.TH VCMAILBOX 7
.
.SH NAME
vcmailbox \- the VideoCore mailbox property interface
.
.
.SH DESCRIPTION
.
The mailbox can be used by the ARM on the Raspberry Pi to communicate with the
VideoCore processor.
From the command line, the
.BR vcmailbox (1)
can be used for this purpose.
The mailbox operates a simple request / response protocol:
.
.IP \(bu 3
The response overwrites the request.
.RS
.IP \(bu 3
The callee is not allowed to return a different buffer address, this allows the
caller to make independent asynchronous requests.
.RE
.
.IP \(bu
The buffer itself is 16-byte aligned as only the upper 28 bits of the address
can be passed via the mailbox.
.
.IP \(bu
All u64/u32/u16 values are in host CPU endian order.
.
.IP \(bu
Unknown tags are ignored (the response bit will not be set).
.
.IP \(bu
Response may include unsolicited tags.
.
.IP \(bu
Response tag lengths may be longer than expected if additional information is
provided in a future format.
.RS
.IP \(bu 3
The response is truncated to the provided buffer length.
.IP \(bu
Incompatible changes require a new tag so that where the buffer is the size
required by a previous version the truncated part should be readable as per the
previous version.
.IP \(bu
Response length indicates the desired length even when it is longer than the
buffer size filled.
.IP \(bu
Tag value length can be used to infer the version of the request/response.
.RE
.
.IP \(bu
Tags should be processed in order except where an interface requires multiple
tags for a single operation (like the frame buffer).
.
.
.SS Mailbox messages
.
.IP \(bu 3
The mailbox interface has 28 bits (MSB) available for the value and 4 bits
(LSB) for the channel.
.RS
.IP \(bu 3
Request message: 28 bits (MSB) buffer address
.IP \(bu
Response message: 28 bits (MSB) buffer address
.RE
.
.IP \(bu
Channels 8 and 9 are used.
.RS
.IP \(bu 3
Channel 8: Request from ARM for response by VC
.IP \(bu
Channel 9: Request from VC for response by ARM (none currently defined)
.RE
.
.
.SS Buffer contents
.
.
.TP
.B u32
buffer size in bytes (including the header values, the end tag and
padding)
.
.TP
.B u32
buffer request/response code
.RS
.PP
Request codes:
.PD 0
.TP 12
.B 0x00000000
process request
.TP
.B \&
All other values reserved
.PD
.PP
Response codes:
.PD 0
.TP 12
.B 0x80000000
request successful
.TP
.B 0x80000001
error parsing request buffer (partial response)
.TP
.B \&
All other values reserved
.PD
.RE
.
.TP
.B u8\|.\|.\|.
sequence of concatenated tags
.
.TP
.B u32
0x0 (end tag)
.
.TP
.B u8\|.\|.\|.
padding
.
.
.SS Tag format
.
.TP
.B u32
tag identifier
.
.TP
.B u32
value buffer size in bytes
.
.TP
.B u32
Request codes:
.PD 0
.RS
.TP 12
.B b31 clear
request
.TP
.B b30-b0
reserved
.RE
.PD
.IP
Response codes:
.PD 0
.RS
.TP 12
.B b31 set
response
.TP
.B b30-b0
value length in bytes
.RE
.PD
.
.TP
.B u8\|.\|.\|.
value buffer
.
.TP
.B u8\|.\|.\|.
padding to align the tag to 32 bits.
.
.
.SH VIDEOCORE TAGS
.
.
.SS Get firmware revision
.PD 0
.TP 12
.B Tag:
0x00000001
.TP
.B Request:
0 bytes
.TP
.B Response:
4 bytes
.RS
.TP
.B u32
firmware revision
.RE
.PD
.
.
.SH HARDWARE TAGS
.
.SS Get board model
.PD 0
.TP 12
.B Tag:
0x00010001
.TP
.B Request:
0 bytes
.TP
.B Response:
4 bytes
.RS
.TP
.B u32
board model
.RE
.PD
.
.SS Get board revision
.PD 0
.TP 12
.B Tag:
0x00010002
.TP
.B Request:
0 bytes
.TP
.B Response:
4 bytes
.RS
.TP
.B u32
board revision
.RE
.PD
.
.SS Get board MAC address
.PD 0
.TP 12
.B Tag:
0x00010003
.TP
.B Request:
0 bytes
.TP
.B Response:
6 bytes
.RS
.TP
.B u8...
MAC address in network byte order
.RE
.PD
.
.SS Get board serial
.PD 0
.TP 12
.B Tag:
0x00010004
.TP
.B Request:
0 bytes
.TP
.B Response:
8 bytes
.RS
.TP
.B u64
board serial
.RE
.PD
.
