Difference between revisions of "Unit BCM2836"

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Revision as of 23:53, 7 December 2016

Return to Unit Reference


Description


Note that most of this information is directly from the BCM2835 documentation as there is no complete technical reference yet available for the BCM2836.

Constants



BCM2836 specific constants BCM2836_*
BCM2836_CPU_COUNT = 4;  


BCM2836 ARM physical to VC IO mapping constants BCM2836_VCIO_*
See: BCM2835-ARM-Peripherals.pdf
 
BCM2836_VCIO_ALIAS = $7E000000;  


BCM2836 ARM physical to VC bus mapping constants BCM2836_VCBUS_*
See: BCM2835-ARM-Peripherals.pdf
 
BCM2836_VCBUS_0_ALIAS = $00000000; 0 Alias - L1 and L2 cached
BCM2836_VCBUS_4_ALIAS = $40000000; 4 Alias - L2 cache coherent (non allocating)
BCM2836_VCBUS_8_ALIAS = $80000000; 8 Alias - L2 cached (only)
BCM2836_VCBUS_C_ALIAS = $C0000000; {C Alias - Direct uncached} Suitable for RPi 2 Model B


BCM2836 peripheral constants BCM2836_PERIPHERALS_*
See: BCM2835-ARM-Peripherals.pdf
 
BCM2836_PERIPHERALS_BASE = $3F000000; Mapped to VC address 7E000000
BCM2836_PERIPHERALS_SIZE = $00FFFFFF;  


BCM2836 interrupt controller 0 constants BCM2836_IC0_*
BCM2836_IC0_REGS_BASE = BCM2836_PERIPHERALS_BASE + $2000;  


BCM2836 system timer constants BCM2836_SYSTEM_TIMER_*
See Section 12
 
BCM2836_SYSTEM_TIMER_REGS_BASE = BCM2836_PERIPHERALS_BASE + $3000;  


BCM2836 message based parallel host interface constants BCM2836_MPHI_*
BCM2836_MPHI_REGS_BASE = BCM2836_PERIPHERALS_BASE + $6000;  


BCM2836 DMA controller constants BCM2836_DMA*
Channels 0 to 14 (See Section 4)
 
BCM2836_DMA0_REGS_BASE = BCM2836_PERIPHERALS_BASE + $7000;  
BCM2836_DMA1_REGS_BASE = BCM2836_PERIPHERALS_BASE + $7100;  
BCM2836_DMA2_REGS_BASE = BCM2836_PERIPHERALS_BASE + $7200;  
BCM2836_DMA3_REGS_BASE = BCM2836_PERIPHERALS_BASE + $7300;  
BCM2836_DMA4_REGS_BASE = BCM2836_PERIPHERALS_BASE + $7400;  
BCM2836_DMA5_REGS_BASE = BCM2836_PERIPHERALS_BASE + $7500;  
BCM2836_DMA6_REGS_BASE = BCM2836_PERIPHERALS_BASE + $7600;  
BCM2836_DMA7_REGS_BASE = BCM2836_PERIPHERALS_BASE + $7700;  
BCM2836_DMA8_REGS_BASE = BCM2836_PERIPHERALS_BASE + $7800;  
BCM2836_DMA9_REGS_BASE = BCM2836_PERIPHERALS_BASE + $7900;  
BCM2836_DMA10_REGS_BASE = BCM2836_PERIPHERALS_BASE + $7A00;  
BCM2836_DMA11_REGS_BASE = BCM2836_PERIPHERALS_BASE + $7B00;  
BCM2836_DMA12_REGS_BASE = BCM2836_PERIPHERALS_BASE + $7C00;  
BCM2836_DMA13_REGS_BASE = BCM2836_PERIPHERALS_BASE + $7D00;  
BCM2836_DMA14_REGS_BASE = BCM2836_PERIPHERALS_BASE + $7E00;  
 
BCM2836_DMA_INT_STATUS_BASE = BCM2836_PERIPHERALS_BASE + $7FE0;  
BCM2836_DMA_ENABLE_BASE = BCM2836_PERIPHERALS_BASE + $7FF0;  


BCM2836 ARM interrupt controller constants BCM2836_INTERRUPT_*
See Section 7
 
BCM2836_INTERRUPT_REGS_BASE = BCM2836_PERIPHERALS_BASE + $B200; Note: Broadcom states 0xB000 but the offsets begin at 0x200 so 0xB200 will be correct


BCM2836 ARM timer constants BCM2836_TIMER_*
See Section 14
 
BCM2836_TIMER_REGS_BASE = BCM2836_PERIPHERALS_BASE + $B400; Note: Broadcom states 0xB000 but the offsets begin at 0x400 so 0xB400 will be correct


BCM2836 ARM mailbox 0 constants BCM2836_MAILBOX0_*
BCM2836_MAILBOX0_REGS_BASE = BCM2836_PERIPHERALS_BASE + $B880;  


BCM2836 ARM mailbox 1 constants BCM2836_MAILBOX1_*
BCM2836_MAILBOX1_REGS_BASE Currently unknown


BCM2836 power management, reset controller and watchdog constants BCM2836_PM_*
BCM2836_PM_REGS_BASE = BCM2836_PERIPHERALS_BASE + $100000;  


BCM2836 clock management constants BCM2836_CM_*
BCM2836_CM_REGS_BASE = BCM2836_PERIPHERALS_BASE + $101000;  


BCM2836 PCM clock constants BCM2836_PCM_CLOCK_*
BCM2836_PCM_CLOCK_BASE = BCM2836_PERIPHERALS_BASE + $101098;  


BCM2836 random number generator constants BCM2836_RNG_*
BCM2836_RNG_REGS_BASE = BCM2836_PERIPHERALS_BASE + $104000;  


BCM2836 GPIO constants BCM2836_GPIO_*
See Section 6
 
BCM2836_GPIO_REGS_BASE = BCM2836_PERIPHERALS_BASE + $200000;  


BCM2836 UART0 (PL011) constants BCM2836_PL011_*
See Section 13
 
BCM2836_PL011_REGS_BASE = BCM2836_PERIPHERALS_BASE + $201000;  


BCM2836 MMCI0 constants BCM2836_MMCI0_*
BCM2836_MMCI0_REGS_BASE = BCM2836_PERIPHERALS_BASE + $202000;  


BCM2836 PCM/I2S audio constants BCM2836_PCM_*
See Section 8
 
BCM2836_PCM_REGS_BASE = BCM2836_PERIPHERALS_BASE + $203000;  


BCM2836 SPI0 constants BCM2836_SPI0_*
See Section 10
 
BCM2836_SPI0_REGS_BASE = BCM2836_PERIPHERALS_BASE + $204000;  


BCM2836 BSC0 (I2C) constants BCM2836_BSC0_*
See Section 3
 
BCM2836_BSC0_REGS_BASE = BCM2836_PERIPHERALS_BASE + $205000;  


BCM2836 PWM constants BCM2836_PWM_*
See Section 9
 
BCM2836_PWM_REGS_BASE = BCM2836_PERIPHERALS_BASE + $20C000;  


BCM2836 I2C/SPI slave constants BCM2836_I2CSPI_*
See Section 11
 
BCM2836_I2CSPI_REGS_BASE = BCM2836_PERIPHERALS_BASE + $214000;  


BCM2836 AUX (UART1, SPI1 and SPI2) constants BCM2836_AUX_*
See Section 2
 
BCM2836_AUX_REGS_BASE = BCM2836_PERIPHERALS_BASE + $215000;  


BCM2836 SD host controller constants BCM2836_SDHCI_*
See Section 5
 
BCM2836_SDHCI_REGS_BASE = BCM2836_PERIPHERALS_BASE + $300000;  


BCM2836 SMI constants BCM2836_SMI_*
BCM2836_SMI_REGS_BASE = BCM2836_PERIPHERALS_BASE + $600000;  


BCM2836 BSC1 (I2C) constants BCM2836_BSC1_*
See Section 3
 
BCM2836_BSC1_REGS_BASE = BCM2836_PERIPHERALS_BASE + $804000;  


BCM2836 BSC2 (I2C) constants BCM2836_BSC2_*
See Section 3
Note: BSC2 master is used dedicated with the HDMI interface and should not be used
 
BCM2836_BSC2_REGS_BASE = BCM2836_PERIPHERALS_BASE + $805000;  


BCM2836 USB constants BCM2836_USB_*
See Section 15
 
BCM2836_USB_REGS_BASE = BCM2836_PERIPHERALS_BASE + $980000;  


BCM2836 V3D constants BCM2836_V3D_*
BCM2836_V3D_REGS_BASE = BCM2836_PERIPHERALS_BASE + $C00000;  


BCM2836 DMA controller constants BCM2836_DMA15_*
Channel 15 (See Section 4)
 
BCM2836_DMA15_REGS_BASE = BCM2836_PERIPHERALS_BASE + $E05000;  


BCM2836 IRQ peripheral constants BCM2836_IRQ_*
IRQs 0-63 are those shared between the GPU and CPU, IRQs 64-95 are CPU-specific
IRQs 0 to 31 appear in the IRQ_pending_1 register
 
System Timer
BCM2836_IRQ_SYSTEM_TIMER_0 = 0; Already used by the VideoCore GPU (Do not use)
BCM2836_IRQ_SYSTEM_TIMER_1 = 1;  
BCM2836_IRQ_SYSTEM_TIMER_2 = 2; Already used by the VideoCore GPU (Do not use)
BCM2836_IRQ_SYSTEM_TIMER_3 = 3;  
Codec
BCM2836_IRQ_CODEC0 = 4;  
BCM2836_IRQ_CODEC1 = 5;  
BCM2836_IRQ_CODEC2 = 6;  
JPEG
BCM2836_IRQ_JPEG = 7; Also available as IRQ 74 in the IRQ_basic_pending register
ISP
BCM2836_IRQ_ISP = 8;  
USB (Synopsys DesignWare Hi-Speed USB 2.0 On-The-Go Controller)
BCM2836_IRQ_USB = 9; Also available as IRQ 75 in the IRQ_basic_pending register
3D
BCM2836_IRQ_3D = 10; Also available as IRQ 76 in the IRQ_basic_pending register
Transposer
BCM2836_IRQ_TRANSPOSER = 11;  
Multicore Sync
BCM2836_IRQ_MULTICORESYNC0 = 12;  
BCM2836_IRQ_MULTICORESYNC1 = 13;  
BCM2836_IRQ_MULTICORESYNC2 = 14;  
BCM2836_IRQ_MULTICORESYNC3 = 15;  
DMA
BCM2836_IRQ_DMA0 = 16;  
BCM2836_IRQ_DMA1 = 17;  
BCM2836_IRQ_DMA2 = 18; Also available as IRQ 77 in the IRQ_basic_pending register
BCM2836_IRQ_DMA3 = 19; Also available as IRQ 78 in the IRQ_basic_pending register
BCM2836_IRQ_DMA4 = 20;  
BCM2836_IRQ_DMA5 = 21;  
BCM2836_IRQ_DMA6 = 22;  
BCM2836_IRQ_DMA7 = 23;  
BCM2836_IRQ_DMA8 = 24;  
BCM2836_IRQ_DMA9 = 25;  
BCM2836_IRQ_DMA10 = 26;  
BCM2836_IRQ_DMA11_14 = 27; BCM2836_IRQ_DMA11 This IRQ is actually shared between DMA channels 11, 12, 13 and 14
BCM2836_IRQ_DMA_ALL = 28; BCM2836_IRQ_DMA12 This IRQ is triggered by any DMA channel (all channels interrupt to allow DMA FIQ)
AUX (UART1, SPI1 and SPI2)
BCM2836_IRQ_AUX = 29;  
ARM
BCM2836_IRQ_ARM = 30;  
GPUDMA
BCM2836_IRQ_GPUDMA = 31;  
IRQs 32 to 63 appear in the IRQ_pending_2 register
 
Hostport
BCM2836_IRQ_HOSTPORT = 32;  
Videoscaler;
BCM2836_IRQ_VIDEOSCALER = 33;  
CCP2TX
BCM2836_IRQ_CCP2TX = 34;  
SDC
BCM2836_IRQ_SDC = 35;  
DSI0
BCM2836_IRQ_DSI0 = 36;  
AVE
BCM2836_IRQ_AVE = 37;  
CAM
BCM2836_IRQ_CAM0 = 38;  
BCM2836_IRQ_CAM1 = 39;  
HDMI
BCM2836_IRQ_HDMI0 = 40;  
BCM2836_IRQ_HDMI1 = 41;  
Pixelvalve
BCM2836_IRQ_PIXELVALVE1 = 42;  
I2C / SPI Slave
BCM2836_IRQ_I2CSPI = 43;  
DSI1
BCM2836_IRQ_DSI1 = 44;  
PWA
BCM2836_IRQ_PWA0 = 45;  
BCM2836_IRQ_PWA1 = 46;  
CPR
BCM2836_IRQ_CPR = 47;  
SMI
BCM2836_IRQ_SMI = 48;  
GPIO
BCM2836_IRQ_GPIO_0 = 49; Bank0
BCM2836_IRQ_GPIO_1 = 50; Bank1
BCM2836_IRQ_GPIO_2 = 51; Bank2 (Non existent in BCM2836)
BCM2836_IRQ_GPIO_ALL = 52; BCM2836_IRQ_GPIO_3 Any Bank (all banks interrupt to allow GPIO FIQ)
I2C
BCM2836_IRQ_I2C = 53; Also available as IRQ 79 in the IRQ_basic_pending register
SPI
BCM2836_IRQ_SPI = 54; Also available as IRQ 80 in the IRQ_basic_pending register
I2S PCM sound
BCM2836_IRQ_I2SPCM = 55; Also available as IRQ 81 in the IRQ_basic_pending register
SDIO
BCM2836_IRQ_SDIO = 56; Also available as IRQ 82 in the IRQ_basic_pending register
PL011 UART
BCM2836_IRQ_PL011 = 57; Also available as IRQ 83 in the IRQ_basic_pending register
Slimbus
BCM2836_IRQ_SLIMBUS = 58;  
VEC
BCM2836_IRQ_VEC = 59;  
CPG
BCM2836_IRQ_CPG = 60;  
RNG
BCM2836_IRQ_RNG = 61;  
SD card host controller (EMMC)
BCM2836_IRQ_SDHCI = 62; Also available as IRQ 84 in the IRQ_basic_pending register
AVSPMON
BCM2836_IRQ_AVSPMON = 63;  
IRQs 64 to 95 appear in the IRQ_basic_pending register
 
ARM Timer
BCM2836_IRQ_ARM_TIMER = 64; ARM IRQ 0
ARM Mailbox
BCM2836_IRQ_ARM_MAILBOX = 65; ARM IRQ 1
ARM Doorbell
BCM2836_IRQ_ARM_DOORBELL0 = 66; ARM IRQ 2
BCM2836_IRQ_ARM_DOORBELL1 = 67; ARM IRQ 3
ARM GPU Halted
BCM2836_IRQ_ARM_GPU0HALTED = 68; ARM IRQ 4
BCM2836_IRQ_ARM_GPU1HALTED = 69; ARM IRQ 5
ARM Illegal Access
BCM2836_IRQ_ARM_ILLEGALTYPE0 = 70; ARM IRQ 6
BCM2836_IRQ_ARM_ILLEGALTYPE1 = 71; ARM IRQ 7
ARM Pending
BCM2836_IRQ_ARM_PENDING0 = 72; ARM IRQ 8
BCM2836_IRQ_ARM_PENDING1 = 73; ARM IRQ 9
ARM JPEG
BCM2836_IRQ_ARM_JPEG = 74; ARM IRQ 10
ARM USB
BCM2836_IRQ_ARM_USB = 75; ARM IRQ 11
colspan="2"|ARM 3D  
BCM2836_IRQ_ARM_3D = 76; ARM IRQ 12
ARM DMA
BCM2836_IRQ_ARM_DMA2 = 77; ARM IRQ 13
BCM2836_IRQ_ARM_DMA3 = 78; ARM IRQ 14
ARM I2C
BCM2836_IRQ_ARM_I2C = 79; ARM IRQ 15
ARM SPI
BCM2836_IRQ_ARM_SPI = 80; ARM IRQ 16
ARM I2SPCM
BCM2836_IRQ_ARM_I2SPCM = 81; ARM IRQ 17
ARM SDIO
BCM2836_IRQ_ARM_SDIO = 82; ARM IRQ 18
ARM PL011 UART
BCM2836_IRQ_ARM_PL011 = 83; ARM IRQ 19
ARM SDHCI
BCM2836_IRQ_ARM_SDHCI = 84; ARM IRQ 20
IRQs 85 to 95 (ARM IRQs 21 to 31) are not assigned
 
