void simply_res_clear(SimplyRes *self) {
while (self->images) {
destroy_image(self, (SimplyImage*) self->images);
}
while (self->fonts) {
destroy_font(self, (SimplyFont*) self->fonts);
}
}
/* Cleanup
* -------
*
* Clean up is simple enough. Just destroy the tile
* image and free the state structure memory.
*/
static void destroy_sample(void* data)
{
struct state* state = data;
cleanup_walls(state);
cleanup_tiles(state);
destroy_image(state->tile_img);
cpBodyFree(state->mouse_body);
cpSpaceFree(state->space);
free(data);
}
void res_destroy_images(void)
{
const struct image_info *info;
for (info = image_infos; info->image != NULL; info++) {
if (info->image->data != NULL) {
destroy_image(info->image);
info->image->data = NULL;
}
}
}
/* Destroying a wizard means destroying each and every
* created resource in the **create\_wizard** function.
* If we fail to do so, we will introduce a memory leak
* to the game.
*/
static void destroy_wizard(struct wizard* wizard)
{
if (wizard != NULL) {
destroy_animation(wizard->walk_right);
destroy_animation(wizard->spell);
destroy_animation(wizard->stand);
destroy_image(wizard->sprite->image);
destroy_sprite(wizard->sprite);
free(wizard);
}
}
void Loser()
{
loseTimes++;
int count=1;
Image *loser;
int ran,i;
srand( time(NULL) );
ran=rand()%2;
while(count<=6)
{
clearScreen();
switch(count)
{
case 1:
loser= read_image("Loser1.pixel","Loser1.color");
break;
case 2:
loser= read_image("Loser2.pixel","Loser2.color");
break;
case 3:
loser= read_image("Loser3.pixel","Loser3.color");
break;
case 4:
loser= read_image("Loser4.pixel","Loser4.color");
break;
case 5:
loser= read_image("Loser5.pixel","Loser5.color");
break;
case 6:
loser= read_image("Loser6.pixel","Loser6.color");
default:
break;
}
count++;
show_image(loser,120,35);
drawCmdWindow(); /* update window immediately */
for(i=0; i<1; i++)
{
playAudio(&audioLose[ran]);
//Sleep(100);
}
Sleep(300);
}
destroy_image(loser);
showTable();
}
void Loser2(int x,int y) //small lose send location
{
int count=1;
Image *loser;
int ran,i;
srand( time(NULL) );
ran=rand()%2;
while(count<=6)
{
clearScreen();
switch(count)
{
case 1:
loser= read_image("Loser21.pixel","Loser21.color");
break;
case 2:
loser= read_image("Loser22.pixel","Loser22.color");
break;
case 3:
loser= read_image("Loser23.pixel","Loser23.color");
break;
case 4:
loser= read_image("Loser24.pixel","Loser24.color");
break;
case 5:
loser= read_image("Loser25.pixel","Loser25.color");
break;
case 6:
loser= read_image("Loser26.pixel","Loser26.color");
default:
break;
}
count++;
show_image(loser,x,y);
drawCmdWindow(); /* update window immediately */
for(i=0; i<1; i++)
{
playAudio(&audioLose[ran]);
//Sleep(300);
}
Sleep(300);
}
destroy_image(loser);
}
static int encode(const char *infile) {
int ok;
image_t image;
const char *outfile;
if(use_verbose) {
printf("encoding %s.. ", infile);
}
if(get_image(infile, &image) < 0) {
fprintf(stderr, "failed reading %s\n", infile);
return -EINVAL;
}
if(valid_size(image.w) == 0 || valid_size(image.h) == 0) {
fprintf(stderr, "image dimensions for %s are not valid, see manual\n", infile);
destroy_image(&image);
return -EINVAL;
}
outfile = figure_outfilename(infile, "kmg");
if(outfile == NULL) {
fprintf(stderr, "memory allocation failed for %s\n", infile);
return -ENOMEM;
}
/* Convert the input image to a 16-bit image according to parameters */
convert_to_16(&image);
/* Save it */
ok = save(outfile, &image);
destroy_image(&image);
printf("\n");
return ok;
}
bool Images::load_texture( ClutterTexture * texture, gpointer data, gsize size, const char * content_type )
{
TPImage * image = decode_image( data, size, content_type );
if ( ! image )
{
return false;
}
load_texture( texture, image, 0, 0, image->width, image->height );
destroy_image( image );
return true;
}
bool Images::load_texture( ClutterTexture * texture, const char * filename )
{
TPImage * image = decode_image( filename );
if ( ! image )
{
return false;
}
load_texture( texture, image, 0, 0, image->width, image->height );
destroy_image( image );
return true;
}
void Xvars::gen_pix_from_trans(int dpyNum,Drawable dest,Drawable src,
const Size& srcSize,TransformType transform,
int depth) {
// Get source image into client memory.
