vos/ambiq-hal-sys/ambiq-sparkfun-sdk/devices/am_devices_mspi_rm67162.c
2022-10-23 23:45:43 -07:00

962 lines
33 KiB
C

//*****************************************************************************
//
//! @file am_devices_mspi_rm67162.c
//!
//! @brief Generic Raydium TFT display driver.
//
//*****************************************************************************
//*****************************************************************************
//
// Copyright (c) 2020, Ambiq Micro
// All rights reserved.
//
// 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 of the copyright holder nor the names of its
// contributors may be used to endorse or promote products derived from this
// software without specific prior written permission.
//
// Third party software included in this distribution is subject to the
// additional license terms as defined in the /docs/licenses directory.
//
// 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 HOLDER 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.
//
// This is part of revision 2.4.2 of the AmbiqSuite Development Package.
//
//*****************************************************************************
#include <string.h>
#include "am_mcu_apollo.h"
#include "am_devices_mspi_rm67162.h"
#include "am_bsp.h"
#include "am_util_delay.h"
#include "am_util.h"
//*****************************************************************************
//
// Global variables.
//
//*****************************************************************************
#define BYTE_NUM_PER_WRITE 65535
//#define BYTE_NUM_PER_WRITE AM_HAL_MSPI_MAX_TRANS_SIZE
#define AM_DEVICES_MSPI_TIMEOUT 1000000
static struct
{
uint32_t row_start;
uint32_t row_end;
uint32_t col_start;
uint32_t col_end;
} gs_display_info;
static am_devices_rm67162_graphic_conf_t g_sGraphic_conf =
{
.bus_mode = AM_DEVICES_RM67162_SPI_WRAM,
.color_mode = AM_DEVICES_RM67162_COLOR_MODE_8BIT,
.scan_mode = AM_DEVICES_RM67162_SCAN_MODE_0,
.max_row = 400, //390,
.max_col = 400, // 390,
.row_offset = 0,
.col_offset = 0 // 6
// .col_offset = 100
};
// Display MSPI configuration
static am_hal_mspi_dev_config_t SerialDisplayMSPICfg =
{
.ui8TurnAround = 1,
.eAddrCfg = AM_HAL_MSPI_ADDR_3_BYTE,
.eInstrCfg = AM_HAL_MSPI_INSTR_1_BYTE,
.ui8ReadInstr = AM_DEVICES_RM67162_MEMORY_READ,
.ui8WriteInstr = AM_DEVICES_RM67162_MEMORY_WRITE_CONTINUE, // AM_DEVICES_RM67162_MEMORY_WRITE_CONTINUE,
.eDeviceConfig = AM_HAL_MSPI_FLASH_SERIAL_CE0,
.ui8WriteLatency = 0,
.eSpiMode = AM_HAL_MSPI_SPI_MODE_0,
.eClockFreq = AM_HAL_MSPI_CLK_48MHZ,
.bEnWriteLatency = false,
.bSendAddr = false,
.bSendInstr = true,
.bSeparateIO = false,
.bTurnaround = false,
.bEmulateDDR = false,
.ui16DMATimeLimit = 0,
.eDMABoundary = AM_HAL_MSPI_BOUNDARY_NONE,
.ui32TCBSize = 0,
.pTCB = 0,
.scramblingStartAddr = 0,
.scramblingEndAddr = 0,
};
typedef struct
{
uint32_t ui32Module;
void *pMspiHandle;
bool bOccupied;
} am_devices_mspi_rm67162_t;
am_devices_mspi_rm67162_t gAmRm67162[AM_DEVICES_MSPI_RM67162_MAX_DEVICE_NUM];
void pfnMSPI_RM67162_Callback(void *pCallbackCtxt, uint32_t status)
{
// Set the DMA complete flag.
*(volatile bool *)pCallbackCtxt = true;
}
//*****************************************************************************
//
// Generic Command Write function.
//
//*****************************************************************************
uint32_t
am_devices_rm67162_command_write(void *pHandle,
uint32_t ui32Instr,
uint8_t *pData,
uint32_t ui32NumBytes)
{
am_hal_mspi_pio_transfer_t Transaction;
am_devices_mspi_rm67162_t *pDisplay = (am_devices_mspi_rm67162_t *)pHandle;
// Create the individual write transaction.
