rt-thread/bsp/lpc824/Libraries/peri_driver/dma/dma_8xx.h

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/*
* @brief LPC8xx DMA chip driver
*
* @note
* Copyright(C) NXP Semiconductors, 2013
* All rights reserved.
*
* @par
* Software that is described herein is for illustrative purposes only
* which provides customers with programming information regarding the
* LPC products. This software is supplied "AS IS" without any warranties of
* any kind, and NXP Semiconductors and its licensor disclaim any and
* all warranties, express or implied, including all implied warranties of
* merchantability, fitness for a particular purpose and non-infringement of
* intellectual property rights. NXP Semiconductors assumes no responsibility
* or liability for the use of the software, conveys no license or rights under any
* patent, copyright, mask work right, or any other intellectual property rights in
* or to any products. NXP Semiconductors reserves the right to make changes
* in the software without notification. NXP Semiconductors also makes no
* representation or warranty that such application will be suitable for the
* specified use without further testing or modification.
*
* @par
* Permission to use, copy, modify, and distribute this software and its
* documentation is hereby granted, under NXP Semiconductors' and its
* licensor's relevant copyrights in the software, without fee, provided that it
* is used in conjunction with NXP Semiconductors microcontrollers. This
* copyright, permission, and disclaimer notice must appear in all copies of
* this code.
*/
#ifndef __DMA_8XX_H_
#define __DMA_8XX_H_
#ifdef __cplusplus
extern "C" {
#endif
/** @defgroup DMA_8XX CHIP: LPC8xx DMA Controller driver
* @ingroup CHIP_8XX_Drivers
* @{
*/
/**
* @brief DMA Controller shared registers structure
*/
typedef struct { /*!< DMA shared registers structure */
__IO uint32_t ENABLESET; /*!< DMA Channel Enable read and Set for all DMA channels */
__I uint32_t RESERVED0;
__O uint32_t ENABLECLR; /*!< DMA Channel Enable Clear for all DMA channels */
__I uint32_t RESERVED1;
__I uint32_t ACTIVE; /*!< DMA Channel Active status for all DMA channels */
__I uint32_t RESERVED2;
__I uint32_t BUSY; /*!< DMA Channel Busy status for all DMA channels */
__I uint32_t RESERVED3;
__IO uint32_t ERRINT; /*!< DMA Error Interrupt status for all DMA channels */
__I uint32_t RESERVED4;
__IO uint32_t INTENSET; /*!< DMA Interrupt Enable read and Set for all DMA channels */
__I uint32_t RESERVED5;
__O uint32_t INTENCLR; /*!< DMA Interrupt Enable Clear for all DMA channels */
__I uint32_t RESERVED6;
__IO uint32_t INTA; /*!< DMA Interrupt A status for all DMA channels */
__I uint32_t RESERVED7;
__IO uint32_t INTB; /*!< DMA Interrupt B status for all DMA channels */
__I uint32_t RESERVED8;
__O uint32_t SETVALID; /*!< DMA Set ValidPending control bits for all DMA channels */
__I uint32_t RESERVED9;
__O uint32_t SETTRIG; /*!< DMA Set Trigger control bits for all DMA channels */
__I uint32_t RESERVED10;
__O uint32_t ABORT; /*!< DMA Channel Abort control for all DMA channels */
} LPC_DMA_COMMON_T;
/**
* @brief DMA Controller shared registers structure
*/
typedef struct { /*!< DMA channel register structure */
__IO uint32_t CFG; /*!< DMA Configuration register */
__I uint32_t CTLSTAT; /*!< DMA Control and status register */
__IO uint32_t XFERCFG; /*!< DMA Transfer configuration register */
__I uint32_t RESERVED;
} LPC_DMA_CHANNEL_T;
/* Reserved bits masks... */
#define DMA_CFG_RESERVED ((3<<2)|(1<<7)|(3<<12)|0xfffc0000)
#define DMA_CTLSTAT_RESERVED (~(1|(1<<2)))
#define DMA_XFERCFG_RESERVED ((3<<6)|(3<<10)|(0x3fu<<26))
/* DMA channel mapping - each channel is mapped to an individual peripheral