XImage* srcImage =
XGetImage(dpy[dpyNum],src,0,0,srcSize.width,srcSize.height,
AllPlanes,ZPixmap);
if (!srcImage) {
std::cerr << "Could not get image in Xvars::gen_pix_from_trans." << std::endl;
return;
}
// Size of destination image.
Size destSize = Transform2D::apply(transform,srcSize);
// Allocate memory for the image.
char* destData = new_bytes_for_image(destSize,depth,srcImage->bitmap_pad);
// Create XImage for the transformed data.
XImage* destImage =
XCreateImage(dpy[dpyNum],visual[dpyNum],depth,ZPixmap,0,
destData,destSize.width,destSize.height,
srcImage->bitmap_pad,0);
assert(destImage);
assert(destData == destImage->data);
// Traverse coordinates of src, compute corresponding position on
// dest and copy the pixel.
Pos srcPos;
for (srcPos.y = 0; srcPos.y < srcSize.height; srcPos.y++) {
for (srcPos.x = 0; srcPos.x < srcSize.width; srcPos.x++) {
Pos destPos = Transform2D::apply(transform,srcPos,srcSize);
unsigned long pix = XGetPixel(srcImage,srcPos.x,srcPos.y);
XPutPixel(destImage,destPos.x,destPos.y,pix);
}
}
put_image(dpyNum,dest,destImage,destSize);
// Make sure to use new/delete for freeing the memory we allocated.
destroy_image(destImage);
XDestroyImage(srcImage);
}
void Winner2(int x,int y)
{
int count=1;
Image *winner;
int ran,i;
srand( time(NULL) );
ran=rand()%2;
int time=7;
while(time--)
{
clearScreen();
switch(count)
{
case 1:
winner= read_image("Winner21.pixel","Winner21.color");
break;
case 2:
winner= read_image("Winner22.pixel","Winner22.color");
break;
case 3:
winner= read_image("Winner23.pixel","Winner23.color");
break;
default:
break;
}
count=(count+1)%4;
show_image(winner,x,y);
drawCmdWindow(); /* update window immediately */
for(i=0; i<1; i++)
{
playAudio(&audioWin[ran]);
//Sleep(300);
}
Sleep(200);
}
destroy_image(winner);
}
/* Free the given sprite, and decrement the reference count on its image.
*/
static void
destroy_sprite (ModeInfo *mi, sprite *sp)
{
slideshow_state *ss = &sss[MI_SCREEN(mi)];
Bool freed_p = False;
image *img;
int i;
if (!sp) abort();
if (sp->state != DEAD) abort();
img = sp->img;
if (!img) abort();
if (!img->loaded_p) abort();
if (!img->used_p) abort();
if (img->refcount <= 0) abort();
for (i = 0; i < ss->nsprites; i++) /* unlink it from the list */
if (ss->sprites[i] == sp)
{
int j;
for (j = i; j < ss->nsprites-1; j++) /* pull remainder forward */
ss->sprites[j] = ss->sprites[j+1];
ss->sprites[j] = 0;
ss->nsprites--;
freed_p = True;
break;
}
if (!freed_p) abort();
free (sp);
sp = 0;
img->refcount--;
if (img->refcount < 0) abort();
if (img->refcount == 0)
destroy_image (mi, img);
}
int do_fork()
{
int pid,i;
pid=fork();
if (pid<0)
perror("sorry, could not fork");
if (pid==0)
{
destroy_image();
x_screen_open(1);
init_timers();
conv_chunk(qlscreen.qm_lo,qlscreen.qm_hi);
redraw_screen(0,0,qlscreen.xres,qlscreen.yres);
XFlush(display);
fork_files();
}
/* resetting the state of the keyboard seems the best */
gKeyDown=0;
for (i=0;i<8;i++) keyrow[i]=0;
return pid;
}
static int
initialize (struct filter *f, struct initdata *i)
{
struct subdata *s = (struct subdata *) f->data;
int x;
int val = 0;
pixel_t **lines1, **lines2 = NULL;
double size;
int width, height;
int threed = 0;
struct filter *f1 = f;