Number of IRQs shared between the GPU and ARM (These correspond to the IRQs that show up in the IRQ_pending_1 and IRQ_pending_2 registers)
BCM2836_GPU_IRQ_COUNT = 64;  
Number of ARM specific IRQs (These correspond to IRQs that show up in the first 8 bits of the IRQ_basic_pending register)
BCM2836_ARM_IRQ_COUNT = 32;  
Number of ARM local IRQs (These correspond to the IRQs that show up in the IRQPending register of the ARM Local registers)
BCM2836_ARM_LOCAL_IRQ_COUNT = 32;  
Total number of IRQs available
BCM2836_IRQ_COUNT = BCM2836_GPU_IRQ_COUNT + BCM2836_ARM_IRQ_COUNT + BCM2836_ARM_LOCAL_IRQ_COUNT; 128
Total number of FIQs available
BCM2836_FIQ_COUNT = 1; This relates only to the shared FIQs, there are more ARM Local FIQs available


BCM2836 system timer frequency constants BCM2836_SYSTEM_TIMER_FREQUENCY*
BCM2836_SYSTEM_TIMER_FREQUENCY = 1000000; Default clock frequency of the BCM2836 System Timer (1MHz)


BCM2836 system timer control/status constants BCM2836_SYSTEM_TIMER_CS_*
See Section 12
 
BCM2836_SYSTEM_TIMER_CS_0 = (1 shl 0); Already used by the VideoCore GPU (Do not use)
BCM2836_SYSTEM_TIMER_CS_1 = (1 shl 1);  
BCM2836_SYSTEM_TIMER_CS_2 = (1 shl 2); Already used by the VideoCore GPU (Do not use)
BCM2836_SYSTEM_TIMER_CS_3 = (1 shl 3);  


BCM2836 DMA control and status constants BCM2836_DMA_CS_*
See Section 4
 
BCM2836_DMA_CS_ACTIVE = (1 shl 0); Activate the DMA (This bit enables the DMA. The DMA will start if this bit is set and the CB_ADDR is non zero. The DMA transfer can be paused and resumed by clearing, then setting it again.)
BCM2836_DMA_CS_END = (1 shl 1); DMA End Flag (Set when the transfer described by the current control block is complete. Write 1 to clear)
BCM2836_DMA_CS_INT = (1 shl 2); Interrupt Status (This is set when the transfer for the CB ends and INTEN is set to 1. Write 1 to clear)
BCM2836_DMA_CS_DREQ = (1 shl 3); DREQ State (Indicates the state of the selected DREQ (Data Request) signal, ie. the DREQ selected by the PERMAP field of the transfer info)
BCM2836_DMA_CS_PAUSED = (1 shl 4); DMA Paused State (Indicates if the DMA is currently paused and not transferring data)
BCM2836_DMA_CS_DREQ_PAUSED = (1 shl 5); DMA Paused by DREQ State (Indicates if the DMA is currently paused and not transferring data due to the DREQ being inactive)
BCM2836_DMA_CS_WAITING_FOR_OUTSTANDING_WRITES = (1 shl 6); DMA is Waiting for the Last Write to be Received (Indicates if the DMA is currently waiting for any outstanding writes to be received, and is not transferring data.)
Bit 7 Reserved - Write as 0, read as don't care
BCM2836_DMA_CS_ERROR = (1 shl 8); DMA Error (Indicates if the DMA has detected an error)
Bits 9:15 Reserved - Write as 0, read as don't care
BCM2836_DMA_CS_PRIORITY = ($F shl 16); AXI Priority Level (Sets the priority of normal AXI bus transactions. Zero is the lowest priority.)
BCM2836_DMA_CS_PANIC_PRIORITY = ($F shl 20); AXI Panic Priority Level (Sets the priority of panicking AXI bus transactions)
Bits 24:27 Reserved - Write as 0, read as don't care
BCM2836_DMA_CS_WAIT_FOR_OUTSTANDING_WRITES = (1 shl 28); Wait for outstanding writes (When set to 1, the DMA will keep a tally of the AXI writes going out and the write responses coming in.)
BCM2836_DMA_CS_DISDEBUG = (1 shl 29); Disable debug pause signal (When set to 1, the DMA will not stop when the debug pause signal is asserted.)
BCM2836_DMA_CS_ABORT = (1 shl 30); Abort DMA (Writing a 1 to this bit will abort the current DMA CB. The DMA will load the next CB and attempt to continue. The bit cannot be read, and will self clear.)
BCM2836_DMA_CS_RESET = (1 shl 31); DMA Channel Reset (Writing a 1 to this bit will reset the DMA. The bit cannot be read, and will self clear.)
 
BCM2836_DMA_CS_PRIORITY_SHIFT = 16;  
 
BCM2836_DMA_CS_PRIORITY_DEFAULT = 0;  


BCM2836 DMA transfer information constants BCM2836_DMA_TI_*
See Section 4
 
BCM2836_DMA_TI_INTEN = (1 shl 0); Interrupt Enable (1 = Generate an interrupt when the transfer described by the current Control Block completes)
BCM2836_DMA_TI_2DMODE = (1 shl 1); 2D Mode (1 = 2D mode interpret the TXFR_LEN register as YLENGTH number of transfers each of XLENGTH, and add the strides to the address after each transfer.)
Bit 2 Reserved - Write as 0, read as don't care
BCM2836_DMA_TI_WAIT_RESP = (1 shl 3); Wait for a Write Response (When set this makes the DMA wait until it receives the AXI write response for each write. This ensures that multiple writes cannot get stacked in the AXI bus pipeline.)
BCM2836_DMA_TI_DEST_INC = (1 shl 4); Destination Address Increment (1 = Destination address increments after each write The address will increment by 4, if DEST_WIDTH=0 else by 32.)
BCM2836_DMA_TI_DEST_WIDTH = (1 shl 5); Destination Transfer Width (1 = Use 128-bit destination write width. 0 = Use 32-bit destination write width.)
BCM2836_DMA_TI_DEST_DREQ = (1 shl 6); Control Destination Writes with DREQ (1 = The DREQ selected by PERMAP will gate the destination writes)
BCM2836_DMA_TI_DEST_IGNORE = (1 shl 7); Ignore Writes (1 = Do not perform destination writes. 0 = Write data to destination)
BCM2836_DMA_TI_SRC_INC = (1 shl 8); Source Address Increment (1 = Source address increments after each read. The address will increment by 4, if S_WIDTH=0 else by 32.)
BCM2836_DMA_TI_SRC_WIDTH = (1 shl 9); Source Transfer Width (1 = Use 128-bit source read width. 0 = Use 32-bit source read width)
BCM2836_DMA_TI_SRC_DREQ = (1 shl 10); Control Source Reads with DREQ (1 = The DREQ selected by PERMAP will gate the source reads)
BCM2836_DMA_TI_SRC_IGNORE = (1 shl 11); Ignore Reads (1 = Do not perform source reads. In addition, destination writes will zero all the write strobes. This is used for fast cache fill operations.)
BCM2836_DMA_TI_BURST_LENGTH = ($F shl 12); Burst Transfer Length (Indicates the burst length of the DMA transfers)
BCM2836_DMA_TI_PERMAP = ($1F shl 16); Peripheral Mapping (Indicates the peripheral number (1-31) whose ready signal shall be used to control the rate of the transfers)
BCM2836_DMA_TI_WAITS = ($3E shl 21); Add Wait Cycles (This slows down the DMA throughput by setting the number of dummy cycles burnt after each DMA read or write operation is completed)
BCM2836_DMA_TI_NO_WIDE_BURSTS = (1 shl 26); Don't Do wide writes as a 2 beat burst (This prevents the DMA from issuing wide writes as 2 beat AXI bursts. This is an inefficient access mode, so the default is to use the bursts.)
Bits 27:31 Reserved - Write as 0, read as don't care
 
Note: BCM2836_DMA_TI_2DMODE, BCM2836_DMA_TI_DEST_IGNORE, BCM2836_DMA_TI_SRC_IGNORE and BCM2836_DMA_TI_NO_WIDE_BURSTS not available on DMA Lite channels
 
BCM2836_DMA_TI_PERMAP_SHIFT = 16;  
BCM2836_DMA_TI_BURST_LENGTH_SHIFT = 12;  
 
BCM2836_DMA_TI_BURST_LENGTH_DEFAULT = 0;  


BCM2836 DMA transfer length constants BCM2836_DMA_TXFR_LEN_*
See Section 4
 
BCM2836_DMA_TXFR_LEN_XLENGTH = ($FFFF shl 0); Transfer Length in bytes
BCM2836_DMA_TXFR_LEN_YLENGTH = ($3FFF shl 16); When in 2D mode, This is the Y transfer length, indicating how many xlength transfers are performed. When in normal linear mode this becomes the top bits of the XLENGTH.
 
Note: BCM2836_DMA_TXFR_LEN_YLENGTH not available on DMA Lite channels


BCM2836 DMA 2D stride constants BCM2836_DMA_STRIDE_*
See Section 4
 
BCM2836_DMA_STRIDE_S_STRIDE = ($FFFF shl 0); Destination Stride (2D Mode) (Signed (2 s complement) byte increment to apply to the destination address at the end of each row in 2D mode)
BCM2836_DMA_STRIDE_D_STRIDE = ($FFFF shl 16); Source Stride (2D Mode) (Signed (2 s complement) byte increment to apply to the source address at the end of each row in 2D mode)
 
Note: BCM2836_DMA_STRIDE_S_STRIDE and BCM2836_DMA_STRIDE_D_STRIDE not available on DMA Lite channels


BCM2836 DMA debug constants BCM2836_DMA_DEBUG_*
See Section 4
 
BCM2836_DMA_DEBUG_READ_LAST_NOT_SET_ERROR = (1 shl 0); Read Last Not Set Error
BCM2836_DMA_DEBUG_FIFO_ERROR = (1 shl 1); Fifo Error
BCM2836_DMA_DEBUG_READ_ERROR = (1 shl 2); Slave Read Response Error
Bit 3 Reserved - Write as 0, read as don't care
BCM2836_DMA_DEBUG_OUTSTANDING_WRITES = ($F shl 4); DMA Outstanding Writes Counter
BCM2836_DMA_DEBUG_DMA_ID = ($FF shl 8); DMA ID
BCM2836_DMA_DEBUG_VERSION = (7 shl 25); DMA Version
BCM2836_DMA_DEBUG_LITE = (1 shl 28); DMA Lite
Bits 29:31 Reserved - Write as 0, read as don't care


BCM2836 DMA engine interrupt status constants BCM2836_DMA_INT_STATUS_*
See Section 4
 
BCM2836_DMA_INT_STATUS_0 = (1 shl 0);  
BCM2836_DMA_INT_STATUS_1 = (1 shl 1);  
BCM2836_DMA_INT_STATUS_2 = (1 shl 2);  
BCM2836_DMA_INT_STATUS_3 = (1 shl 3);  
BCM2836_DMA_INT_STATUS_4 = (1 shl 4);  
BCM2836_DMA_INT_STATUS_5 = (1 shl 5);  
BCM2836_DMA_INT_STATUS_6 = (1 shl 6);  
BCM2836_DMA_INT_STATUS_7 = (1 shl 7);  
BCM2836_DMA_INT_STATUS_8 = (1 shl 8);  
BCM2836_DMA_INT_STATUS_9 = (1 shl 9);  
BCM2836_DMA_INT_STATUS_10 = (1 shl 10);  
BCM2836_DMA_INT_STATUS_11 = (1 shl 11);  
BCM2836_DMA_INT_STATUS_12 = (1 shl 12);  
BCM2836_DMA_INT_STATUS_13 = (1 shl 13);  
BCM2836_DMA_INT_STATUS_14 = (1 shl 14);  
BCM2836_DMA_INT_STATUS_15 = (1 shl 15);  


BCM2836 DMA engine enable constants BCM2836_DMA_ENABLE_*
See Section 4
 
BCM2836_DMA_ENABLE_0 = (1 shl 0);  
BCM2836_DMA_ENABLE_1 = (1 shl 1);  
BCM2836_DMA_ENABLE_2 = (1 shl 2);  
BCM2836_DMA_ENABLE_3 = (1 shl 3);  
BCM2836_DMA_ENABLE_4 = (1 shl 4);  
BCM2836_DMA_ENABLE_5 = (1 shl 5);  
BCM2836_DMA_ENABLE_6 = (1 shl 6);  
BCM2836_DMA_ENABLE_7 = (1 shl 7);  
BCM2836_DMA_ENABLE_8 = (1 shl 8);  
BCM2836_DMA_ENABLE_9 = (1 shl 9);  
BCM2836_DMA_ENABLE_10 = (1 shl 10);  
BCM2836_DMA_ENABLE_11 = (1 shl 11);  
BCM2836_DMA_ENABLE_12 = (1 shl 12);  
BCM2836_DMA_ENABLE_13 = (1 shl 13);  
BCM2836_DMA_ENABLE_14 = (1 shl 14);  


BCM2836 DMA engine DREQ peripheral constants BCM2836_DMA_DREQ_*
See Section 4
 
BCM2836_DMA_DREQ_NONE = 0;  
BCM2836_DMA_DREQ_DSI0 = 1;  
BCM2836_DMA_DREQ_PCMTX = 2;  
BCM2836_DMA_DREQ_PCMRX = 3;  
BCM2836_DMA_DREQ_SMI = 4;  
BCM2836_DMA_DREQ_PWM = 5;  
BCM2836_DMA_DREQ_SPITX = 6;  
BCM2836_DMA_DREQ_SPIRX = 7;  
BCM2836_DMA_DREQ_BSCSPITX = 8;  
BCM2836_DMA_DREQ_BSCSPIRX = 9;  
BCM2836_DMA_DREQ_RESERVED1 = 10;  
BCM2836_DMA_DREQ_EMMC = 11;  
BCM2836_DMA_DREQ_UARTTX = 12;  
BCM2836_DMA_DREQ_SDHOST = 13;  
BCM2836_DMA_DREQ_UARTRX = 14;  
BCM2836_DMA_DREQ_DSI1 = 15;  
BCM2836_DMA_DREQ_SLIMBUS_MCTX = 16;  
BCM2836_DMA_DREQ_HDMI = 17;  
BCM2836_DMA_DREQ_SLIMBUS_MCRX = 18;  
BCM2836_DMA_DREQ_SLIMBUS_DC0 = 19;  
BCM2836_DMA_DREQ_SLIMBUS_DC1 = 20;  
BCM2836_DMA_DREQ_SLIMBUS_DC2 = 21;  
BCM2836_DMA_DREQ_SLIMBUS_DC3 = 22;  
BCM2836_DMA_DREQ_SLIMBUS_DC4 = 23;  
BCM2836_DMA_DREQ_SCALER_FIFO0 = 24;  
BCM2836_DMA_DREQ_SCALER_FIFO1 = 25;  
BCM2836_DMA_DREQ_SCALER_FIFO2 = 26;  
BCM2836_DMA_DREQ_SLIMBUS_DC5 = 27;  
BCM2836_DMA_DREQ_SLIMBUS_DC6 = 28;  
BCM2836_DMA_DREQ_SLIMBUS_DC7 = 29;  
BCM2836_DMA_DREQ_SLIMBUS_DC8 = 30;  
BCM2836_DMA_DREQ_SLIMBUS_DC9 = 31;  


