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-rw-r--r--generic/tkImgGIF.c364
-rw-r--r--generic/tkImgPhoto.c30
2 files changed, 297 insertions, 97 deletions
diff --git a/generic/tkImgGIF.c b/generic/tkImgGIF.c
index 3653141..52ba2d7 100644
--- a/generic/tkImgGIF.c
+++ b/generic/tkImgGIF.c
@@ -29,7 +29,7 @@
* | provided "as is" without express or implied warranty. |
* +-------------------------------------------------------------------+
*
- * RCS: @(#) $Id: tkImgGIF.c,v 1.8 1999/12/09 14:46:33 hobbs Exp $
+ * RCS: @(#) $Id: tkImgGIF.c,v 1.9 2000/01/26 21:11:00 ericm Exp $
*/
/*
@@ -717,6 +717,41 @@ GetDataBlock(chan, buf)
}
+
+/*
+ *----------------------------------------------------------------------
+ *
+ * ReadImage --
+ *
+ * Process a GIF image from a given source, with a given height,
+ * width, transparency, etc.
+ *
+ * This code is based on the code found in the ImageMagick GIF decoder,
+ * which is (c) 2000 ImageMagick Studio.
+ *
+ * Some thoughts on our implementation:
+ * We currently have implementations for two separate GIF decoders in
+ * this source. One is here, in ReadImage; the other is in LWZReadByte.
+ * This is an artifact of our original implementation. Ideally, we
+ * should remove all vestiges of LWZReadByte, which is slow and poorly
+ * documented. However, that would require some additional effort to
+ * collapse the calling layers of this system: Instead of
+ * FileReadGIF -> ReadImage, it would change to FileReadGIF.
+ *
+ * Possible further optimizations: we could pull the GetCode function
+ * directly into ReadImage, which would improve our speed. The reason
+ * I have not yet done so is because GetCode is still used by LWZReadByte,
+ * and I don't want to duplicate the code.
+ *
+ * Results:
+ * Processes a GIF image and loads the pixel data into a memory array.
+ *
+ * Side effects:
+ * None.
+ *
+ *----------------------------------------------------------------------
+ */
+
static int
ReadImage(interp, imagePtr, chan, len, rows, cmap,
width, height, srcX, srcY, interlace, transparent)
@@ -730,26 +765,28 @@ ReadImage(interp, imagePtr, chan, len, rows, cmap,
int interlace;
int transparent;
{
- unsigned char c;
+ unsigned char initialCodeSize;
int v;
- int xpos = 0, ypos = 0, pass = 0;
+ int xpos = 0, ypos = 0, pass = 0, i;
char *pixelPtr;
-
-
+ const static int interlaceStep[] = { 8, 8, 4, 2 };
+ const static int interlaceStart[] = { 0, 4, 2, 1 };
+ unsigned short prefix[(1 << MAX_LWZ_BITS)];
+ unsigned char append[(1 << MAX_LWZ_BITS)];
+ unsigned char stack[(1 << MAX_LWZ_BITS)*2];
+ unsigned char *top;
+ int codeSize, clearCode, inCode, endCode, oldCode, maxCode,
+ code, firstCode;
+
+
/*
- * Initialize the Compression routines
+ * Initialize the decompression routines
*/
- if (! ReadOK(chan, &c, 1)) {
+ if (! ReadOK(chan, &initialCodeSize, 1)) {
Tcl_AppendResult(interp, "error reading GIF image: ",
Tcl_PosixError(interp), (char *) NULL);
return TCL_ERROR;
}
-
- if (LWZReadByte(chan, 1, c) < 0) {
- Tcl_SetResult(interp, "format error in GIF image", TCL_STATIC);
- return TCL_ERROR;
- }
-
if (transparent!=-1) {
cmap[transparent][CM_RED] = 0;
cmap[transparent][CM_GREEN] = 0;
@@ -758,52 +795,154 @@ ReadImage(interp, imagePtr, chan, len, rows, cmap,
}
pixelPtr = imagePtr;
- while ((v = LWZReadByte(chan, 0, c)) >= 0 ) {
- if ((xpos>=srcX) && (xpos<srcX+len) &&
- (ypos>=srcY) && (ypos<srcY+rows)) {
+ /* Initialize the decoder */
+ /* Set values for "special" numbers:
+ * clear code reset the decoder
+ * end code stop decoding
+ * code size size of the next code to retrieve
+ * max code next available table position
+ */
+ clearCode = 1 << (int) initialCodeSize;
+ endCode = clearCode + 1;
+ codeSize = (int) initialCodeSize + 1;
+ maxCode = clearCode + 2;
+ oldCode = -1;
+ firstCode = -1;
+
+ memset((void *)prefix, 0, (1 << MAX_LWZ_BITS) * sizeof(short));
+ memset((void *)append, 0, (1 << MAX_LWZ_BITS) * sizeof(char));
+ for (i = 0; i < clearCode; i++) {
+ append[i] = i;
+ }
+ top = stack;
+
+ GetCode(chan, 0, 1);
+
+ /* Read until we finish the image */
+ for (i = 0, ypos = 0; i < rows; i++) {
+ for (xpos = 0; xpos < len; ) {
+
+ if (top == stack) {
+ /* Bummer -- our stack is empty. Now we have to work! */
+ code = GetCode(chan, codeSize, 0);
+ if (code < 0) {
+ return TCL_OK;
+ }
+
+ if (code > maxCode || code == endCode) {
+ /*
+ * If we're doing things right, we should never
+ * receive a code that is greater than our current
+ * maximum code. If we do, bail, because our decoder
+ * does not yet have that code set up.
