Generated from asvisual.h with ROBODoc v3.2.3 on Mon Feb 18 01:16:12 2002
DESCRIPTION
Defines abstraction layer on top of X Visuals, as well as several
fundamental color datatypes.
SEE ALSO
Structures:
ColorPair
ASScanline
ASVisual
Functions :
ASScanline handling:
prepare_scanline(), free_scanline()
ASVisual initialization :
query_screen_visual(), setup_truecolor_visual(),
setup_pseudo_visual(), setup_as_colormap(),create_asvisual(),
destroy_asvisual()
ASVisual encoding/decoding :
visual2visual_prop(), visual_prop2visual()
ASVisual convenience functions :
create_visual_window(), create_visual_pixmap(),
create_visual_ximage()
Other libAfterImage modules :
ascmap.h asfont.h asimage.h asvisual.h blender.h export.h
import.h transform.h ximage.h
AUTHOR
Sasha Vasko <sasha at aftercode dot net>
FUNCTION
Alpha channel adds visibility parameter to color value.
Alpha channel's value of 0xFF signifies complete visibility, while 0
makes pixel completely transparent.
SOURCE
#define ALPHA_TRANSPARENT 0x00
#define ALPHA_SEMI_TRANSPARENT 0x7F
#define ALPHA_SOLID 0xFF
FUNCTION
ARGB32 is fundamental datatype that hold 32bit value corresponding to
pixels color and transparency value (alpha channel) in ARGB
colorspace. It is encoded as follows :
Lowermost 8 bits - Blue channel
bits 8 to 15 - Green channel
bits 16 to 23 - Red channel
bits 24 to 31 - Alpha channel
EXAMPLE
ASTile.1
SOURCE
typedef CARD32 ARGB32;
#define ARGB32_White 0xFFFFFFFF
#define ARGB32_Black 0xFF000000
/* default background color is #FF000000 : */
#define ARGB32_DEFAULT_BACK_COLOR ARGB32_Black
#define ARGB32_ALPHA_CHAN 3
#define ARGB32_RED_CHAN 2
#define ARGB32_GREEN_CHAN 1
#define ARGB32_BLUE_CHAN 0
#define ARGB32_CHANNELS 4
#if 1
#define MAKE_ARGB32(a,r,g,b) ((( (CARD32)a) <<24)|((((CARD32)r)&0x00FF)<<16)| \
((((CARD32)g)&0x00FF)<<8 )|(( (CARD32)b)&0x00FF))
#else
#define MAKE_ARGB32(a,r,g,b) ((((a)&0x00FF)<<24)|(((r)&0x00FF)<<16)| \
(((g)&0x00FF)<<8)|((b)&0x00FF))
#endif
#define MAKE_ARGB32_GREY(a,l) (((a)<<24)|(((l)&0x00FF)<<16)| \
(((l)&0x00FF)<<8)|((l)&0x00FF))
#define ARGB32_ALPHA8(c) (((c)>>24)&0x00FF)
#define ARGB32_RED8(c) (((c)>>16)&0x00FF)
#define ARGB32_GREEN8(c) (((c)>>8 )&0x00FF)
#define ARGB32_BLUE8(c) ( (c) &0x00FF)
#define ARGB32_CHAN8(c,i) (((c)>>((i)<<3))&0x00FF)
#define MAKE_ARGB32_CHAN8(v,i) (((v)&0x0000FF)<<((i)<<3))
#define ARGB32_ALPHA16(c) ((((c)>>16)&0x00FF00)|0x00FF)
#define ARGB32_RED16(c) ((((c)>>8)&0x00FF00)|0x00FF)
#define ARGB32_GREEN16(c) (( (c) &0x00FF00)|0x00FF)
#define ARGB32_BLUE16(c) ((((c)<<8)&0x00FF00)|0x00FF)
#define ARGB32_CHAN16(c,i) ((ARGB32_CHAN8(c,i)<<8)|0x00FF)
#define MAKE_ARGB32_CHAN16(v,i) ((((v)&0x00FF00)>>8)<<((i)<<3))
FUNCTION
Ids of the channels. These are basically synonyms to related ARGB32
channel numbers
SOURCE
typedef enum
{
IC_BLUE = ARGB32_BLUE_CHAN ,
IC_GREEN = ARGB32_GREEN_CHAN,
IC_RED = ARGB32_RED_CHAN ,
IC_ALPHA = ARGB32_ALPHA_CHAN,
IC_NUM_CHANNELS = ARGB32_CHANNELS
}
ColorPart;
NAME
ColorPair
DESCRIPTION
Convenient structure to hold pair of colors.
