ref: 2ca54f6a26ceda9cfe5012c641154e203ff9a83b
dir: /sys/man/2/allocimage/
.TH ALLOCIMAGE 2 .SH NAME allocimage, allocimagemix, freeimage, nameimage, namedimage, setalpha, loadimage, cloadimage, unloadimage, readimage, writeimage, bytesperline, wordsperline \- allocating, freeing, reading, writing images .SH SYNOPSIS .nf .PP .B #include <u.h> .B #include <libc.h> .B #include <draw.h> .PP .ta \w'\fLImage 'u .B Image *allocimage(Display *d, Rectangle r, .br .B ulong chan, int repl, ulong col) .PP .B Image *allocimagemix(Display *d, ulong one, ulong three) .PP .B int freeimage(Image *i) .PP .B int nameimage(Image *i, char *name, int in) .PP .B Image *namedimage(Display *d, char *name) .PP .B ulong setalpha(ulong color, uchar alpha) .PP .B int loadimage(Image *i, Rectangle r, uchar *data, int ndata) .PP .B int cloadimage(Image *i, Rectangle r, uchar *data, int ndata) .PP .B int unloadimage(Image *i, Rectangle r, uchar *data, int ndata) .PP .B Image *readimage(Display *d, int fd, int dolock) .PP .B int writeimage(int fd, Image *i, int dolock) .PP .B int bytesperline(Rectangle r, int d) .PP .B int wordsperline(Rectangle r, int d) .PP .nf .B enum .nf .ft L .ta +4n +20 { DOpaque = 0xFFFFFFFF, DTransparent = 0x00000000, DBlack = 0x000000FF, DWhite = 0xFFFFFFFF, DRed = 0xFF0000FF, DGreen = 0x00FF00FF, DBlue = 0x0000FFFF, DCyan = 0x00FFFFFF, DMagenta = 0xFF00FFFF, DYellow = 0xFFFF00FF, DPaleyellow = 0xFFFFAAFF, DDarkyellow = 0xEEEE9EFF, DDarkgreen = 0x448844FF, DPalegreen = 0xAAFFAAFF, DMedgreen = 0x88CC88FF, DDarkblue = 0x000055FF, DPalebluegreen = 0xAAFFFFFF, DPaleblue = 0x0000BBFF, DBluegreen = 0x008888FF, DGreygreen = 0x55AAAAFF, DPalegreygreen = 0x9EEEEEFF, DYellowgreen = 0x99994CFF, DMedblue = 0x000099FF, DGreyblue = 0x005DBBFF, DPalegreyblue = 0x4993DDFF, DPurpleblue = 0x8888CCFF, DNotacolor = 0xFFFFFF00, DNofill = DNotacolor, }; .fi .SH DESCRIPTION A new .B Image on .B Display .B d is allocated with .BR allocimage ; it will have the rectangle, pixel channel format, replication flag, and initial fill color given by its arguments. Convenient pixel channels like .BR GREY1 , .BR GREY2 , .BR CMAP8 , .BR RGB16 , .BR RGB24 , and .BR RGBA32 are predefined. All the new image's pixels will have initial value .IR col . If .I col is .BR DNofill , no initialization is done. Representative useful values of color are predefined: .BR DBlack , .BR DWhite , .BR DRed , and so on. Colors are specified by 32-bit numbers comprising, from most to least significant byte, 8-bit values for red, green, blue, and alpha. The values correspond to illumination, so 0 is black and 255 is white. Similarly, for alpha 0 is transparent and 255 is opaque. The .I id field will have been set to the identifying number used by .B /dev/draw (see .IR draw (3)), and the .I cache field will be zero. If .I repl is true, the clip rectangle is set to a very large region; if false, it is set to .IR r . The .I depth field will be set to the number of bits per pixel specified by the channel descriptor (see .IR image (6)). .I Allocimage returns 0 if the server has run out of image memory. .PP .I Allocimagemix is used to allocate background colors. On 8-bit color-mapped displays, it returns a 2×2 replicated image with one pixel colored the color .I one and the other three with .IR three . (This simulates a wider range of tones than can be represented by a single pixel value on a color-mapped display.) On true color displays, it returns a 1×1 replicated image whose pixel is the result of mixing the two colors in a one to three ratio. .PP .I Freeimage frees the resources used by its argument image. .PP .I Nameimage publishes in the server the image .I i under the