qspi.c
73.3 KB
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/****************************************************************************
* arch/arm/src/stm32h7/stm32_qspi.c
*
* Copyright (C) 2016-2017, 2019 Gregory Nutt. All rights reserved.
* Author: dev@ziggurat29.com
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
*
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in
* the documentation and/or other materials provided with the
* distribution.
* 3. Neither the name NuttX nor the names of its contributors may be
* used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
* FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
* COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
* BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS
* OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
* AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
* ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*
****************************************************************************/
/****************************************************************************
* Included Files
****************************************************************************/
#include <nuttx/config.h>
#include <sys/types.h>
#include <stdint.h>
#include <stdbool.h>
#include <stdlib.h>
#include <string.h>
#include <errno.h>
#include <assert.h>
#include <debug.h>
#include <arch/board/board.h>
#include <nuttx/arch.h>
#include <nuttx/wdog.h>
#include <nuttx/clock.h>
#include <nuttx/cache.h>
#include <nuttx/kmalloc.h>
#include <nuttx/semaphore.h>
#include <nuttx/spi/qspi.h>
#include "arm_internal.h"
#include "arm_arch.h"
#include "barriers.h"
#include "stm32_gpio.h"
#include "stm32_dma.h"
#include "stm32_rcc.h"
#include "hardware/stm32_qspi.h"
#include "qspi.h"
#ifdef CONFIG_STM32H7_QUADSPI
#define QSPI_BOOT_IN_MEMORY_MAPPED_MOD
/****************************************************************************
* This defines exist in NuttX from 8.2.2020.
* It can be deleted once when NuttX in submodule will support it.
****************************************************************************/
#define QSPICMD_IDUAL (1 << 3) /* Bit 3: Instruction on two lines */
#define QSPICMD_IQUAD (1 << 4) /* Bit 4: Instruction on four lines */
#define QSPICMD_ISIDUAL(f) (((f) & QSPICMD_IDUAL) != 0)
#define QSPICMD_ISIQUAD(f) (((f) & QSPICMD_IQUAD) != 0)
#define QSPIMEM_IDUAL (1 << 7) /* Bit 7: Instruction on two lines */
#define QSPIMEM_IQUAD (1 << 0) /* Bit 0: Instruction on four lines */
#define QSPIMEM_ISIDUAL(f) (((f) & QSPIMEM_IDUAL) != 0)
#define QSPIMEM_ISIQUAD(f) (((f) & QSPIMEM_IQUAD) != 0)
/* Non-atomic, but more effective modification of registers */
# define modreg8(v,m,a) putreg8((getreg8(a) & ~(m)) | ((v) & (m)), a)
# define modreg16(v,m,a) putreg16((getreg16(a) & ~(m)) | ((v) & (m)), a)
# define modreg32(v,m,a) putreg32((getreg32(a) & ~(m)) | ((v) & (m)), a)
/****************************************************************************
* Pre-processor Definitions
****************************************************************************/
/* QSPI memory synchronization */
#define MEMORY_SYNC() do { ARM_DSB(); ARM_ISB(); } while (0)
/* Ensure that the DMA buffers are word-aligned. */
#define ALIGN_SHIFT 2
#define ALIGN_MASK 3
#define ALIGN_UP(n) (((n)+ALIGN_MASK) & ~ALIGN_MASK)
#define IS_ALIGNED(n) (((uint32_t)(n) & ALIGN_MASK) == 0)
/* Debug ********************************************************************/
/* Check if QSPI debug is enabled */
#ifndef CONFIG_DEBUG_DMA
# undef CONFIG_STM32H7_QSPI_DMADEBUG
#endif
#define DMA_INITIAL 0
#define DMA_AFTER_SETUP 1
#define DMA_AFTER_START 2
#define DMA_CALLBACK 3
#define DMA_TIMEOUT 3
#define DMA_END_TRANSFER 4
#define DMA_NSAMPLES 5
/* Can't have both interrupt-driven QSPI and DMA QSPI */
#if defined(CONFIG_STM32H7_QSPI_INTERRUPTS) && defined(CONFIG_STM32H7_QSPI_DMA)
# error "Cannot enable both interrupt mode and DMA mode for QSPI"
#endif
/* Sanity check that board.h defines requisite QSPI pinmap options for */
#if (!defined(GPIO_QSPI_CS) || !defined(GPIO_QSPI_IO0) || !defined(GPIO_QSPI_IO1) || \
!defined(GPIO_QSPI_IO2) || !defined(GPIO_QSPI_IO3) || !defined(GPIO_QSPI_SCK))
# error you must define QSPI pinmapping options for GPIO_QSPI_CS GPIO_QSPI_IO0 \
GPIO_QSPI_IO1 GPIO_QSPI_IO2 GPIO_QSPI_IO3 GPIO_QSPI_SCK in your board.h
#endif
#ifdef CONFIG_STM32H7_QSPI_DMA
# ifdef DMAMAP_QUADSPI
/* QSPI DMA Channel/Stream selection. There
* are multiple DMA stream options that must be dis-ambiguated in the board.h
* file.
*/
# define DMACHAN_QUADSPI DMAMAP_QUADSPI
# endif
# if defined(CONFIG_STM32H7_QSPI_DMAPRIORITY_LOW)
# define QSPI_DMA_PRIO DMA_SCR_PRILO
# elif defined(CONFIG_STM32H7_QSPI_DMAPRIORITY_MEDIUM)
# define QSPI_DMA_PRIO DMA_SCR_PRIMED
# elif defined(CONFIG_STM32H7_QSPI_DMAPRIORITY_HIGH)
# define QSPI_DMA_PRIO DMA_SCR_PRIHI
# elif defined(CONFIG_STM32H7_QSPI_DMAPRIORITY_VERYHIGH)
# define QSPI_DMA_PRIO DMA_SCR_PRIVERYHI
# else
# define QSPI_DMA_PRIO DMA_SCR_PRIMED
# endif
#endif /* CONFIG_STM32H7_QSPI_DMA */
#ifndef STM32_SYSCLK_FREQUENCY
# error your board.h needs to define the value of STM32_SYSCLK_FREQUENCY
#endif
#if !defined(CONFIG_STM32H7_QSPI_FLASH_SIZE) || 0 == CONFIG_STM32H7_QSPI_FLASH_SIZE
# error you must specify a positive flash size via CONFIG_STM32H7_QSPI_FLASH_SIZE
#endif
/* DMA timeout. The value is not critical; we just don't want the system to
* hang in the event that a DMA does not finish.
*/
#define DMA_TIMEOUT_MS (800)
#define DMA_TIMEOUT_TICKS MSEC2TICK(DMA_TIMEOUT_MS)
/* Clocking *****************************************************************/
/* The board.h file may choose a different clock source for QUADSPI
* peripherial by defining the BOARD_QSPI_CLK macro to one of the
* RCC_D1CCIPR_QSPISEL_XXX values (XXX = HCLK, PLL1, PLL2, PER).
* QUADSPI clock defaults to HCLK.
*/
#ifndef BOARD_QSPI_CLK
/* Clock QUADSPI from HCLK by default */
# define BOARD_QSPI_CLK RCC_D1CCIPR_QSPISEL_HCLK
#endif
/* The QSPI bit rate clock is generated by dividing the peripheral clock by
* a value between 1 and 255.
*
* Find out the frequency of the QSPI clock.
*/
#if BOARD_QSPI_CLK == RCC_D1CCIPR_QSPISEL_HCLK
# define QSPI_CLK_FREQUENCY STM32_HCLK_FREQUENCY
#elif BOARD_QSPI_CLK == RCC_D1CCIPR_QSPISEL_PLL1
# define QSPI_CLK_FREQUENCY STM32_PLL1Q_FREQUENCY
#elif BOARD_QSPI_CLK == RCC_D1CCIPR_QSPISEL_PLL2
# define QSPI_CLK_FREQUENCY STM32_PLL2R_FREQUENCY
#elif BOARD_QSPI_CLK == RCC_D1CCIPR_QSPISEL_PER
# define QSPI_CLK_FREQUENCY STM32_PER_FREQUENCY
#else
# error "BOARD_QSPI_CLK has unknown value!"
#endif
/****************************************************************************
* Private Types
****************************************************************************/
/* The state of the QSPI controller.
*
* NOTE: the STM32H7 supports only a single QSPI peripheral. Logic here is
* designed to support multiple QSPI peripherals.
*/
struct stm32h7_qspidev_s {
struct qspi_dev_s qspi; /* Externally visible part of the QSPI interface */
uint32_t base; /* QSPI controller register base address */
uint32_t frequency; /* Requested clock frequency */
uint32_t actual; /* Actual clock frequency */
uint8_t mode; /* Mode 0,3 */
uint8_t nbits; /* Width of word in bits (8 to 32) */
uint8_t intf; /* QSPI controller number (0) */
bool initialized; /* TRUE: Controller has been initialized */
sem_t exclsem; /* Assures mutually exclusive access to QSPI */
bool memmap; /* TRUE: Controller is in memory mapped mode */
#ifdef CONFIG_STM32H7_QSPI_INTERRUPTS
xcpt_t handler; /* Interrupt handler */
uint8_t irq; /* Interrupt number */
sem_t op_sem; /* Block until complete */
struct qspi_xctnspec_s *xctn; /* context of transaction in progress */
#endif
#ifdef CONFIG_STM32H7_QSPI_DMA
bool candma; /* DMA is supported */
sem_t dmawait; /* Used to wait for DMA completion */
int result; /* DMA result */
DMA_HANDLE dmach; /* QSPI DMA handle */
WDOG_ID dmadog; /* Watchdog that handles DMA timeouts */
#endif
/* Debug stuff */
#ifdef CONFIG_STM32H7_QSPI_DMADEBUG
struct stm32h7_dmaregs_s dmaregs[DMA_NSAMPLES];
#endif
#ifdef CONFIG_STM32H7_QSPI_REGDEBUG
bool wrlast; /* Last was a write */
uint32_t addresslast; /* Last address */
uint32_t valuelast; /* Last value */
int ntimes; /* Number of times */
#endif
};
/* The QSPI transaction specification
*
* This is mostly the values of the CCR and DLR, AR, ABR, broken out into a C
* structure since these fields need to be considered at various phases of
* thee transaction processing activity.