Transaction.ui32NumBytes = ui32NumBytes;
Transaction.bScrambling = false;
Transaction.bDCX = true;
Transaction.eDirection = AM_HAL_MSPI_TX;
Transaction.bSendAddr = false;
Transaction.ui32DeviceAddr = 0;
Transaction.bSendInstr = true;
Transaction.ui16DeviceInstr = ui32Instr;
Transaction.bTurnaround = false;
Transaction.bEnWRLatency = false;
Transaction.bQuadCmd = false;
Transaction.bContinue = false;
Transaction.pui32Buffer = (uint32_t *)pData;
//
// Execute the transction over MSPI.
//
if (am_hal_mspi_blocking_transfer(pDisplay->pMspiHandle, &Transaction, AM_DEVICES_MSPI_TIMEOUT))
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
return AM_DEVICES_RM67162_STATUS_SUCCESS;
}
static uint32_t
am_devices_rm67162_command_read(void *pHandle,
uint32_t ui32Instr,
uint32_t *pData,
uint32_t ui32NumBytes,
bool bTurnaround)
{
am_hal_mspi_pio_transfer_t Transaction;
am_devices_mspi_rm67162_t *pDisplay = (am_devices_mspi_rm67162_t *)pHandle;
// Create the individual write transaction.
Transaction.ui32NumBytes = ui32NumBytes;
Transaction.bScrambling = false;
Transaction.bDCX = true;
Transaction.eDirection = AM_HAL_MSPI_RX;
Transaction.bSendAddr = false;
Transaction.ui32DeviceAddr = 0;
Transaction.bSendInstr = true;
Transaction.ui16DeviceInstr = ui32Instr;
Transaction.bTurnaround = bTurnaround;
Transaction.bEnWRLatency = false;
Transaction.bQuadCmd = false;
Transaction.bContinue = false;
Transaction.pui32Buffer = (uint32_t *)pData;
//
// Execute the transction over MSPI.
//
if (am_hal_mspi_blocking_transfer(pDisplay->pMspiHandle,
&Transaction,
AM_DEVICES_MSPI_TIMEOUT))
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
return AM_DEVICES_RM67162_STATUS_SUCCESS;
}
//*****************************************************************************
//
//! @brief Reads the current status of the external display
//!
//! @param ui32DeviceNumber - Device number of the external display
//!
//! This function reads the device ID register of the external display, and returns
//! the result as an 32-bit unsigned integer value.
//!
//! @return 32-bit status
//
//*****************************************************************************
uint32_t
am_devices_rm67162_reset(void *pHandle)
{
// Hardware Reset
#if 1
am_hal_gpio_state_write(AM_BSP_GPIO_DISPLAY_RESET, AM_HAL_GPIO_OUTPUT_SET);
am_util_delay_ms(20);
am_hal_gpio_state_write(AM_BSP_GPIO_DISPLAY_RESET, AM_HAL_GPIO_OUTPUT_CLEAR);
am_util_delay_ms(20);
am_hal_gpio_state_write(AM_BSP_GPIO_DISPLAY_RESET, AM_HAL_GPIO_OUTPUT_SET);
am_util_delay_ms(20);
#endif
if ( am_devices_rm67162_command_write(pHandle, AM_DEVICES_RM67162_SWRESET, NULL, 0) )
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
am_util_delay_ms(300);
return AM_DEVICES_RM67162_STATUS_SUCCESS;
}
uint32_t
am_devices_rm67162_display_off(void *pHandle)
{
if ( am_devices_rm67162_command_write(pHandle, AM_DEVICES_RM67162_DISPLAY_OFF, NULL, 0) )
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
if ( am_devices_rm67162_command_write(pHandle, AM_DEVICES_RM67162_SLEEP_IN, NULL, 0) )
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
return AM_DEVICES_RM67162_STATUS_SUCCESS;
}
uint32_t
am_devices_rm67162_display_on(void *pHandle)
{
if ( am_devices_rm67162_command_write(pHandle, AM_DEVICES_RM67162_DISPLAY_ON, NULL, 0) )
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
return AM_DEVICES_RM67162_STATUS_SUCCESS;
}
//*****************************************************************************
//
//! @brief Programs the given range of flash addresses.