and direction or a DMA imput mux trigger */
typedef enum {
DMAREQ_USART0_RX, /*!< USART0 receive DMA channel */
DMA_CH0 = DMAREQ_USART0_RX,
DMAREQ_USART0_TX, /*!< USART0 transmit DMA channel */
DMA_CH1 = DMAREQ_USART0_TX,
DMAREQ_USART1_RX, /*!< USART1 receive DMA channel */
DMA_CH2 = DMAREQ_USART1_RX,
DMAREQ_USART1_TX, /*!< USART1 transmit DMA channel */
DMA_CH3 = DMAREQ_USART1_TX,
DMAREQ_USART2_RX, /*!< USART2 receive DMA channel */
DMA_CH4 = DMAREQ_USART2_RX,
DMAREQ_USART2_TX, /*!< USART2 transmit DMA channel */
DMA_CH5 = DMAREQ_USART2_TX,
DMAREQ_SPI0_RX,
DMA_CH6 = DMAREQ_SPI0_RX, /*!< SPI0 receive DMA channel */
DMAREQ_SPI0_TX,
DMA_CH7 = DMAREQ_SPI0_TX, /*!< SPI0 transmit DMA channel */
DMAREQ_SPI1_RX,
DMA_CH8 = DMAREQ_SPI1_RX, /*!< SPI1 receive DMA channel */
DMAREQ_SPI1_TX,
DMA_CH9 = DMAREQ_SPI1_TX, /*!< SPI1 transmit DMA channel */
DMAREQ_I2C0_MST,
DMA_CH10 = DMAREQ_I2C0_MST, /*!< I2C0 Master DMA channel */
DMAREQ_I2C0_SLV,
DMA_CH11 = DMAREQ_I2C0_SLV, /*!< I2C0 Slave DMA channel */
DMAREQ_I2C1_MST,
DMA_CH12 = DMAREQ_I2C1_MST, /*!< I2C1 Master DMA channel */
DMAREQ_I2C1_SLV,
DMA_CH13 = DMAREQ_I2C1_SLV, /*!< I2C1 Slave DMA channel */
DMAREQ_I2C2_MST,
DMA_CH14 = DMAREQ_I2C2_MST, /*!< I2C2 Master DMA channel */
DMAREQ_I2C2_SLV,
DMA_CH15 = DMAREQ_I2C2_SLV, /*!< I2C2 Slave DMA channel */
DMAREQ_I2C3_MST,
DMA_CH16 = DMAREQ_I2C3_MST, /*!< I2C2 Master DMA channel */
DMAREQ_I2C3_SLV,
DMA_CH17 = DMAREQ_I2C3_SLV, /*!< I2C2 Slave DMA channel */
} DMA_CHID_T;
/* On LPC82x, Max DMA channel is 18 */
#define MAX_DMA_CHANNEL (DMA_CH17 + 1)
/* Reserved bits masks... */
#define DMA_COMMON_RESERVED (~(0UL) << MAX_DMA_CHANNEL)
#define DMA_ENABLESET_RESERVED DMA_COMMON_RESERVED
#define DMA_ENABLECLR_RESERVED DMA_COMMON_RESERVED
#define DMA_ACTIVE_RESERVED DMA_COMMON_RESERVED
#define DMA_BUSY_RESERVED DMA_COMMON_RESERVED
#define DMA_ERRINT_RESERVED DMA_COMMON_RESERVED
#define DMA_INTENSET_RESERVED DMA_COMMON_RESERVED
#define DMA_INTENCLR_RESERVED DMA_COMMON_RESERVED
#define DMA_INTA_RESERVED DMA_COMMON_RESERVED
#define DMA_INTB_RESERVED DMA_COMMON_RESERVED
#define DMA_SETVALID_RESERVED DMA_COMMON_RESERVED
#define DMA_SETTRIG_RESERVED DMA_COMMON_RESERVED
#define DMA_ABORT_RESERVED DMA_COMMON_RESERVED
/**
* @brief DMA Controller register block structure
*/
typedef struct { /*!< DMA Structure */
__IO uint32_t CTRL; /*!< DMA control register */
__I uint32_t INTSTAT; /*!< DMA Interrupt status register */
__IO uint32_t SRAMBASE; /*!< DMA SRAM address of the channel configuration table */
__I uint32_t RESERVED2[5];
LPC_DMA_COMMON_T DMACOMMON[1]; /*!< DMA shared channel (common) registers */
__I uint32_t RESERVED0[225];
LPC_DMA_CHANNEL_T DMACH[MAX_DMA_CHANNEL]; /*!< DMA channel registers */
} LPC_DMA_T;
/* Reserved bits masks... */
#define DMA_CTRL_RESERVED (~1)
#define DMA_INTSTAT_RESERVED (~7)
#define DMA_SRAMBASE_RESERVED (0xFF)
typedef enum {
WIDTH_8_BITS = 0,
WIDTH_16_BITS = 1,
WIDTH_32_BITS = 2
} DataWidth;
/**
* @brief Easy API, setup all required things to make DMA ready to use
* @param ch : DMA channel ID
* @return Nothing
*/
void ChipEz_DMA_Init(uint32_t isEnableIRQ);
/**
* @brief Easy API, setup the next transfer for a channel, this function updates DMA descriptor
* @param ch : DMA channel ID
* @param src_address: Source base address
* @param src_increment: Increment of source address after each transfer. Could be DMA_XFERCFG_SRCINC_0/1/2/4
* @param dst_address: Destination base address
* @param dst_increment: Increment of destination address after each transfer. Could be DMA_XFERCFG_DSTINC_0/1/2/4
* @param xfr_width: Width of transfer unit, could be WIDTH_8_BITS, WIDTH_16_BITS, or WIDTH_32_BITS
* @param length_bytes: Transfer length, in bytes. Must NOT makes transfer unit count exceed 1024.