BCM2836 BSC (I2C0/1/2) control constants BCM2836_BSC_C_*
See Section 3.2
 
BCM2836_BSC_C_I2CEN = (1 shl 15); I2C Enable (0 = BSC controller is disabled / 1 = BSC controller is enabled)
BCM2836_BSC_C_INTR = (1 shl 10); INTR Interrupt on RX (0 = Don t generate interrupts on RXR condition / 1 = Generate interrupt while RXR = 1)
BCM2836_BSC_C_INTT = (1 shl 9); INTT Interrupt on TX (0 = Don t generate interrupts on TXW condition / 1 = Generate interrupt while TXW = 1)
BCM2836_BSC_C_INTD = (1 shl 8); INTD Interrupt on DONE (0 = Don t generate interrupts on DONE condition / 1 = Generate interrupt while DONE = 1)
BCM2836_BSC_C_ST = (1 shl 7); ST Start Transfer (0 = No action / 1 = Start a new transfer. One shot operation. Read back as 0.)
BCM2836_BSC_C_CLEAR = (1 shl 5); CLEAR FIFO Clear (00 = No action / x1 = Clear FIFO. One shot operation / 1x = Clear FIFO. One shot operation.)
BCM2836_BSC_C_READ = (1 shl 0); READ Read Transfer (0 = Write Packet Transfer / 1 = Read Packet Transfer)


BCM2836 BSC (I2C0/1/2) status constants BCM2836_BSC_S_*
See Section 3.2
 
BCM2836_BSC_S_CLKT = (1 shl 9); CLKT Clock Stretch Timeout (0 = No errors detected. 1 = Slave has held the SCL signal low (clock stretching) for longer and that specified in the I2CCLKT register Cleared by writing 1 to the field.)
BCM2836_BSC_S_ERR = (1 shl 8); ERR ACK Error (0 = No errors detected. 1 = Slave has not acknowledged its address. Cleared by writing 1 to the field.)
BCM2836_BSC_S_RXF = (1 shl 7); RXF - FIFO Full (0 = FIFO is not full. 1 = FIFO is full. If a read is underway, no further serial data will be received until data is read from FIFO.)
BCM2836_BSC_S_TXE = (1 shl 6); TXE - FIFO Empty (0 = FIFO is not empty. 1 = FIFO is empty. If a write is underway, no further serial data can be transmitted until data is written to the FIFO.)
BCM2836_BSC_S_RXD = (1 shl 5); RXD - FIFO contains Data (0 = FIFO is empty. 1 = FIFO contains at least 1 byte. Cleared by reading sufficient data from FIFO.)
BCM2836_BSC_S_TXD = (1 shl 4); TXD - FIFO can accept Data (0 = FIFO is full. The FIFO cannot accept more data. 1 = FIFO has space for at least 1 byte.)
BCM2836_BSC_S_RXR = (1 shl 3); RXR - FIFO needs Reading (full) (0 = FIFO is less than full and a read is underway. 1 = FIFO is or more full and a read is underway. Cleared by reading sufficient data from the FIFO.)
BCM2836_BSC_S_TXW = (1 shl 2); TXW - FIFO needs Writing (full) (0 = FIFO is at least full and a write is underway (or sufficient data to send). 1 = FIFO is less then full and a write is underway. Cleared by writing sufficient data to the FIFO.)
BCM2836_BSC_S_DONE = (1 shl 1); DONE Transfer Done (0 = Transfer not completed. 1 = Transfer complete. Cleared by writing 1 to the field.)
BCM2836_BSC_S_TA = (1 shl 0); TA Transfer Active (0 = Transfer not active. 1 = Transfer active.)


BCM2836 BSC (I2C0/1/2) data length constants BCM2836_BSC_DLEN_*
See Section 3.2
 
BCM2836_BSC_DLEN_MASK = $FFFF; Data Length. (Writing to DLEN specifies the number of bytes to be transmitted/received. Reading from DLEN when TA = 1 or DONE = 1, returns the number of bytes still to be transmitted or received.)


BCM2836 BSC (I2C0/1/2) slave address constants BCM2836_BSC_A_*
See Section 3.2
 
BCM2836_BSC_A_MASK = $7F; Slave Address


BCM2836 BSC (I2C0/1/2) data FIFO constants BCM2836_BSC_FIFO_*
See Section 3.2
 
BCM2836_BSC_FIFO_MASK = $FF; Writes to the register write transmit data to the FIFO. Reads from register reads received data from the FIFO.
BCM2836_BSC_FIFO_SIZE = 16;  


BCM2836 BSC (I2C0/1/2) clock divider constants BCM2836_BSC_CDIV_*
See Section 3.2
 
BCM2836_BSC_CDIV_MASK = $FFFF; Clock Divider (SCL = core clock / CDIV) (CDIV is always rounded down to an even number)


BCM2836 BSC (I2C0/1/2) data delay constants BCM2836_BSC_DEL_*
See Section 3.2
 
BCM2836_BSC_DEL_FEDL_MASK = ($FFFF shl 16); FEDL Falling Edge Delay (Number of core clock cycles to wait after the falling edge of SCL before outputting next bit of data)
BCM2836_BSC_DEL_REDL_MASK = ($FFFF shl 0); REDL Rising Edge Delay (Number of core clock cycles to wait after the rising edge of SCL before reading the next bit of data)


BCM2836 BSC (I2C0/1/2) clock stretch timeout constants BCM2836_BSC_CLKT_TOUT_*
See Section 3.2
 
BCM2836_BSC_CLKT_TOUT_MASK = $FFFF; TOUT Clock Stretch Timeout Value (Number of SCL clock cycles to wait after the rising edge of SCL before deciding that the slave is not responding)


BCM2836 SPI0 constants BCM2836_SPI0_CS_*
See Section 10.5
 
BCM2836_SPI0_CS_LEN_LONG = (1 shl 25); Enable Long data word in Lossi mode if DMA_LEN is set (0 = writing to the FIFO will write a single byte / 1 = writing to the FIFO will write a 32 bit word)
BCM2836_SPI0_CS_DMA_LEN = (1 shl 24); Enable DMA mode in Lossi mode
BCM2836_SPI0_CS_CSPOL2 = (1 shl 23); Chip Select 2 Polarity (0 = Chip select is active low / 1 = Chip select is active high)
BCM2836_SPI0_CS_CSPOL1 = (1 shl 22); Chip Select 1 Polarity (0 = Chip select is active low / 1 = Chip select is active high)
BCM2836_SPI0_CS_CSPOL0 = (1 shl 21); Chip Select 0 Polarity (0 = Chip select is active low / 1 = Chip select is active high)
BCM2836_SPI0_CS_RXF = (1 shl 20); RXF - RX FIFO Full (0 = RXFIFO is not full / 1 = RX FIFO is full. No further serial data will be sent/received until data is read from FIFO.)
BCM2836_SPI0_CS_RXR = (1 shl 19); RXR RX FIFO needs Reading (full) (0 = RX FIFO is less than full (or not active TA = 0) / 1 = RX FIFO is or more full. Cleared by reading sufficient data from the RX FIFO or setting TA to 0.)
BCM2836_SPI0_CS_TXD = (1 shl 18); TXD TX FIFO can accept Data (0 = TX FIFO is full and so cannot accept more data / 1 = TX FIFO has space for at least 1 byte)
BCM2836_SPI0_CS_RXD = (1 shl 17); RXD RX FIFO contains Data (0 = RX FIFO is empty / 1 = RX FIFO contains at least 1 byte)
BCM2836_SPI0_CS_DONE = (1 shl 16); DONE Transfer Done (0 = Transfer is in progress (or not active TA = 0) / 1 = Transfer is complete. Cleared by writing more data to the TX FIFO or setting TA to 0.)
BCM2836_SPI0_CS_TE_EN = (1 shl 15); Unused
BCM2836_SPI0_CS_LMONO = (1 shl 14); Unused
BCM2836_SPI0_CS_LEN = (1 shl 13); LEN LoSSI enable (0 = The serial interface will behave as an SPI master / 1 = The serial interface will behave as a LoSSI master)
BCM2836_SPI0_CS_REN = (1 shl 12); REN Read Enable. If this bit is set, the SPI peripheral will be able to send data to this device (0 = We intend to write to the SPI peripheral / 1 = We intend to read from the SPI peripheral)
BCM2836_SPI0_CS_ADCS = (1 shl 11); ADCS Automatically Deassert Chip Select (0 = Don't automatically deassert chip select at the end of a DMA transfer chip select is manually controlled by software. / 1 = Automatically deassert chip select at the end of a DMA transfer as determined by SPIDLEN.)
BCM2836_SPI0_CS_INTR = (1 shl 10); INTR Interrupt on RXR (0 = Don t generate interrupts on RX FIFO condition / 1 = Generate interrupt while RXR = 1)
BCM2836_SPI0_CS_INTD = (1 shl 9); INTD Interrupt on Done (0 = Don t generate interrupt on transfer complete / 1 = Generate interrupt when DONE = 1)
BCM2836_SPI0_CS_DMAEN = (1 shl 8); DMAEN DMA Enable (0 = No DMA requests will be issued / 1 = Enable DMA operation. Peripheral generates data requests. These will be taken in four-byte words until the SPIDLEN has been reached.)
BCM2836_SPI0_CS_TA = (1 shl 7); Transfer Active (0 = Transfer not active / 1 = Transfer active)
BCM2836_SPI0_CS_CSPOL = (1 shl 6); Chip Select Polarity (0 = Chip select lines are active low / 1 = Chip select lines are active high)
BCM2836_SPI0_CS_CLEAR_RX = (1 shl 5); CLEAR FIFO Clear (00 = No action / x1 = Clear TX FIFO. One shot operation / 1x = Clear RX FIFO. One shot operation.)
BCM2836_SPI0_CS_CLEAR_TX = (1 shl 4); As above
BCM2836_SPI0_CS_CPOL = (1 shl 3); Clock Polarity (0 = Rest state of clock = low / 1 = Rest state of clock = high)
BCM2836_SPI0_CS_CPHA = (1 shl 2); Clock Phase (0 = First SCLK transition at middle of data bit / 1 = First SCLK transition at beginning of data bit)
BCM2836_SPI0_CS_CS_0 = (0 shl 0); Chip Select (00 = Chip select 0 / 01 = Chip select 1 / 10 = Chip select 2 / 11 = Reserved
BCM2836_SPI0_CS_CS_1 = (1 shl 0); As above
BCM2836_SPI0_CS_CS_2 = (2 shl 0); As above
 
BCM2836_SPI0_CS_CS_MASK = (3 shl 0);  
 
BCM2836_SPI0_FIFO_DMA_DATA = $FFFFFFFF; DMA Mode (DMAEN set) If TA is clear, the first 32-bit write to this register will control SPIDLEN and SPICS. Subsequent reads and writes will be taken as four-byte data words to be read/written to the FIFOs.
BCM2836_SPI0_FIFO_IRQ_DATA = $000000FF; Poll/Interrupt Mode (DMAEN clear, TA set) Writes to the register write bytes to TX FIFO. Reads from register read bytes from the RX FIFO.
 
BCM2836_SPI0_CLK_CDIV = $0000FFFF; Clock Divider (SCLK = Core Clock / CDIV) If CDIV is set to 0, the divisor is 65536. The divisor must be a multiple of 2. Odd numbers rounded down. The maximum SPI clock rate is of the APB clock.
 
BCM2836_SPI0_DLEN_LEN = $0000FFFF; Data Length. The number of bytes to transfer. This field is only valid for DMA mode (DMAEN set) and controls how many bytes to transmit (and therefore receive).
 
BCM2836_SPI0_LTOH_TOH = $0000000F; This sets the Output Hold delay in APB clocks (A value of 0 causes a 1 clock delay)
 
BCM2836_SPI0_DC_RPANIC = ($FF shl 24); DMA Read Panic Threshold (Generate the Panic signal to the RX DMA engine whenever the RX FIFO level is greater than this amount)
BCM2836_SPI0_DC_RDREQ = ($FF shl 16); DMA Read Request Threshold (Generate A DREQ to the RX DMA engine whenever the RX FIFO level is greater than this amount) (RX DREQ is also generated if thetransfer has finished but the RXFIFO isn't empty)
BCM2836_SPI0_DC_TPANIC = ($FF shl 8); DMA Write Panic Threshold (Generate the Panic signal to the TX DMA engine whenever the TX FIFO level is less than or equal to this amount)
BCM2836_SPI0_DC_TDREQ = ($FF shl 0); DMA Write Request Threshold (Generate a DREQ signal to the TX DMA engine whenever the TX FIFO level is less than or equal to this amount)


BCM2836 PWM control constants BCM2836_PWM_CTL_*
See Section 9.6
 
BCM2836_PWM_CTL_MSEN2 = (1 shl 15); Channel 2 M/S Enable (0: PWM algorithm is used / 1: M/S transmission is used)
Bit 14 Reserved - Write as 0, read as don't care
BCM2836_PWM_CTL_USEF2 = (1 shl 13); Channel 2 Use Fifo (0: Data register is transmitted / 1: Fifo is used for transmission)
BCM2836_PWM_CTL_POLA2 = (1 shl 12); Channel 2 Polarity (0 : 0=low 1=high / 1: 1=low 0=high)
BCM2836_PWM_CTL_SBIT2 = (1 shl 11); Channel 2 Silence Bit (Defines the state of the output when no transmission takes place)
BCM2836_PWM_CTL_RPTL2 = (1 shl 10); Channel 2 Repeat Last Data (0: Transmission interrupts when FIFO is empty / 1: Last data in FIFO is transmitted repetedly until FIFO is not empty)
BCM2836_PWM_CTL_MODE2 = (1 shl 9); Channel 2 Mode (0: PWM mode / 1: Serialiser mode)
BCM2836_PWM_CTL_PWEN2 = (1 shl 8); Channel 2 Enable (0: Channel is disabled / 1: Channel is enabled)
BCM2836_PWM_CTL_MSEN1 = (1 shl 7); Channel 1 M/S Enable (0: PWM algorithm is used / 1: M/S transmission is used)
BCM2836_PWM_CTL_CLRF1 = (1 shl 6); Clear Fifo (1: Clears FIFO / 0: Has no effect) (This is a single shot operation. This bit always reads 0.)
BCM2836_PWM_CTL_USEF1 = (1 shl 5); Channel 1 Use Fifo (0: Data register is transmitted / 1: Fifo is used for transmission)
BCM2836_PWM_CTL_POLA1 = (1 shl 4); Channel 1 Polarity (0 : 0=low 1=high / 1: 1=low 0=high)
BCM2836_PWM_CTL_SBIT1 = (1 shl 3); Channel 1 Silence Bit (Defines the state of the output when no transmission takes place)
BCM2836_PWM_CTL_RPTL1 = (1 shl 2); Channel 1 Repeat Last Data (0: Transmission interrupts when FIFO is empty / 1: Last data in FIFO is transmitted repetedly until FIFO is not empty)
BCM2836_PWM_CTL_MODE1 = (1 shl 1); Channel 1 Mode (0: PWM mode / 1: Serialiser mode)
BCM2836_PWM_CTL_PWEN1 = (1 shl 0); Channel 1 Enable (0: Channel is disabled / 1: Channel is enabled)


BCM2836 PWM status constants BCM2836_PWM_STA_*
See Section 9.6
 
BCM2836_PWM_STA_STA4 = (1 shl 12); Channel 4 State
BCM2836_PWM_STA_STA3 = (1 shl 11); Channel 3 State
BCM2836_PWM_STA_STA2 = (1 shl 10); Channel 2 State
BCM2836_PWM_STA_STA1 = (1 shl 9); Channel 1 State
BCM2836_PWM_STA_BERR = (1 shl 8); Bus Error Flag
BCM2836_PWM_STA_GAPO4 = (1 shl 7); Channel 4 Gap Occurred Flag
BCM2836_PWM_STA_GAPO3 = (1 shl 6); Channel 3 Gap Occurred Flag
BCM2836_PWM_STA_GAPO2 = (1 shl 5); Channel 2 Gap Occurred Flag
BCM2836_PWM_STA_GAPO1 = (1 shl 4); Channel 1 Gap Occurred Flag
BCM2836_PWM_STA_RERR1 = (1 shl 3); Fifo Read Error Flag
BCM2836_PWM_STA_WERR1 = (1 shl 2); Fifo Write Error Flag
BCM2836_PWM_STA_EMPT1 = (1 shl 1); Fifo Empty Flag
BCM2836_PWM_STA_FULL1 = (1 shl 0); Fifo Full Flag


