha Channel"));
}
//=========================================================
class PngWriter final : public Tiio::Writer {
png_structp m_png_ptr;
png_infop m_info_ptr;
FILE *m_chan;
bool m_matte;
std::vector<TPixel> *m_colormap;
public:
PngWriter();
~PngWriter();
void open(FILE *file, const TImageInfo &info) override;
void writeLine(char *buffer) override;
void writeLine(short *buffer) override;
Tiio::RowOrder getRowOrder() const override { return Tiio::TOP2BOTTOM; }
void flush() override;
bool write64bitSupported() const override { return true; }
// m_matte is set to "Alpha Channel" property value in the function open()
bool writeAlphaSupported() const override { return m_matte; };
};
//---------------------------------------------------------
PngWriter::PngWriter()
: m_png_ptr(0), m_info_ptr(0), m_matte(true), m_colormap(0) {}
//---------------------------------------------------------
PngWriter::~PngWriter() {
if (m_png_ptr) {
png_destroy_write_struct(&m_png_ptr, &m_info_ptr);
}
if (m_chan) {
fflush(m_chan);
m_chan = 0;
}
}
//---------------------------------------------------------
png_color palette[256];
png_byte alpha[1];
void PngWriter::open(FILE *file, const TImageInfo &info) {
m_info = info;
m_png_ptr = png_create_write_struct(PNG_LIBPNG_VER_STRING,
(png_voidp)0, // user_error_ptr,
0, // user_error_fn,
0); // user_warning_fn);
if (!m_png_ptr) return;
m_info_ptr = png_create_info_struct(m_png_ptr);
if (!m_info_ptr) {
png_destroy_write_struct(&m_png_ptr, (png_infopp)0);
return;
}
m_chan = file;
png_init_io(m_png_ptr, m_chan);
if (!m_properties) m_properties = new Tiio::PngWriterProperties();
TBoolProperty *alphaProp =
(TBoolProperty *)(m_properties->getProperty("Alpha Channel"));
TPointerProperty *colormap =
(TPointerProperty *)(m_properties->getProperty("Colormap"));
m_matte = (alphaProp && alphaProp->getValue()) ? true : false;
if (colormap) m_colormap = (vector<TPixel> *)colormap->getValue();
TUINT32 x_pixels_per_meter = tround(m_info.m_dpix / 0.0254);
TUINT32 y_pixels_per_meter = tround(m_info.m_dpiy / 0.0254);
if (!m_colormap)
png_set_IHDR(m_png_ptr, m_info_ptr, m_info.m_lx, m_info.m_ly,
info.m_bitsPerSample,
m_matte ? PNG_COLOR_TYPE_RGB_ALPHA : PNG_COLOR_TYPE_RGB,
PNG_INTERLACE_NONE, PNG_COMPRESSION_TYPE_DEFAULT,
PNG_FILTER_TYPE_DEFAULT);
else {
png_set_IHDR(m_png_ptr, m_info_ptr, m_info.m_lx, m_info.m_ly, 8,
PNG_COLOR_TYPE_PALETTE, PNG_INTERLACE_NONE,
PNG_COMPRESSION_TYPE_DEFAULT, PNG_FILTER_TYPE_DEFAULT);
for (unsigned int i = 0; i < m_colormap->size(); i++) {
/*unsigned char red = (i>>5)&0x7;
unsigned char green = (i>>2)&0x7;
unsigned char blue = i&0x3;
palette[i].red = (red>>1) | (red<<2) | (red<<5);
palette[i].green = (green>>1) | (green<<2) | (green<<5);
palette[i].blue = blue | (blue<<2) | (blue<<4) | (blue<<6);
if (red==0 && green==0) alpha[i] = 0; else if (blue==0 && green==0)
alpha[i] = 128; else alpha[i] = 255;*/
palette[i].red = (*m_colormap)[i].r;
palette[i].green = (*m_colormap)[i].g;
palette[i].blue = (*m_colormap)[i].b;
}
png_set_PLTE(m_png_ptr, m_info_ptr, palette, m_colormap->size());
}
// png_set_dither(m_png_ptr, palette, 256, 256, 0, 1);
#if defined(TNZ_MACHINE_CHANNEL_ORDER_MBGR)
png_set_bgr(m_png_ptr);
png_set_swap_alpha(m_png_ptr);
#elif defined(TNZ_MACHINE_CHANNEL_ORDER_BGRM)
png_set_bgr(m_png_ptr);
#elif defined(TNZ_MACHINE_CHANNEL_ORDER_MRGB)
png_set_swap_alpha(m_png_ptr);
#elif !defined(TNZ_MACHINE_CHANNEL_ORDER_RGBM)
#error "unknownchannel order"