* @param priority: Channel priority, used internally in DMA, could be from 0 (highest) to 7 (lowest)
* @return Nothing
* @note This function will set the DMA descriptor in the SRAM table to the
* the passed descriptor. This function is only meant to be used when
* the DMA channel is not active and can be used to setup the
* initial transfer for a linked list or ping-pong buffer or just a
* single transfer without a next descriptor.
*/
void ChipEz_DMA_InitChannel( DMA_CHID_T ch, uint32_t src_address, uint32_t src_increment,
uint32_t dst_address, uint32_t dst_increment, uint32_t xfr_width, uint32_t length_bytes, uint32_t priority);
/**
* @brief Easy API, Start transfer of a DMA channel
* @param ch : DMA channel ID
* @param src_increment: Increment of source address after each transfer. Could be DMA_XFERCFG_SRCINC_0/1/2/4.
* Should be consistent with the same parameter used in ChipEz_DMA_InitChannel()
* @param dst_increment: Increment of destination address after each transfer. Could be DMA_XFERCFG_DSTINC_0/1/2/4
* hould be consistent with the same parameter used in ChipEz_DMA_InitChannel()
* @param xfr_width: Width of transfer unit, could be WIDTH_8_BITS, WIDTH_16_BITS, or WIDTH_32_BITS
* Should be consistent with the same parameter used in ChipEz_DMA_InitChannel()
* @param length_bytes: Transfer length, in bytes. Must NOT makes transfer unit count exceed 1024.
* Should be consistent with the same parameter used in ChipEz_DMA_InitChannel()
* @param priority: Channel priority, used internally in DMA, could be from 0 (highest) to 7 (lowest)
* @return Nothing
*/
void ChipEz_DMA_StartTransfer(DMA_CHID_T ch, uint32_t src_increment, uint32_t dst_increment, uint32_t xfr_width, uint32_t length_bytes);
/**
* @brief Easier API, Combine ChipEz_DMA_InitChannel and ChipEz_DMA_StartTransfer with channel busy check
parameter is the same as ChipEz_DMA_InitChannel
@return TRUE when success, FALSE when current channel is busy.
*/
bool ChipEzr_DMA_Transfer( DMA_CHID_T channel, uint32_t src_address, uint32_t src_increment,
uint32_t dst_address, uint32_t dst_increment, uint32_t xfr_width, uint32_t length_bytes, uint32_t priority);
/**
* @brief Easy API, Abort a DMA channel safely
* @param ch : DMA channel ID
* @return Nothing
*/
void ChipEz_DMA_AbortChannel(DMA_CHID_T ch);
/** @defgroup DMA_COMMONDRV_8XX CHIP: LPC8xx DMA Controller driver common functions
* @{
*/
/**
* @brief Initialize DMA controller
* @param pDMA : The base of DMA controller on the chip
* @return Nothing
*/
STATIC INLINE void Chip_DMA_Init(LPC_DMA_T *pDMA)
{
(void) pDMA;
Chip_Clock_EnablePeriphClock(SYSCTL_CLOCK_DMA);
}
/**
* @brief De-Initialize DMA controller
* @param pDMA : The base of DMA controller on the chip
* @return Nothing
*/
STATIC INLINE void Chip_DMA_DeInit(LPC_DMA_T *pDMA)
{
(void) pDMA;
Chip_Clock_DisablePeriphClock(SYSCTL_CLOCK_DMA);
}
/**
* @brief Enable DMA controller
* @param pDMA : The base of DMA controller on the chip
* @return Nothing
*/
STATIC INLINE void Chip_DMA_Enable(LPC_DMA_T *pDMA)
{
pDMA->CTRL = 1;
}
/**
* @brief Disable DMA controller
* @param pDMA : The base of DMA controller on the chip
* @return Nothing
*/
STATIC INLINE void Chip_DMA_Disable(LPC_DMA_T *pDMA)
{
pDMA->CTRL = 0;
}
/* DMA interrupt status bits (common) */
#define DMA_INTSTAT_ACTIVEINT 0x2 /*!< Summarizes whether any enabled interrupts are pending */
#define DMA_INTSTAT_ACTIVEERRINT 0x4 /*!< Summarizes whether any error interrupts are pending */
/**
* @brief Get pending interrupt or error interrupts
* @param pDMA : The base of DMA controller on the chip
* @return An Or'ed value of DMA_INTSTAT_* types
* @note If any DMA channels have an active interrupt or error interrupt
* pending, this functional will a common status that applies to all
* channels.