BCM2836 PWM DMA configuration constants BCM2836_PWM_DMAC_*
See Section 9.6
 
BCM2836_PWM_DMAC_ENAB = (1 shl 31); DMA Enable (0: DMA disabled / 1: DMA enabled)
BCM2836_PWM_DMAC_PANIC = ($FF shl 8); DMA Threshold for PANIC signal (Default: 0x7)
BCM2836_PWM_DMAC_DREQ = ($FF shl 0); DMA Threshold for DREQ signal (Default: 0x7)


BCM2836 PWM constants BCM2836_PWM_*
BCM2836_PWM_CTL = $00000000; PWM Control
BCM2836_PWM_STA = $00000004; PWM Status
BCM2836_PWM_DMAC = $00000008; PWM DMA Configuration
BCM2836_PWM_RNG1 = $00000010; PWM Channel 1 Range
BCM2836_PWM_DAT1 = $00000014; PWM Channel 1 Data
BCM2836_PWM_FIF1 = $00000018; PWM FIFO Input
BCM2836_PWM_RNG2 = $00000020; PWM Channel 2 Range
BCM2836_PWM_DAT2 = $00000024; PWM Channel 2 Data


BCM2836 PL011 UART data constants BCM2836_PL011_DR_*
See Section 13.4
 
BCM2836_PL011_DR_OE = (1 shl 11); Overrun error
BCM2836_PL011_DR_BE = (1 shl 10); Break error
BCM2836_PL011_DR_PE = (1 shl 9); Parity error
BCM2836_PL011_DR_FE = (1 shl 8); Framing error
BCM2836_PL011_DR_DATA = ($FF shl 0); Receive / Transmit data
BCM2836_PL011_DR_ERROR = BCM2836_PL011_DR_OE or BCM2836_PL011_DR_BE or BCM2836_PL011_DR_PE or BCM2836_PL011_DR_FE;  


BCM2836 PL011 UART receive status / error clear constants BCM2836_PL011_RSRECR_*
See Section 13.4
 
BCM2836_PL011_RSRECR_OE = (1 shl 3); Overrun error
BCM2836_PL011_RSRECR_BE = (1 shl 2); Break error
BCM2836_PL011_RSRECR_PE = (1 shl 1); Parity error
BCM2836_PL011_RSRECR_FE = (1 shl 0); Framing error


BCM2836 PL011 UART flag constants BCM2836_PL011_FR_*
See Section 13.4
 
BCM2836_PL011_FR_RI = (1 shl 8); Unsupported, write zero, read as don't care.
BCM2836_PL011_FR_TXFE = (1 shl 7); Transmit FIFO empty
BCM2836_PL011_FR_RXFF = (1 shl 6); Receive FIFO full
BCM2836_PL011_FR_TXFF = (1 shl 5); Transmit FIFO full
BCM2836_PL011_FR_RXFE = (1 shl 4); Receive FIFO empty
BCM2836_PL011_FR_BUSY = (1 shl 3); UART busy
BCM2836_PL011_FR_DCD = (1 shl 2); Unsupported, write zero, read as don't care.
BCM2836_PL011_FR_DSR = (1 shl 1); Unsupported, write zero, read as don't care.
BCM2836_PL011_FR_CTS = (1 shl 0); Clear to send (This bit is the complement of the UART clear to send, nUARTCTS, modem status input. That is, the bit is 1 when nUARTCTS is LOW.)


BCM2836 PL011 UART IrDA constants
See Section 13.4
 
This register is disabled, writing to it has no effect and reading returns 0.


BCM2836 PL011 UART integer baud rate divisor constants BCM2836_PL011_IBRD_*
See Section 13.4
 
BCM2836_PL011_IBRD_MASK = ($FFFF shl 0);  


BCM2836 PL011 UART fractional baud rate divisor constants BCM2836_PL011_FBRD_*
See Section 13.4
 
BCM2836_PL011_FBRD_MASK = ($3F shl 0);  


BCM2836 PL011 UART line control constants BCM2836_PL011_LCRH_*
See Section 13.4
 
BCM2836_PL011_LCRH_SPS = (1 shl 7); Stick parity select
BCM2836_PL011_LCRH_WLEN = (3 shl 5); Word length
BCM2836_PL011_LCRH_WLEN8 = (3 shl 5); 8 bits
BCM2836_PL011_LCRH_WLEN7 = (2 shl 5); 7 bits
BCM2836_PL011_LCRH_WLEN6 = (1 shl 5); 6 bits
BCM2836_PL011_LCRH_WLEN5 = (0 shl 5); 5 bits
BCM2836_PL011_LCRH_FEN = (1 shl 4); Enable FIFOs
BCM2836_PL011_LCRH_STP2 = (1 shl 3); Two stop bits select
BCM2836_PL011_LCRH_EPS = (1 shl 2); Even parity select (0 = odd parity / 1 = even parity)
BCM2836_PL011_LCRH_PEN = (1 shl 1); Parity enable
BCM2836_PL011_LCRH_BRK = (1 shl 0); Send break


BCM2836 PL011 UART control constants BCM2836_PL011_CR_*
See Section 13.4
 
BCM2836_PL011_CR_CTSEN = (1 shl 15); CTS hardware flow control enable (If this bit is set to 1 data is only transmitted when the nUARTCTS signal is asserted)
BCM2836_PL011_CR_RTSEN = (1 shl 14); RTS hardware flow control enable (If this bit is set to 1 data is only requested when there is space in the receive FIFO for it to be received)
BCM2836_PL011_CR_OUT2 = (1 shl 13); Unsupported, write zero, read as don't care.
BCM2836_PL011_CR_OUT1 = (1 shl 12); Unsupported, write zero, read as don't care.
BCM2836_PL011_CR_RTS = (1 shl 11); Request to send (This bit is the complement of the UART request to send, nUARTRTS, modem status output. That is, when the bit is programmed to a 1 then nUARTRTS is LOW.)
BCM2836_PL011_CR_DTR = (1 shl 10); Unsupported, write zero, read as don't care.
BCM2836_PL011_CR_RXE = (1 shl 9); Receive enable
BCM2836_PL011_CR_TXE = (1 shl 8); Transmit enable
BCM2836_PL011_CR_LBE = (1 shl 7); Loopback enable
Bits 6:3 Reserved - Write as 0, read as don't care
BCM2836_PL011_CR_SIRLP = (1 shl 2); Unsupported, write zero, read as don't care.
BCM2836_PL011_CR_SIREN = (1 shl 1); Unsupported, write zero, read as don't care.
BCM2836_PL011_CR_UARTEN = (1 shl 0); UART enable


BCM2836 PL011 UART interrupt FIFO level select constants BCM2836_PL011_IFLS_*
See Section 13.4
 
BCM2836_PL011_IFLS_RXIFPSEL = (7 shl 9); Unsupported, write zero, read as don't care.
BCM2836_PL011_IFLS_TXIFPSEL = (7 shl 6); Unsupported, write zero, read as don't care.
BCM2836_PL011_IFLS_RXIFLSEL = (7 shl 3); Receive interrupt FIFO level select
BCM2836_PL011_IFLS_RXIFLSEL1_8 = (0 shl 3); b000 = Receive FIFO becomes 1/8 full
BCM2836_PL011_IFLS_RXIFLSEL1_4 = (1 shl 3); b001 = Receive FIFO becomes 1/4 full
BCM2836_PL011_IFLS_RXIFLSEL1_2 = (2 shl 3); b010 = Receive FIFO becomes 1/2 full
BCM2836_PL011_IFLS_RXIFLSEL3_4 = (3 shl 3); b011 = Receive FIFO becomes 3/4 full
BCM2836_PL011_IFLS_RXIFLSEL7_8 = (4 shl 3); b100 = Receive FIFO becomes 7/8 full
BCM2836_PL011_IFLS_TXIFLSEL = (7 shl 0); Transmit interrupt FIFO level select}
BCM2836_PL011_IFLS_TXIFLSEL1_8 = (0 shl 0); b000 = Transmit FIFO becomes 1/8 full
BCM2836_PL011_IFLS_TXIFLSEL1_4 = (1 shl 0); b001 = Transmit FIFO becomes 1/4 full
BCM2836_PL011_IFLS_TXIFLSEL1_2 = (2 shl 0); b010 = Transmit FIFO becomes 1/2 full
BCM2836_PL011_IFLS_TXIFLSEL3_4 = (3 shl 0); b011 = Transmit FIFO becomes 3/4 full
BCM2836_PL011_IFLS_TXIFLSEL7_8 = (4 shl 0); b100 = Transmit FIFO becomes 7/8 full


BCM2836 PL011 UART interrupt mask set/clear constants BCM2836_PL011_IMSC_*
See Section 13.4
 
BCM2836_PL011_IMSC_OEIM = (1 shl 10); Overrun error interrupt mask
BCM2836_PL011_IMSC_BEIM = (1 shl 9); Break error interrupt mask
BCM2836_PL011_IMSC_PEIM = (1 shl 8); Parity error interrupt mask
BCM2836_PL011_IMSC_FEIM = (1 shl 7); Framing error interrupt mask
BCM2836_PL011_IMSC_RTIM = (1 shl 6); Receive timeout interrupt mask
BCM2836_PL011_IMSC_TXIM = (1 shl 5); Transmit interrupt mask
BCM2836_PL011_IMSC_RXIM = (1 shl 4); Receive interrupt mask
BCM2836_PL011_IMSC_DSRMIM = (1 shl 3); Unsupported, write zero, read as don't care.
BCM2836_PL011_IMSC_DCDMIM = (1 shl 2); Unsupported, write zero, read as don't care.
BCM2836_PL011_IMSC_CTSMIM = (1 shl 1); nUARTCTS modem interrupt mask
BCM2836_PL011_IMSC_RIMIM = (1 shl 0); Unsupported, write zero, read as don't care.


BCM2836 PL011 UART raw interrupt status constants BCM2836_PL011_RIS_*
See Section 13.4
 
BCM2836_PL011_RIS_OERIS = (1 shl 10); Overrun error interrupt status
BCM2836_PL011_RIS_BERIS = (1 shl 9); Break error interrupt status
BCM2836_PL011_RIS_PERIS = (1 shl 8); Parity error interrupt status
BCM2836_PL011_RIS_FERIS = (1 shl 7); Framing error interrupt status
BCM2836_PL011_RIS_RTRIS = (1 shl 6); Receive timeout interrupt status
BCM2836_PL011_RIS_TXRIS = (1 shl 5); Transmit interrupt status
BCM2836_PL011_RIS_RXRIS = (1 shl 4); Receive interrupt status
BCM2836_PL011_RIS_DSRMRIS = (1 shl 3); Unsupported, write zero, read as don't care.
BCM2836_PL011_RIS_DCDMRIS = (1 shl 2); Unsupported, write zero, read as don't care.
BCM2836_PL011_RIS_CTSMRIS = (1 shl 1); nUARTCTS modem interrupt status
BCM2836_PL011_RIS_RIMRIS = (1 shl 0); Unsupported, write zero, read as don't care.


BCM2836 PL011 UART masked interrupt status constants BCM2836_PL011_MIS_*
See Section 13.4
 
BCM2836_PL011_MIS_OEMIS = (1 shl 10); Overrun error masked interrupt status
BCM2836_PL011_MIS_BEMIS = (1 shl 9); Break error masked interrupt status
BCM2836_PL011_MIS_PEMIS = (1 shl 8); Parity error masked interrupt status
BCM2836_PL011_MIS_FEMIS = (1 shl 7); Framing error masked interrupt status
BCM2836_PL011_MIS_RTMIS = (1 shl 6); Receive timeout masked interrupt status
BCM2836_PL011_MIS_TXMIS = (1 shl 5); Transmit masked interrupt status
BCM2836_PL011_MIS_RXMIS = (1 shl 4); Receive masked interrupt status
BCM2836_PL011_MIS_DSRMMIS = (1 shl 3); Unsupported, write zero, read as don't care.
BCM2836_PL011_MIS_DCDMMIS = (1 shl 2); Unsupported, write zero, read as don't care.
BCM2836_PL011_MIS_CTSMMIS = (1 shl 1); nUARTCTS modem masked interrupt status
BCM2836_PL011_MIS_RIMMIS = (1 shl 0); Unsupported, write zero, read as don't care.


BCM2836 PL011 UART interrupt clear constants BCM2836_PL011_ICR_*
See Section 13.4
 
BCM2836_PL011_ICR_OEIC = (1 shl 10); Overrun error interrupt clear
BCM2836_PL011_ICR_BEIC = (1 shl 9); Break error interrupt clear
BCM2836_PL011_ICR_PEIC = (1 shl 8); Parity error interrupt clear
BCM2836_PL011_ICR_FEIC = (1 shl 7); Framing error interrupt clear
BCM2836_PL011_ICR_RTIC = (1 shl 6); Receive timeout interrupt clear
BCM2836_PL011_ICR_TXIC = (1 shl 5); Transmit interrupt clear
BCM2836_PL011_ICR_RXIC = (1 shl 4); Receive interrupt clear
BCM2836_PL011_ICR_DSRMIC = (1 shl 3); Unsupported, write zero, read as don't care.
BCM2836_PL011_ICR_DCDMIC = (1 shl 2); Unsupported, write zero, read as don't care.
BCM2836_PL011_ICR_CTSMIC = (1 shl 1); nUARTCTS modem interrupt clear
BCM2836_PL011_ICR_RIMIC = (1 shl 0); Unsupported, write zero, read as don't care.


BCM2836 PL011 UART DMA control constants
See Section 13.4
 
This register is disabled, writing to it has no effect and reading returns 0.


BCM2836 ARM interrupt controller constants BCM2836_ARM_INTERRUPT_FIQ_*
See Section 7.5
 
BCM2836_ARM_INTERRUPT_FIQ_ENABLE = (1 shl 7); FIQ enable (Set this bit to 1 to enable FIQ generation. If set to 0 bits 6:0 are don't care.)
BCM2836_ARM_INTERRUPT_FIQ_SOURCE = ($7F shl 0); Select FIQ Source (0..127)


BCM2836 ARM timer constants BCM2836_ARM_TIMER_*
See Section 14.2
 
BCM2836_ARM_TIMER_CONTROL_COUNTER_PRESCALE = ($FF shl 16); Free running counter pre-scaler (Freq is sys_clk/(prescale+1))
BCM2836_ARM_TIMER_CONTROL_COUNTER_ENABLED = (1 shl 9); 0 : Free running counter Disabled / 1 : Free running counter Enabled
BCM2836_ARM_TIMER_CONTROL_DEBUG_HALT = (1 shl 8); 0 : Timers keeps running if ARM is in debug halted mode / 1 : Timers halted if ARM is in debug halted mode
BCM2836_ARM_TIMER_CONTROL_TIMER_ENABLED = (1 shl 7); 0 : Timer disabled / 1 : Timer enabled
BCM2836_ARM_TIMER_CONTROL_INT_ENABLED = (1 shl 5); 0 : Timer interrupt disabled / 1 : Timer interrupt enabled
BCM2836_ARM_TIMER_CONTROL_PRESCALE = (3 shl 2); Pre-scale bits: 00 : pre-scale is clock / 1 (No pre-scale) / 01 : pre-scale is clock / 16 / 10 : pre-scale is clock / 256 / 11 : pre-scale is clock / 1
BCM2836_ARM_TIMER_CONTROL_32BIT = (1 shl 1); 0 : 16-bit counters (default) / 1 : 32-bit counter
BCM2836_ARM_TIMER_CONTROL_ONESHOT = (1 shl 0); 0 = wrapping mode (default) / 1 = one-shot mode (Not supported by BCM2836)
 
BCM2836_ARM_TIMER_RAW_IRQ_PENDING = (1 shl 0); 0 : The interrupt pending bits is clear / 1 : The interrupt pending bit is set
 
BCM2836_ARM_TIMER_MASKED_IRQ_PENDING = (1 shl 0); 0 : Interrupt line not asserted / 1 :Interrupt line is asserted, (the interrupt pending and the interrupt enable bit are set)
 
BCM2836_ARM_TIMER_PREDIVIDER_MASK = ($3FF shl 0); Pre-divider value (timer_clock = apb_clock/(pre_divider+1))


BCM2836 power management, reset controller and watchdog constants BCM2836_PM_*
BCM2836_PM_PASSWORD = $5A000000;  
 