*/
struct qspi_xctnspec_s {
uint8_t instrmode; /* 'instruction mode'; 0=none, 1=single, 2=dual, 3=quad */
uint8_t instr; /* the (8-bit) Instruction (if any) */
uint8_t addrmode; /* 'address mode'; 0=none, 1=single, 2=dual, 3=quad */
uint8_t addrsize; /* address size (n - 1); 0, 1, 2, 3 */
uint32_t addr; /* the address (if any) (1 to 4 bytes as per addrsize) */
uint8_t altbytesmode; /* 'alt bytes mode'; 0=none, 1=single, 2=dual, 3=quad */
uint8_t altbytessize; /* 'alt bytes' size (n - 1); 0, 1, 2, 3 */
uint32_t altbytes; /* the 'alt bytes' (if any) */
uint8_t dummycycles; /* number of Dummy Cycles; 0 - 32 */
uint8_t datamode; /* 'data mode'; 0=none, 1=single, 2=dual, 3=quad */
uint32_t datasize; /* number of data bytes (0xffffffff == undefined) */
FAR void *buffer; /* Data buffer */
uint8_t isddr; /* true if 'double data rate' */
uint8_t issioo; /* true if 'send instruction only once' mode */
#ifdef CONFIG_STM32H7_QSPI_INTERRUPTS
uint8_t function; /* functional mode; to distinguish a read or write */
int8_t disposition; /* how it all turned out */
uint32_t idxnow; /* index into databuffer of current byte in transfer */
#endif
};
/****************************************************************************
* Private Function Prototypes
****************************************************************************/
/* Helpers */
#ifdef CONFIG_STM32H7_QSPI_REGDEBUG
bool qspi_checkreg(struct stm32h7_qspidev_s *priv, bool wr,
uint32_t value, uint32_t address);
#else
# define qspi_checkreg(priv,wr,value,address) (false)
#endif
inline uint32_t qspi_getreg(struct stm32h7_qspidev_s *priv, unsigned int offset);
static inline void qspi_putreg(struct stm32h7_qspidev_s *priv, uint32_t value,
unsigned int offset);
#ifdef CONFIG_DEBUG_SPI_INFO
QUADSPI_RAMFUNC void qspi_dumpregs(struct stm32h7_qspidev_s *priv,
const char *msg);
#else
# define qspi_dumpregs(priv,msg)
#endif
#if defined(CONFIG_DEBUG_SPI_INFO) && defined(CONFIG_DEBUG_GPIO)
QUADSPI_RAMFUNC void qspi_dumpgpioconfig(const char *msg);
#else
# define qspi_dumpgpioconfig(msg)
#endif
/* Interrupts */
#ifdef CONFIG_STM32H7_QSPI_INTERRUPTS
static int qspi0_interrupt(int irq, void *context, FAR void *arg);
#endif
/* DMA support */
#ifdef CONFIG_STM32H7_QSPI_DMA
# ifdef CONFIG_STM32H7_QSPI_DMADEBUG
# define qspi_dma_sample(s,i) stm32h7_dmasample((s)->dmach, &(s)->dmaregs[i])
QUADSPI_RAMFUNC void qspi_dma_sampleinit(struct stm32h7_qspidev_s *priv);
QUADSPI_RAMFUNC void qspi_dma_sampledone(struct stm32h7_qspidev_s *priv);
# else
# define qspi_dma_sample(s,i)
# define qspi_dma_sampleinit(s)
# define qspi_dma_sampledone(s)
# endif
# ifndef CONFIG_STM32H7_QSPI_DMATHRESHOLD
# define CONFIG_STM32H7_QSPI_DMATHRESHOLD 4
# endif
#endif
/* Initialization */
#if !defined(QSPI_BOOT_IN_MEMORY_MAPPED_MOD)
QUADSPI_RAMFUNC int qspi_hw_initialize(struct stm32h7_qspidev_s *priv);
#endif
/****************************************************************************
* Private Data
****************************************************************************/
/* QSPI0 driver operations */
static const struct qspi_ops_s g_qspi0ops = { .lock = qspi_lock, .setfrequency =
qspi_setfrequency, .setmode = qspi_setmode, .setbits = qspi_setbits, .command =
qspi_command, .memory = qspi_memory, .alloc = qspi_alloc, .free = qspi_free,
};
/* This is the overall state of the QSPI0 controller */
static struct stm32h7_qspidev_s g_qspi0dev = { .qspi = { .ops = &g_qspi0ops, },
.base = STM32_QUADSPI_BASE,
#ifdef CONFIG_STM32H7_QSPI_INTERRUPTS
handler = qspi0_interrupt,
.irq = STM32_IRQ_QUADSPI,
#endif
.intf = 0,
#ifdef CONFIG_STM32H7_QSPI_DMA
.candma = true,
#endif
};
/****************************************************************************
* Private Functions
****************************************************************************/
/****************************************************************************
* Name: qspi_checkreg
*
* Description:
* Check if the current register access is a duplicate of the preceding.
*
* Input Parameters:
* value - The value to be written
* address - The address of the register to write to
*
* Returned Value:
* true: This is the first register access of this type.
* false: This is the same as the preceding register access.
*
****************************************************************************/
#ifdef CONFIG_STM32H7_QSPI_REGDEBUG
QUADSPI_RAMFUNC bool qspi_checkreg(struct stm32h7_qspidev_s *priv, bool wr,
uint32_t value, uint32_t address)
{
if (wr == priv->wrlast && /* Same kind of access? */
value == priv->valuelast && /* Same value? */
address == priv->addresslast) { /* Same address? */
/* Yes, then just keep a count of the number of times we did this. */
priv->ntimes++;
return false;
} else {
/* Did we do the previous operation more than once? */
if (priv->ntimes > 0) {
/* Yes... show how many times we did it */
spiinfo("...[Repeats %d times]...\n", priv->ntimes);
}
/* Save information about the new access */
priv->wrlast = wr;
priv->valuelast = value;
priv->addresslast = address;
priv->ntimes = 0;
}
/* Return true if this is the first time that we have done this operation */
return true;
}
#endif
/****************************************************************************
* Name: qspi_getreg
*
* Description:
* Read an QSPI register
*
****************************************************************************/
inline uint32_t qspi_getreg(struct stm32h7_qspidev_s *priv, unsigned int offset)
{
uint32_t address = priv->base + offset;
uint32_t value = getreg32(address);
#ifdef CONFIG_STM32H7_QSPI_REGDEBUG
if (qspi_checkreg(priv, false, value, address)) {
spiinfo("%08x->%08x\n", address, value);
}
#endif
return value;
}
/****************************************************************************
* Name: qspi_putreg
*
* Description:
* Write a value to an QSPI register
*
****************************************************************************/
static inline void qspi_putreg(struct stm32h7_qspidev_s *priv, uint32_t value,
unsigned int offset)
{
uint32_t address = priv->base + offset;
#ifdef CONFIG_STM32H7_QSPI_REGDEBUG
if (qspi_checkreg(priv, true, value, address)) {
spiinfo("%08x<-%08x\n", address, value);
}
#endif
putreg32(value, address);
}
/****************************************************************************
* Name: qspi_dumpregs
*
* Description:
* Dump the contents of all QSPI registers
*
* Input Parameters:
* priv - The QSPI controller to dump
* msg - Message to print before the register data
*
* Returned Value:
* None
*
****************************************************************************/
#ifdef CONFIG_DEBUG_SPI_INFO
QUADSPI_RAMFUNC void qspi_dumpregs(struct stm32h7_qspidev_s *priv, const char *msg)
{
uint32_t regval;
spiinfo("%s:\n", msg);
#if 0
/* this extra verbose output may be helpful in some cases; you'll need
* to make sure your syslog is large enough to accommodate extra output.
*/
regval = getreg32(priv->base + STM32_QUADSPI_CR_OFFSET); /* Control Register */
spiinfo("CR:%08x\n", regval);
spiinfo(" EN:%1d ABORT:%1d DMAEN:%1d TCEN:%1d SSHIFT:%1d\n"
" FTHRES: %d\n"
" TEIE:%1d TCIE:%1d FTIE:%1d SMIE:%1d TOIE:%1d APMS:%1d PMM:%1d\n"
" PRESCALER: %d\n",
(regval & QSPI_CR_EN) ? 1 : 0,
(regval & QSPI_CR_ABORT) ? 1 : 0,
(regval & QSPI_CR_DMAEN) ? 1 : 0,
(regval & QSPI_CR_TCEN) ? 1 : 0,
(regval & QSPI_CR_SSHIFT) ? 1 : 0,
(regval & QSPI_CR_FTHRES_MASK) >> QSPI_CR_FTHRES_SHIFT,
(regval & QSPI_CR_TEIE) ? 1 : 0,
(regval & QSPI_CR_TCIE) ? 1 : 0,
(regval & QSPI_CR_FTIE) ? 1 : 0,
(regval & QSPI_CR_SMIE) ? 1 : 0,
(regval & QSPI_CR_TOIE) ? 1 : 0,
(regval & QSPI_CR_APMS) ? 1 : 0,
(regval & QSPI_CR_PMM) ? 1 : 0,
(regval & QSPI_CR_PRESCALER_MASK) >> QSPI_CR_PRESCALER_SHIFT);
regval = getreg32(priv->base + STM32_QUADSPI_DCR_OFFSET); /* Device Configuration Register */
spiinfo("DCR:%08x\n", regval);
spiinfo(" CKMODE:%1d CSHT:%d FSIZE:%d\n",
(regval & QSPI_DCR_CKMODE) ? 1 : 0,
(regval & QSPI_DCR_CSHT_MASK) >> QSPI_DCR_CSHT_SHIFT,
(regval & QSPI_DCR_FSIZE_MASK) >> QSPI_DCR_FSIZE_SHIFT);
regval = getreg32(priv->base + STM32_QUADSPI_CCR_OFFSET); /* Communication Configuration Register */
spiinfo("CCR:%08x\n", regval);
spiinfo(" INST:%02x IMODE:%d ADMODE:%d ADSIZE:%d ABMODE:%d\n"
" ABSIZE:%d DCYC:%d DMODE:%d FMODE:%d\n"
" SIOO:%1d DDRM:%1d\n",
(regval & QSPI_CCR_INSTRUCTION_MASK) >> QSPI_CCR_INSTRUCTION_SHIFT,
(regval & QSPI_CCR_IMODE_MASK) >> QSPI_CCR_IMODE_SHIFT,
(regval & QSPI_CCR_ADMODE_MASK) >> QSPI_CCR_ADMODE_SHIFT,
(regval & QSPI_CCR_ADSIZE_MASK) >> QSPI_CCR_ABSIZE_SHIFT,
(regval & QSPI_CCR_ABMODE_MASK) >> QSPI_CCR_ABMODE_SHIFT,
(regval & QSPI_CCR_ABSIZE_MASK) >> QSPI_CCR_ABSIZE_SHIFT,
(regval & QSPI_CCR_DCYC_MASK) >> QSPI_CCR_DCYC_SHIFT,
(regval & QSPI_CCR_DMODE_MASK) >> QSPI_CCR_DMODE_SHIFT,
(regval & QSPI_CCR_FMODE_MASK) >> QSPI_CCR_FMODE_SHIFT,
(regval & QSPI_CCR_SIOO) ? 1 : 0,