*/
STATIC INLINE uint32_t Chip_DMA_GetIntStatus(LPC_DMA_T *pDMA)
{
return (pDMA->INTSTAT & ~DMA_INTSTAT_RESERVED);
}
/* DMA channel source/address/next descriptor */
typedef struct {
uint32_t xfercfg; /*!< Transfer configuration (only used in linked lists and ping-pong configs) */
uint32_t source; /*!< DMA transfer source end address */
uint32_t dest; /*!< DMA transfer desintation end address */
uint32_t next; /*!< Link to next DMA descriptor, must be 16 byte aligned */
} DMA_CHDESC_T;
/* DMA SRAM table - this can be optionally used with the Chip_DMA_SetSRAMBase()
function if a DMA SRAM table is needed. */
extern DMA_CHDESC_T Chip_DMA_Table[MAX_DMA_CHANNEL];
/**
* @brief Set DMA controller SRAM base address
* @param pDMA : The base of DMA controller on the chip
* @param base : The base address where the DMA descriptors will be stored
* @return Nothing
* @note A 256 byte block of memory aligned on a 256 byte boundary must be
* provided for this function. It sets the base address used for
* DMA descriptor table (16 descriptors total that use 16 bytes each).<br>
*
* A pre-defined table with correct alignment can be used for this
* function by calling Chip_DMA_SetSRAMBase(LPC_DMA, DMA_ADDR(Chip_DMA_Table));
*/
STATIC INLINE void Chip_DMA_SetSRAMBase(LPC_DMA_T *pDMA, uint32_t base)
{
pDMA->SRAMBASE = base;
}
/**
* @brief Returns DMA controller SRAM base address
* @param pDMA : The base of DMA controller on the chip
* @return The base address where the DMA descriptors are stored
*/
STATIC INLINE uint32_t Chip_DMA_GetSRAMBase(LPC_DMA_T *pDMA)
{
return (pDMA->SRAMBASE & ~DMA_SRAMBASE_RESERVED);
}
/**
* @}
*/
/** @defgroup DMA_COMMON_8XX CHIP: LPC8xx DMA Controller driver common channel functions
* @{
*/
/**
* @brief Enables a single DMA channel
* @param pDMA : The base of DMA controller on the chip
* @param ch : DMA channel ID
* @return Nothing
*/
STATIC INLINE void Chip_DMA_EnableChannel(LPC_DMA_T *pDMA, DMA_CHID_T ch)
{
pDMA->DMACOMMON[0].ENABLESET = (1 << ch);
}
/**
* @brief Disables a single DMA channel
* @param pDMA : The base of DMA controller on the chip
* @param ch : DMA channel ID
* @return Nothing
*/
STATIC INLINE void Chip_DMA_DisableChannel(LPC_DMA_T *pDMA, DMA_CHID_T ch)
{
pDMA->DMACOMMON[0].ENABLECLR = (1 << ch);
}
/**
* @brief Returns all enabled DMA channels
* @param pDMA : The base of DMA controller on the chip
* @return An Or'ed value of all enabled DMA channels (0 - 15)
* @note A high values in bits 0 .. 15 in the return values indicates
* that the channel for that bit (bit 0 = channel 0, bit 1 -
* channel 1, etc.) is enabled. A low state is disabled.
*/
STATIC INLINE uint32_t Chip_DMA_GetEnabledChannels(LPC_DMA_T *pDMA)
{
return (pDMA->DMACOMMON[0].ENABLESET & ~DMA_ENABLESET_RESERVED);
}
/**
* @brief Returns all active DMA channels
* @param pDMA : The base of DMA controller on the chip
* @return An Or'ed value of all active DMA channels (0 - 15)
* @note A high values in bits 0 .. 15 in the return values indicates
* that the channel for that bit (bit 0 = channel 0, bit 1 -
* channel 1, etc.) is active. A low state is inactive. A active
* channel indicates that a DMA operation has been started but
* not yet fully completed.
*/
STATIC INLINE uint32_t Chip_DMA_GetActiveChannels(LPC_DMA_T *pDMA)
{
return (pDMA->DMACOMMON[0].ACTIVE & ~DMA_ACTIVE_RESERVED);
}
/**
* @brief Returns all busy DMA channels
* @param pDMA : The base of DMA controller on the chip
* @return An Or'ed value of all busy DMA channels (0 - 15)
* @note A high values in bits 0 .. 15 in the return values indicates
* that the channel for that bit (bit 0 = channel 0, bit 1 -
* channel 1, etc.) is busy. A low state is not busy. A DMA
* channel is considered busy when there is any operation
* related to that channel in the DMA controller<65>s internal
* pipeline.
*/
STATIC INLINE uint32_t Chip_DMA_GetBusyChannels(LPC_DMA_T *pDMA)
{
return (pDMA->DMACOMMON[0].BUSY & ~DMA_BUSY_RESERVED);
}
/**
* @brief Returns pending error interrupt status for all DMA channels
* @param pDMA : The base of DMA controller on the chip
* @return An Or'ed value of all channels (0 - 15) error interrupt status
* @note A high values in bits 0 .. 15 in the return values indicates
* that the channel for that bit (bit 0 = channel 0, bit 1 -
* channel 1, etc.) has a pending error interrupt. A low state
* indicates no error interrupt.