+ *
+ * If the code is the magic endCode value, quit.
+ */
+ return TCL_OK;
+ }
+
+ if (code == clearCode) {
+ /* Reset the decoder */
+ codeSize = initialCodeSize + 1;
+ maxCode = clearCode + 2;
+ oldCode = -1;
+ continue;
+ }
+
+ if (oldCode == -1) {
+ /*
+ * Last pass reset the decoder, so the first code we
+ * see must be a singleton. Seed the stack with it,
+ * and set up the old/first code pointers for
+ * insertion into the string table. We can't just
+ * roll this into the clearCode test above, because
+ * at that point we have not yet read the next code.
+ */
+ *top++=append[code];
+ oldCode = code;
+ firstCode = code;
+ continue;
+ }
+
+ inCode = code;
+
+ if (code == maxCode) {
+ /*
+ * maxCode is always one bigger than our highest assigned
+ * code. If the code we see is equal to maxCode, then
+ * we are about to add a new string to the table. ???
+ */
+ *top++ = firstCode;
+ code = oldCode;
+ }
+
+ while (code > clearCode) {
+ /*
+ * Populate the stack by tracing the string in the
+ * string table from its tail to its head
+ */
+ *top++ = append[code];
+ code = prefix[code];
+ }
+ firstCode = append[code];
+
+ /*
+ * If there's no more room in our string table, quit.
+ * Otherwise, add a new string to the table
+ */
+ if (maxCode >= (1 << MAX_LWZ_BITS)) {
+ return TCL_OK;
+ }
+
+ /* Push the head of the string onto the stack */
+ *top++ = firstCode;
+
+ /* Add a new string to the string table */
+ prefix[maxCode] = oldCode;
+ append[maxCode] = firstCode;
+ maxCode++;
+
+ /* maxCode tells us the maximum code value we can accept.
+ * If we see that we need more bits to represent it than
+ * we are requesting from the unpacker, we need to increase
+ * the number we ask for.
+ */
+ if ((maxCode >= (1 << codeSize))
+ && (maxCode < (1<<MAX_LWZ_BITS))) {
+ codeSize++;
+ }
+ oldCode = inCode;
+ }
+
+ /* Pop the next color index off the stack */
+ v = *(--top);
+ if (v < 0) {
+ return TCL_OK;
+ }
*pixelPtr++ = cmap[v][CM_RED];
*pixelPtr++ = cmap[v][CM_GREEN];
*pixelPtr++ = cmap[v][CM_BLUE];
if (transparent >= 0) {
*pixelPtr++ = cmap[v][CM_ALPHA];
}
+ xpos++;
}
- ++xpos;
- if (xpos == width) {
- xpos = 0;
- if (interlace) {
- switch (pass) {
- case 0:
- case 1:
- ypos += 8; break;
- case 2:
- ypos += 4; break;
- case 3:
- ypos += 2; break;
+ /* If interlacing, the next ypos is not just +1 */
+ if (interlace) {
+ ypos += interlaceStep[pass];
+ while (ypos >= height) {
+ pass++;
+ if (pass > 3) {
+ return TCL_OK;
}
-
- while (ypos >= height) {
- ++pass;
- switch (pass) {
- case 1:
- ypos = 4; break;
- case 2:
- ypos = 2; break;
- case 3:
- ypos = 1; break;
- default:
- return TCL_OK;
- }
- }
- } else {
- ++ypos;
+ ypos = interlaceStart[pass];
}
- pixelPtr = imagePtr + (ypos-srcY) * len * ((transparent>=0)?4:3);
+ } else {
+ ypos++;
}
- if (ypos >= height)
- break;
+ pixelPtr = imagePtr + (ypos) * len * ((transparent>=0)?4:3);
}
return TCL_OK;
}
@@ -820,7 +959,8 @@ LWZReadByte(chan, flag, input_code_size)
static int max_code, max_code_size;
static int firstcode, oldcode;
static int clear_code, end_code;
- static int table[2][(1<< MAX_LWZ_BITS)];