(regval & QSPI_CCR_DDRM) ? 1 : 0);
regval = getreg32(priv->base + STM32_QUADSPI_SR_OFFSET); /* Status Register */
spiinfo("SR:%08x\n", regval);
spiinfo(" TEF:%1d TCF:%1d FTF:%1d SMF:%1d TOF:%1d BUSY:%1d FLEVEL:%d\n",
(regval & QSPI_SR_TEF) ? 1 : 0,
(regval & QSPI_SR_TCF) ? 1 : 0,
(regval & QSPI_SR_FTF) ? 1 : 0,
(regval & QSPI_SR_SMF) ? 1 : 0,
(regval & QSPI_SR_TOF) ? 1 : 0,
(regval & QSPI_SR_BUSY) ? 1 : 0,
(regval & QSPI_SR_FLEVEL_MASK) >> QSPI_SR_FLEVEL_SHIFT);
#else
spiinfo(" CR:%08x DCR:%08x CCR:%08x SR:%08x\n",
getreg32(priv->base + STM32_QUADSPI_CR_OFFSET), /* Control Register */
getreg32(priv->base + STM32_QUADSPI_DCR_OFFSET), /* Device Configuration Register */
getreg32(priv->base + STM32_QUADSPI_CCR_OFFSET), /* Communication Configuration Register */
getreg32(priv->base + STM32_QUADSPI_SR_OFFSET)); /* Status Register */
spiinfo(" DLR:%08x ABR:%08x PSMKR:%08x PSMAR:%08x\n",
getreg32(priv->base + STM32_QUADSPI_DLR_OFFSET), /* Data Length Register */
getreg32(priv->base + STM32_QUADSPI_ABR_OFFSET), /* Alternate Bytes Register */
getreg32(priv->base + STM32_QUADSPI_PSMKR_OFFSET), /* Polling Status mask Register */
getreg32(priv->base + STM32_QUADSPI_PSMAR_OFFSET)); /* Polling Status match Register */
spiinfo(" PIR:%08x LPTR:%08x\n",
getreg32(priv->base + STM32_QUADSPI_PIR_OFFSET), /* Polling Interval Register */
getreg32(priv->base + STM32_QUADSPI_LPTR_OFFSET)); /* Low-Power Timeout Register */
(void)regval;
#endif
}
#endif
#if defined(CONFIG_DEBUG_SPI_INFO) && defined(CONFIG_DEBUG_GPIO)
QUADSPI_RAMFUNC void qspi_dumpgpioconfig(const char *msg)
{
uint32_t regval;
spiinfo("%s:\n", msg);
/* Port B */
regval = getreg32(STM32_GPIOB_MODER);
spiinfo("B_MODER:%08x\n", regval);
regval = getreg32(STM32_GPIOB_OTYPER);
spiinfo("B_OTYPER:%08x\n", regval);
regval = getreg32(STM32_GPIOB_OSPEED);
spiinfo("B_OSPEED:%08x\n", regval);
regval = getreg32(STM32_GPIOB_PUPDR);
spiinfo("B_PUPDR:%08x\n", regval);
regval = getreg32(STM32_GPIOB_AFRL);
spiinfo("B_AFRL:%08x\n", regval);
regval = getreg32(STM32_GPIOB_AFRH);
spiinfo("B_AFRH:%08x\n", regval);
/* Port D */
regval = getreg32(STM32_GPIOD_MODER);
spiinfo("D_MODER:%08x\n", regval);
regval = getreg32(STM32_GPIOD_OTYPER);
spiinfo("D_OTYPER:%08x\n", regval);
regval = getreg32(STM32_GPIOD_OSPEED);
spiinfo("D_OSPEED:%08x\n", regval);
regval = getreg32(STM32_GPIOD_PUPDR);
spiinfo("D_PUPDR:%08x\n", regval);
regval = getreg32(STM32_GPIOD_AFRL);
spiinfo("D_AFRL:%08x\n", regval);
regval = getreg32(STM32_GPIOD_AFRH);
spiinfo("D_AFRH:%08x\n", regval);
/* Port E */
regval = getreg32(STM32_GPIOE_MODER);
spiinfo("E_MODER:%08x\n", regval);
regval = getreg32(STM32_GPIOE_OTYPER);
spiinfo("E_OTYPER:%08x\n", regval);
regval = getreg32(STM32_GPIOE_OSPEED);
spiinfo("E_OSPEED:%08x\n", regval);
regval = getreg32(STM32_GPIOE_PUPDR);
spiinfo("E_PUPDR:%08x\n", regval);
regval = getreg32(STM32_GPIOE_AFRL);
spiinfo("E_AFRL:%08x\n", regval);
regval = getreg32(STM32_GPIOE_AFRH);
spiinfo("E_AFRH:%08x\n", regval);
}
#endif
#ifdef CONFIG_STM32H7_QSPI_DMADEBUG
/****************************************************************************
* Name: qspi_dma_sampleinit
*
* Description:
* Initialize sampling of DMA registers
*
* Input Parameters:
* priv - QSPI driver instance
*
* Returned Value:
* None
*
****************************************************************************/
QUADSPI_RAMFUNC void qspi_dma_sampleinit(struct stm32h7_qspidev_s *priv)
{
/* Put contents of register samples into a known state */
memset(priv->dmaregs, 0xff,
DMA_NSAMPLES * sizeof(struct stm32h7_dmaregs_s));
/* Then get the initial samples */
stm32h7_dmasample(priv->dmach, &priv->dmaregs[DMA_INITIAL]);
}
/****************************************************************************
* Name: qspi_dma_sampledone
*
* Description:
* Dump sampled DMA registers
*
* Input Parameters:
* priv - QSPI driver instance
*
* Returned Value:
* None
*
****************************************************************************/
QUADSPI_RAMFUNC void qspi_dma_sampledone(struct stm32h7_qspidev_s *priv)
{
/* Sample the final registers */
stm32h7_dmasample(priv->dmach, &priv->dmaregs[DMA_END_TRANSFER]);
/* Then dump the sampled DMA registers */
/* Initial register values */
stm32h7_dmadump(priv->dmach, &priv->dmaregs[DMA_INITIAL],
"Initial Registers");
/* Register values after DMA setup */
stm32h7_dmadump(priv->dmach, &priv->dmaregs[DMA_AFTER_SETUP],
"After DMA Setup");
/* Register values after DMA start */
stm32h7_dmadump(priv->dmach, &priv->dmaregs[DMA_AFTER_START],
"After DMA Start");
/* Register values at the time of the TX and RX DMA callbacks
* -OR- DMA timeout.
*
* If the DMA timed out, then there will not be any RX DMA
* callback samples. There is probably no TX DMA callback
* samples either, but we don't know for sure.
*/
if (priv->result == -ETIMEDOUT) {
stm32h7_dmadump(priv->dmach, &priv->dmaregs[DMA_TIMEOUT],
"At DMA timeout");
} else {
stm32h7_dmadump(priv->dmach, &priv->dmaregs[DMA_CALLBACK],
"At DMA callback");
}
stm32h7_dmadump(priv->dmach, &priv->dmaregs[DMA_END_TRANSFER],
"At End-of-Transfer");
}
#endif
/****************************************************************************
* Name: qspi_setupxctnfromcmd
*
* Description:
* Setup our transaction descriptor from a command info structure
*
* Input Parameters:
* xctn - the transaction descriptor we setup
* cmdinfo - the command info (originating from the MTD device)
*
* Returned Value:
* OK, or -errno if invalid
*
****************************************************************************/
QUADSPI_RAMFUNC int qspi_setupxctnfromcmd(struct qspi_xctnspec_s *xctn,
const struct qspi_cmdinfo_s *cmdinfo)
{
DEBUGASSERT(xctn != NULL && cmdinfo != NULL);
#ifdef CONFIG_DEBUG_SPI_INFO
spiinfo("Transfer:\n");
spiinfo(" flags: %02x\n", cmdinfo->flags);
spiinfo(" cmd: %04x\n", cmdinfo->cmd);
if (QSPICMD_ISADDRESS(cmdinfo->flags)) {
spiinfo(" address/length: %08lx/%d\n",
(unsigned long)cmdinfo->addr, cmdinfo->addrlen);
}
if (QSPICMD_ISDATA(cmdinfo->flags)) {
spiinfo(" %s Data:\n",
QSPICMD_ISWRITE(cmdinfo->flags) ? "Write" : "Read");
spiinfo(" buffer/length: %p/%d\n",
cmdinfo->buffer, cmdinfo->buflen);
}
#endif
DEBUGASSERT(cmdinfo->cmd < 256);
/* Specify the instruction as per command info */
/* XXX III instruction mode, single dual quad option bits */
if (QSPICMD_ISIQUAD(cmdinfo->flags)) {
xctn->instrmode = CCR_IMODE_QUAD;
} else if (QSPICMD_ISIDUAL(cmdinfo->flags)) {
xctn->instrmode = CCR_IMODE_DUAL;
} else {
xctn->instrmode = CCR_IMODE_SINGLE;
}
xctn->instr = cmdinfo->cmd;
/* XXX III option bits for 'send instruction only once' */
xctn->issioo = 0;
/* XXX III options for alt bytes, dummy cycles */
xctn->altbytesmode = CCR_ABMODE_NONE;
xctn->altbytessize = CCR_ABSIZE_8;
xctn->altbytes = 0;
xctn->dummycycles = 0;
/* Specify the address size as needed */
if (QSPICMD_ISADDRESS(cmdinfo->flags)) {
/* XXX III address mode mode, single, dual, quad option bits */
xctn->addrmode = CCR_ADMODE_SINGLE;
if (cmdinfo->addrlen == 1) {
xctn->addrsize = CCR_ADSIZE_8;
} else if (cmdinfo->addrlen == 2) {
xctn->addrsize = CCR_ADSIZE_16;
} else if (cmdinfo->addrlen == 3) {
xctn->addrsize = CCR_ADSIZE_24;
} else if (cmdinfo->addrlen == 4) {
xctn->addrsize = CCR_ADSIZE_32;
} else {
return -EINVAL;
}
xctn->addr = cmdinfo->addr;
} else {
xctn->addrmode = CCR_ADMODE_NONE;
xctn->addrsize = 0;
xctn->addr = cmdinfo->addr;
}
/* Specify the data as needed */
xctn->buffer = cmdinfo->buffer;
if (QSPICMD_ISDATA(cmdinfo->flags)) {
/* XXX III data mode mode, single, dual, quad option bits */
xctn->datamode = CCR_DMODE_SINGLE;
xctn->datasize = cmdinfo->buflen;
/* XXX III double data rate option bits */
xctn->isddr = 0;
} else {
xctn->datamode = CCR_DMODE_NONE;
xctn->datasize = 0;
xctn->isddr = 0;
}
#if defined(CONFIG_STM32H7_QSPI_INTERRUPTS)
xctn->function = QSPICMD_ISWRITE(cmdinfo->flags) ? CCR_FMODE_INDWR :
CCR_FMODE_INDRD;
xctn->disposition = - EIO;
xctn->idxnow = 0;
#endif
return OK;
}
/****************************************************************************
* Name: qspi_setupxctnfrommem
*
* Description:
* Setup our transaction descriptor from a memory info structure
*
* Input Parameters:
* xctn - the transaction descriptor we setup
* meminfo - the memory info (originating from the MTD device)
*
* Returned Value:
* OK, or -errno if invalid
*
****************************************************************************/
QUADSPI_RAMFUNC int qspi_setupxctnfrommem(struct qspi_xctnspec_s *xctn,
const struct qspi_meminfo_s *meminfo)
{
DEBUGASSERT(xctn != NULL && meminfo != NULL);
#ifdef CONFIG_DEBUG_SPI_INFO
spiinfo("Transfer:\n");
spiinfo(" flags: %02x\n", meminfo->flags);
spiinfo(" cmd: %04x\n", meminfo->cmd);
spiinfo(" address/length: %08lx/%d\n",
(unsigned long)meminfo->addr, meminfo->addrlen);
spiinfo(" %s Data:\n", QSPIMEM_ISWRITE(meminfo->flags) ?
