//
// "$Id: Fl_Shared_Image.cxx 12002 2016-10-01 22:35:37Z AlbrechtS $"
//
// Shared image code for the Fast Light Tool Kit (FLTK).
//
// Copyright 1998-2016 by Bill Spitzak and others.
//
// This library is free software. Distribution and use rights are outlined in
// the file "COPYING" which should have been included with this file. If this
// file is missing or damaged, see the license at:
//
// http://www.fltk.org/COPYING.php
//
// Please report all bugs and problems on the following page:
//
// http://www.fltk.org/str.php
//
#include <stdio.h>
#include <stdlib.h>
#include <FL/fl_utf8.h>
#include "flstring.h"
#include <FL/Fl.H>
#include <FL/Fl_Shared_Image.H>
#include <FL/Fl_XBM_Image.H>
#include <FL/Fl_XPM_Image.H>
#include <FL/Fl_Preferences.H>
#include <FL/fl_draw.H>
//
// Global class vars...
//
Fl_Shared_Image **Fl_Shared_Image::images_ = 0; // Shared images
int Fl_Shared_Image::num_images_ = 0; // Number of shared images
int Fl_Shared_Image::alloc_images_ = 0; // Allocated shared images
Fl_Shared_Handler *Fl_Shared_Image::handlers_ = 0;// Additional format handlers
int Fl_Shared_Image::num_handlers_ = 0; // Number of format handlers
int Fl_Shared_Image::alloc_handlers_ = 0; // Allocated format handlers
//
// Typedef the C API sort function type the only way I know how...
//
extern "C" {
typedef int (*compare_func_t)(const void *, const void *);
}
/** Returns the Fl_Shared_Image* array */
Fl_Shared_Image **Fl_Shared_Image::images() {
return images_;
}
/** Returns the total number of shared images in the array. */
int Fl_Shared_Image::num_images() {
return num_images_;
}
/**
Compares two shared images.
The order of comparison is:
-# Image name, usually the filename used to load it
-# Image width
-# Image height
A special case is considered if the width of one of the images is zero
and the other image is marked \p original. In this case the images match,
i.e. the comparison returns success (0).
An image is marked \p original if it was directly loaded from a file or
from memory as opposed to copied and resized images.
This comparison is used in Fl_Shared_Image::find() to find an image that
matches the requested one or to find the position where a new image
should be entered into the sorted list of shared images.
It is usually used in two steps:
-# search with exact width and height
-# if not found, search again with width = 0 (and height = 0)
The first step will only return a match if the image exists with the
same width and height. The second step will match if there is an image
marked \p original with the same name, regardless of width and height.
\returns Whether the images match or their relative sort order (see text).
\retval 0 the images match
\retval <0 Image \p i0 is \e less than image \p i1
\retval >0 Image \p i0 is \e greater than image \p i1
*/
int
Fl_Shared_Image::compare(Fl_Shared_Image **i0, // I - First image
Fl_Shared_Image **i1) { // I - Second image
int i = strcmp((*i0)->name(), (*i1)->name());
if (i) return i;
else if (((*i0)->w() == 0 && (*i1)->original_) ||
((*i1)->w() == 0 && (*i0)->original_)) return 0;
else if ((*i0)->w() != (*i1)->w()) return (*i0)->w() - (*i1)->w();
else return (*i0)->h() - (*i1)->h();
}
/**
Creates an empty shared image.
The constructors create a new shared image record in the image cache.
The constructors are protected and cannot be used directly
from a program. Use the get() method instead.
*/
Fl_Shared_Image::Fl_Shared_Image() : Fl_Image(0,0,0) {
name_ = 0;
refcount_ = 1;
original_ = 0;
image_ = 0;
alloc_image_ = 0;
#if FLTK_ABI_VERSION >= 10304
scaled_image_= 0;
#endif
}
/**
Creates a shared image from its filename and its corresponding Fl_Image* img.
The constructors create a new shared image record in the image cache.
The constructors are protected and cannot be used directly
from a program. Use the get() method instead.
*/
Fl_Shared_Image::Fl_Shared_Image(const char *n, // I - Filename
Fl_Image *img) // I - Image
: Fl_Image(0,0,0) {
name_ = new char[strlen(n) + 1];
strcpy((char *)name_, n);
refcount_ = 1;
image_ = img;
alloc_image_ = !img;
original_ = 1;
#if FLTK_ABI_VERSION >= 10304
scaled_image_= 0;
#endif
if (!img) reload();
else update();
}
/**
Adds a shared image to the image cache.