//!
//! @param pui8TxBuffer - Buffer to write the external flash data from
//! @param ui32NumBytes - Number of bytes to write to the external flash
//!
//! This function uses the data in the provided pui8TxBuffer and copies it to
//! the external flash at the address given by ui32WriteAddress. It will copy
//! exactly ui32NumBytes of data from the original pui8TxBuffer pointer. The
//! user is responsible for ensuring that they do not overflow the target flash
//! memory or underflow the pui8TxBuffer array
//
//! @return 32-bit status
//
//*****************************************************************************
uint32_t
am_devices_rm67162_blocking_write(void *pHandle,
uint8_t *pui8TxBuffer,
uint32_t ui32NumBytes)
{
am_hal_mspi_pio_transfer_t Transaction;
am_devices_mspi_rm67162_t *pDisplay = (am_devices_mspi_rm67162_t *)pHandle;
// Create the individual write transaction.
Transaction.ui32NumBytes = 0;
Transaction.bScrambling = false;
Transaction.bDCX = true;
Transaction.eDirection = AM_HAL_MSPI_TX;
Transaction.bSendAddr = false;
Transaction.ui32DeviceAddr = 0;
Transaction.bSendInstr = true;
Transaction.ui16DeviceInstr = AM_DEVICES_RM67162_MEMORY_WRITE;
Transaction.bTurnaround = false;
Transaction.bEnWRLatency = false;
Transaction.bQuadCmd = false;
Transaction.bContinue = true;
Transaction.pui32Buffer = NULL;
//
// Execute the transction over MSPI.
//
if (am_hal_mspi_blocking_transfer(pDisplay->pMspiHandle, &Transaction, AM_DEVICES_MSPI_TIMEOUT))
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
while (ui32NumBytes)
{
// Create the individual write transaction.
Transaction.ui32NumBytes = (ui32NumBytes > BYTE_NUM_PER_WRITE) ? BYTE_NUM_PER_WRITE : ui32NumBytes;
Transaction.bScrambling = false;
Transaction.bDCX = false;
Transaction.eDirection = AM_HAL_MSPI_TX;
Transaction.bSendAddr = false;
Transaction.ui32DeviceAddr = 0;
Transaction.bSendInstr = false;
Transaction.ui16DeviceInstr = 0;
Transaction.bTurnaround = false;
Transaction.bEnWRLatency = false;
Transaction.bQuadCmd = false;
Transaction.bContinue = (ui32NumBytes > BYTE_NUM_PER_WRITE) ? true : false;
Transaction.pui32Buffer = (uint32_t *)pui8TxBuffer;
//
// Execute the transction over MSPI.
//
if (am_hal_mspi_blocking_transfer(pDisplay->pMspiHandle, &Transaction, AM_DEVICES_MSPI_TIMEOUT))
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
ui32NumBytes -= Transaction.ui32NumBytes;
pui8TxBuffer += Transaction.ui32NumBytes;
}
return AM_DEVICES_RM67162_STATUS_SUCCESS;
}
//*****************************************************************************
//
//! @brief Reads the contents of the fram into a buffer.
//!
//! @param pui8RxBuffer - Buffer to store the received data from the flash
//! @param ui32ReadAddress - Address of desired data in external flash
//! @param ui32NumBytes - Number of bytes to read from external flash
//!
//! This function reads the external flash at the provided address and stores
//! the received data into the provided buffer location. This function will
//! only store ui32NumBytes worth of data.
//
//! @return 32-bit status
//
//*****************************************************************************
uint32_t
am_devices_rm67162_blocking_read(void *pHandle,
uint8_t *pui8RxBuffer,
uint32_t ui32NumBytes)
{
am_hal_mspi_pio_transfer_t Transaction;
am_devices_mspi_rm67162_t *pDisplay = (am_devices_mspi_rm67162_t *)pHandle;
// Create the individual write transaction.