.SS Get ARM memory
.PD 0
.TP 12
.B Tag:
0x00010005
.TP
.B Request:
0 bytes
.TP
.B Response:
8 bytes
.RS
.TP
.B u32
base address in bytes
.TP
.B u32
size in bytes
.RE
.PD
.
.PP
Future formats may specify multiple base+size combinations.
.
.SS Get VC memory
.PD 0
.TP 12
.B Tag:
0x00010006
.TP
.B Request:
0 bytes
.TP
.B Response:
8 bytes
.RS
.TP
.B u32
base address in bytes
.TP
.B u32
size in bytes
.RE
.PD
.
.PP
Future formats may specify multiple base+size combinations.
.
.SS Get clocks
.PD 0
.TP 12
.B Tag:
0x00010007
.TP
.B Request:
0 bytes
.TP
.B Response:
variable bytes (multiple of 8)
.RS
.TP
.B u32
parent clock id (0 for a root clock)
.TP
.B u32
clock id
.TP
.B (repeated)
.RE
.PD
.
.PP
Returns all clocks that exist
.IR "in top-down, breadth-first order" .
Clocks that depend on another clock should be defined as children of that clock. Clocks that depend on no other clocks should have no parent. Clock IDs are as in the
.B CLOCK TAGS
section below.
.
.
.SH CONFIG TAGS
.
.SS Get command line
.PD 0
.TP 12
.B Tag:
0x00050001
.TP
.B Request:
0 bytes
.TP
.B Response:
variable bytes
.RS
.TP
.B u8...
ASCII command line string
.RE
.PD
.
.PP
Caller should not assume the string is null terminated.
.
.
.SH SHARED RESOURCE MANAGEMENT TAGS
.
.SS Get DMA channels
.PD 0
.TP 12
.B Tag:
0x00060001
.TP
.B Request:
0 bytes
.TP
.B Response:
4 bytes
.RS
.TP
.B u32
mask
.RS
.TP 12
.B Bits 0-15
DMA channels 0-15 (0=do not use, 1=usable)
.TP
.B Bits 16-31
reserved for future use
.RE
.RE
.PD
.
.PP
Caller assumes that the VC has enabled all the usable DMA channels.
.
.
.SH POWER TAGS
.
.SS Unique device IDs
.PD 0
.TP 12
.B 0x00000000
SD Card
.TP
.B 0x00000001
UART0
.TP
.B 0x00000002
UART1
.TP
.B 0x00000003
USB HCD
.TP
.B 0x00000004
I2C0
.TP
.B 0x00000005
I2C1
.TP
.B 0x00000006
I2C2
.TP
.B 0x00000007
SPI
.TP
.B 0x00000008
CCP2TX
.TP
.B 0x00000009
Unknown (RPi4)
.TP
.B 0x0000000a
Unknown (RPi4)
.PD
.
.SS Get power state
.PD 0
.TP 12
.B Tag:
0x00020001
.TP
.B Request:
4 bytes
.RS
.TP
.B u32
device id
.RE
.TP
.B Response:
8 bytes
.RS
.TP
.B u32
device id
.TP
.B u32
state
.RS
.TP 12
.B Bit 0
0=off, 1=on
.TP
.B Bit 1
0=device exists, 1=device does not exist
.TP
.B Bits 2-31
reserved for future use
.RE
.RE
.PD
.
.PP
Response indicates current state.
.
.SS Get timing
.PD 0
.TP 12
.B Tag:
0x00020002
.TP
.B Request:
4 bytes
.RS
.TP
.B u32
device id
.RE
.TP
.B Response:
8 bytes
.RS
.TP
.B u32
device id
.TP
.B u32
enable wait time in microseconds
.RE
.PD
.
.PP
Response indicates wait time required after turning a device on before power is stable. Returns 0 wait time if the device does not exist.
.
.SS Set power state
.PD 0
.TP 12
.B Tag:
0x00028001
.TP
.B Request:
8 bytes
.RS
.TP
.B u32
device id
.TP
.B u32
state
.RS
.TP 12
.B Bit 0
0=off, 1=on
.TP
.B Bit 1
0=do not wait, 1=wait
.TP
.B Bits 2-31
reserved for future use (set to 0)
.RE
.RE
.TP
.B Response:
8 bytes
.RS
.TP
.B u32
device id
.TP
.B u32
state
.RS
.TP 12
.B Bit 0
0=off, 1=on
.TP
.B Bit 1
0=device exists, 1=device does not exist
.TP
.B Bits 2-31
reserved for future use
.RE
.RE
.PD
.