BCM2836_PM_RSTC_WRCFG_CLR = $FFFFFFCF;  
BCM2836_PM_RSTC_WRCFG_SET = $00000030;  
BCM2836_PM_RSTC_WRCFG_FULL_RESET = $00000020;  
BCM2836_PM_RSTC_RESET = $00000102;  
 
BCM2836_PM_RSTS_HADPOR_SET = $00001000;  
BCM2836_PM_RSTS_HADSRH_SET = $00000400;  
BCM2836_PM_RSTS_HADSRF_SET = $00000200;  
BCM2836_PM_RSTS_HADSRQ_SET = $00000100;  
BCM2836_PM_RSTS_HADWRH_SET = $00000040;  
BCM2836_PM_RSTS_HADWRF_SET = $00000020;  
BCM2836_PM_RSTS_HADWRQ_SET = $00000010;  
BCM2836_PM_RSTS_HADDRH_SET = $00000004;  
BCM2836_PM_RSTS_HADDRF_SET = $00000002;  
BCM2836_PM_RSTS_HADDRQ_SET = $00000001;  
 
BCM2836_PM_RSTS_RASPBERRYPI_HALT = $00000555; Special value to tell the Raspberry Pi firmware not to reboot
 
BCM2836_PM_WDOG_RESET = $00000000;  
BCM2836_PM_WDOG_TIME_MASK = $000FFFFF;  
 
BCM2836_PM_WDOG_TICKS_PER_SECOND = (1 shl 16);  
BCM2836_PM_WDOG_TICKS_PER_MILLISECOND = (BCM2836_PM_WDOG_TICKS_PER_SECOND div 1000);  


BCM2836 random number generator constants BCM2836_RANDOM_*
BCM2836_RANDOM_DISABLE = $00000000; Disable Random Number Generator
BCM2836_RANDOM_ENABLE = $00000001; Enable Random Number Generator
BCM2836_RANDOM_DOUBLE_SPEED = $00000002; Double Speed Mode (Less Random)


BCM2836 clock management constants BCM2836_CM_*
See Section 6
 
BCM2836_CM_PASSWORD = $5A000000;  


BCM2836 clock manager control constants BCM2836_CM_CTL_*
See Section 6.3
 
BCM2836_CM_CTL_MASH_0 = (0 shl 9); MASH control - 0 = integer division
BCM2836_CM_CTL_MASH_1 = (1 shl 9); MASH control - 1 = 1-stage MASH (equivalent to non-MASH dividers)
BCM2836_CM_CTL_MASH_2 = (2 shl 9); MASH control - 2 = 2-stage MASH
BCM2836_CM_CTL_MASH_3 = (3 shl 9); MASH control - 3 = 3-stage MASH (To avoid lock-ups and glitches do not change this control while BUSY=1 and do not change this control at the same time as asserting ENAB)
BCM2836_CM_CTL_FLIP = (1 shl 8); MASH control - Invert the clock generator output (To avoid output glitches do not switch this control while BUSY=1)
BCM2836_CM_CTL_BUSY = (1 shl 7); Clock generator is running (To avoid glitches and lock-ups, clock sources and setups must not be changed while this flag is set.)
BCM2836_CM_CTL_GATE = (1 shl 6); {Unused}
BCM2836_CM_CTL_KILL = (1 shl 5); Kill the clock generator (0 = no action / 1 = stop and reset the clock generator) (This is intended for test/debug only)
BCM2836_CM_CTL_ENAB = (1 shl 4); Enable the clock generator
 
BCM2836_CM_CTL_SRC_GND = (0 shl 0); Clock source - 0 Hz GND
BCM2836_CM_CTL_SRC_OSC = (1 shl 0); Clock source - 19.2 MHz Oscillator
BCM2836_CM_CTL_SRC_TESTDEBUG0 = (2 shl 0); Clock source - 0 Hz Testdebug0
BCM2836_CM_CTL_SRC_TESTDEBUG1 = (3 shl 0); Clock source - 0 Hz Testdebug1
BCM2836_CM_CTL_SRC_PLLA = (4 shl 0); Clock source - 0 Hz PLLA per
BCM2836_CM_CTL_SRC_PLLC = (5 shl 0); Clock source - 1000 MHz PLLC per (changes with overclock settings)
BCM2836_CM_CTL_SRC_PLLD = (6 shl 0); Clock source - 500 MHz PLLD per
BCM2836_CM_CTL_SRC_HDMI = (7 shl 0); Clock source - 216 MHz HDMI auxiliary


BCM2836 clock manager divisor constants BCM2836_CM_DIV_*
See Section 6.3
 
BCM2836_CM_DIV_INT_MASK = $00FFF000; Integer part of divisor (This value has a minimum limit determined by the MASH setting) (To avoid lock-ups and glitches do not change this control while BUSY=1)
BCM2836_CM_DIV_FRAC_MASK = $00000FFF; Fractional part of divisor (To avoid lock-ups and glitches do not change this control while BUSY=1)


BCM2836 clock manager constants BCM2836_CM_*
BCM2836_CM_GNRICCTL = $00000000; Generic Clock Control
BCM2836_CM_GNRICDIV = $00000004; Generic Clock Divisor
BCM2836_CM_VPUCTL = $00000008; VPU Clock Control
BCM2836_CM_VPUDIV = $0000000C; VPU Clock Divisor
BCM2836_CM_SYSCTL = $00000010; System Clock Control
BCM2836_CM_SYSDIV = $00000014; System Clock Divisor
BCM2836_CM_PERIACTL = $00000018; PERIA Clock Control
BCM2836_CM_PERIADIV = $0000001C; PERIA Clock Divisor
BCM2836_CM_PERIICTL = $00000020; PERII Clock Control
BCM2836_CM_PERIIDIV = $00000024; PERII Clock Divisor
BCM2836_CM_H264CTL = $00000028; H264 Clock Control
BCM2836_CM_H264DIV = $0000002C; H264 Clock Divisor
BCM2836_CM_ISPCTL = $00000030; ISP Clock Control
BCM2836_CM_ISPDIV = $00000034; ISP Clock Divisor
BCM2836_CM_V3DCTL = $00000038; V3D Clock Control
BCM2836_CM_V3DDIV = $0000003C; V3D Clock Divisor
BCM2836_CM_CAM0CTL = $00000040; Camera 0 Clock Control
BCM2836_CM_CAM0DIV = $00000044; Camera 0 Clock Divisor
BCM2836_CM_CAM1CTL = $00000048; Camera 1 Clock Control
BCM2836_CM_CAM1DIV = $0000004C; Camera 1 Clock Divisor
BCM2836_CM_CCP2CTL = $00000050; CCP2 Clock Control
BCM2836_CM_CCP2DIV = $00000054; CCP2 Clock Divisor
BCM2836_CM_DSI0ECTL = $00000058; DSI0E Clock Control
BCM2836_CM_DSI0EDIV = $0000005C; DSI0E Clock Divisor
BCM2836_CM_DSI0PCTL = $00000060; DSI0P Clock Control
BCM2836_CM_DSI0PDIV = $00000064; DSI0P Clock Divisor
BCM2836_CM_DPICTL = $00000068; DPI Clock Control
BCM2836_CM_DPIDIV = $0000006C; DPI Clock Divisor
BCM2836_CM_GP0CTL = $00000070; General Purpose 0 Clock Control
BCM2836_CM_GP0DIV = $00000074; General Purpose 0 Clock Divisor
BCM2836_CM_GP1CTL = $00000078; General Purpose 1 Clock Control
BCM2836_CM_GP1DIV = $0000007C; General Purpose 1 Clock Divisor
BCM2836_CM_GP2CTL = $00000080; General Purpose 2 Clock Control
BCM2836_CM_GP2DIV = $00000084; General Purpose 2 Clock Divisor
BCM2836_CM_HSMCTL = $00000088; HSM Clock Control
BCM2836_CM_HSMDIV = $0000008C; HSM Clock Divisor
BCM2836_CM_OTPCTL = $00000090; OTP Clock Control
BCM2836_CM_OTPDIV = $00000094; OTP Clock Divisor
BCM2836_CM_PCMCTL = $00000098; PCM / I2S Clock Control
BCM2836_CM_PCMDIV = $0000009C; PCM / I2S Clock Divisor
BCM2836_CM_PWMCTL = $000000A0; PWM Clock Control
BCM2836_CM_PWMDIV = $000000A4; PWM Clock Divisor
BCM2836_CM_SLIMCTL = $000000A8; SLIM Clock Control
BCM2836_CM_SLIMDIV = $000000AC; SLIM Clock Divisor
BCM2836_CM_SMICTL = $000000B0; SMI Clock Control
BCM2836_CM_SMIDIV = $000000B4; SMI Clock Divisor
BCM2836_CM_TCNTCTL = $000000C0; TCNT Clock Control
BCM2836_CM_TCNTDIV = $000000C4; TCNT Clock Divisor
BCM2836_CM_TECCTL = $000000C8; TEC Clock Control
BCM2836_CM_TECDIV = $000000CC; TEC Clock Divisor
BCM2836_CM_TD0CTL = $000000D0; TD0 Clock Control
BCM2836_CM_TD0DIV = $000000D4; TD0 Clock Divisor
BCM2836_CM_TD1CTL = $000000D8; TD1 Clock Control
BCM2836_CM_TD1DIV = $000000DC; TD1 Clock Divisor
BCM2836_CM_TSENSCTL = $000000E0; TSENS Clock Control
BCM2836_CM_TSENSDIV = $000000E4; TSENS Clock Divisor
BCM2836_CM_TIMERCTL = $000000E8; Timer Clock Control
BCM2836_CM_TIMERDIV = $000000EC; Timer Clock Divisor
BCM2836_CM_UARTCTL = $000000F0; UART Clock Control
BCM2836_CM_UARTDIV = $000000F4; UART Clock Divisor
BCM2836_CM_VECCTL = $000000F8; VEC Clock Control
BCM2836_CM_VECDIV = $000000FC; VEC Clock Divisor
 
BCM2836_CM_OSCCOUNT = $00000100; Oscillator Count
BCM2836_CM_PLLA = $00000104; PLLA
BCM2836_CM_PLLC = $00000108; PLLC
BCM2836_CM_PLLD = $0000010C; PLLD
BCM2836_CM_PLLH = $00000110; PLLH
BCM2836_CM_LOCK = $00000114; Lock
BCM2836_CM_EVENT = $00000118; Event
BCM2836_CM_INTEN = $00000118; INTEN
BCM2836_CM_DSI0HSCK = $00000120; DSI0HSCK
BCM2836_CM_CKSM = $00000124; CKSM
BCM2836_CM_OSCFREQI = $00000128; Oscillator Frequency Integer
BCM2836_CM_OSCFREQF = $0000012C; Oscillator Frequency Fraction
BCM2836_CM_PLLTCTL = $00000130; PLLT Control
BCM2836_CM_PLLTCNT0 = $00000134; PLLT0 Count
BCM2836_CM_PLLTCNT1 = $00000138; PLLT1 Count
BCM2836_CM_PLLTCNT2 = $0000013C; PLLT2 Count
BCM2836_CM_PLLTCNT3 = $00000140; PLLT3 Count
BCM2836_CM_TDCLKEN = $00000144; TD Clock Enable
BCM2836_CM_BURSTCTL = $00000148; Burst Control
BCM2836_CM_BURSTCNT = $0000014C; Burst Count
BCM2836_CM_DSI1ECTL = $00000158; DSI1E Clock Control
BCM2836_CM_DSI1EDIV = $0000015C; DSI1E Clock Divisor
BCM2836_CM_DSI1PCTL = $00000160; DSI1P Clock Control
BCM2836_CM_DSI1PDIV = $00000164; DSI1P Clock Divisor
BCM2836_CM_DFTCTL = $00000168; DFT Clock Control
BCM2836_CM_DFTDIV = $0000016C; DFT Clock Divisor
BCM2836_CM_PLLB = $00000170; PLLB
 
BCM2836_CM_PULSECTL = $00000190; Pulse Clock Control
BCM2836_CM_PULSEDIV = $00000194; Pulse Clock Divisor
BCM2836_CM_SDCCTL = $000001A8; SDC Clock Control
BCM2836_CM_SDCDIV = $000001AC; SDC Clock Divisor
BCM2836_CM_ARMCTL = $000001B0; ARM Clock Control
BCM2836_CM_ARMDIV = $000001B4; ARM Clock Divisor
BCM2836_CM_AVEOCTL = $000001B8; AVEO Clock Control
BCM2836_CM_AVEODIV = $000001BC; AVEO Clock Divisor
BCM2836_CM_EMMCCTL = $000001C0; EMMC Clock Control
BCM2836_CM_EMMCDIV = $000001C4; EMMC Clock Divisor


BCM2836 mailbox constants BCM2836_MAILBOX_*
BCM2836_MAILBOX_0 = 0;  
BCM2836_MAILBOX_1 = 1;  


BCM2836 mailbox 0 channel constants BCM2836_MAILBOX0_CHANNEL_*
See https://github.com/raspberrypi/firmware/wiki/Mailboxes
 
BCM2836_MAILBOX0_CHANNEL_POWER_MGMT = 0;  
BCM2836_MAILBOX0_CHANNEL_FRAMEBUFFER = 1;  
BCM2836_MAILBOX0_CHANNEL_UART = 2;  
BCM2836_MAILBOX0_CHANNEL_VCHIQ = 3;  
BCM2836_MAILBOX0_CHANNEL_LEDS = 4;  
BCM2836_MAILBOX0_CHANNEL_BUTTONS = 5;  
BCM2836_MAILBOX0_CHANNEL_TOUCHSCREEN = 6;  
BCM2836_MAILBOX0_CHANNEL_UNKNOWN = 7;  
BCM2836_MAILBOX0_CHANNEL_PROPERTYTAGS_ARMVC = 8;  
BCM2836_MAILBOX0_CHANNEL_PROPERTYTAGS_VCARM = 9;  


BCM2836 mailbox 1 channel constants BCM2836_MAILBOX_*
See https://github.com/raspberrypi/firmware/wiki/Mailboxes
Currently unknown
 
The BCM2836 mailboxes pass 28-bit messages (The low 4 bits of the 32-bit value are used to specify the channel)
BCM2836_MAILBOX_CHANNEL_MASK = $0000000F;  
BCM2836_MAILBOX_DATA_MASK = $FFFFFFF0;  


BCM2836 mailbox status flag constants BCM2836_MAILBOX_STATUS_*
BCM2836_MAILBOX_STATUS_FULL = $80000000;  
BCM2836_MAILBOX_STATUS_EMPTY = $40000000;  


BCM2836 mailbox property tag constants BCM2836_MBOX_TAG_*
See https://github.com/raspberrypi/firmware/wiki/Mailbox-property-interface or \include\soc\bcm2835\raspberrypi-firmware.h
 
VideoCore
BCM2836_MBOX_TAG_GET_FIRMWARE_REV = $00000001;  
Hardware
BCM2836_MBOX_TAG_GET_BOARD_MODEL = $00010001;  
BCM2836_MBOX_TAG_GET_BOARD_REV = $00010002;  
 
BCM2836_MBOX_TAG_GET_MAC_ADDRESS = $00010003;  
 
BCM2836_MBOX_TAG_GET_BOARD_SERIAL = $00010004;  
 
BCM2836_MBOX_TAG_GET_ARM_MEMORY = $00010005;  
BCM2836_MBOX_TAG_GET_VC_MEMORY = $00010006;  
 
BCM2836_MBOX_TAG_GET_CLOCKS = $00010007;  
Shared Resource Management
BCM2836_MBOX_TAG_GET_POWER_STATE = $00020001; Response indicates current state
BCM2836_MBOX_TAG_GET_TIMING = $00020002; Response indicates wait time required after turning a device on before power is stable
BCM2836_MBOX_TAG_SET_POWER_STATE = $00028001; Response indicates new state, with/without waiting for the power to become stable.
 
BCM2836_MBOX_TAG_GET_CLOCK_STATE = $00030001;  
BCM2836_MBOX_TAG_SET_CLOCK_STATE = $00038001;  
 
BCM2836_MBOX_TAG_GET_CLOCK_RATE = $00030002;  
BCM2836_MBOX_TAG_SET_CLOCK_RATE = $00038002;  
 
BCM2836_MBOX_TAG_GET_CLOCK_MAX_RATE = $00030004; Return the maximum supported clock rate for the given clock. Clocks should not be set higher than this.
BCM2836_MBOX_TAG_GET_CLOCK_MIN_RATE = $00030007; Return the minimum supported clock rate for the given clock. This may be used when idle.
 