"Write" : "Read");
spiinfo(" buffer/length: %p/%d\n", meminfo->buffer, meminfo->buflen);
#endif
DEBUGASSERT(meminfo->cmd < 256);
/* Specify the instruction as per command info */
/* XXX III instruction mode, single dual quad option bits */
if (QSPIMEM_ISIQUAD(meminfo->flags)) {
xctn->instrmode = CCR_IMODE_QUAD;
} else if (QSPIMEM_ISIDUAL(meminfo->flags)) {
xctn->instrmode = CCR_IMODE_DUAL;
} else {
xctn->instrmode = CCR_IMODE_SINGLE;
}
xctn->instr = meminfo->cmd;
/* XXX III option bits for 'send instruction only once' */
xctn->issioo = 0;
/* XXX III options for alt bytes */
xctn->altbytesmode = CCR_ABMODE_NONE;
xctn->altbytessize = CCR_ABSIZE_8;
xctn->altbytes = 0;
xctn->dummycycles = meminfo->dummies;
/* Specify the address size as needed */
/* XXX III there should be a separate flags for single/dual/quad for each
* of i,a,d
*/
if (QSPIMEM_ISDUALIO(meminfo->flags)) {
xctn->addrmode = CCR_ADMODE_DUAL;
} else if (QSPIMEM_ISQUADIO(meminfo->flags)) {
xctn->addrmode = CCR_ADMODE_QUAD;
} else {
xctn->addrmode = CCR_ADMODE_SINGLE;
}
if (meminfo->addrlen == 1) {
xctn->addrsize = CCR_ADSIZE_8;
} else if (meminfo->addrlen == 2) {
xctn->addrsize = CCR_ADSIZE_16;
} else if (meminfo->addrlen == 3) {
xctn->addrsize = CCR_ADSIZE_24;
} else if (meminfo->addrlen == 4) {
xctn->addrsize = CCR_ADSIZE_32;
} else {
return -EINVAL;
}
xctn->addr = meminfo->addr;
/* Specify the data as needed */
xctn->buffer = meminfo->buffer;
/* XXX III there should be a separate flags for single/dual/quad for each
* of i,a,d
*/
if (QSPIMEM_ISDUALIO(meminfo->flags)) {
xctn->datamode = CCR_DMODE_DUAL;
} else if (QSPIMEM_ISQUADIO(meminfo->flags)) {
xctn->datamode = CCR_DMODE_QUAD;
} else {
xctn->datamode = CCR_DMODE_SINGLE;
}
xctn->datasize = meminfo->buflen;
/* XXX III double data rate option bits */
xctn->isddr = 0;
#if defined(CONFIG_STM32H7_QSPI_INTERRUPTS)
xctn->function = QSPIMEM_ISWRITE(meminfo->flags) ? CCR_FMODE_INDWR :
CCR_FMODE_INDRD;
xctn->disposition = - EIO;
xctn->idxnow = 0;
#endif
return OK;
}
/****************************************************************************
* Name: qspi_waitstatusflags
*
* Description:
* Spin wait for specified status flags to be set as desired
*
* Input Parameters:
* priv - The QSPI controller to dump
* mask - bits to check, can be multiple
* polarity - true wait if any set, false to wait if all reset
*
* Returned Value:
* None
*
****************************************************************************/
QUADSPI_RAMFUNC static void qspi_waitstatusflags(struct stm32h7_qspidev_s *priv,
uint32_t mask, int polarity)
{
uint32_t regval;
if (polarity) {
while (!((regval = qspi_getreg(priv, STM32_QUADSPI_SR_OFFSET)) & mask))
;
} else {
while (((regval = qspi_getreg(priv, STM32_QUADSPI_SR_OFFSET)) & mask))
;
}
}
/****************************************************************************
* Name: qspi_abort
*
* Description:
* Abort any transaction in progress
*
* Input Parameters:
* priv - The QSPI controller to dump
*
* Returned Value:
* None
*
****************************************************************************/
QUADSPI_RAMFUNC static void qspi_abort(struct stm32h7_qspidev_s *priv)
{
uint32_t regval;
regval = qspi_getreg(priv, STM32_QUADSPI_CR_OFFSET);
regval |= QSPI_CR_ABORT;
qspi_putreg(priv, regval, STM32_QUADSPI_CR_OFFSET);
}
/****************************************************************************
* Name: qspi_ccrconfig
*
* Description:
* Do common Communications Configuration Register setup
*
* Input Parameters:
* priv - The QSPI controller to dump
* xctn - the transaction descriptor; CCR setup
* fctn - 'functional mode'; 0=indwrite, 1=indread, 2=autopoll, 3=memmmap
*
* Returned Value:
* None
*
****************************************************************************/
QUADSPI_RAMFUNC static void qspi_ccrconfig(struct stm32h7_qspidev_s *priv,
struct qspi_xctnspec_s *xctn, uint8_t fctn)
{
uint32_t regval;
/* If we have data, and it's not memory mapped, write the length */
if (CCR_DMODE_NONE != xctn->datamode && CCR_FMODE_MEMMAP != fctn) {
qspi_putreg(priv, xctn->datasize - 1, STM32_QUADSPI_DLR_OFFSET);
}
/* If we have alternate bytes, stick them in now */
if (CCR_ABMODE_NONE != xctn->altbytesmode) {
qspi_putreg(priv, xctn->altbytes, STM32_QUADSPI_ABR_OFFSET);
}
/* Build the CCR value and set it */
regval = QSPI_CCR_INST(xctn->instr) | QSPI_CCR_IMODE(xctn->instrmode)
| QSPI_CCR_ADMODE(xctn->addrmode) | QSPI_CCR_ADSIZE(xctn->addrsize)
| QSPI_CCR_ABMODE(xctn->altbytesmode) | QSPI_CCR_ABSIZE(xctn->altbytessize)
| QSPI_CCR_DCYC(xctn->dummycycles) | QSPI_CCR_DMODE(xctn->datamode)
| QSPI_CCR_FMODE(fctn) | (xctn->isddr ? QSPI_CCR_SIOO : 0)
| (xctn->issioo ? QSPI_CCR_DDRM : 0);
qspi_putreg(priv, regval, STM32_QUADSPI_CCR_OFFSET);
/* If we have and need and address, set that now, too */
if (CCR_ADMODE_NONE != xctn->addrmode && CCR_FMODE_MEMMAP != fctn) {
qspi_putreg(priv, xctn->addr, STM32_QUADSPI_AR_OFFSET);
}
}
#if defined(CONFIG_STM32H7_QSPI_INTERRUPTS)
/****************************************************************************
* Name: qspi0_interrupt
*
* Description:
* Interrupt handler; we handle all QSPI cases -- reads, writes,
* automatic status polling, etc.
*
* Input Parameters:
* irq -
* context -
*
* Returned Value:
* OK means we handled it
*
****************************************************************************/
static int qspi0_interrupt(int irq, void *context, FAR void *arg)
{
uint32_t status;
uint32_t cr;
uint32_t regval;
/* Let's find out what is going on */
status = qspi_getreg(&g_qspi0dev, STM32_QUADSPI_SR_OFFSET);
cr = qspi_getreg(&g_qspi0dev, STM32_QUADSPI_CR_OFFSET);
/* Is it 'FIFO Threshold'? */
if ((status & QSPI_SR_FTF) && (cr & QSPI_CR_FTIE)) {
volatile uint32_t *datareg =
(volatile uint32_t *)(g_qspi0dev.base + STM32_QUADSPI_DR_OFFSET);
if (g_qspi0dev.xctn->function == CCR_FMODE_INDWR) {
/* Write data until we have no more or have no place to put it */
while (((regval = qspi_getreg(
&g_qspi0dev, STM32_QUADSPI_SR_OFFSET)) & QSPI_SR_FTF) != 0) {
if (g_qspi0dev.xctn->idxnow < g_qspi0dev.xctn->datasize) {
*(volatile uint8_t *)datareg =
((uint8_t *)g_qspi0dev.xctn->buffer)
[g_qspi0dev.xctn->idxnow];
++g_qspi0dev.xctn->idxnow;
} else {
/* Fresh out of data to write */
break;
}
}
} else if (g_qspi0dev.xctn->function == CCR_FMODE_INDRD) {
/* Read data until we have no more or have no place to put it */
while (((regval = qspi_getreg(
&g_qspi0dev, STM32_QUADSPI_SR_OFFSET)) & QSPI_SR_FTF) != 0) {
if (g_qspi0dev.xctn->idxnow < g_qspi0dev.xctn->datasize) {
((uint8_t *)g_qspi0dev.xctn->buffer)
[g_qspi0dev.xctn->idxnow] = *(volatile uint8_t *)datareg;
++g_qspi0dev.xctn->idxnow;
} else {
/* no room at the inn */
break;
}
}
}
}
/* Is it 'Transfer Complete'? */
if ((status & QSPI_SR_TCF) && (cr & QSPI_CR_TCIE)) {
/* Acknowledge interrupt */
qspi_putreg(&g_qspi0dev, QSPI_FCR_CTCF, STM32_QUADSPI_FCR_OFFSET);
/* Disable the QSPI FIFO Threshold, Transfer Error and Transfer
* complete Interrupts
*/
regval = qspi_getreg(&g_qspi0dev, STM32_QUADSPI_CR_OFFSET);
regval &= ~(QSPI_CR_TEIE | QSPI_CR_TCIE | QSPI_CR_FTIE);
qspi_putreg(&g_qspi0dev, regval, STM32_QUADSPI_CR_OFFSET);
/* Do the last bit of read if needed */
if (g_qspi0dev.xctn->function == CCR_FMODE_INDRD) {
volatile uint32_t *datareg =
(volatile uint32_t *)(g_qspi0dev.base + STM32_QUADSPI_DR_OFFSET);
/* Read any remaining data */
while (((regval = qspi_getreg(
&g_qspi0dev, STM32_QUADSPI_SR_OFFSET)) &
QSPI_SR_FLEVEL_MASK) != 0) {
if (g_qspi0dev.xctn->idxnow < g_qspi0dev.xctn->datasize) {
((uint8_t *)g_qspi0dev.xctn->buffer)
[g_qspi0dev.xctn->idxnow] = *(volatile uint8_t *)datareg;
++g_qspi0dev.xctn->idxnow;
} else {
/* No room at the inn */
break;
}
}
}
/* Use 'abort' to ditch any stray fifo contents and clear BUSY flag */
qspi_abort(&g_qspi0dev);
/* Set success status */
g_qspi0dev.xctn->disposition = OK;
/* Signal complete */
nxsem_post(&g_qspi0dev.op_sem);
}
/* Is it 'Status Match'? */
if ((status & QSPI_SR_SMF) && (cr & QSPI_CR_SMIE)) {
/* Acknowledge interrupt */
qspi_putreg(&g_qspi0dev, QSPI_FCR_CSMF, STM32_QUADSPI_FCR_OFFSET);
/* If 'automatic poll mode stop' is activated, we're done */
if (cr & QSPI_CR_APMS) {
/* Disable the QSPI Transfer Error and Status Match Interrupts */
regval = qspi_getreg(&g_qspi0dev, STM32_QUADSPI_CR_OFFSET);
regval &= ~(QSPI_CR_TEIE | QSPI_CR_SMIE);
qspi_putreg(&g_qspi0dev, regval, STM32_QUADSPI_CR_OFFSET);
/* Set success status */
g_qspi0dev.xctn->disposition = OK;
/* Signal complete */
nxsem_post(&g_qspi0dev.op_sem);
} else {
/* XXX if it's NOT auto stop; something needs to happen here;
* a callback?