inhermisc (f, i);
if (datalost (f, i))
s->recal = 1;
while (f1)
{
if (f1->action == &threed_filter)
threed = 1;
f1 = f1->next;
}
f->imageversion = i->image->version;
if (f->childimage != NULL)
destroy_image (f->childimage);
s->image = f->image = i->image;
s->image->flags |= PROTECTBUFFERS;
s->currlines = f->image->currlines;
s->forpversion = f->image->palette->version;
s->forversion = f->fractalc->version;
if (f->image->width * f->image->pixelwidth <
f->image->height * f->image->pixelheight)
size = f->image->width * f->image->pixelwidth / 2;
else
size = f->image->height * f->image->pixelheight / 2;
width = (int) (size / f->image->pixelwidth);
height = (int) (size / f->image->pixelheight);
/*fractalc_resize_to(f->fractalc,size,size); */
lines1 = (pixel_t **) malloc (sizeof (*lines1) * height);
if (f->image->nimages == 2)
lines2 = (pixel_t **) malloc (sizeof (*lines2) * height);
if (lines1 == NULL)
return 0;
if (f->image->nimages == 2 && lines2 == NULL)
{
free (lines1);
return 0;
}
for (x = 0; x < height; x++)
{
lines1[x] =
i->image->currlines[x + (threed ? f->image->height / 3 : 0)];
if (f->image->nimages == 2)
lines2[x] =
i->image->oldlines[x + (threed ? f->image->height / 3 : 0)];
}
if (f->image->nimages == 2)
for (x = 0; x < f->image->height; x++)
{
memcpy (f->image->oldlines[x], f->image->currlines[x],
f->image->width * f->image->bytesperpixel);
}
f->childimage = i->image =
create_image_lines (width, height, f->image->nimages, lines1, lines2,
i->image->palette, myflip, FREELINES,
f->image->pixelwidth, f->image->pixelheight);
if (i->image == NULL)
{
free (lines1);
free (lines2);
return 0;
}
f->childimage->data = s;
x = f->previous->action->initialize (f->previous, i);
if (!x)
return 0;
if (s->second != NULL)
{
i->image = f->image;
val = s->second->action->initialize (s->second, i);
if (!val)
return 0;
}
return (x | val);
}
Boolean Xvars::load_pixmap(Drawable* pixmap,Drawable* mask,
int dpyNum,char** xpmBits,Boolean fullSize) {
// Just load XPM as is.
if (fullSize) {
XpmAttributes attr;
attr.valuemask = XpmCloseness;
attr.closeness = XPM_CLOSENESS;
attr.alloc_close_colors = True;
int val =
XpmCreatePixmapFromData(dpy[dpyNum],root[dpyNum],
xpmBits,
pixmap,mask,
&attr);
XpmFreeAttributes(&attr);
Boolean ret = (val == XpmSuccess);
if (!*pixmap || (mask && !*mask)) {
ret = False;
}
return ret;
}
//// Load image and mask into memory, reduce them and put them up to the
//// display server as a new pixmap and mask
XImage* srcImage;
XImage* srcMask;
Size srcSize;
// Load in src image from supplied data.
XpmAttributes attr;
attr.valuemask = XpmReturnPixels | XpmCloseness;
attr.closeness = XPM_CLOSENESS;
attr.alloc_close_colors = True;
// Perhaps should use XpmReturnAllocPixels, neither gives the transparent
// value.
int val =
XpmCreateImageFromData(dpy[dpyNum],
xpmBits,
&srcImage,(mask ? &srcMask : (XImage**)NULL),
&attr);
srcSize.width = attr.width;
srcSize.height = attr.height;
if (val != XpmSuccess) {
XpmFreeAttributes(&attr);
return False;
}
// Must be even size.
assert((srcSize.width % 2 == 0) &&
(srcSize.height % 2 == 0));
int depth = srcImage->depth;
int bitmap_pad = srcImage->bitmap_pad;
// Size of reduced, destination image.