BCM2836_MBOX_TAG_GET_TURBO = $00030009; Get the turbo state for index id. id should be 0. level will be zero for non-turbo and one for turbo.
BCM2836_MBOX_TAG_SET_TURBO = $00038009; 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.
 
BCM2836_MBOX_TAG_GET_STC = $0003000b;  
Voltage
BCM2836_MBOX_TAG_GET_VOLTAGE = $00030003; The voltage value may be clamped to the supported range. A value of 0x80000000 means the id was not valid.
BCM2836_MBOX_TAG_SET_VOLTAGE = $00038003; The voltage value may be clamped to the supported range. A value of 0x80000000 means the id was not valid.
 
BCM2836_MBOX_TAG_GET_MAX_VOLTAGE = $00030005; Return the maximum supported voltage rate for the given id. Voltages should not be set higher than this.
BCM2836_MBOX_TAG_GET_MIN_VOLTAGE = $00030008; Return the minimum supported voltage rate for the given id. This may be used when idle.
 
BCM2836_MBOX_TAG_GET_TEMP = $00030006; Return the temperature of the SoC in thousandths of a degree C. id should be zero.
BCM2836_MBOX_TAG_GET_MAX_TEMP = $0003000a; 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.
 
BCM2836_MBOX_TAG_ALLOCATE_MEMORY = $0003000c; Allocates contiguous memory on the GPU. Size and alignment are in bytes.
BCM2836_MBOX_TAG_LOCK_MEMORY = $0003000d; Lock buffer in place, and return a bus address. Must be done before memory can be accessed.
BCM2836_MBOX_TAG_UNLOCK_MEMORY = $0003000e; Unlock buffer. It retains contents, but may move. Needs to be locked before next use. status=0 is success.
BCM2836_MBOX_TAG_RELEASE_MEMORY = $0003000f; Free the memory buffer. status=0 is success
 
BCM2836_MBOX_TAG_EXECUTE_CODE = $00030010; 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.
BCM2836_MBOX_TAG_EXECUTE_QPU = $00030011;  
BCM2836_MBOX_TAG_ENABLE_QPU = $00030012;  
 
BCM2836_MBOX_TAG_GET_DISPMANX_HANDLE = $00030014; 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.
BCM2836_MBOX_TAG_GET_EDID_BLOCK = $00030020; 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.
 
BCM2836_MBOX_TAG_GET_CUSTOMER_OTP = $00030021;  
BCM2836_MBOX_TAG_SET_CUSTOMER_OTP = $00038021;  
 
BCM2836_MBOX_TAG_GET_DOMAIN_STATE = $00030030;  
BCM2836_MBOX_TAG_SET_DOMAIN_STATE = $00038030;  
Frame Buffer
BCM2836_MBOX_TAG_ALLOCATE_BUFFER = $00040001; 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.
BCM2836_MBOX_TAG_RELEASE_BUFFER = $00048001; Releases and disables the frame buffer
 
BCM2836_MBOX_TAG_SET_BLANK_SCREEN = $00040002;  
BCM2836_MBOX_TAG_TST_BLANK_SCREEN = $00044002;  
 
BCM2836_MBOX_TAG_GET_PHYSICAL_W_H = $00040003; 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.
BCM2836_MBOX_TAG_TEST_PHYSICAL_W_H = $00044003;  
BCM2836_MBOX_TAG_SET_PHYSICAL_W_H = $00048003;  
 
BCM2836_MBOX_TAG_GET_VIRTUAL_W_H = $00040004; 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.
BCM2836_MBOX_TAG_TEST_VIRTUAL_W_H = $00044004;  
BCM2836_MBOX_TAG_SET_VIRTUAL_W_H = $00048004;  
 
BCM2836_MBOX_TAG_GET_DEPTH = $00040005;  
BCM2836_MBOX_TAG_TEST_DEPTH = $00044005;  
BCM2836_MBOX_TAG_SET_DEPTH = $00048005;  
 
BCM2836_MBOX_TAG_GET_PIXEL_ORDER = $00040006;  
BCM2836_MBOX_TAG_TEST_PIXEL_ORDER = $00044006;  
BCM2836_MBOX_TAG_SET_PIXEL_ORDER = $00048006;  
 
BCM2836_MBOX_TAG_GET_ALPHA_MODE = $00040007;  
BCM2836_MBOX_TAG_TEST_ALPHA_MODE = $00044007;  
BCM2836_MBOX_TAG_SET_ALPHA_MODE = $00048007;  
 
BCM2836_MBOX_TAG_GET_PITCH = $00040008;  
BCM2836_MBOX_TAG_TST_PITCH = $00044008;  
BCM2836_MBOX_TAG_SET_PITCH = $00048008;  
 
BCM2836_MBOX_TAG_GET_VIRTUAL_OFFSET = $00040009; Offset of physical display window within virtual buffer
BCM2836_MBOX_TAG_TEST_VIRTUAL_OFFSET = $00044009;  
BCM2836_MBOX_TAG_SET_VIRTUAL_OFFSET = $00048009;  
 
BCM2836_MBOX_TAG_GET_OVERSCAN = $0004000a;  
BCM2836_MBOX_TAG_TEST_OVERSCAN = $0004400a;  
BCM2836_MBOX_TAG_SET_OVERSCAN = $0004800a;  
 
BCM2836_MBOX_TAG_GET_PALETTE = $0004000b;  
BCM2836_MBOX_TAG_TEST_PALETTE = $0004400b;  
BCM2836_MBOX_TAG_SET_PALETTE = $0004800b;  
 
BCM2836_MBOX_TAG_GET_TOUCHBUF = $0004000f;  
BCM2836_MBOX_TAG_GET_GPIOVIRTBUF = $00040010;  
 
BCM2836_MBOX_TAG_GET_LAYER = $0004000c;  
BCM2836_MBOX_TAG_TST_LAYER = $0004400c;  
BCM2836_MBOX_TAG_SET_LAYER = $0004800c;  
 
BCM2836_MBOX_TAG_GET_TRANSFORM = $0004000d;  
BCM2836_MBOX_TAG_TST_TRANSFORM = $0004400d;  
BCM2836_MBOX_TAG_SET_TRANSFORM = $0004800d;  
 
BCM2836_MBOX_TAG_TST_VSYNC = $0004400e;  
BCM2836_MBOX_TAG_SET_VSYNC = $0004800e;  
 
BCM2836_MBOX_TAG_SET_BACKLIGHT = $0004800f;  
 
BCM2836_MBOX_TAG_SET_CURSOR_INFO = $00008010; 00008011 These were reversed in the documentation, see Linux \include\soc\bcm2835\raspberrypi-firmware.h
BCM2836_MBOX_TAG_SET_CURSOR_STATE = $00008011; 00008010
VCHIQ
BCM2836_MBOX_TAG_VCHIQ_INIT = $00048010;  
Config
BCM2836_MBOX_TAG_GET_COMMAND_LINE = $00050001;  
Shared Resource Management
BCM2836_MBOX_TAG_GET_DMA_CHANNELS = $00060001; Caller assumes that the VC has enabled all the usable DMA channels
End
BCM2836_MBOX_TAG_END = $00000000;  


BCM2836 mailbox board revision value constants BCM2836_BOARD_REV_*
See: http://elinux.org/RPi_HardwareHistory
 
BCM2836_BOARD_REV_2B_1 = $00A01041;  
BCM2836_BOARD_REV_2B_2 = $00A21041;  
BCM2836_BOARD_REV_3B_1 = $00A02082;  
 
BCM2836_BOARD_REV_MASK = $00FFFFFF; Mask off the warranty bit


BCM2836 mailbox board revision constants BCM2836_BOARD_REVISION_*
See: https://github.com/AndrewFromMelbourne/raspberry_pi_revision
 
BCM2836_BOARD_REVISION_PCB_MASK = ($F shl 0); PCB Revision Number
 
BCM2836_BOARD_REVISION_MODEL_MASK = ($FF shl 4); Model Number
BCM2836_BOARD_REVISION_MODEL_A = (0 shl 4); Model A (Cannot occur on BCM2836)
BCM2836_BOARD_REVISION_MODEL_B = (1 shl 4); Model B (Cannot occur on BCM2836)
BCM2836_BOARD_REVISION_MODEL_APLUS = (2 shl 4); Model A+ (Cannot occur on BCM2836)
BCM2836_BOARD_REVISION_MODEL_BPLUS = (3 shl 4); Model B+ (Cannot occur on BCM2836)
BCM2836_BOARD_REVISION_MODEL_2B = (4 shl 4); Model 2B
BCM2836_BOARD_REVISION_MODEL_ALPHA = (5 shl 4); Unknown
BCM2836_BOARD_REVISION_MODEL_COMPUTE = (6 shl 4); Compute Module (Cannot occur on BCM2836)
BCM2836_BOARD_REVISION_MODEL_UNKNOWN = (7 shl 4); Unknown
BCM2836_BOARD_REVISION_MODEL_3B = (8 shl 4); Model 3B
BCM2836_BOARD_REVISION_MODEL_ZERO = (9 shl 4); Model Zero (Cannot occur on BCM2836)
 
BCM2836_BOARD_REVISION_PROCESSOR_MASK = ($F shl 12); Processor Type
BCM2836_BOARD_REVISION_PROCESSOR_BCM2835 = (0 shl 12); BCM2835 (Cannot occur on BCM2836)
BCM2836_BOARD_REVISION_PROCESSOR_BCM2836 = (1 shl 12); BCM2836
BCM2836_BOARD_REVISION_PROCESSOR_BCM2837 = (2 shl 12); BCM2837
 
BCM2836_BOARD_REVISION_MANUFACTURER_MASK = ($F shl 16); Manufacturer
BCM2836_BOARD_REVISION_MANUFACTURER_SONY = (0 shl 16); Sony
BCM2836_BOARD_REVISION_MANUFACTURER_EGOMAN = (1 shl 16); Egoman
BCM2836_BOARD_REVISION_MANUFACTURER_EMBEST = (2 shl 16); Embest
BCM2836_BOARD_REVISION_MANUFACTURER_UNKNOWN = (3 shl 16); Unknown
BCM2836_BOARD_REVISION_MANUFACTURER_EMBEST2 = (4 shl 16); Embest
 
BCM2836_BOARD_REVISION_MEMORY_MASK = ($7 shl 20); Memory Size
BCM2836_BOARD_REVISION_MEMORY_256M = (0 shl 20); 256M
BCM2836_BOARD_REVISION_MEMORY_512M = (1 shl 20); 512M
BCM2836_BOARD_REVISION_MEMORY_1024M = (2 shl 20); 1024M
 
BCM2836_BOARD_REVISION_ENCODED_FLAG = (1 shl 23); Endcoded Flag, if set then revision uses this encoding.
 
BCM2836_BOARD_REVISION_MASK = $00FFFFFF; Mask off the warranty bits


BCM2836 mailbox power state device constants BCM2836_MBOX_POWER_DEVID_*
BCM2836_MBOX_POWER_DEVID_SDHCI = 0;  
BCM2836_MBOX_POWER_DEVID_SDHCI = 0;  
BCM2836_MBOX_POWER_DEVID_UART0 = 1;  
BCM2836_MBOX_POWER_DEVID_UART1 = 2;  
BCM2836_MBOX_POWER_DEVID_USB_HCD = 3;  
BCM2836_MBOX_POWER_DEVID_I2C0 = 4;  
BCM2836_MBOX_POWER_DEVID_I2C1 = 5;  
BCM2836_MBOX_POWER_DEVID_I2C2 = 6;  
BCM2836_MBOX_POWER_DEVID_SPI = 7;  
BCM2836_MBOX_POWER_DEVID_CCP2TX = 8;  
 
BCM2836_MBOX_POWER_DEVID_UNKNOWN = $FFFFFFFF;  


BCM2836 mailbox power state request constants BCM2836_MBOX_SET_POWER_STATE_REQ_*
BCM2836_MBOX_SET_POWER_STATE_REQ_OFF = (0 shl 0);  
BCM2836_MBOX_SET_POWER_STATE_REQ_ON = (1 shl 0);  
BCM2836_MBOX_SET_POWER_STATE_REQ_WAIT = (1 shl 1);  


BCM2836 mailbox power state response constants BCM2836_MBOX_POWER_STATE_RESP_*
BCM2836_MBOX_POWER_STATE_RESP_OFF = (0 shl 0);  
BCM2836_MBOX_POWER_STATE_RESP_ON = (1 shl 0);  
BCM2836_MBOX_POWER_STATE_RESP_NODEV = (1 shl 1); Device doesn't exist


BCM2836 mailbox clock state/rate id constants BCM2836_MBOX_CLOCK_ID_*
BCM2836_MBOX_CLOCK_ID_RESERVED = 0;  
BCM2836_MBOX_CLOCK_ID_EMMC = 1;  
BCM2836_MBOX_CLOCK_ID_UART = 2;  
BCM2836_MBOX_CLOCK_ID_ARM = 3;  
BCM2836_MBOX_CLOCK_ID_CORE = 4;  
BCM2836_MBOX_CLOCK_ID_V3D = 5;  
BCM2836_MBOX_CLOCK_ID_H264 = 6;  
BCM2836_MBOX_CLOCK_ID_ISP = 7;  
BCM2836_MBOX_CLOCK_ID_SDRAM = 8;  
BCM2836_MBOX_CLOCK_ID_PIXEL = 9;  
BCM2836_MBOX_CLOCK_ID_PWM = 10;  
 
BCM2836_MBOX_CLOCK_ID_UNKNOWN = $FFFFFFFF;  


BCM2836 mailbox clock state request constants BCM2836_MBOX_SET_CLOCK_STATE_REQ_*
BCM2836_MBOX_SET_CLOCK_STATE_REQ_OFF = (0 shl 0);  
BCM2836_MBOX_SET_CLOCK_STATE_REQ_ON = (1 shl 0);  
BCM2836_MBOX_SET_CLOCK_STATE_REQ_NOCLOCK = (1 shl 1); Clock doesn't exist


BCM2836 mailbox clock state response constants BCM2836_MBOX_CLOCK_STATE_RESP_*
BCM2836_MBOX_CLOCK_STATE_RESP_OFF = (0 shl 0);  
BCM2836_MBOX_CLOCK_STATE_RESP_ON = (1 shl 0);  
BCM2836_MBOX_CLOCK_STATE_RESP_NOCLOCK = (1 shl 1); Clock doesn't exist


BCM2836 mailbox clock rate turbo constants BCM2836_MBOX_CLOCK_RATE_*
BCM2836_MBOX_CLOCK_RATE_REQ_SKIP_TURBO = (1 shl 0);  


BCM2836 mailbox voltage id constants BCM2836_MBOX_VOLTAGE_ID_*
BCM2836_MBOX_VOLTAGE_ID_RESERVED = $00000000;  
BCM2836_MBOX_VOLTAGE_ID_CORE = $00000001;  
BCM2836_MBOX_VOLTAGE_ID_SDRAM_C = $00000002;  
BCM2836_MBOX_VOLTAGE_ID_SDRAM_P = $00000003;  
BCM2836_MBOX_VOLTAGE_ID_SDRAM_I = $00000004;  


BCM2836 mailbox voltage constants BCM2836_MBOX_VOLTAGE_*
BCM2836_MBOX_VOLTAGE_INVALID = $80000000; A value of 0x80000000 means the id was not valid


BCM2836 mailbox temperature id constants BCM2836_MBOX_TEMP_ID_*
BCM2836_MBOX_TEMP_ID_SOC = 0;  