.PP
Response indicates new state, with/without waiting for the power to become stable.
.
.
.SH CLOCK TAGS
.
.SS Unique clock IDs
.PD 0
.TP 12
.B 0x00000000
reserved
.TP
.B 0x00000001
EMMC
.TP
.B 0x00000002
UART
.TP
.B 0x00000003
ARM
.TP
.B 0x00000004
CORE
.TP
.B 0x00000005
V3D
.TP
.B 0x00000006
H264
.TP
.B 0x00000007
ISP
.TP
.B 0x00000008
SDRAM
.TP
.B 0x00000009
PIXEL
.TP
.B 0x0000000a
PWM
.TP
.B 0x0000000b
HEVC
.TP
.B 0x0000000c
EMMC2
.TP
.B 0x0000000d
M2MC
.TP
.B 0x0000000e
PIXEL_BVB
.PD
.
.PP
All clocks are the
.I base clocks
for those peripherals, e.g. 3MHz for UART, 50/100MHz for EMMC, not the dividers applied using the peripheral.
.
.SS Get clock state
.PD 0
.TP 12
.B Tag:
0x00030001
.TP
.B Request:
4 bytes
.RS
.TP
.B u32
clock id
.RE
.TP
.B Response:
8 bytes
.RS
.TP
.B u32
clock id
.TP
.B u32
state
.RS
.TP 12
.B Bit 0
0=off, 1=on
.TP
.B Bit 1
0=clock exists, 1=clock does not exist
.TP
.B Bits 2-31
reserved for future use
.RE
.RE
.PD
.
.SS Set clock state
.PD 0
.TP 12
.B Tag:
0x00038001
.TP
.B Request:
8 bytes
.RS
.TP
.B u32
clock id
.TP
.B u32
state
.RS
.TP 12
.B Bit 0
0=off, 1=on
.TP
.B Bit 1
0=clock exists, 1=clock does not exist
.TP
.B Bits 2-31
reserved for future use (set to 0)
.RE
.RE
.TP
.B Response:
8 bytes
.RS
.TP
.B u32
clock id
.TP
.B u32
state
.RS
.TP 12
.B Bit 0
0=off, 1=on
.TP
.B Bit 1
0=clock exists, 1=clock does not exist
.TP
.B Bits 2-31
reserved for future use
.RE
.RE
.PD
.
.SS Get clock rate
.PD 0
.TP 12
.B Tag:
0x00030002
.TP
.B Request:
4 bytes
.RS
.TP
.B u32
clock id
.RE
.TP
.B Response:
8 bytes
.RS
.TP
.B u32
clock id
.TP
.B u32
rate (in Hz)
.RE
.PD
.
.PP
Next enable rate should be returned even if the clock is not running. A rate of 0 is returned if the clock does not exist.
.
.SS Set clock rate
.PD 0
.TP 12
.B Tag:
0x00038002
.TP
.B Request:
12 bytes
.RS
.TP
.B u32
clock id
.TP
.B u32
rate (in Hz)
.TP
.B u32
skip setting turbo
.RE
.TP
.B Response:
8 bytes
.RS
.TP
.B u32
clock id
.TP
.B u32
rate (in Hz)
.RE
.PD
.
.PP
Next supported enable rate should be returned even if the clock is not running. A rate of 0 is returned if the clock does not exist. The clock rate may be clamped to the supported range.
.
.PP
By default when setting arm freq above default, other turbo settings will be enabled (e.g. voltage, sdram and gpu frequencies). You can disable this effect by setting "skip setting turbo" to 1.
.
.SS Get max clock rate
.PD 0
.TP 12
.B Tag:
0x00030004
.TP
.B Request:
4 bytes
.RS
.TP
.B u32
clock id
.RE
.TP
.B Response:
8 bytes
.RS
.TP
.B u32
clock id
.TP
.B u32
rate (in Hz)
.RE
.PD
.
.PP
Return the maximum supported clock rate for the given clock. Clocks should not be set higher than this.
.
.SS Get min clock rate
.PD 0
.TP 12
.B Tag:
0x00030007
.TP
.B Request:
4 bytes
.RS
.TP
.B u32
clock id
.RE
.TP
.B Response:
8 bytes
.RS
.TP
.B u32
clock id
.TP
.B u32
rate (in Hz)
.RE
.PD
.
.PP
Return the minimum supported clock rate for the given clock. This may be used when idle.
.