Size destSize;
destSize.set(srcSize.width / 2,srcSize.height / 2);
// Create image for dest data.
char* destData =
new_bytes_for_image(destSize,depth,bitmap_pad);
XImage *destImage =
XCreateImage(dpy[dpyNum],visual[dpyNum],depth,ZPixmap,0,
destData,destSize.width,destSize.height,
bitmap_pad,0);
assert(destImage);
// Create dest mask if needed.
XImage *destMask;
if (mask) {
assert(srcMask->depth == 1);
char* destMaskData =
new_bytes_for_image(destSize,1,bitmap_pad);
destMask =
XCreateImage(dpy[dpyNum],visual[dpyNum],1,ZPixmap,0,
destMaskData,destSize.width,destSize.height,
bitmap_pad,0);
assert(destMask);
}
// Do the pixel reduction.
// unstretch_image(dpyNum,destImage,srcImage,attr.pixels,attr.npixels);
unstretch_image(dpyNum,destImage,srcImage,
attr.pixels,attr.npixels);
if (mask) {
unstretch_image(dpyNum,destMask,srcMask,NULL,0);
}
// Kill src image and mask.
XpmFreeAttributes(&attr);
XDestroyImage(srcImage);
if (mask) {
XDestroyImage(srcMask);
}
// Create dest pixmap and mask
*pixmap = XCreatePixmap(dpy[dpyNum],root[dpyNum],
destSize.width,destSize.height,
depth);
if (!*pixmap) {
// Should do more cleanup.
return False;
}
if (mask) {
*mask = XCreatePixmap(dpy[dpyNum],root[dpyNum],
destSize.width,destSize.height,
1);
if (!*mask) {
// Should do more cleanup.
return False;
}
}
// Put dest image and mask up to the display server.
put_image(dpyNum,*pixmap,destImage,destSize);
if (mask) {
put_image(dpyNum,*mask,destMask,destSize);
}
// Kill dest image and mask
destroy_image(destImage);
if (mask) {
destroy_image(destMask);
}
return True;
}
void calculate_difference_images(Image *source_image1, Image *source_image2, int n, Image *dest_image) {
for (int i = 0; i < n; i++) {
int h = source_image1[i].height;
if (source_image2[i].height < h)
h = source_image2[i].height;
int w = source_image1[i].width;
if (source_image2[i].width < w)
w = source_image2[i].width;
dest_image[i] = source_image1[i]; // Copy fields.
dest_image[i].pixels = (unsigned int *)malloc(h * source_image1[i].extended_width * 4);
Image *source1;
int source1_is_cloned = 0;
Image cloned_image1;
if (source_image1[i].is_half_float) {
dest_image[i].is_half_float = 0;
dest_image[i].bits_per_component = 8;
clone_image(&source_image1[i], &cloned_image1);
convert_image_from_half_float(&cloned_image1, dynamic_range_min, dynamic_range_max,
dynamic_range_gamma);
convert_image_to_or_from_cairo_format(&cloned_image1);
source1 = &cloned_image1;
source1_is_cloned = 1;
}
else
source1 = &source_image1[i];
Image *source2;
int source2_is_cloned = 0;
Image cloned_image2;
if (source_image2[i].is_half_float) {
clone_image(&source_image2[i], &cloned_image2);
convert_image_from_half_float(&cloned_image2, dynamic_range_min, dynamic_range_max,
dynamic_range_gamma);
convert_image_to_or_from_cairo_format(&cloned_image2);
source2 = &cloned_image2;
source2_is_cloned = 1;
}
else
source2 = &source_image2[i];
bool have_alpha = source1->alpha_bits > 0 && source2->alpha_bits > 0;
for (int y = 0; y < h; y++)
for (int x = 0; x < w; x++) {
uint32_t pixel1 = source1->pixels[y * source1->extended_width + x];
uint32_t pixel2 = source2->pixels[y * source2->extended_width + x];
int difference = 0;
bool add_rgb_diff = true;
if (have_alpha) {
int a1 = pixel_get_a(pixel1);
int a2 = pixel_get_a(pixel2);
if ((a1 | a2) == 0)
add_rgb_diff = false;
else
difference += abs(a1 - a2);
}
else
add_rgb_diff = true;
if (add_rgb_diff)
difference += abs(pixel_get_r(pixel1) - pixel_get_r(pixel2)) +
abs(pixel_get_g(pixel1) - pixel_get_g(pixel2)) +
abs(pixel_get_b(pixel1) - pixel_get_b(pixel2));
if (difference > 255)
difference = 255;
dest_image[i].pixels[y * dest_image[i].extended_width + x] =
pack_rgb_alpha_0xff(difference, difference, difference);
}
if (source1_is_cloned)
destroy_image(source1);
if (source2_is_cloned)
destroy_image(source2);
}
}
void destroyinheredimage(struct filter *f)
{
if (f->flags & ALLOCEDIMAGE)
destroy_image(f->childimage), f->flags &=
~(ALLOCEDIMAGE | SHAREDDATA), f->childimage = NULL;
}
/* Cleanup
* -------
*
* Clean up is simple enough. Just destroy the star
* image and free the state structure memory.