*/
}
}
/* Is it' Transfer Error'? :( */
if ((status & QSPI_SR_TEF) && (cr & QSPI_CR_TEIE)) {
/* Acknowledge interrupt */
qspi_putreg(&g_qspi0dev, QSPI_FCR_CTEF, STM32_QUADSPI_FCR_OFFSET);
/* Disable all the QSPI Interrupts */
regval = qspi_getreg(&g_qspi0dev, STM32_QUADSPI_CR_OFFSET);
regval &= ~(QSPI_CR_TEIE | QSPI_CR_TCIE | QSPI_CR_FTIE |
QSPI_CR_SMIE | QSPI_CR_TOIE);
qspi_putreg(&g_qspi0dev, regval, STM32_QUADSPI_CR_OFFSET);
/* Set error status; 'transfer error' means that, in 'indirect mode',
* an invalid address is attempted to be accessed. 'Invalid' is
* presumably relative to the FSIZE field in CCR; the manual is not
* explicit, but what else could it be?
*/
g_qspi0dev.xctn->disposition = - EIO;
/* Signal complete */
nxsem_post(&g_qspi0dev.op_sem);
}
/* Is it 'Timeout'? */
if ((status & QSPI_SR_TOF) && (cr & QSPI_CR_TOIE)) {
/* Acknowledge interrupt */
qspi_putreg(&g_qspi0dev, QSPI_FCR_CTOF, STM32_QUADSPI_FCR_OFFSET);
/* XXX this interrupt simply means that, in 'memory mapped mode',
* the QSPI memory has not been accessed for a while, and the
* IP block was configured to automatically de-assert CS after
* a timeout. And now we're being informed that has happened.
*
* But who cares? If someone does, perhaps a user callback is
* appropriate, or some signal? Either way, realize the xctn
* member is /not/ valid, so you can't set the disposition
* field. Also, note signaling completion has no meaning here
* because in memory mapped mode no one holds the semaphore.
*/
}
return OK;
}
#elif defined(CONFIG_STM32H7_QSPI_DMA)
/****************************************************************************
* Name: qspi_dma_timeout
*
* Description:
* The watchdog timeout setup when a has expired without completion of a
* DMA.
*
* Input Parameters:
* argc - The number of arguments (should be 1)
* arg - The argument (state structure reference cast to uint32_t)
*
* Returned Value:
* None
*
* Assumptions:
* Always called from the interrupt level with interrupts disabled.
*
****************************************************************************/
QUADSPI_RAMFUNC void qspi_dma_timeout(int argc, uint32_t arg, ...)
{
struct stm32h7_qspidev_s *priv = (struct stm32h7_qspidev_s *)arg;
DEBUGASSERT(priv != NULL);
/* Sample DMA registers at the time of the timeout */
qspi_dma_sample(priv, DMA_CALLBACK);
/* Report timeout result, perhaps overwriting any failure reports from
* the TX callback.
*/
priv->result = -ETIMEDOUT;
/* Then wake up the waiting thread */
nxsem_post(&priv->dmawait);
}
/****************************************************************************
* Name: qspi_dma_callback
*
* Description:
* This callback function is invoked at the completion of the QSPI DMA.
*
* Input Parameters:
* handle - The DMA handler
* isr - source of the DMA interrupt
* arg - A pointer to the chip select structure
*
* Returned Value:
* None
*
****************************************************************************/
QUADSPI_RAMFUNC void qspi_dma_callback(DMA_HANDLE handle, uint8_t isr, void *arg)
{
struct stm32h7_qspidev_s *priv = (struct stm32h7_qspidev_s *)arg;
DEBUGASSERT(priv != NULL);
/* Cancel the watchdog timeout */
wd_cancel(priv->dmadog);
/* Sample DMA registers at the time of the callback */
qspi_dma_sample(priv, DMA_CALLBACK);
/* Report the result of the transfer only if the callback has not already
* reported an error.
*/
if (priv->result == -EBUSY) {
/* Save the result of the transfer if no error was previously
* reported
*/
if (isr & DMA_STREAM_TCIF_BIT) {
priv->result = OK;
} else if (isr & DMA_STREAM_TEIF_BIT) {
priv->result = -EIO;
} else {
priv->result = OK;
}
}
/* Then wake up the waiting thread */
nxsem_post(&priv->dmawait);
}
/****************************************************************************
* Name: qspi_regaddr
*
* Description:
* Return the address of an QSPI register
*
****************************************************************************/
static inline uintptr_t qspi_regaddr(struct stm32h7_qspidev_s *priv,
unsigned int offset)
{
return priv->base + offset;
}
/****************************************************************************
* Name: qspi_memory_dma
*
* Description:
* Perform one QSPI memory transfer using DMA
*
* Input Parameters:
* priv - Device-specific state data
* meminfo - Describes the memory transfer to be performed.
* xctn - Describes the transaction context.
*
* Returned Value:
* Zero (OK) on SUCCESS, a negated errno on value of failure
*
****************************************************************************/
QUADSPI_RAMFUNC int qspi_memory_dma(struct stm32h7_qspidev_s *priv,
struct qspi_meminfo_s *meminfo,
struct qspi_xctnspec_s *xctn)
{
uint32_t dmaflags;
uint32_t regval;
int ret;
/* Initialize register sampling */
qspi_dma_sampleinit(priv);
/* Determine DMA flags and setup the DMA */
if (QSPIMEM_ISWRITE(meminfo->flags)) {
/* Setup the DMA (memory-to-peripheral) */
dmaflags = (QSPI_DMA_PRIO | DMA_SCR_MSIZE_8BITS |
DMA_SCR_PSIZE_8BITS | DMA_SCR_MINC | DMA_SCR_DIR_M2P);
up_clean_dcache((uintptr_t)meminfo->buffer,
(uintptr_t)meminfo->buffer + meminfo->buflen);
} else {
/* Setup the DMA (peripheral-to-memory) */
dmaflags = (QSPI_DMA_PRIO | DMA_SCR_MSIZE_8BITS |
DMA_SCR_PSIZE_8BITS | DMA_SCR_MINC | DMA_SCR_DIR_P2M);
}
stm32_dmasetup(priv->dmach, qspi_regaddr(priv, STM32_QUADSPI_DR_OFFSET),
(uint32_t)meminfo->buffer, meminfo->buflen, dmaflags);
qspi_dma_sample(priv, DMA_AFTER_SETUP);
/* Enable the memory transfer */
regval = qspi_getreg(priv, STM32_QUADSPI_CR_OFFSET);
regval |= QSPI_CR_DMAEN;
qspi_putreg(priv, regval, STM32_QUADSPI_CR_OFFSET);
/* Set up the Communications Configuration Register as per command info */
qspi_ccrconfig(priv, xctn,
QSPIMEM_ISWRITE(meminfo->flags) ? CCR_FMODE_INDWR :
CCR_FMODE_INDRD);
/* Start the DMA */
priv->result = -EBUSY;
stm32_dmastart(priv->dmach, qspi_dma_callback, priv, false);
qspi_dma_sample(priv, DMA_AFTER_START);
/* Wait for DMA completion. This is done in a loop because there may be
* false alarm semaphore counts that cause nxsem_wait() not fail to wait
* or to wake-up prematurely (for example due to the receipt of a signal).
* We know that the DMA has completed when the result is anything other
* that -EBUSY.
*/
do {
/* Start (or re-start) the watchdog timeout */
ret = wd_start(priv->dmadog, DMA_TIMEOUT_TICKS,
qspi_dma_timeout, 1, (uint32_t)priv);
if (ret < 0) {
spierr("ERROR: wd_start failed: %d\n", ret);
}
/* Wait for the DMA complete */
ret = nxsem_wait(&priv->dmawait);
if (QSPIMEM_ISREAD(meminfo->flags)) {
up_invalidate_dcache((uintptr_t)meminfo->buffer,
(uintptr_t)meminfo->buffer + meminfo->buflen);
}
/* Cancel the watchdog timeout */
wd_cancel(priv->dmadog);
/* Check if we were awakened by an error of some kind */
if (ret < 0) {
/* EINTR is not a failure. That simply means that the wait
* was awakened by a signal.
*/
if (ret != -EINTR) {
DEBUGPANIC();
regval = qspi_getreg(priv, STM32_QUADSPI_CR_OFFSET);
regval &= ~QSPI_CR_DMAEN;
qspi_putreg(priv, regval, STM32_QUADSPI_CR_OFFSET);
return ret;
}
}
/* Note that we might be awakened before the wait is over due to
* residual counts on the semaphore. So, to handle, that case,
* we loop until something changes the DMA result to any value other
* than -EBUSY.
*/
} while (priv->result == -EBUSY);
/* Wait for Transfer complete, and not busy */
qspi_waitstatusflags(priv, QSPI_SR_TCF, 1);
qspi_waitstatusflags(priv, QSPI_SR_BUSY, 0);
MEMORY_SYNC();
/* Dump the sampled DMA registers */
qspi_dma_sampledone(priv);
/* Make sure that the DMA is stopped (it will be stopped automatically
* on normal transfers, but not necessarily when the transfer terminates
* on an error condition).