SOURCE
typedef struct ColorPair
{
ARGB32 fore;
ARGB32 back;
}ColorPair;
NAME
ASScanline
SYNOPSIS
ASScanline is a structure to hold contents of the single scanline.
DESCRIPTION
ASScanline holds data for the single scanline, split into channels
with 32 bits per pixel per channel. All the memory is allocated at
once, and then split in between channels. There are three ways to
access channel data :
1) using blue, green, red, alpha pointers.
2) using channels[] array of pointers - convenient in loops
4) using xc3, xc2, xc1 pointers. These are different from red, green,
blue in the way that xc3 will point to blue when BGR mode is specified
at the time of creation, otherwise it will point to red channel.
Likewise xc1 will point to red in BGR mode and blue otherwise.
xc2 always points to green channel's data. This is convenient while
writing XImages and when channels in source and destination has to be
reversed, while reading images from files.
Channel data is always aligned by 8 byte boundary allowing for
utilization of MMX, floating point and other 64bit registers for
transfer and processing.
SEE ALSO
ASImage
SOURCE
typedef struct ASScanline
{
#define SCL_DO_BLUE (0x01<<ARGB32_BLUE_CHAN )
#define SCL_DO_GREEN (0x01<<ARGB32_GREEN_CHAN)
#define SCL_DO_RED (0x01<<ARGB32_RED_CHAN )
#define SCL_DO_ALPHA (0x01<<ARGB32_ALPHA_CHAN)
#define SCL_DO_COLOR (SCL_DO_RED|SCL_DO_GREEN|SCL_DO_BLUE)
#define SCL_DO_ALL (SCL_DO_RED|SCL_DO_GREEN|SCL_DO_BLUE| \
SCL_DO_ALPHA)
CARD32 flags ; /* combination of the above values */
CARD32 *buffer ;
CARD32 *blue, *green, *red, *alpha ;
CARD32 *channels[IC_NUM_CHANNELS];
CARD32 *xc3, *xc2, *xc1; /* since some servers require
* BGR mode here we store what
* goes into what color component
* in XImage */
ARGB32 back_color;
unsigned int width, shift;
unsigned int offset_x ;
}ASScanline;
SYNOPSIS
long ARGB32_manhattan_distance (long a, long b);
INPUTS
a, b - ARGB32 color values to calculate Manhattan distance in between
RETURN VALUE
returns calculated Manhattan distance.
DESCRIPTION
This function can be used to evaluate closeness of two colors.
SYNOPSIS
ASScanline *prepare_scanline ( unsigned int width,
unsigned int shift,
ASScanline *reusable_memory,
Bool BGR_mode);
INPUTS
width - width of the scanline.
shift - format of contained data. 0 means - 32bit unshifted
8 means - 24.8bit ( 8 bit left shifted ).
reusable_memory - preallocated object.
BGR_mode - if True will cause xc3 to point to Blue and xc1 to
point to red.
DESCRIPTION
This function allocates memory ( if reusable_memory is NULL ) for
the new ASScanline structure. Structures buffers gets allocated to
hold scanline data of at least width pixel wide. Buffers are adjusted
to start on 8 byte boundary.
SYNOPSIS
void free_scanline ( ASScanline *sl, Bool reusable );
INPUTS
sl - pointer to previously allocated ASScanline structure to be
deallocated.
reusable - if true then ASScanline object itself will not be
deallocated.
DESCRIPTION
free_scanline() frees all the buffer memory allocated for ASScanline.
If reusable is false then object itself in not freed. That is usable
for declaring ASScanline on stack.
NAME
ASVisual
SYNOPSIS
ASVisual is abstraction layer on top of X Server Visual.
DESCRIPTION
This structure has been introduced in order to compensate for the
fact that X may have so many different types of Visuals. It provides
shortcuts to most Visual data, compensated for differences in Visuals.