#endif
png_set_pHYs(m_png_ptr, m_info_ptr, x_pixels_per_meter, y_pixels_per_meter,
1);
if (m_colormap && m_matte) {
alpha[0] = 0;
// png_set_tRNS(m_png_ptr, m_info_ptr, alpha, 1, PNG_COLOR_TYPE_PALETTE);
png_color_16 bgcolor;
bgcolor.index = 0;
png_set_tRNS(m_png_ptr, m_info_ptr, alpha, 1, &bgcolor);
}
png_write_info(m_png_ptr, m_info_ptr);
}
//---------------------------------------------------------
void PngWriter::flush() {
png_write_end(m_png_ptr, m_info_ptr);
fflush(m_chan);
}
//---------------------------------------------------------
void PngWriter::writeLine(short *buffer) {
{
TPixel64 *pix = (TPixel64 *)buffer;
unsigned short *tmp;
tmp = (unsigned short *)malloc((m_info.m_lx + 1) * 3);
// unsigned short tmp[10000];
int k = 0;
for (int j = 0; j < m_info.m_lx; j++, pix++) {
// depremultiply here
TPixel64 depremult_pix(*pix);
if (m_matte && depremult_pix.m != 0) depremult(depremult_pix);
#if defined(TNZ_MACHINE_CHANNEL_ORDER_MRGB) || \
defined(TNZ_MACHINE_CHANNEL_ORDER_RGBM)
tmp[k++] = mySwap(pix->r);
tmp[k++] = mySwap(pix->g);
tmp[k++] = mySwap(pix->b);
#elif defined(TNZ_MACHINE_CHANNEL_ORDER_MBGR) || \
defined(TNZ_MACHINE_CHANNEL_ORDER_BGRM)
tmp[k++] = mySwap(pix->b);
tmp[k++] = mySwap(pix->g);
tmp[k++] = mySwap(pix->r);
#else
#error "unknown channel order"
#endif
if (m_matte)
tmp[k++] = mySwap(pix->m); // ?? does it take care MRGB or MBGR case?
}
png_write_row(m_png_ptr, (unsigned char *)tmp);
}
}
//=========================================================
void PngWriter::writeLine(char *buffer) {
// TBoolProperty* alphaProp =
// (TBoolProperty*)(m_properties->getProperty("Alpha Channel"));
if (m_matte || m_colormap) {
unsigned char *tmp = new unsigned char[(m_info.m_lx + 1) * 4];
TPixel32 *pix = (TPixel32 *)buffer;
int k = 0;
for (int j = 0; j < m_info.m_lx; j++, pix++) {
// depremultiply here
TPixel32 depremult_pix(*pix);
if (depremult_pix.m != 0) depremult(depremult_pix);
#if defined(TNZ_MACHINE_CHANNEL_ORDER_MRGB)
tmp[k++] = depremult_pix.m;
tmp[k++] = depremult_pix.r;
tmp[k++] = depremult_pix.g;
tmp[k++] = depremult_pix.b;
#elif defined(TNZ_MACHINE_CHANNEL_ORDER_RGBM)
tmp[k++] = depremult_pix.r;
tmp[k++] = depremult_pix.g;
tmp[k++] = depremult_pix.b;
tmp[k++] = depremult_pix.m;
#elif defined(TNZ_MACHINE_CHANNEL_ORDER_MBGR)
tmp[k++] = depremult_pix.m;
tmp[k++] = depremult_pix.b;
tmp[k++] = depremult_pix.g;
tmp[k++] = depremult_pix.r;
#elif defined(TNZ_MACHINE_CHANNEL_ORDER_BGRM)
tmp[k++] = depremult_pix.b;
tmp[k++] = depremult_pix.g;
tmp[k++] = depremult_pix.r;
tmp[k++] = depremult_pix.m;
#else
#error "unknown channel order"
#endif
}
png_write_row(m_png_ptr, tmp);
delete[] tmp;
} else {
TPixel32 *pix = (TPixel32 *)buffer;
unsigned char *tmp = new unsigned char[(m_info.m_lx + 1) * 3];
int k = 0;
for (int j = 0; j < m_info.m_lx; j++) {
// tmp = (pix->r&0xe0)|((pix->g&0xe0)>>3) | ((pix->b&0xc0)>>6);
#if defined(TNZ_MACHINE_CHANNEL_ORDER_MRGB) || \
defined(TNZ_MACHINE_CHANNEL_ORDER_RGBM)
tmp[k++] = pix->r;
tmp[k++] = pix->g;
tmp[k++] = pix->b;
#elif defined(TNZ_MACHINE_CHANNEL_ORDER_MBGR) || \
defined(TNZ_MACHINE_CHANNEL_ORDER_BGRM)
tmp[k++] = pix->b;
tmp[k++] = pix->g;
tmp[k++] = pix->r;
#else
#error "unknown channel order"
#endif
++pix;
}
png_write_row(m_png_ptr, tmp);
delete[] tmp;
}
}
//=========================================================
Tiio::Reader *Tiio::makePngReader() { return new PngReader(); }
Tiio::Writer *Tiio::makePngWriter() { return new PngWriter(); }