.SS Get turbo
.PD 0
.TP 12
.B Tag:
0x00030009
.TP
.B Request:
4 bytes
.RS
.TP
.B u32
id
.RE
.TP
.B Response:
8 bytes
.RS
.TP
.B u32
id
.TP
.B u32
level
.RE
.PD
.
.PP
Get the turbo state for index id. id should be 0. level will be zero for non-turbo and one for turbo.
.
.SS Set turbo
.PD 0
.TP 12
.B Tag:
0x00038009
.TP
.B Request:
8 bytes
.RS
.TP
.B u32
id
.TP
.B u32
level
.RE
.TP
.B Response:
8 bytes
.RS
.TP
.B u32
id
.TP
.B u32
level
.RE
.PD
.
.PP
Set the turbo state for index id. id should be zero. level will be zero for non-turbo and one for turbo.
This will cause GPU clocks to be set to maximum when enabled and minimum when disabled.
.
.
.SH VOLTAGE TAGS
.
.SS Unique voltage IDs
.PD 0
.TP 12
.B 0x00000000
reserved
.TP
.B 0x00000001
Core
.TP
.B 0x00000002
SDRAM_C
.TP
.B 0x00000003
SDRAM_P
.TP
.B 0x00000004
SDRAM_I
.PD
.
.SS Get voltage
.PD 0
.TP 12
.B Tag:
0x00030003
.TP
.B Request:
4 bytes
.RS
.TP
.B u32
voltage id
.RE
.TP
.B Response:
8 bytes
.RS
.TP
.B u32
voltage id
.TP
.B u32
value (offset from 1.2V in units of 0.025V)
.RE
.PD
.
.PP
The voltage value may be clamped to the supported range.
A value of 0x80000000 means the id was not valid.
.
.SS Set voltage
.PD 0
.TP 12
.B Tag:
0x00038003
.TP
.B Request:
8 bytes
.RS
.TP
.B u32
voltage id
.TP
.B u32
value (offset from 1.2V in units of 0.025V)
.RE
.TP
.B Response:
8 bytes
.RS
.TP
.B u32
voltage id
.TP
.B u32
value (offset from 1.2V in units of 0.025V)
.RE
.PD
.
.PP
The voltage value may be clamped to the supported range.
A value of 0x80000000 means the id was not valid.
.
.SS Get max voltage
.PD 0
.TP 12
.B Tag:
0x00030005
.TP
.B Request:
4 bytes
.RS
.TP
.B u32
voltage id
.RE
.TP
.B Response:
8 bytes
.RS
.TP
.B u32
voltage id
.TP
.B u32
value (offset from 1.2V in units of 0.025V)
.RE
.PD
.
.PP
Return the maximum supported voltage rate for the given id. Voltages should not be set higher than this.
.
.SS Get min voltage
.PD 0
.TP 12
.B Tag:
0x00030008
.TP
.B Request:
4 bytes
.RS
.TP
.B u32
voltage id
.RE
.TP
.B Response:
8 bytes
.RS
.TP
.B u32
voltage id
.TP
.B u32
value (offset from 1.2V in units of 0.025V)
.RE
.PD
.
.PP
Return the minimum supported voltage rate for the given id. This may be used when idle.
.
.SS Get temperature
.PD 0
.TP 12
.B Tag:
0x00030006
.TP
.B Request:
4 bytes
.RS
.TP
.B u32
temperature id
.RE
.TP
.B Response:
8 bytes
.RS
.TP
.B u32
temperature id
.TP
.B u32
value
.RE
.PD
.
.PP
Return the temperature of the SoC in thousandths of a degree C. id should be zero.
.
.SS Get max temperature
.PD 0
.TP 12
.B Tag:
0x0003000a
.TP
.B Request:
4 bytes
.RS
.TP
.B u32
temperature id
.RE
.TP
.B Response:
8 bytes
.RS
.TP
.B u32
temperature id
.TP
.B u32
value
.RE
.PD
.
.PP
Return the maximum safe temperature of the SoC in thousandths of a degree C. id should be zero.
Overclock may be disabled above this temperature.
.
.SS Allocate memory
.PD 0
.TP 12
.B Tag:
0x0003000c
.TP
.B Request:
12 bytes
.RS
.TP
.B u32
size
.TP
.B u32
alignment
.TP
.B u32
flags
.RE
.TP
.B Response:
4 bytes
.RS
.TP
.B u32
handle
.RE
.PD
.
.PP
Allocates contiguous memory on the GPU. size and alignment are in bytes. flags contain:
.
.PP
.TS
l l l .