For PseudoColor visual it also contains preallocated set of colors.
This colormap allows us to write XImages very fast and without
exhausting available X colors. This colormap consist of 8, 64, or 4096
colors and constitutes fraction of colors available in particular
colordepth. This colors are allocated to be evenly spread around RGB
spectrum. Thus when converting from internal presentation - all we
need to do is to discard unused bits, and use rest of them bits as
an index in our colormap. Opposite conversion is much trickier and we
engage into nasty business of having hash table mapping pixel values
into colors, or straight table doing same in lower colordepths.
Idea is that we do all internal processing in 32bit colordepth, and
ASVisual provides us with means to convert it to actual X display
format. Respectively ASVisual has methods to write out XImage lines
and read XImage lines.
ASVisual creation is a tricky process. Basically first we have to go
through the list of available Visuals and choose the best suitable.
Then based on the type of this Visual we have to setup our data
members and method hooks. Several functions provided for that :
query_screen_visual() - will lookup best suitable visual
setup_truecolor_visual() - will setup hooks if visual is TrueColor
setup_pseudo_visual() - will setup hooks and data if Visual is
PseudoColor.
setup_as_colormap() - will preallocate colors for PseudoColor.
Alternative to the above is :
create_asvisual() - it encapsulates all of the above
functionality, and returns completely set
up ASVisual object.
Since Visual selected for ASVisual may differ from default
( we choose the best suitable ), all the window creation function
must provide colormap and some other parameters, like border color
for example. Thus we created some convenience functions.
These should be used instead of standard Xlib calls :
create_visual_window() - to create window
create_visual_pixmap() - to create pixmap
create_visual_ximage() - to create XImage
ASVisual could be dealolocated and its resources freed with :
destroy_asvisual()
EXAMPLE
asview.c: ASView
SOURCE
typedef struct ASVisual
{
Display *dpy;
/* This envvar will be used to determine what X Visual (in hex) to use.
* If unset then best possible will be selected automagically : */
#define ASVISUAL_ID_ENVVAR "AFTERIMAGE_VISUAL_ID"
XVisualInfo visual_info;
/* this things are calculated based on Visual : */
unsigned long rshift, gshift, bshift;
unsigned long rbits, gbits, bbits;
unsigned long true_depth; /* could be 15 when X reports 16 */
Bool BGR_mode;
Bool msb_first;
/* we must have colormap so that we can safely create windows
* with different visuals even if we are in TrueColor mode : */
Colormap colormap;
Bool own_colormap; /* tells us to free colormap when we
* done */
unsigned long black_pixel, white_pixel;
/* for PseudoColor mode we need some more stuff : */
enum {
ACM_None = 0,
ACM_3BPP,
ACM_6BPP,
ACM_12BPP
} as_colormap_type ; /* there can only be 64 or 4096 entries
* so far ( 6 or 12 bpp) */
unsigned long *as_colormap; /* array of preallocated colors for
* PseudoColor mode */
union /* reverse color lookup tables : */
{
ARGB32 *xref;
struct ASHashTable *hash;
}as_colormap_reverse ;
/* different useful callbacks : */
CARD32 (*color2pixel_func) ( struct ASVisual *asv,
CARD32 encoded_color,
unsigned long *pixel);
void (*pixel2color_func) ( struct ASVisual *asv,
unsigned long pixel,
CARD32 *red, CARD32 *green,
CARD32 *blue);
void (*ximage2scanline_func)( struct ASVisual *asv, XImage *xim,
ASScanline *sl, int y,
unsigned char *xim_data );
void (*scanline2ximage_func)( struct ASVisual *asv, XImage *xim,
ASScanline *sl, int y,
unsigned char *xim_data );
#ifndef X_DISPLAY_MISSING
#define ARGB2PIXEL(asv,argb,pixel) \
(asv)->color2pixel_func((asv),(argb),(pixel))
#define GET_SCANLINE(asv,xim,sl,y,xim_data) \
(asv)->ximage2scanline_func((asv),(xim),(sl),(y),(xim_data))
#define PUT_SCANLINE(asv,xim,sl,y,xim_data) \
(asv)->scanline2ximage_func((asv),(xim),(sl),(y),(xim_data))
#else
#define ARGB2PIXEL(asv,argb,pixel) \
do{ break; }while(0)
#define GET_SCANLINE(asv,xim,sl,y,xim_data) \
do{ break; }while(0)
#define PUT_SCANLINE(asv,xim,sl,y,xim_data) \
do{ break; }while(0)
#endif
}ASVisual;
SYNOPSIS
Bool query_screen_visual( ASVisual *asv, Display *dpy, int screen,
Window root, int default_depth );
INPUTS
asv - preallocated ASVisual structure.
dpy - valid pointer to opened X display.
screen - screen number on which to query visuals.
root - root window on that screen.
default_depth- default colordepth of the screen.