+ static int prefix[(1 << MAX_LWZ_BITS)];
+ static int append[(1 << MAX_LWZ_BITS)];
static int stack[(1<<(MAX_LWZ_BITS))*2], *sp;
register int i;
@@ -832,26 +972,31 @@ LWZReadByte(chan, flag, input_code_size)
max_code_size = 2*clear_code;
max_code = clear_code+2;
+ /* Init the lwz unpacker */
GetCode(chan, 0, 1);
fresh = 1;
+ /* Initialize prefix and append tables */
+ memset((void *)prefix, 0, (1 << MAX_LWZ_BITS) * sizeof(int));
+ memset((void *)append, 0, (1 << MAX_LWZ_BITS) * sizeof(int));
for (i = 0; i < clear_code; ++i) {
- table[0][i] = 0;
- table[1][i] = i;
+ append[i] = i;
}
- for (; i < (1<<MAX_LWZ_BITS); ++i) {
- table[0][i] = table[1][0] = 0;
- }
-
sp = stack;
return 0;
} else if (fresh) {
+ /*
+ * find the first "real" code and return that. Because of
+ * how LWZ works, it will necessarily refer to a single char,
+ * so we need not bother with the stack
+ */
fresh = 0;
do {
- firstcode = oldcode = GetCode(chan, code_size, 0);
+ firstcode = GetCode(chan, code_size, 0);
} while (firstcode == clear_code);
+ oldcode = firstcode;
return firstcode;
}
@@ -861,13 +1006,10 @@ LWZReadByte(chan, flag, input_code_size)
while ((code = GetCode(chan, code_size, 0)) >= 0) {
if (code == clear_code) {
+ memset((void *)prefix, 0, (1 << MAX_LWZ_BITS) * sizeof(int));
+ memset((void *)append, 0, (1 << MAX_LWZ_BITS) * sizeof(int));
for (i = 0; i < clear_code; ++i) {
- table[0][i] = 0;
- table[1][i] = i;
- }
-
- for (; i < (1<<MAX_LWZ_BITS); ++i) {
- table[0][i] = table[1][i] = 0;
+ append[i] = i;
}
code_size = set_code_size+1;
@@ -901,8 +1043,8 @@ LWZReadByte(chan, flag, input_code_size)
}
while (code >= clear_code) {
- *sp++ = table[1][code];
- if (code == table[0][code]) {
+ *sp++ = append[code];
+ if (code == prefix[code]) {
return -2;
/*
@@ -911,14 +1053,14 @@ LWZReadByte(chan, flag, input_code_size)
printf("circular table entry BIG ERROR\n");
*/
}
- code = table[0][code];
+ code = prefix[code];
}
- *sp++ = firstcode = table[1][code];
+ *sp++ = firstcode = append[code];
if ((code = max_code) <(1<<MAX_LWZ_BITS)) {
- table[0][code] = oldcode;
- table[1][code] = firstcode;
+ prefix[code] = oldcode;
+ append[code] = firstcode;
++max_code;
if ((max_code>=max_code_size) && (max_code_size < (1<<MAX_LWZ_BITS))) {
max_code_size *= 2;
@@ -934,6 +1076,35 @@ LWZReadByte(chan, flag, input_code_size)
return code;
}
+
+/*
+ *----------------------------------------------------------------------
+ *
+ * GetCode --
+ *
+ * Extract the next compression code from the file. In GIF's, the
+ * compression codes are between 3 and 12 bits long and are then
+ * packed into 8 bit bytes, left to right, for example:
+ * bbbaaaaa
+ * dcccccbb
+ * eeeedddd
+ * ...
+ * We use a byte buffer read from the file and a sliding window
+ * to unpack the bytes. Thanks to ImageMagick for the sliding window
+ * idea.
+ * args: chan the channel to read from
+ * code_size size of the code to extract
+ * flag boolean indicating whether the extractor
+ * should be reset or not
+ *
+ * Results:
+ * code the next compression code
+ *
+ * Side effects:
+ * May consume more input from chan.