Name	Value	Comments
\_	\_	\_
MEM_FLAG_NORMAL	0	normal allocating alias; don't use from ARM
MEM_FLAG_DISCARDABLE	1 << 0	can be resized to 0 at any time; use for cached data
MEM_FLAG_DIRECT	1 << 2	0xC alias uncached
MEM_FLAG_COHERENT	1 << 3	0x8 alias; non-allocating in L2 but coherent
MEM_FLAG_L1_NONALLOCATING	3 << 2	Allocating in L2
MEM_FLAG_ZERO	1 << 4	Initialise buffer to all zeros
MEM_FLAG_NO_INIT	1 << 5	Don't initialise; default is initialise to all ones
MEM_FLAG_HINT_PERMALOCK	1 << 6	Likely to be locked for long periods of time
.TE
.
.SS Lock memory
.PD 0
.TP 12
.B Tag:
0x0003000d
.TP
.B Request:
4 bytes
.RS
.TP
.B u32
handle
.RE
.TP
.B Response:
4 bytes
.RS
.TP
.B u32
bus address
.RE
.PD
.
.PP
Lock buffer in place, and return a bus address. Must be done before memory can be accessed
.
.SS Unlock memory
.PD 0
.TP 12
.B Tag:
0x0003000e
.TP
.B Request:
4 bytes
.RS
.TP
.B u32
handle
.RE
.TP
.B Response:
4 bytes
.RS
.TP
.B u32
status
.RE
.PD
.
.PP
Unlock buffer. It retains contents, but may move. Needs to be locked before next use.
status=0 is success.
.
.SS Release Memory
.PD 0
.TP 12
.B Tag:
0x0003000f
.TP
.B Request:
4 bytes
.RS
.TP
.B u32
handle
.RE
.TP
.B Response:
4 bytes
.RS
.TP
.B u32
status
.RE
.PD
.
.PP
Free the memory buffer. status=0 is success.
.
.SS Execute Code
.PD 0
.TP 12
.B Tag:
0x00030010
.TP
.B Request:
28 bytes
.RS
.TP
.B u32
function pointer
.TP
.B u32
r0
.TP
.B u32
r1
.TP
.B u32
r2
.TP
.B u32
r3
.TP
.B u32
r4
.TP
.B u32
r5
.RE
.TP
.B Response:
4 bytes
.RS
.TP
.B u32
r0
.RE
.PD
.
.PP
Calls the function at given (bus) address and with arguments given. E.g.
r0 = fn(r0, r1, r2, r3, r4, r5);
It blocks until call completes. The (GPU) instruction cache is implicitly flushed.
Setting the lsb of function pointer address will suppress the instruction cache flush if you know the buffer hasn't changed since last execution.
.
.SS Get Dispmanx Resource mem handle
.PD 0
.TP 12
.B Tag:
0x00030014
.TP
.B Request:
4 bytes
.RS
.TP
.B u32
dispmanx resource handle
.RE
.TP
.B Response:
8 bytes
.RS
.TP
.B u32
0 is successful
.TP
.B u32
mem handle for resource
.RE
.PD
.
.PP
Gets the mem_handle associated with a created dispmanx resource.
This can be locked and the memory directly written from the arm to avoid having to copy the image data to GPU.
.
.SS Get EDID block
.PD 0
.TP 12
.B Tag:
0x00030020
.TP
.B Request:
4 bytes
.RS
.TP
.B u32
block number
.RE
.TP
.B Response:
136 bytes
.RS
.TP
.B u32
block number
.TP
.B u32
status
.TP
.B u8\|.\|.\|.
EDID block
.RE
.PD
.
.PP
This reads the specified EDID block from attached HDMI/DVI device.
There will always be at least one block of 128 bytes, but there may be additional blocks. You should keep requesting blocks (starting from 0) until the status returned is non-zero.
.
.
.SH FRAME BUFFER TAGS
.
.IP \(bu 3
All tags in the request are processed in one operation.
.IP \(bu
It is not valid to mix Test tags with Get/Set tags in the same operation and no tags will be returned.
.IP \(bu
Get tags will be processed after all Set tags.
.IP \(bu
If an allocate buffer tag is omitted when setting parameters, then no change occurs unless it can be accommodated without changing the buffer base or size.
.IP \(bu
When an allocate buffer response is returned, the old buffer area (if the base or size has changed) is implicitly freed.
.
.PP
For example:
.
.IP 1. 3
The current values/defaults are loaded into a temporary struct
.
.IP 2.
The tags are used to overwrite some or all of the values
.
.IP 3.
Validation of Test/Set tags occurs
.
.IP 4.
The Set changes are applied and responses based on the requested Get/Test/Set tags are written to the buffer
.