Transaction.ui32NumBytes = 0;
Transaction.bScrambling = false;
Transaction.bDCX = true;
Transaction.eDirection = AM_HAL_MSPI_RX;
Transaction.bSendAddr = false;
Transaction.ui32DeviceAddr = 0;
Transaction.bSendInstr = true;
Transaction.ui16DeviceInstr = AM_DEVICES_RM67162_MEMORY_READ;
Transaction.bTurnaround = false;
Transaction.bEnWRLatency = false;
Transaction.bQuadCmd = false;
Transaction.bContinue = true;
Transaction.pui32Buffer = NULL;
while (ui32NumBytes)
{
// Create the individual write transaction.
Transaction.ui32NumBytes = (ui32NumBytes > BYTE_NUM_PER_WRITE) ? BYTE_NUM_PER_WRITE : ui32NumBytes;
Transaction.bScrambling = false;
Transaction.bDCX = false;
Transaction.eDirection = AM_HAL_MSPI_RX;
Transaction.bSendAddr = false;
Transaction.ui32DeviceAddr = 0;
Transaction.bSendInstr = false;
Transaction.ui16DeviceInstr = 0;
Transaction.bTurnaround = false;
Transaction.bEnWRLatency = false;
Transaction.bQuadCmd = false;
Transaction.bContinue = (ui32NumBytes > BYTE_NUM_PER_WRITE) ? true : false;
Transaction.pui32Buffer = (uint32_t *)pui8RxBuffer;
//
// Execute the transction over MSPI.
//
if (am_hal_mspi_blocking_transfer(pDisplay->pMspiHandle,
&Transaction,
AM_DEVICES_MSPI_TIMEOUT))
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
ui32NumBytes -= Transaction.ui32NumBytes;
pui8RxBuffer += Transaction.ui32NumBytes;
}
return AM_DEVICES_RM67162_STATUS_SUCCESS;
}
//*****************************************************************************
//
//! @brief Programs the given range of display addresses.
//!
//! @param ui32Module - MSPI Instance
//! @param pui8TxBuffer - Buffer to write the data from
//! @param ui32NumBytes - Number of bytes to write to the display memory
//! @param bWaitForCompletion - Waits for CQ/DMA to complete before return.
//!
//! This function uses the data in the provided pui8TxBuffer and copies it to
//! the external flash at the address given by ui32WriteAddress. It will copy
//! exactly ui32NumBytes of data from the original pui8TxBuffer pointer. The
//! user is responsible for ensuring that they do not overflow the target flash
//! memory or underflow the pui8TxBuffer array
//
//! @return 32-bit status
//
//*****************************************************************************
uint32_t
am_devices_rm67162_nonblocking_write(void *pHandle,
uint8_t *pui8TxBuffer,
uint32_t ui32NumBytes,
bool bWaitForCompletion)
{
am_hal_mspi_dma_transfer_t Transaction;
volatile bool bDMAComplete = false;
am_devices_mspi_rm67162_t *pDisplay = (am_devices_mspi_rm67162_t *)pHandle;
//
// Enable DCX for DMA Transactions.
//
if (am_hal_mspi_control(pDisplay->pMspiHandle, AM_HAL_MSPI_REQ_DCX_EN, 0))
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
//
// Create the transaction.
//
Transaction.ui8Priority = 1;
Transaction.eDirection = AM_HAL_MSPI_TX;
Transaction.ui32TransferCount = ui32NumBytes;
Transaction.ui32DeviceAddress = 0;
Transaction.ui32SRAMAddress = (uint32_t)pui8TxBuffer;
Transaction.ui32PauseCondition = 0;
Transaction.ui32StatusSetClr = 0;
//
// Execute the transction over MSPI.
//
if (am_hal_mspi_nonblocking_transfer(pDisplay->pMspiHandle,
&Transaction,
AM_HAL_MSPI_TRANS_DMA,
pfnMSPI_RM67162_Callback,
(void *)&bDMAComplete))
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
if (bWaitForCompletion)
{
// Wait for DMA Complete or Timeout
for (uint32_t i = 0; i < AM_DEVICES_MSPI_TIMEOUT; i++)
{
if (bDMAComplete)
{
break;
}
//
// Call the BOOTROM cycle function to delay for about 1 microsecond.