BCM2836 mailbox memory flag constants BCM2836_MBOX_MEM_FLAG_*
BCM2836_MBOX_MEM_FLAG_DISCARDABLE = (1 shl 0); Can be resized to 0 at any time. Use for cached data.
BCM2836_MBOX_MEM_FLAG_NORMAL = (0 shl 2); Normal allocating alias. Don't use from ARM.
BCM2836_MBOX_MEM_FLAG_DIRECT = (1 shl 2); 0xC alias uncached
BCM2836_MBOX_MEM_FLAG_COHERENT = (2 shl 2); 0x8 alias. Non-allocating in L2 but coherent.
BCM2836_MBOX_MEM_FLAG_L1_NONALLOCATING = (BCM2836_MBOX_MEM_FLAG_DIRECT or BCM2836_MBOX_MEM_FLAG_COHERENT); Allocating in L2
BCM2836_MBOX_MEM_FLAG_ZERO = (1 shl 4); Initialise buffer to all zeros
BCM2836_MBOX_MEM_FLAG_NO_INIT = (1 shl 5); Don't initialise (default is initialise to all ones).
BCM2836_MBOX_MEM_FLAG_HINT_PERMALOCK = (1 shl 6); Likely to be locked for long periods of time


BCM2836 mailbox blank screen constants BCM2836_MBOX_BLANK_SCREEN_*
BCM2836_MBOX_BLANK_SCREEN_REQ_ON = (1 shl 0);  


BCM2836 mailbox pixel order constants BCM2836_MBOX_PIXEL_ORDER_*
BCM2836_MBOX_PIXEL_ORDER_BGR = 0;  
BCM2836_MBOX_PIXEL_ORDER_RGB = 1;  


BCM2836 mailbox alpha mode constants BCM2836_MBOX_ALPHA_MODE_*
BCM2836_MBOX_ALPHA_MODE_0_OPAQUE = 0;  
BCM2836_MBOX_ALPHA_MODE_0_TRANSPARENT= 1;  
BCM2836_MBOX_ALPHA_MODE_IGNORED = 2;  


BCM2836 mailbox palette constants BCM2836_MBOX_PALETTE_*
BCM2836_MBOX_PALETTE_INVALID = $00000001;  


BCM2836 mailbox cursor state constants BCM2836_MBOX_CURSOR_*
BCM2836_MBOX_CURSOR_INVISIBLE = 0;  
BCM2836_MBOX_CURSOR_VISIBLE = 1;  


BCM2836 mailbox cursor state flag constants BCM2836_MBOX_CURSOR_STATE_*
BCM2836_MBOX_CURSOR_STATE_DISPLAY_COORDS = (0 shl 0);  
BCM2836_MBOX_CURSOR_STATE_FRAMEBUFFER_COORDS = (1 shl 0);  


BCM2836 mailbox cursor constants BCM2836_MBOX_CURSOR_*
BCM2836_MBOX_CURSOR_INVALID = $00000001;  


BCM2836 mailbox request constants BCM2836_MBOX_REQUEST_*
BCM2836_MBOX_REQUEST_CODE = $00000000;  
BCM2836_MBOX_RESPONSE_CODE_SUCCESS = $80000000;  
BCM2836_MBOX_RESPONSE_CODE_ERROR = $80000001;  


BCM2836 mailbox tag request constants BCM2836_MBOX_TAG_REQUEST_*
BCM2836_MBOX_TAG_REQUEST_CODE = $00000000;  
BCM2836_MBOX_TAG_RESPONSE_CODE = $80000000;  


BCM2836 GPIO constants BCM2836_GPIO_*
BCM2836_GPIO_PIN_COUNT = 54;  
BCM2836_GPIO_BANK_COUNT = 2;  


BCM2837 virtual GPIO constants BCM2837_VIRTUAL_GPIO_*
BCM2837_VIRTUAL_GPIO_PIN_COUNT = 2; Raspberry Pi 3B only


BCM2836 function select register constants BCM2836_GP*
BCM2836_GPFSEL0 = $00000000; GPIO Function Select 0
BCM2836_GPFSEL1 = $00000004; GPIO Function Select 1
BCM2836_GPFSEL2 = $00000008; GPIO Function Select 2
BCM2836_GPFSEL3 = $0000000C; GPIO Function Select 3
BCM2836_GPFSEL4 = $00000010; GPIO Function Select 4
BCM2836_GPFSEL5 = $00000014; GPIO Function Select 5
 
Pin Output Set Registers
BCM2836_GPSET0 = $0000001C; GPIO Pin Output Set 0
BCM2836_GPSET1 = $00000020; GPIO Pin Output Set 1
 
Pin Output Clear Registers
BCM2836_GPCLR0 = $00000028; GPIO Pin Output Clear 0
BCM2836_GPCLR1 = $0000002C; GPIO Pin Output Clear 1
 
Pin Level Registers
BCM2836_GPLEV0 = $00000034; GPIO Pin Level 0
BCM2836_GPLEV1 = $00000038; GPIO Pin Level 1
 
Pin Event Detect Status Registers
BCM2836_GPEDS0 = $00000040; GPIO Pin Event Detect Status 0
BCM2836_GPEDS1 = $00000044; GPIO Pin Event Detect Status 1
 
Pin Rising Edge Detect Enable Registers
BCM2836_GPREN0 = $0000004c; GPIO Pin Rising Edge Detect Enable 0
BCM2836_GPREN1 = $00000050; GPIO Pin Rising Edge Detect Enable 1
 
Pin Falling Edge Detect Enable Registers
BCM2836_GPFEN0 = $00000058; GPIO Pin Falling Edge Detect Enable 0
BCM2836_GPFEN1 = $0000005c; GPIO Pin Falling Edge Detect Enable 1
 
Pin High Detect Enable Registers
BCM2836_GPHEN0 = $00000064; GPIO Pin High Detect Enable 0
BCM2836_GPHEN1 = $00000068; GPIO Pin High Detect Enable 1
 
Pin Low Detect Enable Registers
BCM2836_GPLEN0 = $00000070; GPIO Pin Low Detect Enable 0
BCM2836_GPLEN1 = $00000074; GPIO Pin Low Detect Enable 1
 
Pin Async. Rising Edge Detect Registers
BCM2836_GPAREN0 = $0000007c; GPIO Pin Async. Rising Edge Detect 0
BCM2836_GPAREN1 = $00000080; GPIO Pin Async. Rising Edge Detect 1
 
Pin Async. Falling Edge Detect Registers
BCM2836_GPAFEN0 = $00000088; GPIO Pin Async. Falling Edge Detect 0
BCM2836_GPAFEN1 = $0000008c; GPIO Pin Async. Falling Edge Detect 1
 
Pin Pull-up/down Enable Registers
BCM2836_GPPUD = $00000094; GPIO Pin Pull-up/down Enable
 
Pin Pull-up/down Enable Clock Registers
BCM2836_GPPUDCLK0 = $00000098; GPIO Pin Pull-up/down Enable Clock 0
BCM2836_GPPUDCLK1 = $0000009C; GPIO Pin Pull-up/down Enable Clock 1
 
Function Select Mask
BCM2836_GPFSEL_MASK = 7;  
 
Function Select Values
BCM2836_GPFSEL_IN = 0;  
BCM2836_GPFSEL_OUT = 1;  
BCM2836_GPFSEL_ALT0 = 4;  
BCM2836_GPFSEL_ALT1 = 5;  
BCM2836_GPFSEL_ALT2 = 6;  
BCM2836_GPFSEL_ALT3 = 7;  
BCM2836_GPFSEL_ALT4 = 3;  
BCM2836_GPFSEL_ALT5 = 2;  
 
Pin Output Set Mask
BCM2836_GPSET_MASK = 1;  
 
Pin Output Clear Mask
BCM2836_GPCLR_MASK = 1;  
 
Pin Level Mask
BCM2836_GPLEV_MASK = 1;  
 
Pin Event Detect Status Mask
BCM2836_GPEDS_MASK = 1;  
 
Pin Rising Edge Detect Enable Mask
BCM2836_GPREN_MASK = 1;  
 
Pin Falling Edge Detect Enable Mask
BCM2836_GPFEN_MASK = 1;  
 
Pin High Detect Enable Mask
BCM2836_GPHEN_MASK = 1;  
 
Pin Low Detect Enable Mask
BCM2836_GPLEN_MASK = 1;  
 
Pin Async. Rising Edge Detect Mask
BCM2836_GPAREN_MASK = 1;  
 
Pin Async. Falling Edge Detect Mask
BCM2836_GPAFEN_MASK = 1;  
 
Pull-up/down Enable Mask
BCM2836_GPPUD_MASK = 3;  
 
Pull-up/down Enable Values
BCM2836_GPPUD_NONE = 0;  
BCM2836_GPPUD_DOWN = 1;  
BCM2836_GPPUD_UP = 2;  
 
Pin Pull-up/down Enable Clock Mask
BCM2836_GPPUDCLK_MASK = 1;  


BCM2836 ARM local constants BCM2836_ARM_LOCAL_*
See: QA7 Rev3.4.pdf
 
BCM2836_ARM_LOCAL_BASE = $40000000;  
BCM2836_ARM_LOCAL_SIZE = $0003FFFF;  


BCM2836 ARM local peripheral constants BCM2836_ARM_LOCAL_REGS_*
See: QA7 Rev3.4.pdf
 
BCM2836_ARM_LOCAL_REGS_BASE = (BCM2836_ARM_LOCAL_BASE + $0000);  


BCM2836 IRQ local ARM peripheral constants BCM2836_IRQ_LOCAL_ARM_*
See: QA7 Rev3.4.pdf
IRQs 96 to 127 appear in the IRQPending register
 
ARM Generic Timers
BCM2836_IRQ_LOCAL_ARM_CNTPSIRQ = 96; ARM Local IRQ 0
BCM2836_IRQ_LOCAL_ARM_CNTPNSIRQ = 97; ARM Local IRQ 1
BCM2836_IRQ_LOCAL_ARM_CNTHPIRQ = 98; ARM Local IRQ 2
BCM2836_IRQ_LOCAL_ARM_CNTVIRQ = 99; ARM Local IRQ 3
ARM Malboxes0-3
BCM2836_IRQ_LOCAL_ARM_MAILBOX0 = 100; ARM Local IRQ 4
BCM2836_IRQ_LOCAL_ARM_MAILBOX1 = 101; ARM Local IRQ 5
BCM2836_IRQ_LOCAL_ARM_MAILBOX2 = 102; ARM Local IRQ 6
BCM2836_IRQ_LOCAL_ARM_MAILBOX3 = 103; ARM Local IRQ 7
GPU Int Routing
BCM2836_IRQ_LOCAL_ARM_GPU = 104; ARM Local IRQ 8
ARM Performance Monitoring
BCM2836_IRQ_LOCAL_ARM_PMU = 105; ARM Local IRQ 9
AXI Outstanding
BCM2836_IRQ_LOCAL_ARM_AXI = 106; {ARM Local IRQ 9} ARM Local IRQ 9
ARM Local Timer
BCM2836_IRQ_LOCAL_ARM_TIMER = 107; ARM Local IRQ 11
ARM Local Peripherals 1-15 (Not Used)
BCM2836_IRQ_LOCAL_ARM_PERIPHERAL1 = 108; ARM Local IRQ 12
BCM2836_IRQ_LOCAL_ARM_PERIPHERAL2 = 109; ARM Local IRQ 13
BCM2836_IRQ_LOCAL_ARM_PERIPHERAL3 = 110; ARM Local IRQ 14
BCM2836_IRQ_LOCAL_ARM_PERIPHERAL4 = 111; ARM Local IRQ 15
BCM2836_IRQ_LOCAL_ARM_PERIPHERAL5 = 112; ARM Local IRQ 16
BCM2836_IRQ_LOCAL_ARM_PERIPHERAL6 = 113; ARM Local IRQ 17
BCM2836_IRQ_LOCAL_ARM_PERIPHERAL7 = 114; ARM Local IRQ 18
BCM2836_IRQ_LOCAL_ARM_PERIPHERAL8 = 115; ARM Local IRQ 19
BCM2836_IRQ_LOCAL_ARM_PERIPHERAL9 = 116; ARM Local IRQ 20
BCM2836_IRQ_LOCAL_ARM_PERIPHERAL10 = 117; ARM Local IRQ 21
BCM2836_IRQ_LOCAL_ARM_PERIPHERAL11 = 118; ARM Local IRQ 22
BCM2836_IRQ_LOCAL_ARM_PERIPHERAL12 = 119; ARM Local IRQ 23
BCM2836_IRQ_LOCAL_ARM_PERIPHERAL13 = 120; ARM Local IRQ 24
BCM2836_IRQ_LOCAL_ARM_PERIPHERAL14 = 121; ARM Local IRQ 25
BCM2836_IRQ_LOCAL_ARM_PERIPHERAL15 = 122; ARM Local IRQ 26
 
IRQs 123 to 127 (ARM Local IRQs 27 to 31) are not assigned


BCM2836 ARM local control constants BCM2836_ARM_LOCAL_CONTROL_*
See Section 4.2
 
BCM2836_ARM_LOCAL_CONTROL_APB_CLOCK = (1 shl 8); 64-bit Core timer runs from the APB clock
BCM2836_ARM_LOCAL_CONTROL_CRYSTAL_CLOCK = (0 shl 8); 64-bit Core timer runs from the Crystal clock
BCM2836_ARM_LOCAL_CONTROL_INCREMENT_2 = (1 shl 9); 64-bit Core timer increments by 2
BCM2836_ARM_LOCAL_CONTROL_INCREMENT_1 = (0 shl 9); 64-bit Core timer increments by 1


BCM2836 ARM local GPU interrupt routing constants BCM2836_ARM_LOCAL_GPU_INT_ROUTING_*
See Section 4.4
 
BCM2836_ARM_LOCAL_GPU_INT_ROUTING_IRQ0 = (0 shl 0); GPU IRQ goes to IRQ input of core 0
BCM2836_ARM_LOCAL_GPU_INT_ROUTING_IRQ1 = (1 shl 0); GPU IRQ goes to IRQ input of core 1
BCM2836_ARM_LOCAL_GPU_INT_ROUTING_IRQ2 = (2 shl 0); GPU IRQ goes to IRQ input of core 2
BCM2836_ARM_LOCAL_GPU_INT_ROUTING_IRQ3 = (3 shl 0); GPU IRQ goes to IRQ input of core 3
BCM2836_ARM_LOCAL_GPU_INT_ROUTING_FIQ0 = (0 shl 2); GPU FIQ goes to FIQ input of core 0
BCM2836_ARM_LOCAL_GPU_INT_ROUTING_FIQ1 = (1 shl 2); GPU FIQ goes to FIQ input of core 1
BCM2836_ARM_LOCAL_GPU_INT_ROUTING_FIQ2 = (2 shl 2); GPU FIQ goes to FIQ input of core 2
BCM2836_ARM_LOCAL_GPU_INT_ROUTING_FIQ3 = (3 shl 2); GPU FIQ goes to FIQ input of core 3
 
BCM2836_ARM_LOCAL_GPU_INT_ROUTING_IRQ_MASK = (3 shl 0);  
BCM2836_ARM_LOCAL_GPU_INT_ROUTING_FIQ_MASK = (3 shl 2);  


BCM2836 ARM local PM interrupt routing set/clear constants BCM2836_ARM_LOCAL_PM_INT_ROUTING_*
See Section 4.5
 
BCM2836_ARM_LOCAL_PM_INT_ROUTING_IRQ0 = (1 shl 0); Core 0 PM IRQ Enable (This bit is only valid if bit 4 is clear otherwise it is ignored)
BCM2836_ARM_LOCAL_PM_INT_ROUTING_IRQ1 = (1 shl 1); Core 1 PM IRQ Enable (This bit is only valid if bit 5 is clear otherwise it is ignored)
BCM2836_ARM_LOCAL_PM_INT_ROUTING_IRQ2 = (1 shl 2); Core 2 PM IRQ Enable (This bit is only valid if bit 6 is clear otherwise it is ignored)
BCM2836_ARM_LOCAL_PM_INT_ROUTING_IRQ3 = (1 shl 3); Core 3 PM IRQ Enable (This bit is only valid if bit 7 is clear otherwise it is ignored)
BCM2836_ARM_LOCAL_PM_INT_ROUTING_FIQ0 = (1 shl 4); Core 0 PM FIQ Enable (If set, this bit overrides the IRQ bit 0)
BCM2836_ARM_LOCAL_PM_INT_ROUTING_FIQ1 = (1 shl 5); Core 1 PM FIQ Enable (If set, this bit overrides the IRQ bit 1)
BCM2836_ARM_LOCAL_PM_INT_ROUTING_FIQ2 = (1 shl 6); Core 2 PM FIQ Enable (If set, this bit overrides the IRQ bit 2)
BCM2836_ARM_LOCAL_PM_INT_ROUTING_FIQ3 = (1 shl 7); Core 3 PM FIQ Enable (If set, this bit overrides the IRQ bit 3)