*/
static void destroy_sample(void* data)
{
struct state* state = data;
destroy_image(state->star_img);
free(data);
}
static coded_image *
CodedImageSource_get_frame_from_python( PyObject *self, int frame, int quality ) {
PyGILState_STATE gstate;
gstate = PyGILState_Ensure();
PyObject *result_obj = PyObject_CallMethod( (PyObject *) self, "get_frame", "i", frame );
PyGILState_Release( gstate );
if( !result_obj ) {
PyErr_Print();
return NULL;
}
Py_ssize_t plane_count = PySequence_Length( result_obj );
if( plane_count == -1 ) {
PyErr_Print();
return NULL;
}
coded_image *image = g_new0( coded_image, 1 );
image->free_func = (GFreeFunc) destroy_image;
for( Py_ssize_t plane = 0; plane < plane_count && plane < CODED_IMAGE_MAX_PLANES; plane++ ) {
PyObject *plane_obj = PySequence_GetItem( result_obj, plane );
if( !plane_obj ) {
PyErr_Print();
Py_CLEAR(result_obj);
destroy_image( image );
return NULL;
}
PyObject *data_obj = PyObject_GetAttrString( plane_obj, "data" );
if( data_obj == Py_None ) {
Py_CLEAR(data_obj);
Py_CLEAR(plane_obj);
continue;
}
PyObject *stride_obj = PyObject_GetAttrString( plane_obj, "stride" );
PyObject *line_count_obj = PyObject_GetAttrString( plane_obj, "line_count" );
Py_CLEAR(plane_obj);
if( !data_obj || !stride_obj || !line_count_obj ) {
PyErr_Print();
Py_CLEAR(data_obj);
Py_CLEAR(stride_obj);
Py_CLEAR(line_count_obj);
Py_CLEAR(result_obj);
destroy_image( image );
return NULL;
}
image->stride[plane] = PyLong_AsLong( stride_obj );
Py_CLEAR(stride_obj);
image->line_count[plane] = PyLong_AsLong( line_count_obj );
Py_CLEAR(line_count_obj);
if( PyErr_Occurred() ) {
PyErr_Print();
Py_CLEAR(data_obj);
Py_CLEAR(result_obj);
destroy_image( image );
return NULL;
}
Py_buffer buffer;
if( PyObject_GetBuffer( data_obj, &buffer, PyBUF_SIMPLE ) == -1 ) {
PyErr_Print();
Py_CLEAR(data_obj);
Py_CLEAR(result_obj);
destroy_image( image );
return NULL;
}
if( buffer.len != image->stride[plane] * image->line_count[plane] ) {
Py_CLEAR(data_obj);
Py_CLEAR(result_obj);
PyBuffer_Release( &buffer );
destroy_image( image );
g_warning(
"Error in plane %zd: expected %zd bytes, got %zd bytes.",
plane,
(Py_ssize_t) image->stride[plane] * image->line_count[plane],
buffer.len );
return NULL;
}
image->data[plane] = g_memdup( buffer.buf, buffer.len );
PyBuffer_Release( &buffer );
Py_CLEAR(data_obj);
}
return image;
}
int create_texture(LPTEXTURE *t, const char *path, uint16 *width, uint16 *height, int numMips, BOOL * colorkey, D3DPOOL pool)
{
#ifdef TEXTURE_PNG
HRESULT hr;
texture_image_t image;
Change_Ext( path, image.path, ".PNG" );
if( ! File_Exists( (char*) image.path ) )
{
DebugPrintf("Could not find texture file: %s\n",path);
return TRUE;
}
// at this point i have mips turned off for the commit
// cause it appears that mip levels after 0 are not present
// i think we need to copy each successive mipmap in at a time
numMips = 1;
// load the image
if(load_image( &image, numMips )!=0)
{
DebugPrintf("couldn't load image\n");