//
am_hal_flash_delay( FLASH_CYCLES_US(1) );
}
// Check the status.
if (!bDMAComplete)
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
}
return AM_DEVICES_RM67162_STATUS_SUCCESS;
}
//*****************************************************************************
//
//! @brief Programs the given range of display addresses.
//!
//! @param ui32Module - MSPI Instance
//! @param pui8TxBuffer - Buffer to write the data from
//! @param ui32NumBytes - Number of bytes to write to the display memory
//! @param ui32PauseCondition - CQ Pause condition before execution.
//! @param ui32StatusSetClr - CQ Set/Clear condition after execution.
//! @param pfnCallback - Callback function after execution.
//! @param pCallbackCtxt - Callback context after execution.
//!
//! This function uses the data in the provided pui8TxBuffer and copies it to
//! the external display the address given by ui32WriteAddress. It will copy
//! exactly ui32NumBytes of data from the original pui8TxBuffer pointer. The
//! user is responsible for ensuring that they do not overflow the target display
//! memory or underflow the pui8TxBuffer array
//
//! @return 32-bit status
//
//*****************************************************************************
uint32_t
am_devices_rm67162_nonblocking_write_adv(void *pHandle,
uint8_t *pui8TxBuffer,
uint32_t ui32NumBytes,
uint32_t ui32PauseCondition,
uint32_t ui32StatusSetClr,
am_hal_mspi_callback_t pfnCallback,
void *pCallbackCtxt)
{
am_hal_mspi_dma_transfer_t Transaction;
am_devices_mspi_rm67162_t *pDisplay = (am_devices_mspi_rm67162_t *)pHandle;
//
// Create the transaction.
//
Transaction.ui8Priority = 1;
Transaction.eDirection = AM_HAL_MSPI_TX;
Transaction.ui32TransferCount = ui32NumBytes;
Transaction.ui32DeviceAddress = 0;
Transaction.ui32SRAMAddress = (uint32_t)pui8TxBuffer;
Transaction.ui32PauseCondition = ui32PauseCondition;
Transaction.ui32StatusSetClr = ui32StatusSetClr;
// am_hal_gpio_state_write(AM_BSP_GPIO_IOM0_DCX, AM_HAL_GPIO_OUTPUT_CLEAR);
//
// Execute the transction over IOM.
//
if (am_hal_mspi_nonblocking_transfer(pDisplay->pMspiHandle,
&Transaction,
AM_HAL_MSPI_TRANS_DMA,
pfnCallback,
pCallbackCtxt))
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
return AM_DEVICES_RM67162_STATUS_SUCCESS;
}
//*****************************************************************************
//
//! @brief Reads the contents of the display into a buffer.
//!
//! @param ui32Module - MSPI Instance
//! @param pui8RxBuffer - Buffer to store the received data from the flash
//! @param ui32NumBytes - Number of bytes to read from external flash
//! @param bWaitForCompletion - Waits for CQ/DMA to complete before return.
//!
//! This function reads the external display at the provided address and stores
//! the received data into the provided buffer location. This function will
//! only store ui32NumBytes worth of data.
//
//! @return 32-bit status
//
//*****************************************************************************
uint32_t
am_devices_rm67162_nonblocking_read(void *pHandle,
uint8_t *pui8RxBuffer,
uint32_t ui32NumBytes,
bool bWaitForCompletion)
{
am_hal_mspi_dma_transfer_t Transaction;
volatile bool bDMAComplete = false;
am_devices_mspi_rm67162_t *pDisplay = (am_devices_mspi_rm67162_t *)pHandle;
//
// Create the transaction.
//
Transaction.ui8Priority = 1;
Transaction.eDirection = AM_HAL_MSPI_RX;
Transaction.ui32TransferCount = ui32NumBytes;
Transaction.ui32DeviceAddress = 0;
Transaction.ui32SRAMAddress = (uint32_t)pui8RxBuffer;
Transaction.ui32PauseCondition = 0;
Transaction.ui32StatusSetClr = 0;
//
// Execute the transction over MSPI.