BCM2836 ARM local interrupt routing0 (0-7) constants BCM2836_ARM_LOCAL_INT_ROUTING0_TIMER_*
See Section 4.11
 
BCM2836_ARM_LOCAL_INT_ROUTING0_TIMER_IRQ0 = (0 shl 0); Local timer interrupt goes to Core 0 IRQ
BCM2836_ARM_LOCAL_INT_ROUTING0_TIMER_IRQ1 = (1 shl 0); Local timer interrupt goes to Core 1 IRQ
BCM2836_ARM_LOCAL_INT_ROUTING0_TIMER_IRQ2 = (2 shl 0); Local timer interrupt goes to Core 2 IRQ
BCM2836_ARM_LOCAL_INT_ROUTING0_TIMER_IRQ3 = (3 shl 0); Local timer interrupt goes to Core 3 IRQ
BCM2836_ARM_LOCAL_INT_ROUTING0_TIMER_FIQ0 = (4 shl 0); Local timer interrupt goes to Core 0 FIQ
BCM2836_ARM_LOCAL_INT_ROUTING0_TIMER_FIQ1 = (5 shl 0); Local timer interrupt goes to Core 1 FIQ
BCM2836_ARM_LOCAL_INT_ROUTING0_TIMER_FIQ2 = (6 shl 0); Local timer interrupt goes to Core 2 FIQ
BCM2836_ARM_LOCAL_INT_ROUTING0_TIMER_FIQ3 = (7 shl 0); Local timer interrupt goes to Core 3 FIQ


BCM2836 ARM local AXI outstanding count constants BCM2836_ARM_LOCAL_AXI_COUNT_*
See Section 4.9
 
BCM2836_ARM_LOCAL_AXI_COUNT_READ_MASK = ($3FF shl 0); Outstanding reads counter
BCM2836_ARM_LOCAL_AXI_COUNT_WRITE_MASK = ($3FF shl 16); Outstanding writes counter


BCM2836 ARM local AXI outstanding IRQ constants BCM2836_ARM_LOCAL_AXI_IRQ_*
See Section 4.9
Core 0 Only
 
BCM2836_ARM_LOCAL_AXI_IRQ_ENABLE = (1 shl 20);  
BCM2836_ARM_LOCAL_AXI_IRQ_TIMEOUT = ($FFFFF shl 0);  


BCM2836 ARM local timer control constants BCM2836_ARM_LOCAL_TIMER_CONTROL_*
See Section 4.11
 
BCM2836_ARM_LOCAL_TIMER_CONTROL_INT_STATUS = (1 shl 31); Interrupt flag (Read Only)
BCM2836_ARM_LOCAL_TIMER_CONTROL_INT_ENABLE = (1 shl 29); Interrupt enable (1= enabled)
BCM2836_ARM_LOCAL_TIMER_CONTROL_ENABLE = (1 shl 28); Timer enable (1 = enabled)
BCM2836_ARM_LOCAL_TIMER_CONTROL_VALUE_MASK = ($0FFFFFFF shl 0); Re-load value


BCM2836 ARM local timer clear reload constants BCM2836_ARM_LOCAL_TIMER_CLEAR_*
See Section 4.11
Write Only
 
BCM2836_ARM_LOCAL_TIMER_CLEAR_INT = (1 shl 31); Interrupt flag clear when written as 1 (Write Only)
BCM2836_ARM_LOCAL_TIMER_CLEAR_RELOAD = (1 shl 30); Local timer reloaded when written as 1 (Write Only)


BCM2836 ARM local timer interrupt control constants BCM2836_ARM_LOCAL_TIMER_INT_CONTROL_*
See Section 4.6
Note: These are the ARM Generic Timers (See ARM Architecture Reference Manual
 
BCM2836_ARM_LOCAL_TIMER_INT_CONTROL_CNTPSIRQ = (1 shl 0); Physical Secure Timer IRQ Enable (This bit is only valid if bit 4 is clear otherwise it is ignored)
BCM2836_ARM_LOCAL_TIMER_INT_CONTROL_CNTPNSIRQ = (1 shl 1); Physical Non Secure Timer IRQ Enable (This bit is only valid if bit 5 is clear otherwise it is ignored)
BCM2836_ARM_LOCAL_TIMER_INT_CONTROL_CNTHPIRQ = (1 shl 2); Hypervisor Timer IRQ Enable (This bit is only valid if bit 6 is clear otherwise it is ignored)
BCM2836_ARM_LOCAL_TIMER_INT_CONTROL_CNTVIRQ = (1 shl 3); Virtual Timer IRQ Enable (This bit is only valid if bit 7 is clear otherwise it is ignored)
BCM2836_ARM_LOCAL_TIMER_INT_CONTROL_CNTPSFIQ = (1 shl 4); Physical Secure Timer FIQ Enable (If set, this bit overrides the IRQ bit 0)
BCM2836_ARM_LOCAL_TIMER_INT_CONTROL_CNTPNSFIQ = (1 shl 5); Physical Non Secure Timer FIQ Enable (If set, this bit overrides the IRQ bit 1)
BCM2836_ARM_LOCAL_TIMER_INT_CONTROL_CNTHPFIQ = (1 shl 6); Hypervisor Timer FIQ Enable (If set, this bit overrides the IRQ bit 2)
BCM2836_ARM_LOCAL_TIMER_INT_CONTROL_CNTVFIQ = (1 shl 7); Virtual Timer FIQ Enable (If set, this bit overrides the IRQ bit 3)


BCM2836 ARM local mailbox interrupt control constants BCM2836_ARM_LOCAL_MAILBOX_INT_CONTROL_*
See Section 4.7
 
BCM2836_ARM_LOCAL_MAILBOX_INT_CONTROL_MAILBOX0IRQ = (1 shl 0); Mailbox-0 IRQ Enable (This bit is only valid if bit 4 is clear otherwise it is ignored)
BCM2836_ARM_LOCAL_MAILBOX_INT_CONTROL_MAILBOX1IRQ = (1 shl 1); Mailbox-1 IRQ Enable (This bit is only valid if bit 5 is clear otherwise it is ignored)
BCM2836_ARM_LOCAL_MAILBOX_INT_CONTROL_MAILBOX2IRQ = (1 shl 2); Mailbox-2 IRQ Enable (This bit is only valid if bit 6 is clear otherwise it is ignored)
BCM2836_ARM_LOCAL_MAILBOX_INT_CONTROL_MAILBOX3IRQ = (1 shl 3); Mailbox-3 IRQ Enable (This bit is only valid if bit 7 is clear otherwise it is ignored)
BCM2836_ARM_LOCAL_MAILBOX_INT_CONTROL_MAILBOX0FIQ = (1 shl 0); Mailbox-0 FIQ Enable (If set, this bit overrides the IRQ bit 0)
BCM2836_ARM_LOCAL_MAILBOX_INT_CONTROL_MAILBOX1FIQ = (1 shl 0); Mailbox-1 FIQ Enable (If set, this bit overrides the IRQ bit 1)
BCM2836_ARM_LOCAL_MAILBOX_INT_CONTROL_MAILBOX2FIQ = (1 shl 0); Mailbox-2 FIQ Enable (If set, this bit overrides the IRQ bit 2)
BCM2836_ARM_LOCAL_MAILBOX_INT_CONTROL_MAILBOX3FIQ = (1 shl 0); Mailbox-3 FIQ Enable (If set, this bit overrides the IRQ bit 3)


BCM2836 ARM local IRQ pending constants BCM2836_ARM_LOCAL_IRQ_PENDING_*
See Section 4.10
 
BCM2836_ARM_LOCAL_IRQ_PENDING_CNTPSIRQ = (1 shl 0); Physical Secure Timer Interrupt
BCM2836_ARM_LOCAL_IRQ_PENDING_CNTPNSIRQ = (1 shl 1); Physical Non Secure Timer Interrupt
BCM2836_ARM_LOCAL_IRQ_PENDING_CNTHPIRQ = (1 shl 2); Hypervisor Timer Interrupt
BCM2836_ARM_LOCAL_IRQ_PENDING_CNTVIRQ = (1 shl 3); Virtual Timer Interrupt
BCM2836_ARM_LOCAL_IRQ_PENDING_MAILBOX0 = (1 shl 4); Mailbox 0 Interrupt
BCM2836_ARM_LOCAL_IRQ_PENDING_MAILBOX1 = (1 shl 5); Mailbox 1 Interrupt
BCM2836_ARM_LOCAL_IRQ_PENDING_MAILBOX2 = (1 shl 6); Mailbox 2 Interrupt
BCM2836_ARM_LOCAL_IRQ_PENDING_MAILBOX3 = (1 shl 7); Mailbox 3 Interrupt
BCM2836_ARM_LOCAL_IRQ_PENDING_GPU = (1 shl 8); GPU Routed Interrupt (Can only be assigned to one core)
BCM2836_ARM_LOCAL_IRQ_PENDING_PMU = (1 shl 9); Performance Monitor Interrupt
BCM2836_ARM_LOCAL_IRQ_PENDING_AXI = (1 shl 10); AXI Outstanding Interrupt (Core 0 Only)
BCM2836_ARM_LOCAL_IRQ_PENDING_TIMER = (1 shl 11); Local Timer Interrupt
BCM2836_ARM_LOCAL_IRQ_PENDING_PERIPHERAL1 = (1 shl 12); Local Peripheral 1 Interrupt (Not Used)
BCM2836_ARM_LOCAL_IRQ_PENDING_PERIPHERAL2 = (1 shl 13); Local Peripheral 2 Interrupt (Not Used)
BCM2836_ARM_LOCAL_IRQ_PENDING_PERIPHERAL3 = (1 shl 14); Local Peripheral 3 Interrupt (Not Used)
BCM2836_ARM_LOCAL_IRQ_PENDING_PERIPHERAL4 = (1 shl 15); Local Peripheral 4 Interrupt (Not Used)
BCM2836_ARM_LOCAL_IRQ_PENDING_PERIPHERAL5 = (1 shl 16); Local Peripheral 5 Interrupt (Not Used)
BCM2836_ARM_LOCAL_IRQ_PENDING_PERIPHERAL6 = (1 shl 17); Local Peripheral 6 Interrupt (Not Used)
BCM2836_ARM_LOCAL_IRQ_PENDING_PERIPHERAL7 = (1 shl 18); Local Peripheral 7 Interrupt (Not Used)
BCM2836_ARM_LOCAL_IRQ_PENDING_PERIPHERAL8 = (1 shl 19); Local Peripheral 8 Interrupt (Not Used)
BCM2836_ARM_LOCAL_IRQ_PENDING_PERIPHERAL9 = (1 shl 20); Local Peripheral 9 Interrupt (Not Used)
BCM2836_ARM_LOCAL_IRQ_PENDING_PERIPHERAL10 = (1 shl 21); Local Peripheral 10 Interrupt (Not Used)
BCM2836_ARM_LOCAL_IRQ_PENDING_PERIPHERAL11 = (1 shl 22); Local Peripheral 11 Interrupt (Not Used)
BCM2836_ARM_LOCAL_IRQ_PENDING_PERIPHERAL12 = (1 shl 23); Local Peripheral 12 Interrupt (Not Used)
BCM2836_ARM_LOCAL_IRQ_PENDING_PERIPHERAL13 = (1 shl 24); Local Peripheral 13 Interrupt (Not Used)
BCM2836_ARM_LOCAL_IRQ_PENDING_PERIPHERAL14 = (1 shl 25); Local Peripheral 14 Interrupt (Not Used)
BCM2836_ARM_LOCAL_IRQ_PENDING_PERIPHERAL15 = (1 shl 26); Local Peripheral 15 Interrupt (Not Used)


BCM2836 ARM local FIQ pending constants BCM2836_ARM_LOCAL_FIQ_PENDING_*
See Section 4.10
 
BCM2836_ARM_LOCAL_FIQ_PENDING_CNTPSIRQ = (1 shl 0); Physical Secure Timer Fast Interrupt
BCM2836_ARM_LOCAL_FIQ_PENDING_CNTPNSIRQ = (1 shl 1); Physical Non Secure Timer Fast Interrupt
BCM2836_ARM_LOCAL_FIQ_PENDING_CNTHPIRQ = (1 shl 2); Hypervisor Timer Fast Interrupt
BCM2836_ARM_LOCAL_FIQ_PENDING_CNTVIRQ = (1 shl 3); Virtual Timer Fast Interrupt
BCM2836_ARM_LOCAL_FIQ_PENDING_MAILBOX0 = (1 shl 4); Mailbox 0 Fast Interrupt
BCM2836_ARM_LOCAL_FIQ_PENDING_MAILBOX1 = (1 shl 5); Mailbox 1 Fast Interrupt
BCM2836_ARM_LOCAL_FIQ_PENDING_MAILBOX2 = (1 shl 6); Mailbox 2 Fast Interrupt
BCM2836_ARM_LOCAL_FIQ_PENDING_MAILBOX3 = (1 shl 7); Mailbox 3 Fast Interrupt
BCM2836_ARM_LOCAL_FIQ_PENDING_GPU = (1 shl 8); GPU Routed Fast Interrupt (Can only be assigned to one core)
BCM2836_ARM_LOCAL_FIQ_PENDING_PMU = (1 shl 9); Performance Monitor Fast Interrupt
BCM2836_ARM_LOCAL_FIQ_PENDING_TIMER = (1 shl 11); Local Timer Fast Interrupt
BCM2836_ARM_LOCAL_FIQ_PENDING_PERIPHERAL1 = (1 shl 12); Local Peripheral 1 Fast Interrupt (Not Used)
BCM2836_ARM_LOCAL_FIQ_PENDING_PERIPHERAL2 = (1 shl 13); Local Peripheral 2 Fast Interrupt (Not Used)
BCM2836_ARM_LOCAL_FIQ_PENDING_PERIPHERAL3 = (1 shl 14); Local Peripheral 3 Fast Interrupt (Not Used)
BCM2836_ARM_LOCAL_FIQ_PENDING_PERIPHERAL4 = (1 shl 15); Local Peripheral 4 Fast Interrupt (Not Used)
BCM2836_ARM_LOCAL_FIQ_PENDING_PERIPHERAL5 = (1 shl 16); Local Peripheral 5 Fast Interrupt (Not Used)
BCM2836_ARM_LOCAL_FIQ_PENDING_PERIPHERAL6 = (1 shl 17); Local Peripheral 6 Fast Interrupt (Not Used)
BCM2836_ARM_LOCAL_FIQ_PENDING_PERIPHERAL7 = (1 shl 18); Local Peripheral 7 Fast Interrupt (Not Used)
BCM2836_ARM_LOCAL_FIQ_PENDING_PERIPHERAL8 = (1 shl 19); Local Peripheral 8 Fast Interrupt (Not Used)
BCM2836_ARM_LOCAL_FIQ_PENDING_PERIPHERAL9 = (1 shl 20); Local Peripheral 9 Fast Interrupt (Not Used)
BCM2836_ARM_LOCAL_FIQ_PENDING_PERIPHERAL10 = (1 shl 21); Local Peripheral 10 Fast Interrupt (Not Used)
BCM2836_ARM_LOCAL_FIQ_PENDING_PERIPHERAL11 = (1 shl 22); Local Peripheral 11 Fast Interrupt (Not Used)
BCM2836_ARM_LOCAL_FIQ_PENDING_PERIPHERAL12 = (1 shl 23); Local Peripheral 12 Fast Interrupt (Not Used)
BCM2836_ARM_LOCAL_FIQ_PENDING_PERIPHERAL13 = (1 shl 24); Local Peripheral 13 Fast Interrupt (Not Used)
BCM2836_ARM_LOCAL_FIQ_PENDING_PERIPHERAL14 = (1 shl 25); Local Peripheral 14 Fast Interrupt (Not Used)
BCM2836_ARM_LOCAL_FIQ_PENDING_PERIPHERAL15 = (1 shl 26); Local Peripheral 15 Fast Interrupt (Not Used)


Type definitions


To be documented

Public variables


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Function declarations


None defined


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