Documentation/fb/pxafb.rst - linux - Git at Google

 ================================
 Driver for PXA25x LCD controller
 ================================

 The driver supports the following options, either via
 options=<OPTIONS> when modular or video=pxafb:<OPTIONS> when built in.

 For example::

 	modprobe pxafb options=vmem:2M,mode:640x480-8,passive

 or on the kernel command line::

 	video=pxafb:vmem:2M,mode:640x480-8,passive

 vmem: VIDEO_MEM_SIZE

 	Amount of video memory to allocate (can be suffixed with K or M
 	for kilobytes or megabytes)

 mode:XRESxYRES[-BPP]

 	XRES == LCCR1_PPL + 1

 	YRES == LLCR2_LPP + 1

 		The resolution of the display in pixels

 	BPP == The bit depth. Valid values are 1, 2, 4, 8 and 16.

 pixclock:PIXCLOCK

 	Pixel clock in picoseconds

 left:LEFT == LCCR1_BLW + 1

 right:RIGHT == LCCR1_ELW + 1

 hsynclen:HSYNC == LCCR1_HSW + 1

 upper:UPPER == LCCR2_BFW

 lower:LOWER == LCCR2_EFR

 vsynclen:VSYNC == LCCR2_VSW + 1

 	Display margins and sync times

 color | mono => LCCR0_CMS

 	umm...

 active | passive => LCCR0_PAS

 	Active (TFT) or Passive (STN) display

 single | dual => LCCR0_SDS

 	Single or dual panel passive display

 4pix | 8pix => LCCR0_DPD

 	4 or 8 pixel monochrome single panel data

 hsync:HSYNC, vsync:VSYNC

 	Horizontal and vertical sync. 0 => active low, 1 => active
 	high.

 dpc:DPC

 	Double pixel clock. 1=>true, 0=>false

 outputen:POLARITY

 	Output Enable Polarity. 0 => active low, 1 => active high

 pixclockpol:POLARITY

 	pixel clock polarity
 	0 => falling edge, 1 => rising edge


 Overlay Support for PXA27x and later LCD controllers
 ====================================================

   PXA27x and later processors support overlay1 and overlay2 on-top of the
   base framebuffer (although under-neath the base is also possible). They
   support palette and no-palette RGB formats, as well as YUV formats (only
   available on overlay2). These overlays have dedicated DMA channels and
   behave in a similar way as a framebuffer.

   However, there are some differences between these overlay framebuffers
   and normal framebuffers, as listed below:

   1. overlay can start at a 32-bit word aligned position within the base
      framebuffer, which means they have a start (x, y). This information
      is encoded into var->nonstd (no, var->xoffset and var->yoffset are
      not for such purpose).

   2. overlay framebuffer is allocated dynamically according to specified
      'struct fb_var_screeninfo', the amount is decided by::

 	var->xres_virtual * var->yres_virtual * bpp

      bpp = 16 -- for RGB565 or RGBT555

      bpp = 24 -- for YUV444 packed

      bpp = 24 -- for YUV444 planar

      bpp = 16 -- for YUV422 planar (1 pixel = 1 Y + 1/2 Cb + 1/2 Cr)

      bpp = 12 -- for YUV420 planar (1 pixel = 1 Y + 1/4 Cb + 1/4 Cr)

      NOTE:

      a. overlay does not support panning in x-direction, thus
 	var->xres_virtual will always be equal to var->xres

      b. line length of overlay(s) must be on a 32-bit word boundary,
 	for YUV planar modes, it is a requirement for the component
 	with minimum bits per pixel,  e.g. for YUV420, Cr component
 	for one pixel is actually 2-bits, it means the line length
 	should be a multiple of 16-pixels

      c. starting horizontal position (XPOS) should start on a 32-bit
 	word boundary, otherwise the fb_check_var() will just fail.

      d. the rectangle of the overlay should be within the base plane,
 	otherwise fail

      Applications should follow the sequence below to operate an overlay
      framebuffer:

 	 a. open("/dev/fb[1-2]", ...)
 	 b. ioctl(fd, FBIOGET_VSCREENINFO, ...)
 	 c. modify 'var' with desired parameters:

 	    1) var->xres and var->yres
 	    2) larger var->yres_virtual if more memory is required,
 	       usually for double-buffering
 	    3) var->nonstd for starting (x, y) and color format
 	    4) var->{red, green, blue, transp} if RGB mode is to be used

 	 d. ioctl(fd, FBIOPUT_VSCREENINFO, ...)
 	 e. ioctl(fd, FBIOGET_FSCREENINFO, ...)
 	 f. mmap
 	 g. ...

   3. for YUV planar formats, these are actually not supported within the
      framebuffer framework, application has to take care of the offsets
      and lengths of each component within the framebuffer.

   4. var->nonstd is used to pass starting (x, y) position and color format,
      the detailed bit fields are shown below::

       31                23  20         10          0
        +-----------------+---+----------+----------+
        |  ... unused ... |FOR|   XPOS   |   YPOS   |
        +-----------------+---+----------+----------+

      FOR  - color format, as defined by OVERLAY_FORMAT_* in pxafb.h

 	  - 0 - RGB
 	  - 1 - YUV444 PACKED
 	  - 2 - YUV444 PLANAR
 	  - 3 - YUV422 PLANAR
 	  - 4 - YUR420 PLANAR

      XPOS - starting horizontal position

      YPOS - starting vertical position
	================================
	Driver for PXA25x LCD controller
	================================

	The driver supports the following options, either via
	options=<OPTIONS> when modular or video=pxafb:<OPTIONS> when built in.