return S_FALSE;
}
// create d3d texture
hr = lpD3DDevice->CreateTexture( image.w, image.h, numMips, 0, D3DFMT_A8R8G8B8, pool, texture, NULL );
if (FAILED(hr))
{
DebugPrintf("couldn't create texture\n");
return hr;
}
// copy data into the texture
{
int y, x;
int size = 4;
int pitch = size*image.w;
D3DLOCKED_RECT lrect;
BYTE* pBits;
LPTEXTURE _texture = *texture;
_texture->LockRect(0,&lrect,NULL,D3DLOCK_DISCARD);
pBits = (BYTE*)lrect.pBits;
for (y = 0; y < image.h; y++)
{
for (x = 0; x < image.w; x++)
{
// move to the correct offset in the table
// y is the row and pitch is the size of a row
// (x*size) is the length of each pixel data (column)
DWORD index = (y*pitch)+(x*size);
// d3d has it's own pitch value cause it stores data at the end of the row
DWORD index_p = (y*lrect.Pitch)+(x*size);
// D3DFMT_A8R8G8B8 data will be accessible backwards: bgra
// image.data is packed in rgba
pBits[index_p] = (BYTE)gamma_table[image.data[index+2]]; // blue
pBits[index_p+1] = (BYTE)gamma_table[image.data[index+1]]; // green
pBits[index_p+2] = (BYTE)gamma_table[image.data[index]]; // red
// colour key
if( image.colorkey && (pBits[index_p] + pBits[index_p+1] + pBits[index_p+2]) == 0 )
pBits[index_p+3] = 0; // alpha - pixel will not be coppied do to alpha=0 ignore
// do not colour key
else
pBits[index_p+3] = (BYTE)gamma_table[image.data[index+3]]; // alpha
}
}
_texture->UnlockRect(0);
}
// return the values
*width = (uint16) image.w;
*height = (uint16) image.h;
(*colorkey) = (BOOL) image.colorkey;
// info
DebugPrintf( "Created texture: file=%s, width=%d, height=%d, colorkey=%s\n",
image.path, image.w, image.h, (image.colorkey ? "true" : "false") );
//
destroy_image( &image );
//
return S_OK;
#else
LPDIRECT3DTEXTURE9 * texture = (LPDIRECT3DTEXTURE9*)t;
D3DXIMAGE_INFO imageInfo;
// if the file doesn't exist
char real_file[256];
if( ! File_Exists( (char*) path ) )
{
// try to find a png version
Change_Ext( path, real_file, ".PNG" );
path = &real_file[0];
}
if( ! File_Exists( (char*) path ) )
{
// try to find a png version
Change_Ext( path, real_file, ".BMP" );
path = &real_file[0];
DebugPrintf("Could not find PNG version of: %s\n",path);
}
if( ! File_Exists( (char*) path ) )
{
DebugPrintf("Could not find texture file: %s\n",path);
return S_FALSE;
}
HRESULT LastError = D3DXCreateTextureFromFileEx(lpD3DDevice,
path,
0,//*width,
0,//*height,
numMips,
0,
// most likely will end up as the format the file is in
D3DFMT_A8R8G8B8, // all texure data will be accessible in LockRect()'s pBits backwards: bgra
pool,
D3DX_DEFAULT,
D3DX_DEFAULT,
(*colorkey) ? OPAQUE_BLACK : 0, // colour key
&imageInfo,
NULL,
texture);
if (FAILED(LastError))
{
DebugPrintf("couldn't create texture\n");
}
// return the values
*width = (uint16) imageInfo.Width;
*height = (uint16) imageInfo.Height;
// image has no alpha layer
// only way image would have an alpha layer
// is the updated textures we created
// which will have exactly this format!