*/
STATIC INLINE uint32_t Chip_DMA_GetErrorIntChannels(LPC_DMA_T *pDMA)
{
return (pDMA->DMACOMMON[0].ERRINT & ~DMA_ERRINT_RESERVED);
}
/**
* @brief Clears a pending error interrupt status for a single DMA channel
* @param pDMA : The base of DMA controller on the chip
* @param ch : DMA channel ID
* @return Nothing
*/
STATIC INLINE void Chip_DMA_ClearErrorIntChannel(LPC_DMA_T *pDMA, DMA_CHID_T ch)
{
pDMA->DMACOMMON[0].ERRINT = (1 << ch);
}
/**
* @brief Enables a single DMA channel's interrupt used in common DMA interrupt
* @param pDMA : The base of DMA controller on the chip
* @param ch : DMA channel ID
* @return Nothing
*/
STATIC INLINE void Chip_DMA_EnableIntChannel(LPC_DMA_T *pDMA, DMA_CHID_T ch)
{
pDMA->DMACOMMON[0].INTENSET = (1 << ch);
}
/**
* @brief Disables a single DMA channel's interrupt used in common DMA interrupt
* @param pDMA : The base of DMA controller on the chip
* @param ch : DMA channel ID
* @return Nothing
*/
STATIC INLINE void Chip_DMA_DisableIntChannel(LPC_DMA_T *pDMA, DMA_CHID_T ch)
{
pDMA->DMACOMMON[0].INTENCLR = (1 << ch);
}
/**
* @brief Returns all enabled interrupt channels
* @param pDMA : The base of DMA controller on the chip
* @return Nothing
* @note A high values in bits 0 .. 15 in the return values indicates
* that the channel for that bit (bit 0 = channel 0, bit 1 -
* channel 1, etc.) has an enabled interrupt for the channel.
* A low state indicates that the DMA channel will not contribute
* to the common DMA interrupt status.
*/
STATIC INLINE uint32_t Chip_DMA_GetEnableIntChannels(LPC_DMA_T *pDMA)
{
return (pDMA->DMACOMMON[0].INTENSET & ~DMA_INTENSET_RESERVED);
}
/**
* @brief Returns active A interrupt status for all channels
* @param pDMA : The base of DMA controller on the chip
* @return Nothing
* @note A high values in bits 0 .. 15 in the return values indicates
* that the channel for that bit (bit 0 = channel 0, bit 1 -
* channel 1, etc.) has an active A interrupt for the channel.
* A low state indicates that the A interrupt is not active.
*/
STATIC INLINE uint32_t Chip_DMA_GetActiveIntAChannels(LPC_DMA_T *pDMA)
{
return (pDMA->DMACOMMON[0].INTA & ~DMA_INTA_RESERVED);
}
/**
* @brief Clears active A interrupt status for a single channel
* @param pDMA : The base of DMA controller on the chip
* @param ch : DMA channel ID
* @return Nothing
*/
STATIC INLINE void Chip_DMA_ClearActiveIntAChannel(LPC_DMA_T *pDMA, DMA_CHID_T ch)
{
pDMA->DMACOMMON[0].INTA = (1 << ch);
}
/**
* @brief Returns active B interrupt status for all channels
* @param pDMA : The base of DMA controller on the chip
* @return Nothing
* @note A high values in bits 0 .. 15 in the return values indicates
* that the channel for that bit (bit 0 = channel 0, bit 1 -
* channel 1, etc.) has an active B interrupt for the channel.
* A low state indicates that the B interrupt is not active.
*/
STATIC INLINE uint32_t Chip_DMA_GetActiveIntBChannels(LPC_DMA_T *pDMA)
{
return (pDMA->DMACOMMON[0].INTB & ~DMA_INTB_RESERVED);
}
/**
* @brief Clears active B interrupt status for a single channel
* @param pDMA : The base of DMA controller on the chip
* @param ch : DMA channel ID
* @return Nothing
*/
STATIC INLINE void Chip_DMA_ClearActiveIntBChannel(LPC_DMA_T *pDMA, DMA_CHID_T ch)
{
pDMA->DMACOMMON[0].INTB = (1 << ch);
}
/**
* @brief Sets the VALIDPENDING control bit for a single channel
* @param pDMA : The base of DMA controller on the chip
* @param ch : DMA channel ID
* @return Nothing
* @note See the User Manual for more information for what this bit does.
*
*/
STATIC INLINE void Chip_DMA_SetValidChannel(LPC_DMA_T *pDMA, DMA_CHID_T ch)
{
pDMA->DMACOMMON[0].SETVALID = (1 << ch);
}
/**
* @brief Sets the TRIG bit for a single channel
* @param pDMA : The base of DMA controller on the chip
* @param ch : DMA channel ID
* @return Nothing
* @note See the User Manual for more information for what this bit does.
*/
STATIC INLINE void Chip_DMA_SetTrigChannel(LPC_DMA_T *pDMA, DMA_CHID_T ch)
{
pDMA->DMACOMMON[0].SETTRIG = (1 << ch);
}
/**
* @brief Aborts a DMA operation for a single channel
* @param pDMA : The base of DMA controller on the chip
* @param ch : DMA channel ID
* @return Nothing
* @note To abort a channel, the channel should first be disabled. Then wait
* until the channel is no longer busy by checking the corresponding
* bit in BUSY. Finally, abort the channel operation. This prevents the
* channel from restarting an incomplete operation when it is enabled
* again.