This \b protected method adds an image to the cache, an ordered list
of shared images. The cache is searched for a matching image whenever
one is requested, for instance with Fl_Shared_Image::get() or
Fl_Shared_Image::find().
*/
void
Fl_Shared_Image::add() {
Fl_Shared_Image **temp; // New image pointer array...
if (num_images_ >= alloc_images_) {
// Allocate more memory...
temp = new Fl_Shared_Image *[alloc_images_ + 32];
if (alloc_images_) {
memcpy(temp, images_, alloc_images_ * sizeof(Fl_Shared_Image *));
delete[] images_;
}
images_ = temp;
alloc_images_ += 32;
}
images_[num_images_] = this;
num_images_ ++;
if (num_images_ > 1) {
qsort(images_, num_images_, sizeof(Fl_Shared_Image *),
(compare_func_t)compare);
}
}
//
// 'Fl_Shared_Image::update()' - Update the dimensions of the shared images.
//
void
Fl_Shared_Image::update() {
if (image_) {
w(image_->w());
h(image_->h());
d(image_->d());
data(image_->data(), image_->count());
}
}
/**
The destructor frees all memory and server resources that are
used by the image.
The destructor is protected and cannot be used directly from a program.
Use the Fl_Shared_Image::release() method instead.
*/
Fl_Shared_Image::~Fl_Shared_Image() {
if (name_) delete[] (char *)name_;
if (alloc_image_) delete image_;
#if FLTK_ABI_VERSION >= 10304
delete scaled_image_;
#endif
}
/**
Releases and possibly destroys (if refcount <= 0) a shared image.
In the latter case, it will reorganize the shared image array
so that no hole will occur.
*/
void Fl_Shared_Image::release() {
int i; // Looping var...
refcount_ --;
if (refcount_ > 0) return;
for (i = 0; i < num_images_; i ++)
if (images_[i] == this) {
num_images_ --;
if (i < num_images_) {
memmove(images_ + i, images_ + i + 1,
(num_images_ - i) * sizeof(Fl_Shared_Image *));
}
break;
}
delete this;
if (num_images_ == 0 && images_) {
delete[] images_;
images_ = 0;
alloc_images_ = 0;
}
}
/** Reloads the shared image from disk. */
void Fl_Shared_Image::reload() {
// Load image from disk...
int i; // Looping var
FILE *fp; // File pointer
uchar header[64]; // Buffer for auto-detecting files
Fl_Image *img; // New image
if (!name_) return;
if ((fp = fl_fopen(name_, "rb")) != NULL) {
if (fread(header, 1, sizeof(header), fp)==0) { /* ignore */ }
fclose(fp);
} else {
return;
}
// Load the image as appropriate...
if (memcmp(header, "#define", 7) == 0) // XBM file
img = new Fl_XBM_Image(name_);
else if (memcmp(header, "/* XPM */", 9) == 0) // XPM file
img = new Fl_XPM_Image(name_);
else {
// Not a standard format; try an image handler...
for (i = 0, img = 0; i < num_handlers_; i ++) {
img = (handlers_[i])(name_, header, sizeof(header));
if (img) break;
}
}
if (img) {
if (alloc_image_) delete image_;
alloc_image_ = 1;
if ((img->w() != w() && w()) || (img->h() != h() && h())) {
// Make sure the reloaded image is the same size as the existing one.
Fl_Image *temp = img->copy(w(), h());
delete img;
image_ = temp;
} else {
image_ = img;
}
update();
}
}
//
// 'Fl_Shared_Image::copy()' - Copy and resize a shared image...
//
// Note: intentionally no doxygen docs here.
// For doxygen docs see Fl_Image::copy().
Fl_Image *
Fl_Shared_Image::copy(int W, int H) {
Fl_Image *temp_image; // New image file
Fl_Shared_Image *temp_shared; // New shared image
// Make a copy of the image we're sharing...
if (!image_) temp_image = 0;
else temp_image = image_->copy(W, H);
// Then make a new shared image...
temp_shared = new Fl_Shared_Image();
temp_shared->name_ = new char[strlen(name_) + 1];
strcpy((char *)temp_shared->name_, name_);
temp_shared->refcount_ = 1;
temp_shared->image_ = temp_image;
temp_shared->alloc_image_ = 1;
temp_shared->update();
return temp_shared;
}
//
// 'Fl_Shared_Image::color_average()' - Blend colors...