if( imageInfo.Format != D3DFMT_A8R8G8B8 )
(*colorkey) = FALSE;
// debugging info
DebugPrintf("Created texture from %s\n",path);
DebugPrintf("Texture Details: width=%d, height=%d, depth=%d, mips=%d, image_format=%s, file_format=%s\n",
imageInfo.Width, imageInfo.Height, imageInfo.Depth, imageInfo.MipLevels,
d3d_format(imageInfo.Format), d3d_image_file_formats[imageInfo.ImageFileFormat] );
/*
// saves the texture in it's loaded format to a file
{
static int count = 0;
sprintf(buf, ".\\Dumps\\%s.png", fileName);
D3DXSaveTextureToFile(buf, D3DXIFF_PNG, (*texture), 0);
count++;
}
*/
//
// gamma correction
//
{
unsigned int y, x;
int size = 4;
D3DLOCKED_RECT lrect;
BYTE* pBits;
LPDIRECT3DTEXTURE9 _texture = *texture;
_texture->LockRect(0,&lrect,NULL,D3DLOCK_DISCARD);
pBits = (BYTE*)lrect.pBits;
for (y = 0; y < imageInfo.Height; y++)
{
for (x = 0; x < imageInfo.Width; x++)
{
// move to the correct off set in the table
// pitch is the width of a row
// (x*size) is the length of each pixel data
DWORD index = (x*size)+(y*lrect.Pitch);
// D3DFMT_A8R8G8B8 data will be accessible backwards: bgra
pBits[index] = (BYTE)gamma_table[pBits[index]]; // Blue
pBits[index+1] = (BYTE)gamma_table[pBits[index+1]];// Green
pBits[index+2] = (BYTE)gamma_table[pBits[index+2]];// Red
// i did not see any alpha values changed for gamma in d3d6 version
//pBits[index+3] = (BYTE)gamma_table[pBits[index+3]];// Alpha
}
}
_texture->UnlockRect(0);
}
return LastError;
#endif
}
void start()
{
int count=1;
int ok=0;
Image *start;
int time=20;//29
while(time--)
{
clearScreen();
switch(count)
{
case 1:
start= read_image("start1.pixel","start1.color");
break;
case 2:
start= read_image("start2.pixel","start2.color");
break;
case 3:
start= read_image("start3.pixel","start3.color");
break;
case 4:
start= read_image("start4.pixel","start4.color");
break;
case 5:
start= read_image("start5.pixel","start5.color");
break;
case 6:
start= read_image("start6.pixel","start6.color");
break;
case 7:
start= read_image("start7.pixel","start7.color");
break;
case 8:
start= read_image("start8.pixel","start8.color");
break;
case 9:
start= read_image("start9.pixel","start9.color");
break;
case 10:
start= read_image("start10.pixel","start10.color");
break;
case 11:
start= read_image("start11.pixel","start11.color");
break;
case 12:
start= read_image("start12.pixel","start12.color");
break;
case 13:
start= read_image("start13.pixel","start13.color");
break;
case 14:
start= read_image("start14.pixel","start14.color");
break;
case 15:
start= read_image("start15.pixel","start15.color");
break;
case 16:
start= read_image("start16.pixel","start16.color");
break;
default:
break;
}
if(count==16)
{
ok=1;
}
if(ok)
{
// count=(count+1)%16+10;
if(count==15)
{
count=16;
}
else
{
count=15;
}
}
else
{
count++;
}
show_image(start,125,35);
drawCmdWindow();
int i=0;
for(i=0; i<1; i++)
{
playAudio(&audio[0]);
//Sleep(500);
}
Sleep(500);
}
destroy_image(start);
}
void gameover()
{
int count=2;
Image *gameover;
int ran,i;
srand( time(NULL) );
ran=rand()%6;
while(count<=11)
{
clearScreen();
switch(count)
{
case 2:
gameover= read_image("gameover2.pixel","gameover2.color");
break;
case 3:
gameover= read_image("gameover3.pixel","gameover3.color");
break;
case 4:
gameover= read_image("gameover4.pixel","gameover4.color");
break;
case 5:
gameover= read_image("gameover5.pixel","gameover5.color");
break;
case 6:
gameover= read_image("gameover6.pixel","gameover6.color");
break;
case 7:
gameover= read_image("gameover7.pixel","gameover7.color");
break;
case 8:
gameover= read_image("gameover8.pixel","gameover8.color");
break;
case 9:
gameover= read_image("gameover9.pixel","gameover9.color");
break;
case 10:
gameover= read_image("gameover10.pixel","gameover10.color");
break;
case 11:
gameover= read_image("gameover11.pixel","gameover11.color");
break;
default:
break;
}
count++;
show_image(gameover,120,35);
drawCmdWindow();
if(count%4==0)
{
for(i=0; i<2; i++)
{
playAudio(&audioOver[ran]);
//Sleep(300);
}
}
Sleep(300);
}
destroy_image(gameover);
}