*/
STATIC INLINE void Chip_DMA_AbortChannel(LPC_DMA_T *pDMA, DMA_CHID_T ch)
{
pDMA->DMACOMMON[0].ABORT = (1 << ch);
}
/**
* @}
*/
/** @defgroup DMA_CHANNEL_8XX CHIP: LPC8xx DMA Controller driver channel specific functions
* @{
*/
/* Support macro for DMA_CHDESC_T */
#define DMA_ADDR(addr) ((uint32_t) (addr))
/* Support definitions for setting the configuration of a DMA channel. You
will need to get more information on these options from the User manual. */
#define DMA_CFG_PERIPHREQEN (1 << 0) /*!< Enables Peripheral DMA requests */
#define DMA_CFG_HWTRIGEN (1 << 1) /*!< Use hardware triggering via imput mux */
#define DMA_CFG_TRIGPOL_LOW (0 << 4) /*!< Hardware trigger is active low or falling edge */
#define DMA_CFG_TRIGPOL_HIGH (1 << 4) /*!< Hardware trigger is active high or rising edge */
#define DMA_CFG_TRIGTYPE_EDGE (0 << 5) /*!< Hardware trigger is edge triggered */
#define DMA_CFG_TRIGTYPE_LEVEL (1 << 5) /*!< Hardware trigger is level triggered */
#define DMA_CFG_TRIGBURST_SNGL (0 << 6) /*!< Single transfer. Hardware trigger causes a single transfer */
#define DMA_CFG_TRIGBURST_BURST (1 << 6) /*!< Burst transfer (see UM) */
#define DMA_CFG_BURSTPOWER_1 (0 << 8) /*!< Set DMA burst size to 1 transfer */
#define DMA_CFG_BURSTPOWER_2 (1 << 8) /*!< Set DMA burst size to 2 transfers */
#define DMA_CFG_BURSTPOWER_4 (2 << 8) /*!< Set DMA burst size to 4 transfers */
#define DMA_CFG_BURSTPOWER_8 (3 << 8) /*!< Set DMA burst size to 8 transfers */
#define DMA_CFG_BURSTPOWER_16 (4 << 8) /*!< Set DMA burst size to 16 transfers */
#define DMA_CFG_BURSTPOWER_32 (5 << 8) /*!< Set DMA burst size to 32 transfers */
#define DMA_CFG_BURSTPOWER_64 (6 << 8) /*!< Set DMA burst size to 64 transfers */
#define DMA_CFG_BURSTPOWER_128 (7 << 8) /*!< Set DMA burst size to 128 transfers */
#define DMA_CFG_BURSTPOWER_256 (8 << 8) /*!< Set DMA burst size to 256 transfers */
#define DMA_CFG_BURSTPOWER_512 (9 << 8) /*!< Set DMA burst size to 512 transfers */
#define DMA_CFG_BURSTPOWER_1024 (10 << 8) /*!< Set DMA burst size to 1024 transfers */
#define DMA_CFG_BURSTPOWER(n) ((n) << 8) /*!< Set DMA burst size to 2^n transfers, max n=10 */
#define DMA_CFG_SRCBURSTWRAP (1 << 14) /*!< Source burst wrapping is enabled for this DMA channel */
#define DMA_CFG_DSTBURSTWRAP (1 << 15) /*!< Destination burst wrapping is enabled for this DMA channel */
#define DMA_CFG_CHPRIORITY(p) ((p) << 16) /*!< Sets DMA channel priority, min 0 (highest), max 3 (lowest) */
/**
* @brief Setup a DMA channel configuration
* @param pDMA : The base of DMA controller on the chip
* @param ch : DMA channel ID
* @param cfg : An Or'ed value of DMA_CFG_* values that define the channel's configuration
* @return Nothing
* @note This function sets up all configurable options for the DMA channel.
* These options are usually set once for a channel and then unchanged.<br>
*
* The following example show how to configure the channel for peripheral
* DMA requests, burst transfer size of 1 (in 'transfers', not bytes),
* continuous reading of the same source address, incrementing destination
* address, and highest channel priority.<br>
* Example: Chip_DMA_SetupChannelConfig(pDMA, SSP0_RX_DMA,
* (DMA_CFG_PERIPHREQEN | DMA_CFG_TRIGBURST_BURST | DMA_CFG_BURSTPOWER_1 |
* DMA_CFG_SRCBURSTWRAP | DMA_CFG_CHPRIORITY(0)));<br>
*
* The following example show how to configure the channel for an external
* trigger from the imput mux with low edge polarity, a burst transfer size of 8,
* incrementing source and destination addresses, and lowest channel
* priority.<br>
* Example: Chip_DMA_SetupChannelConfig(pDMA, DMA_CH14,
* (DMA_CFG_HWTRIGEN | DMA_CFG_TRIGPOL_LOW | DMA_CFG_TRIGTYPE_EDGE |
* DMA_CFG_TRIGBURST_BURST | DMA_CFG_BURSTPOWER_8 |
* DMA_CFG_CHPRIORITY(3)));<br>
*
* For non-peripheral DMA triggering (DMA_CFG_HWTRIGEN definition), use the
* DMA input mux functions to configure the DMA trigger source for a DMA channel.