//
void
Fl_Shared_Image::color_average(Fl_Color c, // I - Color to blend with
float i) { // I - Blend fraction
if (!image_) return;
image_->color_average(c, i);
update();
}
//
// 'Fl_Shared_Image::desaturate()' - Convert the image to grayscale...
//
void
Fl_Shared_Image::desaturate() {
if (!image_) return;
image_->desaturate();
update();
}
//
// 'Fl_Shared_Image::draw()' - Draw a shared image...
//
void Fl_Shared_Image::draw(int X, int Y, int W, int H, int cx, int cy) {
#if FLTK_ABI_VERSION >= 10304
if (!image_) {
Fl_Image::draw(X, Y, W, H, cx, cy);
return;
}
if (w() == image_->w() && h() == image_->h()) {
image_->draw(X, Y, W, H, cx, cy);
return;
}
fl_push_clip(X, Y, W, H);
int done = 0;
// don't call Fl_Graphics_Driver::draw_scaled(Fl_Image*,...) for an enlarged Fl_Bitmap or Fl_Pixmap
if ((d() != 0 && count() < 2) || (w() <= image_->w() && h() <= image_->h())) {
done = fl_graphics_driver->draw_scaled(image_, X-cx, Y-cy, w(), h());
}
if (!done) {
if (scaled_image_ && (scaled_image_->w() != w() || scaled_image_->h() != h())) {
delete scaled_image_;
scaled_image_ = NULL;
}
if (!scaled_image_) {
Fl_RGB_Scaling previous = RGB_scaling();
RGB_scaling(scaling_algorithm_); // useless but no harm if image_ is not an Fl_RGB_Image
scaled_image_ = image_->copy(w(), h());
RGB_scaling(previous);
}
scaled_image_->draw(X-cx, Y-cy, scaled_image_->w(), scaled_image_->h(), 0, 0);
}
fl_pop_clip();
#else
if (image_) image_->draw(X, Y, W, H, cx, cy);
else Fl_Image::draw(X, Y, W, H, cx, cy);
#endif // FLTK_ABI_VERSION
}
/** Sets the drawing size of the shared image.
This function gives the shared image its own size, independently from the size of the original image
that is typically larger.
This can be useful to draw a shared image on a drawing surface whose resolution is higher
than the drawing unit for this surface: all pixels of the original image become available to fill
an area of the drawing surface sized at <tt>width,height</tt>.
Examples of such drawing surfaces: laser printers, PostScript files, PDF printers, retina displays on Apple hardware.
\param width,height maximum width and height (in drawing units) to use when drawing the shared image
\param proportional if not null, keep the width and height of the shared image proportional to those of its original image
\param can_expand if null, the width and height of the shared image will not exceed those of the original image
\version 1.3.4 and requires compiling with FLTK_ABI_VERSION = 10304
Example code: scale an image to fit in a box
\code
Fl_Box *b = ... // a box
Fl_Shared_Image *shared = Fl_Shared_Image::get("/path/to/picture.jpeg"); // read a picture file
shared->scale(b->w(), b->h(), 1); // set the drawing size of the shared image to the size of the box
b->image(shared); // use the shared image as the box image
b->align(FL_ALIGN_INSIDE | FL_ALIGN_CENTER | FL_ALIGN_CLIP); // the image is to be drawn centered in the box
\endcode
*/
void Fl_Shared_Image::scale(int width, int height, int proportional, int can_expand)
{
#if FLTK_ABI_VERSION >= 10304
w(width);
h(height);
if (!image_) return;
float fw = image_->w() / float(width);
float fh = image_->h() / float(height);
if (proportional) {
if (fh > fw) fw = fh;
else fh = fw;
}
if (!can_expand) {
if (fw < 1) fw = 1;
if (fh < 1) fh = 1;
}
w(int(image_->w() / fw));
h(int(image_->h() / fh));
#endif
}
Fl_RGB_Scaling Fl_Shared_Image::scaling_algorithm_ = FL_RGB_SCALING_BILINEAR;
//
// 'Fl_Shared_Image::uncache()' - Uncache the shared image...
//
void Fl_Shared_Image::uncache()
{
if (image_) image_->uncache();
}
/** Finds a shared image from its name and size specifications.
This uses a binary search in the image cache.
If the image \p name exists with the exact width \p W and height \p H,
then it is returned.
If \p W == 0 and the image \p name exists with another size, then the
\b original image with that \p name is returned.
In either case the refcount of the returned image is increased.
The found image should be released with Fl_Shared_Image::release()
when no longer needed.