RETURN VALUE
True on success, False on failure
ASVisual structure pointed by asv will have the following data
members set on success :
dpy, visual_info, colormap, own_colormap, black_pixel, white_pixel.
DESCRIPTION
query_screen_visual() will go though prioritized list of possible
Visuals and attempt to match those to what is available on the
specified screen. If all items from list fail, then it goes about
querying default visual.
Once X Visual has been identified, we create X colormap and allocate
white and black pixels from it.
SYNOPSIS
Bool setup_truecolor_visual( ASVisual *asv );
INPUTS
asv - preallocated ASVisual structure.
RETURN VALUE
True on success, False if visual is not TrueColor.
DESCRIPTION
setup_truecolor_visual() checks if Visual is indeed TrueColor and if
so it goes about querying color masks, deducing real XImage
colordepth, and whether we work in BGR mode. It then goes about
setting up correct hooks to X IO functions.
SYNOPSIS
void setup_pseudo_visual( ASVisual *asv );
INPUTS
asv - preallocated ASVisual structure.
DESCRIPTION
setup_pseudo_visual() assumes that Visual is PseudoColor. It then
tries to decide as to how many colors preallocate, and goes about
setting up correct X IO hooks and possibly initialization of reverse
colormap in case ASVisual already has colormap preallocated.
SYNOPSIS
void setup_as_colormap( ASVisual *asv );
INPUTS
asv - preallocated ASVisual structure.
DESCRIPTION
That has to be called in order to pre-allocate sufficient number of
colors. It uses colormap size identification supplied in ASVisual
structure. If colors where preallocated successfully - it will also
create reverse lookup colormap.
SYNOPSIS
ASVisual *create_asvisual_for_id( Display *dpy, int screen,
int default_depth,
VisualID visual_id,
ASVisual *reusable_memory );
INPUTS
dpy - valid pointer to opened X display.
screen - screen number on which to query visuals.
root - root window on that screen.
default_depth- default colordepth of the screen.
visual_id - ID of X visual to use.
reusable_memory - pointer to preallocated ASVisual structure.
RETURN VALUE
Pointer to ASVisual structure initialized with enough information
to be able to deal with current X Visual.
DESCRIPTION
This function calls all the needed functions in order to setup new
ASVisual structure for the specified screen and visual. If
reusable_memory is not null - it will not allocate new ASVisual
structure, but instead will use supplied one. Useful for allocating
ASVisual on stack.
This particular function will not do any autodetection and will use
Visual ID supplied. That is usefull when libAfterImage is used with
an app that has its own approach to Visual handling, and since Visuals
on all Windows, Pixmaps and colormaps must match, there is a need to
synchronise visuals used by an app and libAfterImage.
SYNOPSIS
ASVisual *create_asvisual( Display *dpy, int screen,
int default_depth,
ASVisual *reusable_memory );
INPUTS
dpy - valid pointer to opened X display.
screen - screen number on which to query visuals.
root - root window on that screen.
default_depth- default colordepth of the screen.
reusable_memory - pointer to preallocated ASVisual structure.
RETURN VALUE
Pointer to ASVisual structure initialized with enough information
to be able to deal with current X Visual.
DESCRIPTION
This function calls all the needed functions in order to setup new
ASVisual structure for the specified screen. If reusable_memory is
not null - it will not allocate new ASVisual structure, but instead
will use supplied one. Useful for allocating ASVisual on stack.
It is different from create_asvisualfor_id() in that it will attempt
to autodetect best possible visual for the screen. For example on some
SUN Solaris X servers there will be both 8bpp pseudocolor and 24bpp
truecolor, and default will be 8bpp. In this scenario libAfterImage
will detect and use 24bpp true color visual, thus producing much better
results.