	For example::

	modprobe pxafb options=vmem:2M,mode:640x480-8,passive

	or on the kernel command line::

	video=pxafb:vmem:2M,mode:640x480-8,passive

	vmem: VIDEO_MEM_SIZE

	Amount of video memory to allocate (can be suffixed with K or M
	for kilobytes or megabytes)

	mode:XRESxYRES[-BPP]

	XRES == LCCR1_PPL + 1

	YRES == LLCR2_LPP + 1

	The resolution of the display in pixels

	BPP == The bit depth. Valid values are 1, 2, 4, 8 and 16.

	pixclock:PIXCLOCK

	Pixel clock in picoseconds

	left:LEFT == LCCR1_BLW + 1

	right:RIGHT == LCCR1_ELW + 1

	hsynclen:HSYNC == LCCR1_HSW + 1

	upper:UPPER == LCCR2_BFW

	lower:LOWER == LCCR2_EFR

	vsynclen:VSYNC == LCCR2_VSW + 1

	Display margins and sync times

	color \| mono => LCCR0_CMS

	umm...

	active \| passive => LCCR0_PAS

	Active (TFT) or Passive (STN) display

	single \| dual => LCCR0_SDS

	Single or dual panel passive display

	4pix \| 8pix => LCCR0_DPD

	4 or 8 pixel monochrome single panel data

	hsync:HSYNC, vsync:VSYNC

	Horizontal and vertical sync. 0 => active low, 1 => active
	high.

	dpc:DPC

	Double pixel clock. 1=>true, 0=>false

	outputen:POLARITY

	Output Enable Polarity. 0 => active low, 1 => active high

	pixclockpol:POLARITY

	pixel clock polarity
	0 => falling edge, 1 => rising edge


	Overlay Support for PXA27x and later LCD controllers
	====================================================

	PXA27x and later processors support overlay1 and overlay2 on-top of the
	base framebuffer (although under-neath the base is also possible). They
	support palette and no-palette RGB formats, as well as YUV formats (only
	available on overlay2). These overlays have dedicated DMA channels and
	behave in a similar way as a framebuffer.

	However, there are some differences between these overlay framebuffers
	and normal framebuffers, as listed below:

	1. overlay can start at a 32-bit word aligned position within the base
	framebuffer, which means they have a start (x, y). This information
	is encoded into var->nonstd (no, var->xoffset and var->yoffset are
	not for such purpose).

	2. overlay framebuffer is allocated dynamically according to specified
	'struct fb_var_screeninfo', the amount is decided by::

	var->xres_virtual * var->yres_virtual * bpp

	bpp = 16 -- for RGB565 or RGBT555

	bpp = 24 -- for YUV444 packed

	bpp = 24 -- for YUV444 planar

	bpp = 16 -- for YUV422 planar (1 pixel = 1 Y + 1/2 Cb + 1/2 Cr)

	bpp = 12 -- for YUV420 planar (1 pixel = 1 Y + 1/4 Cb + 1/4 Cr)

	NOTE:

	a. overlay does not support panning in x-direction, thus
	var->xres_virtual will always be equal to var->xres

	b. line length of overlay(s) must be on a 32-bit word boundary,
	for YUV planar modes, it is a requirement for the component
	with minimum bits per pixel, e.g. for YUV420, Cr component
	for one pixel is actually 2-bits, it means the line length
	should be a multiple of 16-pixels

	c. starting horizontal position (XPOS) should start on a 32-bit
	word boundary, otherwise the fb_check_var() will just fail.

	d. the rectangle of the overlay should be within the base plane,
	otherwise fail

	Applications should follow the sequence below to operate an overlay
	framebuffer:

	a. open("/dev/fb[1-2]", ...)
	b. ioctl(fd, FBIOGET_VSCREENINFO, ...)
	c. modify 'var' with desired parameters:

	1) var->xres and var->yres
	2) larger var->yres_virtual if more memory is required,
	usually for double-buffering
	3) var->nonstd for starting (x, y) and color format
	4) var->{red, green, blue, transp} if RGB mode is to be used

	d. ioctl(fd, FBIOPUT_VSCREENINFO, ...)
	e. ioctl(fd, FBIOGET_FSCREENINFO, ...)
	f. mmap
	g. ...

	3. for YUV planar formats, these are actually not supported within the
	framebuffer framework, application has to take care of the offsets
	and lengths of each component within the framebuffer.

	4. var->nonstd is used to pass starting (x, y) position and color format,
	the detailed bit fields are shown below::

	31 23 20 10 0
	+-----------------+---+----------+----------+
	\| ... unused ... \|FOR\| XPOS \| YPOS \|
	+-----------------+---+----------+----------+

	FOR - color format, as defined by OVERLAY_FORMAT_* in pxafb.h

	- 0 - RGB
	- 1 - YUV444 PACKED
	- 2 - YUV444 PLANAR
	- 3 - YUV422 PLANAR
	- 4 - YUR420 PLANAR

	XPOS - starting horizontal position

	YPOS - starting vertical position