Duplicating the same tag in one request/response is prohibited. The expected result is either an error or implementation specified undefined behaviour (such as only using the last instance of the tag).
.PD
.
.SS Allocate buffer
.PD 0
.TP 12
.B Tag:
0x00040001
.TP
.B Request:
4 bytes
.RS
.TP
.B u32
alignment in bytes
.RE
.TP
.B Response:
8 bytes
.RS
.TP
.B u32
frame buffer base address in bytes
.TP
.B u32
frame buffer size in bytes
.RE
.PD
.
.PP
If the requested alignment is unsupported then the current base and size (which may be 0 if not allocated) is returned and no change occurs.
.
.SS Release buffer
.PD 0
.TP 12
.B Tag:
0x00048001
.TP
.B Request:
0 bytes
.TP
.B Response:
0 bytes
.PD
.
.PP
Releases and disables the frame buffer.
.
.SS Blank screen
.PD 0
.TP 12
.B Tag:
0x00040002
.TP
.B Request:
4 bytes
.RS
.TP
.B u32
state
.RS
.TP 12
.B Bit 0
0=off, 1=on
.TP
.B Bits 1-31
reserved for future use (set to 0)
.RE
.RE
.TP
.B Response:
4 bytes
.RS
.TP
.B u32
state
.RS
.TP 12
.B Bit 0
0=off, 1=on
.TP
.B Bits 1-31
reserved for future use
.RE
.RE
.PD
.
.SS Get physical (display) width/height
.PD 0
.TP 12
.B Tag:
0x00040003
.TP
.B Request:
0 bytes
.TP
.B Response:
8 bytes
.RS
.TP
.B u32
width in pixels
.TP
.B u32
height in pixels
.RE
.PD
.
.PP
Note that the "physical (display)" size is the size of the allocated buffer in memory, not the resolution of the video signal sent to the display device.
.
.SS Test physical (display) width/height
.PD 0
.TP 12
.B Tag:
0x00044003
.TP
.B Request:
8 bytes
.RS
.TP
.B u32
width in pixels
.TP
.B u32
height in pixels
.RE
.TP
.B Response:
8 bytes
.RS
.TP
.B u32
width in pixels
.TP
.B u32
height in pixels
.RE
.PD
.
.PP
Response is the same as the request (or modified), to indicate if this configuration is supported (in combination with all the other settings). Does not modify the current hardware or frame buffer state.
.
.SS Set physical (display) width/height
.PD 0
.TP 12
.B Tag:
0x00048003
.TP
.B Request:
8 bytes
.RS
.TP
.B u32
width in pixels
.TP
.B u32
height in pixels
.RE
.TP
.B Response:
8 bytes
.RS
.TP
.B u32
width in pixels
.TP
.B u32
height in pixels
.RE
.PD
.
.PP
The response may not be the same as the request so it must be checked. May be the previous width/height or 0 for unsupported.
.
.
.SS Get virtual (buffer) width/height
.PD 0
.TP 12
.B Tag:
0x00040004
.TP
.B Request:
0 bytes
.TP
.B Response:
8 bytes
.RS
.TP
.B u32
width in pixels
.TP
.B u32
height in pixels
.RE
.PD
.
.PP
Note that the "virtual (buffer)" size is the portion of buffer that is sent to the display device, not the resolution the buffer itself. This may be smaller than the allocated buffer size in order to implement panning.
.
.SS Test virtual (buffer) width/height
.PD 0
.TP 12
.B Tag:
0x00044004
.TP
.B Request:
8 bytes
.RS
.TP
.B u32
width in pixels
.TP
.B u32
height in pixels
.RE
.TP
.B Response:
8 bytes
.RS
.TP
.B u32
width in pixels
.TP
.B u32
height in pixels
.RE
.PD
.
.PP
Response is the same as the request (or modified), to indicate if this configuration is supported (in combination with all the other settings). Does not modify the current hardware or frame buffer state.
.
.SS Set virtual (buffer) width/height
.PD 0
.TP 12
.B Tag:
0x00048004
.TP
.B Request:
8 bytes
.RS
.TP
.B u32
width in pixels
.TP
.B u32
height in pixels
.RE
.TP
.B Response:
8 bytes
.RS
.TP
.B u32
width in pixels
.TP
.B u32
height in pixels
.RE
.PD
.
.PP
The response may not be the same as the request so it must be checked. May be the previous width/height or 0 for unsupported.
.
.SS Get depth
.PD 0
.TP 12
.B Tag:
0x00040005
.TP
.B Request:
0 bytes
.TP
.B Response:
4 bytes
.RS
.TP
.B u32
bits per pixel
.RE
.PD
.