//
if (am_hal_mspi_nonblocking_transfer(pDisplay->pMspiHandle,
&Transaction,
AM_HAL_MSPI_TRANS_DMA,
pfnMSPI_RM67162_Callback,
(void *)&bDMAComplete))
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
if (bWaitForCompletion)
{
// Wait for DMA Complete or Timeout
for (uint32_t i = 0; i < AM_DEVICES_MSPI_TIMEOUT; i++)
{
if (bDMAComplete)
{
break;
}
//
// Call the BOOTROM cycle function to delay for about 1 microsecond.
//
am_hal_flash_delay( FLASH_CYCLES_US(1) );
}
// Check the status.
if (!bDMAComplete)
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
}
return AM_DEVICES_RM67162_STATUS_SUCCESS;
}
static uint32_t
am_devices_set_row_col(void *pHandle, am_devices_rm67162_graphic_conf_t *psGraphic_conf)
{
uint8_t data[10] = {0};
gs_display_info.row_start = psGraphic_conf->row_offset;
gs_display_info.row_end = psGraphic_conf->max_row + psGraphic_conf->row_offset - 1;
gs_display_info.col_start = psGraphic_conf->col_offset;
gs_display_info.col_end = psGraphic_conf->max_col + psGraphic_conf->col_offset - 1;
/* set column start address */
data[0] = (gs_display_info.col_start / 256);
data[1] = (gs_display_info.col_start % 256);
data[2] = (gs_display_info.col_end / 256);
data[3] = (gs_display_info.col_end % 256);
if (am_devices_rm67162_command_write(pHandle, AM_DEVICES_RM67162_COLUMN_ADDR_SETTING, data, 4))//Column
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
/* set row start address */
data[0] = (gs_display_info.row_start / 256);
data[1] = (gs_display_info.row_start % 256);
data[2] = (gs_display_info.row_end / 256);
data[3] = (gs_display_info.row_end % 256);
if (am_devices_rm67162_command_write(pHandle, AM_DEVICES_RM67162_ROW_ADDR_SETTING, data, 4))//raw
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
return AM_DEVICES_RM67162_STATUS_SUCCESS;
}
static uint32_t
am_devices_lcm_init(void *pHandle, am_devices_rm67162_graphic_conf_t *psGraphic_conf)
{
uint8_t data[10] = {0};
/* Tearing effect line ON */
data[0] = 0x0;
if (am_devices_rm67162_command_write(pHandle, AM_DEVICES_RM67162_TEARING_EFFECT_LINE_ON, data, 1))
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
data[0] = psGraphic_conf->bus_mode;
if (am_devices_rm67162_command_write(pHandle, AM_DEVICES_RM67162_SET_DSPI_MODE, data, 1))
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
data[0] = psGraphic_conf->color_mode ;
if (am_devices_rm67162_command_write(pHandle, AM_DEVICES_RM67162_DATA_FORMAT_SEL, data, 1))
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
data[0] = psGraphic_conf->scan_mode;
if (am_devices_rm67162_command_write(pHandle, AM_DEVICES_RM67162_SCAN_MODE, data, 1))
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
data[0] = 0x20;
if (am_devices_rm67162_command_write(pHandle, AM_DEVICES_RM67162_SET_WRITE_DISPLAY_CTRL, data, 1))
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
//
// Set row/col start/end addresses.
//
am_devices_set_row_col(pHandle, psGraphic_conf);
/* set tear scan-line */
data[0] = 0x00;
data[1] = 0x28; // 0xf0
if ( am_devices_rm67162_command_write(pHandle, AM_DEVICES_RM67162_SET_TEAR_SCANLINE, data, 2) )
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
if ( am_devices_rm67162_command_write(pHandle, AM_DEVICES_RM67162_SLEEP_OUT, NULL, 0) )
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
am_util_delay_ms(130);
if ( am_devices_rm67162_command_write(pHandle, AM_DEVICES_RM67162_DISPLAY_ON, NULL, 0) )
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
am_util_delay_ms(200);
// am_hal_gpio_state_write(AM_BSP_GPIO_DISPLAY_BL, AM_HAL_GPIO_OUTPUT_CLEAR);
am_util_stdio_printf("AM_BSP_GPIO_DISPLAY_BL set on \n");
return AM_DEVICES_RM67162_STATUS_SUCCESS;
}
//*****************************************************************************
//
//! @brief Initialize the rm67162 driver.