*/
stm32_dmastop(priv->dmach);
regval = qspi_getreg(priv, STM32_QUADSPI_CR_OFFSET);
regval &= ~QSPI_CR_DMAEN;
qspi_putreg(priv, regval, STM32_QUADSPI_CR_OFFSET);
/* Complain if the DMA fails */
if (priv->result) {
spierr("ERROR: DMA failed with result: %d\n", priv->result);
}
return priv->result;
}
#endif
#if !defined(CONFIG_STM32H7_QSPI_INTERRUPTS)
/****************************************************************************
* Name: qspi_receive_blocking
*
* Description:
* Do common data receive in a blocking (status polling) way
*
* Input Parameters:
* priv - The QSPI controller to dump
* xctn - the transaction descriptor
*
* Returned Value:
* OK, or -errno on error
*
****************************************************************************/
QUADSPI_RAMFUNC int qspi_receive_blocking(struct stm32h7_qspidev_s *priv,
struct qspi_xctnspec_s *xctn)
{
int ret = OK;
volatile uint32_t *datareg = (volatile uint32_t *)(priv->base
+ STM32_QUADSPI_DR_OFFSET);
uint8_t *dest = (uint8_t *) xctn->buffer;
uint32_t addrval;
uint32_t regval;
addrval = qspi_getreg(priv, STM32_QUADSPI_AR_OFFSET);
if (dest != NULL) {
/* Counter of remaining data */
uint32_t remaining = xctn->datasize;
/* Ensure CCR register specifies indirect read */
regval = qspi_getreg(priv, STM32_QUADSPI_CCR_OFFSET);
regval &= ~QSPI_CCR_FMODE_MASK;
regval |= QSPI_CCR_FMODE(CCR_FMODE_INDRD);
qspi_putreg(priv, regval, STM32_QUADSPI_CCR_OFFSET);
/* Start the transfer by re-writing the address in AR register */
qspi_putreg(priv, addrval, STM32_QUADSPI_AR_OFFSET);
/* Transfer loop */
while (remaining > 0) {
/* Wait for Fifo Threshold, or Transfer Complete, to read data */
qspi_waitstatusflags(priv, QSPI_SR_FTF | QSPI_SR_TCF, 1);
*dest = *(volatile uint8_t *) datareg;
dest++;
remaining--;
}
if (ret == OK) {
/* Wait for transfer complete, then clear it */
qspi_waitstatusflags(priv, QSPI_SR_TCF, 1);
qspi_putreg(priv, QSPI_FCR_CTCF, STM32_QUADSPI_FCR_OFFSET);
/* Use Abort to clear the busy flag, and ditch any extra bytes in
* fifo
*/
qspi_abort(priv);
}
} else {
ret = -EINVAL;
}
return ret;
}
/****************************************************************************
* Name: qspi_transmit_blocking
*
* Description:
* Do common data transmit in a blocking (status polling) way
*
* Input Parameters:
* priv - The QSPI controller to dump
* xctn - the transaction descriptor
*
* Returned Value:
* OK, or -errno on error
*
****************************************************************************/
QUADSPI_RAMFUNC int qspi_transmit_blocking(struct stm32h7_qspidev_s *priv,
struct qspi_xctnspec_s *xctn)
{
int ret = OK;
volatile uint32_t *datareg = (volatile uint32_t *)(priv->base
+ STM32_QUADSPI_DR_OFFSET);
uint8_t *src = (uint8_t *) xctn->buffer;
if (src != NULL) {
/* Counter of remaining data */
uint32_t remaining = xctn->datasize;
/* Transfer loop */
while (remaining > 0) {
/* Wait for Fifo Threshold to write data */
qspi_waitstatusflags(priv, QSPI_SR_FTF, 1);
*(volatile uint8_t *) datareg = *src++;
remaining--;
}
if (ret == OK) {
/* Wait for transfer complete, then clear it */
qspi_waitstatusflags(priv, QSPI_SR_TCF, 1);
qspi_putreg(priv, QSPI_FCR_CTCF, STM32_QUADSPI_FCR_OFFSET);
/* Use Abort to clear the Busy flag */
qspi_abort(priv);
}
} else {
ret = -EINVAL;
}
return ret;
}
#endif
/****************************************************************************
* Name: qspi_lock
*
* Description:
* On QSPI buses where there are multiple devices, it will be necessary to
* lock QSPI to have exclusive access to the buses for a sequence of
* transfers. The bus should be locked before the chip is selected. After
* locking the QSPI bus, the caller should then also call the setfrequency,
* setbits, and setmode methods to make sure that the QSPI is properly
* configured for the device. If the QSPI bus is being shared, then it
* may have been left in an incompatible state.
*
* Input Parameters:
* dev - Device-specific state data
* lock - true: Lock QSPI bus, false: unlock QSPI bus
*
* Returned Value:
* None
*
****************************************************************************/
QUADSPI_RAMFUNC int qspi_lock(struct qspi_dev_s *dev, bool lock)
{
#if 0 //semaphore can't work as ramfunc
struct stm32h7_qspidev_s *priv = (struct stm32h7_qspidev_s *)dev;
int ret;
spiinfo("lock=%d\n", lock);
if (lock) {
/* Take the semaphore (perhaps waiting) */
do {
ret = nxsem_wait(&priv->exclsem);
/* The only case that an error should occur here is if the wait
* was awakened by a signal.
*/
DEBUGASSERT(ret == OK || ret == -EINTR);
} while (ret == -EINTR);
} else {
ret = nxsem_post(&priv->exclsem);
}
return ret;
#endif
return 0;
}
/****************************************************************************
* Name: qspi_setfrequency
*
* Description:
* Set the QSPI frequency.
*
* Input Parameters:
* dev - Device-specific state data
* frequency - The QSPI frequency requested
*
* Returned Value:
* Returns the actual frequency selected
*
****************************************************************************/
QUADSPI_RAMFUNC uint32_t qspi_setfrequency(struct qspi_dev_s *dev,
uint32_t frequency)
{
struct stm32h7_qspidev_s *priv = (struct stm32h7_qspidev_s *) dev;
uint32_t actual;
uint32_t prescaler;
uint32_t regval;
if (priv->memmap) {
/* XXX we have no better return here, but the caller will find out
* in their subsequent calls.
*/
return 0;
}
spiinfo("frequency=%d\n", frequency);
DEBUGASSERT(priv);
/* Wait till BUSY flag reset */
qspi_abort(priv);
qspi_waitstatusflags(priv, QSPI_SR_BUSY, 0);
/* Check if the requested frequency is the same as the frequency
* selection
*/
if (priv->frequency == frequency) {
/* We are already at this frequency. Return the actual. */
return priv->actual;
}
/* Configure QSPI to a frequency as close as possible to the requested
* frequency.
*
* QSCK frequency = QSPI_CLK_FREQUENCY / prescaler, or
* prescaler = QSPI_CLK_FREQUENCY / frequency
*
* Where prescaler can have the range 1 to 256 and the
* STM32_QUADSPI_CR_OFFSET register field holds prescaler - 1.
* NOTE that a "ceiling" type of calculation is performed.
* 'frequency' is treated as a not-to-exceed value.
*/
prescaler = (frequency + QSPI_CLK_FREQUENCY - 1) / frequency;
/* Make sure that the divider is within range */
if (prescaler < 1) {
prescaler = 1;
} else if (prescaler > 256) {
prescaler = 256;
}
/* Save the new prescaler value (minus one) */
regval = qspi_getreg(priv, STM32_QUADSPI_CR_OFFSET);
regval &= ~(QSPI_CR_PRESCALER_MASK);
regval |= (prescaler - 1) << QSPI_CR_PRESCALER_SHIFT;
qspi_putreg(priv, regval, STM32_QUADSPI_CR_OFFSET);
/* Calculate the new actual frequency */
actual = QSPI_CLK_FREQUENCY / prescaler;
spiinfo("prescaler=%d actual=%d\n", prescaler, actual);
/* Save the frequency setting */
priv->frequency = frequency;
priv->actual = actual;
spiinfo("Frequency %d->%d\n", frequency, actual);
return actual;
}
/****************************************************************************
* Name: qspi_setmode
*
* Description:
* Set the QSPI mode. Optional. See enum qspi_mode_e for mode definitions.
* NOTE: the STM32H7 QSPI supports only modes 0 and 3.
*
* Input Parameters:
* dev - Device-specific state data
* mode - The QSPI mode requested
*
* Returned Value:
* none
*
****************************************************************************/
QUADSPI_RAMFUNC void qspi_setmode(struct qspi_dev_s *dev, enum qspi_mode_e mode)
{
struct stm32h7_qspidev_s *priv = (struct stm32h7_qspidev_s *) dev;
uint32_t regval;
if (priv->memmap) {
/* XXX we have no better return here, but the caller will find out
* in their subsequent calls.
*/
return;
}
spiinfo("mode=%d\n", mode);
/* Has the mode changed? */
if (mode != priv->mode) {
/* Yes... Set the mode appropriately:
*
* QSPI CPOL CPHA
* MODE
* 0 0 0
* 1 0 1
* 2 1 0
* 3 1 1
*/
regval = qspi_getreg(priv, STM32_QUADSPI_DCR_OFFSET);
regval &= ~(QSPI_DCR_CKMODE);
switch (mode) {
case QSPIDEV_MODE0: /* CPOL=0; CPHA=0 */
break;
case QSPIDEV_MODE3: /* CPOL=1; CPHA=1 */
regval |= (QSPI_DCR_CKMODE);
break;
case QSPIDEV_MODE1: /* CPOL=0; CPHA=1 */
case QSPIDEV_MODE2: /* CPOL=1; CPHA=0 */
spiinfo("unsupported mode=%d\n", mode);
default:
DEBUGASSERT(FALSE);
return;
}
qspi_putreg(priv, regval, STM32_QUADSPI_DCR_OFFSET);
spiinfo("DCR=%08x\n", regval);
/* Save the mode so that subsequent re-configurations will be faster */
priv->mode = mode;
}
}
/****************************************************************************
* Name: qspi_setbits
*
* Description:
* Set the number if bits per word.
* NOTE: the STM32H7 QSPI only supports 8 bits, so this does nothing.
*
* Input Parameters:
* dev - Device-specific state data
* nbits - The number of bits requests
*
* Returned Value:
* none
*
****************************************************************************/
QUADSPI_RAMFUNC void qspi_setbits(struct qspi_dev_s *dev, int nbits)
{
/* Not meaningful for the STM32H7x6 */
if (8 != nbits) {
spiinfo("unsupported nbits=%d\n", nbits);
DEBUGASSERT(FALSE);
}
}
/****************************************************************************
* Name: qspi_command
*
* Description:
* Perform one QSPI data transfer
*
* Input Parameters:
* dev - Device-specific state data
* cmdinfo - Describes the command transfer to be performed.
*
* Returned Value:
* Zero (OK) on SUCCESS, a negated errno on value of failure
*
****************************************************************************/
QUADSPI_RAMFUNC int qspi_command(struct qspi_dev_s *dev,
struct qspi_cmdinfo_s *cmdinfo)
{
struct stm32h7_qspidev_s *priv = (struct stm32h7_qspidev_s *) dev;
struct qspi_xctnspec_s xctn;
int ret;
/* Reject commands issued while in memory mapped mode, which will
* automatically cancel the memory mapping. You must exit the
* memory mapped mode first.
*/
if (priv->memmap) {
return -EBUSY;
}
/* Set up the transaction descriptor as per command info */
ret = qspi_setupxctnfromcmd(&xctn, cmdinfo);
if (OK != ret) {
return ret;
}
/* Prepare for transaction */
/* Wait 'till non-busy */
qspi_abort(priv);
qspi_waitstatusflags(priv, QSPI_SR_BUSY, 0);
/* Clear flags */
qspi_putreg(priv,
QSPI_FCR_CTEF | QSPI_FCR_CTCF | QSPI_FCR_CSMF | QSPI_FCR_CTOF,
STM32_QUADSPI_FCR_OFFSET);
#ifdef CONFIG_STM32H7_QSPI_INTERRUPTS
/* interrupt mode will need access to the transaction context */
priv->xctn = &xctn;
if (QSPICMD_ISDATA(cmdinfo->flags)) {
DEBUGASSERT(cmdinfo->buffer != NULL && cmdinfo->buflen > 0);
DEBUGASSERT(IS_ALIGNED(cmdinfo->buffer));
if (QSPICMD_ISWRITE(cmdinfo->flags)) {
uint32_t regval;
/* Set up the Communications Configuration Register as per command
* info
*/
qspi_ccrconfig(priv, &xctn, CCR_FMODE_INDWR);
/* Enable 'Transfer Error' 'FIFO Threshhold' and
* 'Transfer Complete' interrupts.