given .IR name . If .I in is non-zero, the image is published; otherwise .I i must be already named .I name and it is withdrawn from publication. .I Namedimage returns a reference to the image published under the given .I name on .B Display .IR d . These routines permit unrelated applications sharing a display to share an image; for example they provide the mechanism behind .B getwindow (see .IR graphics (2)). .PP The RGB values in a color are .I premultiplied by the alpha value; for example, a 50% red is .B 0x7F00007F not .BR 0xFF00007F . The function .I setalpha performs the alpha computation on a given .BR color , ignoring its initial alpha value, multiplying the components by the supplied .BR alpha . For example, to make a 50% red color value, one could execute .B setalpha(DRed, .BR 0x7F) . .PP The remaining functions deal with moving groups of pixel values between image and user space or external files. There is a fixed format for the exchange and storage of image data (see .IR image (6)). .PP .I Unloadimage reads a rectangle of pixels from image .I i into .IR data , whose length is specified by .IR ndata . It is an error if .I ndata is too small to accommodate the pixels. .PP .I Loadimage replaces the specified rectangle in image .I i with the .I ndata bytes of .IR data . .PP The pixels are presented one horizontal line at a time, starting with the top-left pixel of .IR r . In the data processed by these routines, each scan line starts with a new byte in the array, leaving the last byte of the previous line partially empty, if necessary. Pixels are packed as tightly as possible within .IR data , regardless of the rectangle being extracted. Bytes are filled from most to least significant bit order, as the .I x coordinate increases, aligned so .IR x =0 would appear as the leftmost pixel of its byte. Thus, for .B depth 1, the pixel at .I x offset 165 within the rectangle will be in a .I data byte at bit-position .B 0x04 regardless of the overall rectangle: 165 mod 8 equals 5, and .B "0x80\ >>\ 5" equals .BR 0x04 . .PP .B Cloadimage does the same as .IR loadimage , but for .I ndata bytes of compressed image .I data (see .IR image (6)). On each call to .IR cloadimage, the .I data must be at the beginning of a compressed data block, in particular, it should start with the .B y coordinate and data length for the block. .PP .IR Loadimage , .IR cloadimage , and .I unloadimage return the number of bytes copied. .PP .I Readimage creates an image from data contained in an external file (see .IR image (6) for the file format); .I fd is a file descriptor obtained by opening such a file for reading. The returned image is allocated using .IR allocimage . The .I dolock flag specifies whether the .B Display should be synchronized for multithreaded access; single-threaded programs can leave it zero. .PP .I Writeimage writes image .I i onto file descriptor .IR fd , which should be open for writing. The format is as described for .IR readimage . .PP .I Readimage and .I writeimage do not close .IR fd . .PP .I Bytesperline and .I wordsperline return the number of bytes or words occupied in memory by one scan line of rectangle .I r in an image with .I d bits per pixel. .SH EXAMPLE To allocate a single-pixel replicated image that may be used to paint a region red, .EX red = allocimage(display, Rect(0, 0, 1, 1), RGB24, 1, DRed); .EE .SH SOURCE .B /sys/src/libdraw .SH "SEE ALSO" .IR graphics (2), .IR draw (2), .IR draw (3), .IR image (6) .SH DIAGNOSTICS These functions return pointer 0 or integer \-1 on failure, usually due to insufficient memory. .PP May set .IR errstr . .SH BUGS .B Depth must be a divisor or multiple of 8.