//!
//! @param ui32Module - MSPI module ID.
//! @param psMSPISettings - MSPI device structure describing the target spiflash.
//! @param ppMspiHandle - MSPI handler.
//!
//! This function should be called before any other am_devices_rm67162
//! functions. It is used to set tell the other functions how to communicate
//! with the TFT display hardware.
//!
//! @return Status.
//
//*****************************************************************************
uint32_t
am_devices_mspi_rm67162_init(uint32_t ui32Module,
am_devices_mspi_rm67162_config_t *psMSPISettings,
void **ppHandle,
void **ppMspiHandle)
{
uint32_t ui32Status;
uint32_t ui32DeviceID;
uint32_t ui32Index = 0;
am_hal_mspi_dev_config_t mspiDevCfg;
void *pMspiHandle;
if ((ui32Module > AM_REG_MSPI_NUM_MODULES) || (psMSPISettings == NULL))
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
// Allocate a vacant device handle
for ( ui32Index = 0; ui32Index < AM_DEVICES_MSPI_RM67162_MAX_DEVICE_NUM; ui32Index++ )
{
if ( gAmRm67162[ui32Index].bOccupied == false )
{
break;
}
}
if ( ui32Index == AM_DEVICES_MSPI_RM67162_MAX_DEVICE_NUM )
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
//
// Re-Configure the MSPI for the requested operation mode.
//
mspiDevCfg = SerialDisplayMSPICfg;
mspiDevCfg.eClockFreq = psMSPISettings->eClockFreq;
//mspiDevCfg.eDeviceConfig = psMSPISettings->eDeviceConfig;
mspiDevCfg.ui32TCBSize = psMSPISettings->ui32NBTxnBufLength;
mspiDevCfg.pTCB = psMSPISettings->pNBTxnBuf;
mspiDevCfg.scramblingStartAddr = psMSPISettings->ui32ScramblingStartAddr;
mspiDevCfg.scramblingEndAddr = psMSPISettings->ui32ScramblingEndAddr;
mspiDevCfg.eXipMixedMode = psMSPISettings->eMixedMode;
//
// Configure the MSPI pins.
//
am_bsp_mspi_pins_enable(ui32Module, mspiDevCfg.eDeviceConfig);
//
// Initialize the MSPI instance.
// Enable power to the MSPI instance.
// Configure the MSPI for Serial operation during initialization.
// Enable the MSPI.
// HAL Success return is 0
//
if ( am_hal_mspi_initialize(ui32Module, &pMspiHandle) ||
am_hal_mspi_power_control(pMspiHandle, AM_HAL_SYSCTRL_WAKE, false) ||
am_hal_mspi_device_configure(pMspiHandle, &mspiDevCfg) ||
am_hal_mspi_enable(pMspiHandle) )
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
else
{
//
// Enable DCX for DMA Transactions.
//
if ( am_hal_mspi_control(pMspiHandle, AM_HAL_MSPI_REQ_DCX_EN, 0) )
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
//
// Enable MSPI interrupts.
//
ui32Status = am_hal_mspi_interrupt_clear(pMspiHandle, AM_HAL_MSPI_INT_CQUPD | AM_HAL_MSPI_INT_ERR );
if (AM_HAL_STATUS_SUCCESS != ui32Status)
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
ui32Status = am_hal_mspi_interrupt_enable(pMspiHandle, AM_HAL_MSPI_INT_CQUPD | AM_HAL_MSPI_INT_ERR );
if (AM_HAL_STATUS_SUCCESS != ui32Status)
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
gAmRm67162[ui32Index].pMspiHandle = pMspiHandle;
gAmRm67162[ui32Index].ui32Module = ui32Module;
*ppMspiHandle = pMspiHandle;
*ppHandle = (void *)&gAmRm67162[ui32Index];
//
// Read the Device ID.