.PP
Test depth
.PD 0
.TP 12
.B Tag:
0x00044005
.TP
.B Request:
4 bytes
.RS
.TP
.B u32
bits per pixel
.RE
.TP
.B Response:
4 bytes
.RS
.TP
.B u32
bits per pixel
.RE
.PD
.
.PP
Response is the same as the request (or modified), to indicate if this configuration is supported (in combination with all the other settings). Does not modify the current hardware or frame buffer state.
.
.SS Set depth
.PD 0
.TP 12
.B Tag:
0x00048005
.TP
.B Request:
4 bytes
.RS
.TP
.B u32
bits per pixel
.RE
.TP
.B Response:
4 bytes
.RS
.TP
.B u32
bits per pixel
.RE
.PD
.
.PP
The response may not be the same as the request so it must be checked. May be the previous depth or 0 for unsupported.
.
.SS Get pixel order
.PD 0
.TP 12
.B Tag:
0x00040006
.TP
.B Request:
0 bytes
.TP
.B Response:
4 bytes
.RS
.TP
.B u32
state
.RS
.TP
.B 0x0
BGR
.TP
.B 0x1
RGB
.RE
.RE
.PD
.
.SS Test pixel order
.PD 0
.TP 12
.B Tag:
0x00044006
.TP
.B Request:
4 bytes
.RS
.TP
.B u32
state (as above)
.RE
.TP
.B Response:
4 bytes
.RS
.TP
.B u32
state (as above)
.RE
.PD
.
.PP
Response is the same as the request (or modified), to indicate if this configuration is supported (in combination with all the other settings). Does not modify the current hardware or frame buffer state.
.
.SS Set pixel order
.PD 0
.TP 12
.B Tag:
0x00048006
.TP
.B Request:
4 bytes
.RS
.TP
.B u32
state (as above)
.RE
.TP
.B Response:
4 bytes
.RS
.TP
.B u32
state (as above)
.RE
.PD
.
.PP
The response may not be the same as the request so it must be checked.
.
.SS Get alpha mode
.PD 0
.TP 12
.B Tag:
0x00040007
.TP
.B Request:
0 bytes
.TP
.B Response:
4 bytes
.RS
.TP
.B u32
state
.RS
.TP
.B 0x0
Alpha channel enabled (0 = fully opaque)
.TP
.B 0x1
Alpha channel reversed (0 = fully transparent)
.TP
.B 0x2
Alpha channel ignored
.RE
.RE
.PD
.
.SS Test alpha mode
.PD 0
.TP 12
.B Tag:
0x00044007
.TP
.B Request:
4 bytes
.RS
.TP
.B u32
state (as above)
.RE
.TP
.B Response:
4 bytes
.RS
.TP
.B u32
state (as above)
.RE
.PD
.
.PP
Response is the same as the request (or modified), to indicate if this configuration is supported (in combination with all the other settings). Does not modify the current hardware or frame buffer state.
.
.SS Set alpha mode
.PD 0
.TP 12
.B Tag:
0x00048007
.TP
.B Request:
4 bytes
.RS
.TP
.B u32
state (as above)
.RE
.TP
.B Response:
4 bytes
.RS
.TP
.B u32
state (as above)
.RE
.PD
.
.PP
The response may not be the same as the request so it must be checked.
.
.SS Get pitch
.PD 0
.TP 12
.B Tag:
0x00040008
.TP
.B Request:
0 bytes
.TP
.B Response:
4 bytes
.RS
.TP
.B u32
bytes per line
.RE
.PD
.
.SS Get virtual offset
.PD 0
.TP 12
.B Tag:
0x00040009
.TP
.B Request:
0 bytes
.TP
.B Response:
8 bytes
.RS
.TP
.B u32
X in pixels
.TP
.B u32
Y in pixels
.RE
.PD
.
.SS Test virtual offset
.PD 0
.TP 12
.B Tag:
0x00044009
.TP
.B Request:
8 bytes
.RS
.TP
.B u32
X in pixels
.TP
.B u32
Y in pixels
.RE
.TP
.B Response:
8 bytes
.RS
.TP
.B u32
X in pixels
.TP
.B u32
Y in pixels
.RE
.PD
.
.PP
Response is the same as the request (or modified), to indicate if this configuration is supported (in combination with all the other settings). Does not modify the current hardware or frame buffer state.
.
.SS Set virtual offset
.PD 0
.TP 12
.B Tag:
0x00048009
.TP
.B Request:
8 bytes
.RS
.TP
.B u32
X in pixels
.TP
.B u32
Y in pixels
.RE
.TP
.B Response:
8 bytes
.RS
.TP
.B u32
X in pixels
.TP
.B u32
Y in pixels
.RE
.PD
.