*/
regval = qspi_getreg(priv, STM32_QUADSPI_CR_OFFSET);
regval |= (QSPI_CR_TEIE | QSPI_CR_FTIE | QSPI_CR_TCIE);
qspi_putreg(priv, regval, STM32_QUADSPI_CR_OFFSET);
} else {
uint32_t regval;
uint32_t addrval;
addrval = qspi_getreg(priv, STM32_QUADSPI_AR_OFFSET);
/* Set up the Communications Configuration Register as per command
* info
*/
qspi_ccrconfig(priv, &xctn, CCR_FMODE_INDRD);
/* Start the transfer by re-writing the address in AR register */
qspi_putreg(priv, addrval, STM32_QUADSPI_AR_OFFSET);
/* Enable 'Transfer Error' 'FIFO Threshhold' and
* 'Transfer Complete' interrupts
*/
regval = qspi_getreg(priv, STM32_QUADSPI_CR_OFFSET);
regval |= (QSPI_CR_TEIE | QSPI_CR_FTIE | QSPI_CR_TCIE);
qspi_putreg(priv, regval, STM32_QUADSPI_CR_OFFSET);
}
} else {
uint32_t regval;
/* We have no data phase, the command will execute as soon as we emit
* the CCR
*/
/* Enable 'Transfer Error' and 'Transfer Complete' interrupts */
regval = qspi_getreg(priv, STM32_QUADSPI_CR_OFFSET);
regval |= (QSPI_CR_TEIE | QSPI_CR_TCIE);
qspi_putreg(priv, regval, STM32_QUADSPI_CR_OFFSET);
/* Set up the Communications Configuration Register as per command
* info
*/
qspi_ccrconfig(priv, &xctn, CCR_FMODE_INDRD);
}
/* Wait for the interrupt routine to finish it's magic */
nxsem_wait(&priv->op_sem);
MEMORY_SYNC();
/* Convey the result */
ret = xctn.disposition;
/* because command transfers are so small, we're not going to use
* DMA for them, only interrupts or polling
*/
#else
/* Polling mode */
/* Set up the Communications Configuration Register as per command info */
qspi_ccrconfig(priv, &xctn, CCR_FMODE_INDWR);
/* That may be it, unless there is also data to transfer */
if (QSPICMD_ISDATA(cmdinfo->flags)) {
DEBUGASSERT(cmdinfo->buffer != NULL && cmdinfo->buflen > 0);
DEBUGASSERT(IS_ALIGNED(cmdinfo->buffer));
if (QSPICMD_ISWRITE(cmdinfo->flags)) {
ret = qspi_transmit_blocking(priv, &xctn);
} else {
ret = qspi_receive_blocking(priv, &xctn);
}
MEMORY_SYNC()
;
} else {
ret = OK;
}
/* Wait for Transfer complete, and not busy
if (QSPICMD_ISDATA(cmdinfo->flags))
{
qspi_waitstatusflags(priv, QSPI_SR_TCF, 1);
}
*/
qspi_waitstatusflags(priv, QSPI_SR_BUSY, 0);
#endif
return ret;
}
/****************************************************************************
* Name: qspi_memory
*
* Description:
* Perform one QSPI memory transfer
*
* Input Parameters:
* dev - Device-specific state data
* meminfo - Describes the memory transfer to be performed.
*
* Returned Value:
* Zero (OK) on SUCCESS, a negated errno on value of failure
*
****************************************************************************/
QUADSPI_RAMFUNC int qspi_memory(struct qspi_dev_s *dev,
struct qspi_meminfo_s *meminfo)
{
struct stm32h7_qspidev_s *priv = (struct stm32h7_qspidev_s *) dev;
struct qspi_xctnspec_s xctn;
int ret;
/* Reject commands issued while in memory mapped mode, which will
* automatically cancel the memory mapping. You must exit the
* memory mapped mode first.
*/
if (priv->memmap) {
return -EBUSY;
}
/* Set up the transaction descriptor as per command info */
ret = qspi_setupxctnfrommem(&xctn, meminfo);
if (OK != ret) {
return ret;
}
/* Prepare for transaction */
/* Wait 'till non-busy */
qspi_abort(priv);
qspi_waitstatusflags(priv, QSPI_SR_BUSY, 0);
/* Clear flags */
qspi_putreg(priv,
QSPI_FCR_CTEF | QSPI_FCR_CTCF | QSPI_FCR_CSMF | QSPI_FCR_CTOF,
STM32_QUADSPI_FCR_OFFSET);
#ifdef CONFIG_STM32H7_QSPI_INTERRUPTS
/* interrupt mode will need access to the transaction context */
priv->xctn = &xctn;
DEBUGASSERT(meminfo->buffer != NULL && meminfo->buflen > 0);
DEBUGASSERT(IS_ALIGNED(meminfo->buffer));
if (QSPIMEM_ISWRITE(meminfo->flags)) {
uint32_t regval;
/* Set up the Communications Configuration Register as per command
* info
*/
qspi_ccrconfig(priv, &xctn, CCR_FMODE_INDWR);
/* Enable 'Transfer Error' 'FIFO Threshhold' and 'Transfer Complete'
* interrupts
*/
regval = qspi_getreg(priv, STM32_QUADSPI_CR_OFFSET);
regval |= (QSPI_CR_TEIE | QSPI_CR_FTIE | QSPI_CR_TCIE);
qspi_putreg(priv, regval, STM32_QUADSPI_CR_OFFSET);
} else {
uint32_t regval;
uint32_t addrval;
addrval = qspi_getreg(priv, STM32_QUADSPI_AR_OFFSET);
/* Set up the Communications Configuration Register as per command
* info
*/
qspi_ccrconfig(priv, &xctn, CCR_FMODE_INDRD);
/* Start the transfer by re-writing the address in AR register */
qspi_putreg(priv, addrval, STM32_QUADSPI_AR_OFFSET);
/* Enable 'Transfer Error' 'FIFO Threshhold' and 'Transfer Complete'
* interrupts
*/
regval = qspi_getreg(priv, STM32_QUADSPI_CR_OFFSET);
regval |= (QSPI_CR_TEIE | QSPI_CR_FTIE | QSPI_CR_TCIE);
qspi_putreg(priv, regval, STM32_QUADSPI_CR_OFFSET);
}
/* Wait for the interrupt routine to finish it's magic */
nxsem_wait(&priv->op_sem);
MEMORY_SYNC();
/* convey the result */
ret = xctn.disposition;
#elif defined(CONFIG_STM32H7_QSPI_DMA)
/* Can we perform DMA? Should we perform DMA? */
if (priv->candma &&
meminfo->buflen > CONFIG_STM32H7_QSPI_DMATHRESHOLD &&
IS_ALIGNED((uintptr_t)meminfo->buffer) &&
IS_ALIGNED(meminfo->buflen)) {
ret = qspi_memory_dma(priv, meminfo, &xctn);
} else {
/* polling mode */
/* Set up the Communications Configuration Register as per command
* info
*/
qspi_ccrconfig(priv, &xctn,
QSPIMEM_ISWRITE(meminfo->flags) ? CCR_FMODE_INDWR :
CCR_FMODE_INDRD);
/* Transfer data */
DEBUGASSERT(meminfo->buffer != NULL && meminfo->buflen > 0);
DEBUGASSERT(IS_ALIGNED(meminfo->buffer));
if (QSPIMEM_ISWRITE(meminfo->flags)) {
ret = qspi_transmit_blocking(priv, &xctn);
} else {
ret = qspi_receive_blocking(priv, &xctn);
}
/* Wait for Transfer complete, and not busy */
qspi_waitstatusflags(priv, QSPI_SR_TCF, 1);
qspi_waitstatusflags(priv, QSPI_SR_BUSY, 0);
MEMORY_SYNC();
}
#else
/* polling mode */
/* Set up the Communications Configuration Register as per command info */
qspi_ccrconfig(priv, &xctn,
QSPIMEM_ISWRITE(meminfo->flags) ? CCR_FMODE_INDWR :
CCR_FMODE_INDRD);
/* Transfer data */
DEBUGASSERT(meminfo->buffer != NULL && meminfo->buflen > 0);
DEBUGASSERT(IS_ALIGNED(meminfo->buffer));
if (QSPIMEM_ISWRITE(meminfo->flags)) {
ret = qspi_transmit_blocking(priv, &xctn);
} else {
ret = qspi_receive_blocking(priv, &xctn);
}
/* Wait for Transfer complete, and not busy */
//qspi_waitstatusflags(priv, QSPI_SR_TCF, 1);
qspi_waitstatusflags(priv, QSPI_SR_BUSY, 0);
MEMORY_SYNC()
;
#endif
return ret;
}
/****************************************************************************
* Name: qspi_alloc
*
* Description:
* Allocate a buffer suitable for DMA data transfer
*
* Input Parameters:
* dev - Device-specific state data
* buflen - Buffer length to allocate in bytes
*
* Returned Value:
* Address of the allocated memory on success; NULL is returned on any
* failure.
*
****************************************************************************/
QUADSPI_RAMFUNC FAR void *qspi_alloc(FAR struct qspi_dev_s *dev, size_t buflen)
{
/* Here we exploit the carnal knowledge the kmm_malloc() will return memory
* aligned to 64-bit addresses. The buffer length must be large enough to
* hold the rested buflen in units a 32-bits.
*/
return kmm_malloc(ALIGN_UP(buflen));
}
/****************************************************************************
* Name: QSPI_FREE
*
* Description:
* Free memory returned by QSPI_ALLOC
*
* Input Parameters:
* dev - Device-specific state data
* buffer - Buffer previously allocated via QSPI_ALLOC
*
* Returned Value:
* None.
*
****************************************************************************/
QUADSPI_RAMFUNC void qspi_free(FAR struct qspi_dev_s *dev, FAR void *buffer)
{
if (buffer) {
kmm_free(buffer);
}
}
/****************************************************************************
* Name: qspi_hw_initialize
*
* Description:
* Initialize the QSPI peripheral from hardware reset.
*
* Input Parameters:
* priv - Device state structure.