SYNOPSIS
void destroy_asvisual( ASVisual *asv, Bool reusable );
INPUTS
asv - valid ASVisual structure.
reusable - if True it will cause function to not free object
itself.
DESCRIPTION
Cleanup function. Frees all the memory and deallocates all the
resources. If reusable is False it will also free the object, pointed
to by asv.
EXAMPLE
asview.c: ASView.2
SYNOPSIS
Bool visual2visual_prop( ASVisual *asv, size_t *size,
unsigned long *version, unsigned long **data );
INPUTS
asv - valid ASVisual structure.
RETURN VALUE
size - size of the encoded memory block.
version - version of the encoding
data - actual encoded memory block
True on success, False on failure
DESCRIPTION
This function will encode ASVisual structure into memory block of
32 bit values, suitable for storing in X property.
SYNOPSIS
Bool visual_prop2visual( ASVisual *asv, Display *dpy, int screen,
size_t size,
unsigned long version, unsigned long *data );
INPUTS
asv - valid ASVisual structure.
dpy - valid pointer to open X display.
screen - screen number.
size - encoded memory block's size.
version - version of encoding.
data - actual encoded memory block.
RETURN VALUE
True on success, False on failure
DESCRIPTION
visual_prop2visual() will read ASVisual data from the memory block
encoded by visual2visual_prop(). It could be used to read data from
X property and convert it into usable information - such as colormap,
visual info, etc.
Note: setup_truecolor_visual() or setup_pseudo_visual() has to be
invoked in order to complete ASVisual setup.
SYNOPSIS
Window create_visual_window( ASVisual *asv, Window parent,
int x, int y,
unsigned int width, unsigned int height,
unsigned int border_width,
unsigned int wclass,
unsigned long mask,
XSetWindowAttributes *attributes );
INPUTS
asv - pointer to the valid ASVisual structure.
parent - Window ID of the parent the window.
x, y - initial position of the new window.
width, height - initial size of the new window.
border_width - initial border width of the new window.
wclass - Window class - InputOnly or InputOutput.
mask - defines what attributes are set.
attributes - different window attributes.
RETURN VALUE
ID of the newly created window on success. None on failure.
DESCRIPTION
create_visual_window() will do sanity checks on passed parameters,
it will then add mandatory attributes if needed, and attempt to
create window for the specified ASVisual.
SYNOPSIS
GC create_visual_gc( ASVisual *asv, Window root,
unsigned long mask, XGCValues *gcvalues );
INPUTS
asv - pointer to the valid ASVisual structure.
root - Window ID of the root window of destination screen
mask, gcvalues - values for creation of new GC - see XCreateGC() for
details.
RETURN VALUE
New GC created for regular window on success. NULL on failure.
DESCRIPTION
create_visual_gc() will create temporary window for the ASVisual
specific depth and Visual and it will then create GC for such window.
Obtained GC should be good to be used for manipulation of windows and
Pixmaps created for the same ASVisual.
SYNOPSIS
Pixmap create_visual_pixmap( ASVisual *asv, Window root,
unsigned int width, unsigned int height,
unsigned int depth );
INPUTS
asv - pointer to the valid ASVisual structure.
root - Window ID of the root window of destination screen
width, height - size of the pixmap to create.
depth - depth of the pixmap to create. If 0 asv->true_depth
will be used.
RETURN VALUE
ID of the newly created pixmap on success. None on failure.
DESCRIPTION
create_visual_pixmap() will perform sanity checks on passed
parameters, and attempt to create pixmap for the specified ASVisual,
root and depth.
SYNOPSIS
XImage* create_visual_ximage( ASVisual *asv,
unsigned int width, unsigned int height,
unsigned int depth );
INPUTS
asv - pointer to the valid ASVisual structure.
width, height - size of the XImage to create.
depth - depth of the XImage to create. If 0 asv->true_depth
will be used.
RETURN VALUE
pointer to newly created XImage on success. NULL on failure.
DESCRIPTION
create_visual_ximage() will perform sanity checks on passed
parameters, and it will attempt to create XImage of sufficient size,
and specified colordepth. It will also setup hooks for XImage
deallocation to be handled by custom function.