*/
STATIC INLINE void Chip_DMA_SetupChannelConfig(LPC_DMA_T *pDMA, DMA_CHID_T ch, uint32_t cfg)
{
pDMA->DMACH[ch].CFG = cfg;
}
/* DMA channel control and status register definitions */
#define DMA_CTLSTAT_VALIDPENDING (1 << 0) /*!< Valid pending flag for this channel */
#define DMA_CTLSTAT_TRIG (1 << 2) /*!< Trigger flag. Indicates that the trigger for this channel is currently set */
/**
* @brief Returns channel specific status flags
* @param pDMA : The base of DMA controller on the chip
* @param ch : DMA channel ID
* @return AN Or'ed value of DMA_CTLSTAT_VALIDPENDING and DMA_CTLSTAT_TRIG
*/
STATIC INLINE uint32_t Chip_DMA_GetChannelStatus(LPC_DMA_T *pDMA, DMA_CHID_T ch)
{
return (pDMA->DMACH[ch].XFERCFG & ~DMA_XFERCFG_RESERVED);
}
/* DMA channel transfer configuration registers definitions */
#define DMA_XFERCFG_CFGVALID (1 << 0) /*!< Configuration Valid flag */
#define DMA_XFERCFG_RELOAD (1 << 1) /*!< Indicates whether the channels control structure will be reloaded when the current descriptor is exhausted */
#define DMA_XFERCFG_SWTRIG (1 << 2) /*!< Software Trigger */
#define DMA_XFERCFG_CLRTRIG (1 << 3) /*!< Clear Trigger */
#define DMA_XFERCFG_SETINTA (1 << 4) /*!< Set Interrupt flag A for this channel to fire when descriptor is complete */
#define DMA_XFERCFG_SETINTB (1 << 5) /*!< Set Interrupt flag B for this channel to fire when descriptor is complete */
#define DMA_XFERCFG_WIDTH_8 (0 << 8) /*!< 8-bit transfers are performed */
#define DMA_XFERCFG_WIDTH_16 (1 << 8) /*!< 16-bit transfers are performed */
#define DMA_XFERCFG_WIDTH_32 (2 << 8) /*!< 32-bit transfers are performed */
#define DMA_XFERCFG_SRCINC_0 (0 << 12) /*!< DMA source address is not incremented after a transfer */
#define DMA_XFERCFG_SRCINC_1 (1 << 12) /*!< DMA source address is incremented by 1 (width) after a transfer */
#define DMA_XFERCFG_SRCINC_2 (2 << 12) /*!< DMA source address is incremented by 2 (width) after a transfer */
#define DMA_XFERCFG_SRCINC_4 (3 << 12) /*!< DMA source address is incremented by 4 (width) after a transfer */
#define DMA_XFERCFG_DSTINC_0 (0 << 14) /*!< DMA destination address is not incremented after a transfer */
#define DMA_XFERCFG_DSTINC_1 (1 << 14) /*!< DMA destination address is incremented by 1 (width) after a transfer */
#define DMA_XFERCFG_DSTINC_2 (2 << 14) /*!< DMA destination address is incremented by 2 (width) after a transfer */
#define DMA_XFERCFG_DSTINC_4 (3 << 14) /*!< DMA destination address is incremented by 4 (width) after a transfer */
#define DMA_XFERCFG_XFERCOUNT(n) ((n - 1) << 16) /*!< DMA transfer count in 'transfers', between (0)1 and (1023)1024 */
/**
* @brief Setup a DMA channel transfer configuration
* @param pDMA : The base of DMA controller on the chip
* @param ch : DMA channel ID
* @param cfg : An Or'ed value of DMA_XFERCFG_* values that define the channel's transfer configuration
* @return Nothing
* @note This function sets up the transfer configuration for the DMA channel.<br>
*
* The following example show how to configure the channel's transfer for
* multiple transfer descriptors (ie, ping-pong), interrupt 'A' trigger on
* transfer descriptor completion, 128 byte size transfers, and source and
* destination address increment.<br>
* Example: Chip_DMA_SetupChannelTransfer(pDMA, SSP0_RX_DMA,
* (DMA_XFERCFG_CFGVALID | DMA_XFERCFG_RELOAD | DMA_XFERCFG_SETINTA |
* DMA_XFERCFG_WIDTH_8 | DMA_XFERCFG_SRCINC_1 | DMA_XFERCFG_DSTINC_1 |
* DMA_XFERCFG_XFERCOUNT(128)));<br>
*/
STATIC INLINE void Chip_DMA_SetupChannelTransfer(LPC_DMA_T *pDMA, DMA_CHID_T ch, uint32_t cfg)
{
pDMA->DMACH[ch].XFERCFG = cfg;
}
/**
* @brief Set DMA transfer register interrupt bits (safe)
* @param pDMA : The base of DMA controller on the chip
* @param ch : DMA channel ID
* @param mask : Bits to set
* @return Nothing
* @note This function safely sets bits in the DMA channel specific XFERCFG
* register.