*
* Returned Value:
* Zero (OK) on SUCCESS, a negated errno on value of failure
*
****************************************************************************/
#if !defined(QSPI_BOOT_IN_MEMORY_MAPPED_MOD)
int qspi_hw_initialize(struct stm32h7_qspidev_s *priv)
{
uint32_t regval;
/* Disable the QSPI; abort anything happening, disable, wait for not busy */
qspi_abort(priv);
regval = 0;
regval &= ~(QSPI_CR_EN);
qspi_putreg(priv, regval, STM32_QUADSPI_CR_OFFSET);
/* Wait till BUSY flag reset */
qspi_waitstatusflags(priv, QSPI_SR_BUSY, 0);
/* Disable all interrupt sources for starters */
regval = qspi_getreg(priv, STM32_QUADSPI_CR_OFFSET);
regval &= ~(QSPI_CR_TEIE | QSPI_CR_TCIE | QSPI_CR_FTIE | QSPI_CR_SMIE |
QSPI_CR_TOIE | QSPI_CR_FSEL | QSPI_CR_DFM);
#if defined(CONFIG_STM32H7_QSPI_MODE_BANK2)
regval |= QSPI_CR_FSEL;
#endif
#if defined(CONFIG_STM32H7_QSPI_MODE_DUAL)
regval |= QSPI_CR_DFM;
#endif
/* Configure QSPI FIFO Threshold */
regval &= ~(QSPI_CR_FTHRES_MASK);
regval |= ((CONFIG_STM32H7_QSPI_FIFO_THESHOLD - 1) <<
QSPI_CR_FTHRES_SHIFT);
qspi_putreg(priv, regval, STM32_QUADSPI_CR_OFFSET);
/* Wait till BUSY flag reset */
qspi_waitstatusflags(priv, QSPI_SR_BUSY, 0);
/* Configure QSPI Clock Prescaler and Sample Shift */
regval = qspi_getreg(priv, STM32_QUADSPI_CR_OFFSET);
regval &= ~(QSPI_CR_PRESCALER_MASK | QSPI_CR_SSHIFT);
regval |= (0x01 << QSPI_CR_PRESCALER_SHIFT);
regval |= (0x00);
qspi_putreg(priv, regval, STM32_QUADSPI_CR_OFFSET);
/* Configure QSPI Flash Size, CS High Time and Clock Mode */
regval = qspi_getreg(priv, STM32_QUADSPI_DCR_OFFSET);
regval &= ~(QSPI_DCR_CKMODE | QSPI_DCR_CSHT_MASK | QSPI_DCR_FSIZE_MASK);
regval |= (0x00);
regval |= ((CONFIG_STM32H7_QSPI_CSHT - 1) << QSPI_DCR_CSHT_SHIFT);
if (0 != CONFIG_STM32H7_QSPI_FLASH_SIZE) {
unsigned int nsize = CONFIG_STM32H7_QSPI_FLASH_SIZE;
int nlog2size = 31;
while ((nsize & 0x80000000) == 0) {
--nlog2size;
nsize <<= 1;
}
regval |= ((nlog2size - 1) << QSPI_DCR_FSIZE_SHIFT);
}
qspi_putreg(priv, regval, STM32_QUADSPI_DCR_OFFSET);
/* Enable QSPI */
regval = qspi_getreg(priv, STM32_QUADSPI_CR_OFFSET);
regval |= QSPI_CR_EN;
qspi_putreg(priv, regval, STM32_QUADSPI_CR_OFFSET);
/* Wait till BUSY flag reset */
qspi_waitstatusflags(priv, QSPI_SR_BUSY, 0);
qspi_dumpregs(priv, "After initialization");
qspi_dumpgpioconfig("GPIO");
return OK;
}
#endif //!defined(QSPI_BOOT_IN_MEMORY_MAPPED_MOD)
/****************************************************************************
* Public Functions
****************************************************************************/
/****************************************************************************
* Name: stm32h7_qspi_initialize
*
* Description:
* Initialize the selected QSPI port in master mode
*
* Input Parameters:
* intf - Interface number(must be zero)
*
* Returned Value:
* Valid QSPI device structure reference on success; a NULL on failure
*
****************************************************************************/
struct qspi_dev_s *stm32h7_qspi_initialize(int intf)
{
struct stm32h7_qspidev_s *priv;
#if !defined(QSPI_BOOT_IN_MEMORY_MAPPED_MOD)
uint32_t regval;
int ret;
#endif
/* The STM32H7 has only a single QSPI port */
spiinfo("intf: %d\n", intf);
DEBUGASSERT(intf == 0);
/* Select the QSPI interface */
if (intf == 0) {
/* If this function is called multiple times, the following operations
* will be performed multiple times.
*/
/* Select QSPI0 */
priv = &g_qspi0dev;
#if !defined(QSPI_BOOT_IN_MEMORY_MAPPED_MOD)
/* Select QSPI clock source */
modreg32(BOARD_QSPI_CLK, RCC_D1CCIPR_QSPISEL_MASK, STM32_RCC_D1CCIPR);
/* Enable clocking to the QSPI peripheral */
regval = getreg32(STM32_RCC_AHB3ENR);
regval |= RCC_AHB3ENR_QSPIEN;
putreg32(regval, STM32_RCC_AHB3ENR);
/* Reset the QSPI peripheral */
regval = getreg32(STM32_RCC_AHB3RSTR);
regval |= RCC_AHB3RSTR_QSPIRST;
putreg32(regval, STM32_RCC_AHB3RSTR);
regval &= ~RCC_AHB3RSTR_QSPIRST;
putreg32(regval, STM32_RCC_AHB3RSTR);
/* Configure multiplexed pins as connected on the board. */
stm32_configgpio(GPIO_QSPI_CS);
stm32_configgpio(GPIO_QSPI_IO0);
stm32_configgpio(GPIO_QSPI_IO1);
stm32_configgpio(GPIO_QSPI_IO2);
stm32_configgpio(GPIO_QSPI_IO3);
stm32_configgpio(GPIO_QSPI_SCK);
#endif //!defined(QSPI_BOOT_IN_MEMORY_MAPPED_MOD)
} else {
spierr("ERROR: QSPI%d not supported\n", intf);
return NULL;
}
/* Has the QSPI hardware been initialized? */
if (!priv->initialized) {
/* Now perform one time initialization.
*
* Initialize the QSPI semaphore that enforces mutually exclusive
* access to the QSPI registers.
*/
nxsem_init(&priv->exclsem, 0, 1);
#ifdef CONFIG_STM32H7_QSPI_DMA
/* Pre-allocate DMA channels. */
if (priv->candma) {
priv->dmach = stm32_dmachannel(DMACHAN_QUADSPI);
if (!priv->dmach) {
spierr("ERROR: Failed to allocate the DMA channel\n");
priv->candma = false;
}
}
/* Initialize the QSPI semaphore that is used to wake up the waiting
* thread when the DMA transfer completes. This semaphore is used for
* signaling and, hence, should not have priority inheritance enabled.
*/
nxsem_init(&priv->dmawait, 0, 0);
nxsem_setprotocol(&priv->dmawait, SEM_PRIO_NONE);
/* Create a watchdog time to catch DMA timeouts */
priv->dmadog = wd_create();
if (priv->dmadog == NULL) {
spierr("ERROR: Failed to create wdog\n");
goto errout_with_dmahandles;
}
#endif
#ifdef CONFIG_STM32H7_QSPI_INTERRUPTS
/* Attach the interrupt handler */
ret = irq_attach(priv->irq, priv->handler, NULL);
if (ret < 0) {
spierr("ERROR: Failed to attach irq %d\n", priv->irq);
goto errout_with_dmadog;
}
/* Initialize the semaphore that blocks until the operation completes.
* This semaphore is used for signaling and, hence, should not have
* priority inheritance enabled.
*/
nxsem_init(&priv->op_sem, 0, 0);
nxsem_setprotocol(&priv->op_sem, SEM_PRIO_NONE);
#endif
/* Perform hardware initialization. Puts the QSPI into an active
* state.
*/
#if !defined(QSPI_BOOT_IN_MEMORY_MAPPED_MOD)
ret = qspi_hw_initialize(priv);
if (ret < 0) {
spierr("ERROR: Failed to initialize QSPI hardware\n");
goto errout_with_irq;
}
#endif
/* Enable interrupts at the NVIC */
priv->initialized = true;
priv->memmap = false;
#ifdef CONFIG_STM32H7_QSPI_INTERRUPTS
up_enable_irq(priv->irq);
#endif
}
return &priv->qspi;
#if !defined(QSPI_BOOT_IN_MEMORY_MAPPED_MOD)
errout_with_irq:
#endif
#ifdef CONFIG_STM32H7_QSPI_INTERRUPTS
irq_detach(priv->irq);
errout_with_dmadog:
#endif
#ifdef CONFIG_STM32H7_QSPI_DMA
wd_delete(priv->dmadog);
errout_with_dmahandles:
nxsem_destroy(&priv->dmawait);
if (priv->dmach) {
stm32_dmafree(priv->dmach);
priv->dmach = NULL;
}
#endif
nxsem_destroy(&priv->exclsem);
return NULL;
}
/****************************************************************************
* Name: stm32h7_qspi_enter_memorymapped
*
* Description:
* Put the QSPI device into memory mapped mode
*
* Input Parameters:
* dev - QSPI device
* meminfo - parameters like for a memory transfer used for reading
*
* Returned Value:
* None
*
****************************************************************************/
QUADSPI_RAMFUNC void stm32h7_qspi_enter_memorymapped(struct qspi_dev_s *dev,
const struct qspi_meminfo_s *meminfo, uint32_t lpto)
{
struct stm32h7_qspidev_s *priv = (struct stm32h7_qspidev_s *) dev;
uint32_t regval;
struct qspi_xctnspec_s xctn;
/* lock during this mode change */
qspi_lock(dev, true);
if (priv->memmap) {
qspi_lock(dev, false);
return;
}
/* Abort anything in-progress */
qspi_abort(priv);
/* Wait till BUSY flag reset */
qspi_waitstatusflags(priv, QSPI_SR_BUSY, 0);
/* if we want the 'low-power timeout counter' */
if (lpto > 0) {
/* Set the Low Power Timeout value (automatically de-assert
* CS if memory is not accessed for a while)
*/
qspi_putreg(priv, lpto, STM32_QUADSPI_LPTR_OFFSET);
/* Clear Timeout interrupt */
qspi_putreg(&g_qspi0dev, QSPI_FCR_CTOF, STM32_QUADSPI_FCR_OFFSET);
#ifdef CONFIG_STM32H7_QSPI_INTERRUPTS
/* Enable Timeout interrupt */
regval = qspi_getreg(priv, STM32_QUADSPI_CR_OFFSET);
regval |= (QSPI_CR_TCEN | QSPI_CR_TOIE);
qspi_putreg(priv, regval, STM32_QUADSPI_CR_OFFSET);
#endif
} else {
regval = qspi_getreg(priv, STM32_QUADSPI_CR_OFFSET);
regval &= ~QSPI_CR_TCEN;
qspi_putreg(priv, regval, STM32_QUADSPI_CR_OFFSET);
}
/* create a transaction object */
qspi_setupxctnfrommem(&xctn, meminfo);
#ifdef CONFIG_STM32H7_QSPI_INTERRUPTS
priv->xctn = NULL;
#endif
/* set it into the ccr */
qspi_ccrconfig(priv, &xctn, CCR_FMODE_MEMMAP);
priv->memmap = true;
/* we should be in memory mapped mode now */
qspi_dumpregs(priv, "After memory mapped:");
/* finished this mode change */
qspi_lock(dev, false);
}
/****************************************************************************
* Name: stm32h7_qspi_exit_memorymapped
*
* Description:
* Take the QSPI device out of memory mapped mode
*
* Input Parameters:
* dev - QSPI device
*
* Returned Value:
* None
*
****************************************************************************/
QUADSPI_RAMFUNC void stm32h7_qspi_exit_memorymapped(struct qspi_dev_s *dev)
{
struct stm32h7_qspidev_s *priv = (struct stm32h7_qspidev_s *) dev;
qspi_lock(dev, true);
/* A simple abort is sufficient */
qspi_abort(priv);
priv->memmap = false;
struct qspi_xctnspec_s xctn = { 0 };
xctn.datamode = 3; /* 3 = quad */
qspi_ccrconfig(priv, &xctn, CCR_FMODE_INDWR);
qspi_lock(dev, false);
}
#endif /* CONFIG_STM32H7_QSPI */