//
am_devices_rm67162_read_id((void*)&gAmRm67162[ui32Index], &ui32DeviceID);
am_util_stdio_printf("RM67167 Device ID = %6X\n", (ui32DeviceID & 0x00FFFFFF));
//
// Device specific TFT display initialization.
//
am_util_delay_ms(500);
am_devices_rm67162_reset((void*)&gAmRm67162[ui32Index]);
ui32Status = am_devices_lcm_init((void*)&gAmRm67162[ui32Index], &g_sGraphic_conf);
if (AM_DEVICES_RM67162_STATUS_SUCCESS != ui32Status)
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
gAmRm67162[ui32Index].bOccupied = true;
//am_hal_gpio_state_write(AM_BSP_GPIO_DISPLAY_BL, AM_HAL_GPIO_OUTPUT_SET);
//
// Return the status.
//
return AM_DEVICES_RM67162_STATUS_SUCCESS;
}
}
uint32_t
am_devices_mspi_rm67162_row_col_reset(void *pHandle)
{
uint32_t ui32Status = am_devices_set_row_col(pHandle, &g_sGraphic_conf);
if (AM_DEVICES_RM67162_STATUS_SUCCESS != ui32Status)
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
return AM_DEVICES_RM67162_STATUS_SUCCESS;
}
//*****************************************************************************
//
//! @brief De-Initialize the rm67162 driver.
//!
//! @param ui32Module - MSPI Module#
//!
//! This function reverses the initialization
//!
//! @return Status.
//
//*****************************************************************************
uint32_t
am_devices_rm67162_term(void *pHandle)
{
am_devices_mspi_rm67162_t *pDisplay = (am_devices_mspi_rm67162_t *)pHandle;
if ( pDisplay->ui32Module > AM_REG_IOM_NUM_MODULES )
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
// am_hal_gpio_interrupt_clear(AM_HAL_GPIO_MASKBIT(pGpioIntMask, AM_BSP_GPIO_DISPLAY_TE));
// am_hal_gpio_interrupt_disable(AM_HAL_GPIO_MASKBIT(pGpioIntMask, AM_BSP_GPIO_DISPLAY_TE));
// NVIC_DisableIRQ(GPIO_IRQn);
// Disable the pins
// am_bsp_iom_display_pins_disable(AM_BSP_4_WIRES_SPI_MODE);
//
// Disable the MSPI.
//
am_hal_mspi_disable(pDisplay->pMspiHandle);
//
// Disable power to and uninitialize the MSPI instance.
//
am_hal_mspi_power_control(pDisplay->pMspiHandle, AM_HAL_SYSCTRL_DEEPSLEEP, false);
am_hal_mspi_deinitialize(pDisplay->pMspiHandle);
// Free this device handle
pDisplay->bOccupied = false;
//
// Return the status.
//
return AM_DEVICES_RM67162_STATUS_SUCCESS;
}
uint32_t
am_devices_rm67162_read_id(void *pHandle, uint32_t *pdata)
{
if (am_devices_rm67162_command_read(pHandle, AM_DEVICES_RM67162_READ_ID, pdata, 3, true))
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
return AM_DEVICES_RM67162_STATUS_SUCCESS;
}
uint32_t
am_devices_mspi_rm67162_set_transfer_window(void *pHandle, uint32_t startRow, uint32_t startCol, uint32_t endRow, uint32_t endCol)
{
uint8_t data[4] = {0};
/* set column start address */
data[0] = (startCol / 256);
data[1] = (startCol % 256);
data[2] = (endCol / 256);
data[3] = (endCol % 256);
if (am_devices_rm67162_command_write(pHandle, AM_DEVICES_RM67162_COLUMN_ADDR_SETTING, data, 4))//Column
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
/* set row start address */
data[0] = (startRow / 256);
data[1] = (startRow % 256);
data[2] = (endRow / 256);
data[3] = (endRow % 256);
if (am_devices_rm67162_command_write(pHandle, AM_DEVICES_RM67162_ROW_ADDR_SETTING, data, 4))//raw
{
return AM_DEVICES_RM67162_STATUS_ERROR;
}
return AM_DEVICES_RM67162_STATUS_SUCCESS;
}