.PP
The response may not be the same as the request so it must be checked. May be the previous offset or 0 for unsupported.
.
.SS Get overscan
.PD 0
.TP 12
.B Tag:
0x0004000a
.TP
.B Request:
0 bytes
.TP
.B Response:
16 bytes
.RS
.TP
.B u32
top in pixels
.TP
.B u32
bottom in pixels
.TP
.B u32
left in pixels
.TP
.B u32
right in pixels
.RE
.PD
.
.SS Test overscan
.PD 0
.TP 12
.B Tag:
0x0004400a
.TP
.B Request:
16 bytes
.RS
.TP
.B u32
top in pixels
.TP
.B u32
bottom in pixels
.TP
.B u32
left in pixels
.TP
.B u32
right in pixels
.RE
.TP
.B Response:
16 bytes
.RS
.TP
.B u32
top in pixels
.TP
.B u32
bottom in pixels
.TP
.B u32
left in pixels
.TP
.B u32
right in pixels
.RE
.PD
.
.PP
Response is the same as the request (or modified), to indicate if this configuration is supported (in combination with all the other settings). Does not modify the current hardware or frame buffer state.
.
.SS Set overscan
.PD 0
.TP 12
.B Tag:
0x0004800a
.TP
.B Request:
16 bytes
.RS
.TP
.B u32
top in pixels
.TP
.B u32
bottom in pixels
.TP
.B u32
left in pixels
.TP
.B u32
right in pixels
.RE
.TP
.B Response:
16 bytes
.RS
.TP
.B u32
top in pixels
.TP
.B u32
bottom in pixels
.TP
.B u32
left in pixels
.TP
.B u32
right in pixels
.RE
.PD
.
.PP
The response may not be the same as the request so it must be checked. May be the previous overscan or 0 for unsupported.
.
.SS Get palette
.PD 0
.TP 12
.B Tag:
0x0004000b
.TP
.B Request:
0 bytes
.TP
.B Response:
1024 bytes
.RS
.TP
.B u32...
RGBA palette values (index 0 to 255)
.RE
.PD
.
.SS Test palette
.PD 0
.TP 12
.B Tag:
0x0004400b
.TP
.B Request:
24 bytes..1032 bytes
.RS
.TP
.B u32
offset: first palette index to set (0-255)
.TP
.B u32
length: number of palette entries to set (1-256)
.TP
.B u32...
RGBA palette values (offset to offset+length-1)
.RE
.TP
.B Response:
4 bytes
.RS
.TP
.B u32
0=valid, 1=invalid
.RE
.PD
.
.PP
Response is the same as the request (or modified), to indicate if this configuration is supported (in combination with all the other settings). Does not modify the current hardware or frame buffer state.
.
.SS Set palette
.PD 0
.TP 12
.B Tag:
0x0004800b
.TP
.B Request:
24 bytes..1032 bytes
.RS
.TP
.B u32
offset: first palette index to set (0-255)
.TP
.B u32
length: number of palette entries to set (1-256)
.TP
.B u32...
RGBA palette values (offset to offset+length-1)
.RE
.TP
.B Response:
4 bytes
.RS
.TP
.B u32
0=valid, 1=invalid
.RE
.PD
.
.PP
The response may not be the same as the request so it must be checked. Palette changes should not be partially applied.
.
.SS Set Cursor Info
.PD 0
.TP 12
.B Tag:
0x00008010
.TP
.B Request:
24 bytes
.RS
.TP
.B u32
width
.TP
.B u32
height
.TP
.B u32
(unused)
.TP
.B u32
pointer to pixels
.TP
.B u32
hotspotX
.TP
.B u32
hotspotY
.RE
.TP
.B Response:
4 bytes
.RS
.TP
.B u32
0=valid, 1=invalid
.RE
.PD
.
.PP
Format is 32bpp (ARGB).
Width and height should be >= 16 and (width * height) <= 64.
.
.SS Set Cursor State
.PD 0
.TP 12
.B Tag:
0x00008011
.TP
.B Request:
16 bytes
.RS
.TP
.B u32
enable (1=visible, 0=invisible)
.TP
.B u32
x
.TP
.B u32
y
.TP
.B u32
flags; 0=display coords, 1=framebuffer coords
.RE
.TP
.B Response:
4 bytes
.RS
.TP
.B u32
0=valid, 1=invalid
.RE
.PD
.
.PP
if Set Cursor Info hasn't been called a default cursor will be used (64x64 with hotspot at 0,0).