*/
Fl_Shared_Image* Fl_Shared_Image::find(const char *name, int W, int H) {
Fl_Shared_Image *key, // Image key
**match; // Matching image
if (num_images_) {
key = new Fl_Shared_Image();
key->name_ = new char[strlen(name) + 1];
strcpy((char *)key->name_, name);
key->w(W);
key->h(H);
match = (Fl_Shared_Image **)bsearch(&key, images_, num_images_,
sizeof(Fl_Shared_Image *),
(compare_func_t)compare);
delete key;
if (match) {
(*match)->refcount_ ++;
return *match;
}
}
return 0;
}
/**
Find or load an image that can be shared by multiple widgets.
If the image exists with the requested size, this image will be returned.
If the image exists, but only with another size, then a new copy with the
requested size (width \p W and height \p H) will be created as a resized
copy of the original image. The new image is added to the internal list
of shared images.
If the image does not yet exist, then a new image of the proper
dimension is created from the filename \p name. The original image
from filename \p name is always added to the list of shared images in
its original size. If the requested size differs, then the resized
copy with width \p W and height \p H is also added to the list of
shared images.
\note If the sizes differ, then \e two images are created as mentioned above.
This is intentional so the original image is cached and preserved.
If you request the same image with another size later, then the
\b original image will be found, copied, resized, and returned.
Shared JPEG and PNG images can also be created from memory by using their
named memory access constructor.
You should release() the image when you're done with it.
\param name name of the image
\param W, H desired size
\see Fl_Shared_Image::find(const char *name, int W, int H)
\see Fl_Shared_Image::release()
\see Fl_JPEG_Image::Fl_JPEG_Image(const char *name, const unsigned char *data)
\see Fl_PNG_Image::Fl_PNG_Image (const char *name_png, const unsigned char *buffer, int maxsize)
*/
Fl_Shared_Image* Fl_Shared_Image::get(const char *name, int W, int H) {
Fl_Shared_Image *temp; // Image
if ((temp = find(name, W, H)) != NULL) return temp;
if ((temp = find(name)) == NULL) {
temp = new Fl_Shared_Image(name);
if (!temp->image_) {
delete temp;
return NULL;
}
temp->add();
}
if ((temp->w() != W || temp->h() != H) && W && H) {
temp = (Fl_Shared_Image *)temp->copy(W, H);
temp->add();
}
return temp;
}
/** Builds a shared image from a pre-existing Fl_RGB_Image.
\param[in] rgb an Fl_RGB_Image used to build a new shared image.
\param[in] own_it 1 if the shared image should delete \p rgb when
it is itself deleted, 0 otherwise
\version 1.3.4
*/
Fl_Shared_Image *Fl_Shared_Image::get(Fl_RGB_Image *rgb, int own_it)
{
Fl_Shared_Image *shared = new Fl_Shared_Image(Fl_Preferences::newUUID(), rgb);
shared->alloc_image_ = own_it;
shared->add();
return shared;
}
/** Adds a shared image handler, which is basically a test function
for adding new formats.
*/
void Fl_Shared_Image::add_handler(Fl_Shared_Handler f) {
int i; // Looping var...
Fl_Shared_Handler *temp; // New image handler array...
// First see if we have already added the handler...
for (i = 0; i < num_handlers_; i ++) {
if (handlers_[i] == f) return;
}
if (num_handlers_ >= alloc_handlers_) {
// Allocate more memory...
temp = new Fl_Shared_Handler [alloc_handlers_ + 32];
if (alloc_handlers_) {
memcpy(temp, handlers_, alloc_handlers_ * sizeof(Fl_Shared_Handler));
delete[] handlers_;
}
handlers_ = temp;
alloc_handlers_ += 32;
}
handlers_[num_handlers_] = f;
num_handlers_ ++;
}
/** Removes a shared image handler. */
void Fl_Shared_Image::remove_handler(Fl_Shared_Handler f) {
int i; // Looping var...
// First see if the handler has been added...
for (i = 0; i < num_handlers_; i ++) {
if (handlers_[i] == f) break;
}
if (i >= num_handlers_) return;
// OK, remove the handler from the array...
num_handlers_ --;
if (i < num_handlers_) {
// Shift later handlers down 1...
memmove(handlers_ + i, handlers_ + i + 1,
(num_handlers_ - i) * sizeof(Fl_Shared_Handler ));
}
}
//
// End of "$Id: Fl_Shared_Image.cxx 12002 2016-10-01 22:35:37Z AlbrechtS $".
//