*/
STATIC INLINE void Chip_DMA_SetTranBits(LPC_DMA_T *pDMA, DMA_CHID_T ch, uint32_t mask)
{
/* Read and write values may not be the same, write 0 to
undefined bits */
pDMA->DMACH[ch].XFERCFG = (pDMA->DMACH[ch].XFERCFG & ~DMA_XFERCFG_RESERVED) | mask;
}
/**
* @brief Clear DMA transfer register interrupt bits (safe)
* @param pDMA : The base of DMA controller on the chip
* @param ch : DMA channel ID
* @param mask : Bits to clear
* @return Nothing
* @note This function safely clears bits in the DMA channel specific XFERCFG
* register.
*/
STATIC INLINE void Chip_DMA_ClearTranBits(LPC_DMA_T *pDMA, DMA_CHID_T ch, uint32_t mask)
{
/* Read and write values may not be the same, write 0 to
undefined bits */
pDMA->DMACH[ch].XFERCFG &= ~(DMA_XFERCFG_RESERVED | mask);
}
/**
* @brief Update the transfer size in an existing DMA channel transfer configuration
* @param pDMA : The base of DMA controller on the chip
* @param ch : DMA channel ID
* @param trans : Number of transfers to update the transfer configuration to (1 - 1023)
* @return Nothing
*/
STATIC INLINE void Chip_DMA_SetupChannelTransferSize(LPC_DMA_T *pDMA, DMA_CHID_T ch, uint32_t trans)
{
pDMA->DMACH[ch].XFERCFG = (pDMA->DMACH[ch].XFERCFG & ~(DMA_XFERCFG_RESERVED | (0x3FF << 16))) | DMA_XFERCFG_XFERCOUNT(trans);
}
/**
* @brief Sets a DMA channel configuration as valid
* @param pDMA : The base of DMA controller on the chip
* @param ch : DMA channel ID
* @return Nothing
*/
STATIC INLINE void Chip_DMA_SetChannelValid(LPC_DMA_T *pDMA, DMA_CHID_T ch)
{
Chip_DMA_SetTranBits(pDMA, ch, DMA_XFERCFG_CFGVALID);
}
/**
* @brief Sets a DMA channel configuration as invalid
* @param pDMA : The base of DMA controller on the chip
* @param ch : DMA channel ID
* @return Nothing
*/
STATIC INLINE void Chip_DMA_SetChannelInValid(LPC_DMA_T *pDMA, DMA_CHID_T ch)
{
Chip_DMA_ClearTranBits(pDMA, ch, DMA_XFERCFG_CFGVALID);
}
/**
* @brief Performs a software trigger of the DMA channel
* @param pDMA : The base of DMA controller on the chip
* @param ch : DMA channel ID
* @return Nothing
*/
STATIC INLINE void Chip_DMA_SWTriggerChannel(LPC_DMA_T *pDMA, DMA_CHID_T ch)
{
Chip_DMA_SetTranBits(pDMA, ch, DMA_XFERCFG_SWTRIG);
}
/**
* @brief Checks if the given channel is active or not
* @param pDMA : The base of DMA controller on the chip
* @param ch : DMA channel ID
* @return 1 if channel @a ch is active; 0 if channel @a ch is not active
*/
STATIC INLINE bool Chip_DMA_IsChannelActive(LPC_DMA_T *pDMA, DMA_CHID_T ch)
{
return (pDMA->DMACOMMON[0].ACTIVE & (1 << ch)) != 0;
}
/**
* @brief Sets up a DMA channel with the passed DMA transfer descriptor
* @param pDMA : The base of DMA controller on the chip
* @param ch : DMA channel ID
* @param desc : Pointer to DMA transfer descriptor
* @return false if the DMA channel was active, otherwise true
* @note This function will set the DMA descriptor in the SRAM table to the
* the passed descriptor. This function is only meant to be used when
* the DMA channel is not active and can be used to setup the
* initial transfer for a linked list or ping-pong buffer or just a
* single transfer without a next descriptor.<br>
*
* If using this function to write the initial transfer descriptor in
* a linked list or ping-pong buffer configuration, it should contain a
* non-NULL 'next' field pointer.
*/
STATIC INLINE bool Chip_DMA_SetupTranChannel(LPC_DMA_T *pDMA, DMA_CHID_T ch, const DMA_CHDESC_T *desc)
{
/* If channel is active return false */
if (Chip_DMA_IsChannelActive(pDMA, ch))
return false;
/* Assign the descriptor to descriptor table */
((DMA_CHDESC_T *) (pDMA->SRAMBASE & ~DMA_SRAMBASE_RESERVED))[ch] = *desc;
return true;
}
/**
* @}
*/
#endif /* __DMA_8XX_H_ */