+ *
+ *----------------------------------------------------------------------
+ */
static int
GetCode(chan, code_size, flag)
@@ -942,46 +1113,51 @@ GetCode(chan, code_size, flag)
int flag;
{
static unsigned char buf[280];
- static int curbit, lastbit, done, last_byte;
- int i, j, ret;
- unsigned char count;
+ static int bytes = 0, done;
+ static unsigned char *c;
+ static unsigned int window;
+ static int bitsInWindow = 0;
+ int ret;
+
if (flag) {
- curbit = 0;
- lastbit = 0;
+ /* Initialize the decoder */
+ bitsInWindow = 0;
+ bytes = 0;
+ window = 0;
done = 0;
+ c = NULL;
return 0;
}
-
- if ( (curbit+code_size) >= lastbit) {
+ while (bitsInWindow < code_size) {
+ /* Not enough bits in our window to cover the request */
if (done) {
- /* ran off the end of my bits */
return -1;
}
- if (last_byte >= 2) {
- buf[0] = buf[last_byte-2];
- }
- if (last_byte >= 1) {
- buf[1] = buf[last_byte-1];
- }
-
- if ((count = GetDataBlock(chan, &buf[2])) == 0) {
- done = 1;
+ if (bytes == 0) {
+ /* Not enough bytes in our buffer to add to the window */
+ bytes = GetDataBlock(chan, buf);
+ c = buf;
+ if (bytes <= 0) {
+ done = 1;
+ break;
+ }
}
-
- last_byte = 2 + count;
- curbit = (curbit - lastbit) + 16;
- lastbit = (2+count)*8 ;
- }
-
- ret = 0;
- for (i = curbit, j = 0; j < code_size; ++i, ++j) {
- ret |= ((buf[ i / 8 ] & (1 << (i % 8))) != 0) << j;
+ /* Tack another byte onto the window, see if that's enough */
+ window += (*c) << bitsInWindow;
+ c++;
+ bitsInWindow += 8;
+ bytes--;
}
- curbit += code_size;
+ /* The next code will always be the last code_size bits of the window */
+ ret = window & ((1 << code_size) - 1);
+
+ /* Shift data in the window to put the next code at the end */
+ window >>= code_size;
+ bitsInWindow -= code_size;
return ret;
}
diff --git a/generic/tkImgPhoto.c b/generic/tkImgPhoto.c
index 97e61af..17b61eb 100644
--- a/generic/tkImgPhoto.c
+++ b/generic/tkImgPhoto.c
@@ -15,7 +15,7 @@
* Department of Computer Science,
* Australian National University.
*
- * RCS: @(#) $Id: tkImgPhoto.c,v 1.13 2000/01/26 17:02:27 ericm Exp $
+ * RCS: @(#) $Id: tkImgPhoto.c,v 1.14 2000/01/26 21:11:00 ericm Exp $
*/
#include "tkInt.h"
@@ -3760,7 +3760,13 @@ Tk_PhotoPutBlock(handle, blockPtr, x, y, width, height)
destLinePtr = masterPtr->pix24 + (y * masterPtr->width + x) * 4;
pitch = masterPtr->width * 4;
- if ((blockPtr->pixelSize == 4) && (greenOffset == 1) && (blueOffset == 2) && (alphaOffset == 0)
+ /*
+ * This test is probably too restrictive. We should also be able to
+ * do a memcpy if pixelSize == 3 and alphaOffset == 0. Maybe other cases
+ * too.
+ */
+ if ((blockPtr->pixelSize == 4)
+ && (greenOffset == 1) && (blueOffset == 2) && (alphaOffset == 3)
&& (width <= blockPtr->width) && (height <= blockPtr->height)
&& ((height == 1) || ((x == 0) && (width == masterPtr->width)
&& (blockPtr->pitch == pitch)))) {
@@ -3811,7 +3817,25 @@ Tk_PhotoPutBlock(handle, blockPtr, x, y, width, height)
if (alphaOffset) {
int x1, y1, end;
-
+
+ /*
+ * This block is grossly inefficient. For each row in the image, it
+ * finds each continguous string of transparent pixels, then marks those
+ * areas as invalid in the validRegion mask. This makes drawing very
+ * efficient, because of the way we use X: we just say, here's your
+ * mask, and here's your data. We need not worry about the current
+ * background color, etc. But this costs us a lot on the image setup.
+ * Still, image setup only happens once, whereas the drawing happens
+ * many times, so this might be the best way to go.
+ *
+ * An alternative might be to not set up this mask, and instead, at
+ * drawing time, for each transparent pixel, set its color to the
+ * color of the background behind that pixel. This is what I suspect
+ * most of programs do. However, they don't have to deal with the canvas,
+ * which could have many different background colors. Determining the
+ * correct bg color for a given pixel might be expensive.
+ */
+
destLinePtr = masterPtr->pix24 + (y * masterPtr->width + x) * 4 + 3;
for (y1 = 0; y1 < height; y1++) {
x1 = 0;