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paidaxing
Contributor III

Hi,

   When i use the spifi_polling_transfer of SDK , it can not store and read negative ,Please tell me if it can store negative numbers and show me how to do it.

Thanks

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EduardoZamora
NXP TechSupport
NXP TechSupport

Hi,

You can try, for example, changing the following line:

data |= ((uint32_t)(g_buffer[i + j])) << (j * 8);

to:

data |= ((int32_t)(g_buffer[i + j] & 0xFF)) << (j * 8);

when programming the page.

Regards,
Eduardo.

在原帖中查看解决方案

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paidaxing
Contributor III

Hi, 

The output show as follows:

I only change the g_buffer from uint to int and store negative values.

1701411316256.png

1701410680480.png

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EduardoZamora
NXP TechSupport
NXP TechSupport

Hello @paidaxing

Hope you are doing well.

Just to confirm, what version of the JN5189 SDK and MCUXpresso are you using?

Could you please provide more details on what you are trying to achieve? What is the purpose of your development?

What is the procedure you are following to try to "store and read negative" data?

Regards,
Eduardo.

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paidaxing
Contributor III
the version of JN5189 SDK 2.6.5 and the version of MCUXPresso is MCUXpressoIDE_11.5.1_7266.
I want to store the negative integer external flash and read it out.

/*
* Copyright (c) 2016, Freescale Semiconductor, Inc.
* Copyright 2016 NXP
* All rights reserved.
*
*
* SPDX-License-Identifier: BSD-3-Clause
*/

#include "board.h"
#include "fsl_debug_console.h"
#include "fsl_spifi.h"

#include "pin_mux.h"
#include "fsl_flash.h"
#include <stdbool.h>
/*******************************************************************************
* Definitions
******************************************************************************/
#define CLOCK_ABSTRACTION
/* Abstract attaching the clock */
#define EXAMPLE_SPIFI_CLK_SRC (kMAIN_CLK_to_SPIFI)
#define EXAMPLE_SPIFI_ATTACH_MAIN_CLK (CLOCK_AttachClk(EXAMPLE_SPIFI_CLK_SRC))
/* Abstract getting the clock */
#define EXAMPLE_SPIFI_CLK (kCLOCK_Spifi)
#define EXAMPLE_SPIFI_CLOCK_FREQ (CLOCK_GetFreq(EXAMPLE_SPIFI_CLK))

#define EXAMPLE_SPIFI (SPIFI)
#define PAGE_SIZE (256)
#define SECTOR_SIZE (4096)
#define EXAMPLE_SPI_BAUDRATE (16000000L)


/*! SR_WIP - Write in progress bit. Volatile bit.
* 0: not in write operation. 1: write operation.
*/
#define SR_WIP(x) (((uint32_t)(((uint32_t)(x)) << SR_WIP_SHIFT)) & SR_WIP_MASK)
#define SR_WIP_MASK (0x1U)
#define SR_WIP_SHIFT (0U)

/*! SR_WEL - Write enable latch. Volatile bit.
* 0: not write enable. 1: write enable.
*/
#define SR_WEL(x) (((uint32_t)(((uint32_t)(x)) << SR_WEL_SHIFT)) & SR_WEL_MASK)
#define SR_WEL_MASK (0x2U)
#define SR_WEL_SHIFT (1U)

/*! SR_QE - Quad enable. Non-volatile bit.
* 0: not Quad enable. 1: Quad enable.
*/
#define SR_QE(x) (((uint32_t)(((uint32_t)(x)) << SR_QE_SHIFT)) & SR_QE_MASK)
#define SR_QE_MASK (0x40U)
#define SR_QE_SHIFT (6U)

typedef enum _command_t
{
RDID, /* Write Status Register */
RDSR, /* Read Status Register */
RDCR, /* Read Configuration Register */
WREN, /* Write Enable */
WRDI, /* Write Disable */
WRSR, /* Write Status Register */
PP4, /* Quad Page Program */
QPP, /* Quad Input Page Program */
QREAD, /* 1I-4O read */
SE, /* Sector Erase */
READ, /* Read */
DREAD, /* 1I-2O read */
READ2, /* 2I-2O read */
PP, /* Page Program */
READ4, /* 4I-4O read */
BE64K, /* Block Erase */
BE32K, /* Block Erase */
CE, /* Chip Erase */
DP, /* Deep Power Down */
RSTEN, /* Reset Enable*/
RST, /* Reset*/
MAX_CMD
} command_t;

/*******************************************************************************
* Prototypes
******************************************************************************/

/*******************************************************************************
* Variables
******************************************************************************/
int16_t g_buffer[PAGE_SIZE] = {0};

spifi_command_t command[] = {
[RDID] = {4, false, kSPIFI_DataInput, 0, kSPIFI_CommandAllSerial, kSPIFI_CommandOpcodeOnly, 0x9F},
[RDSR] = {1, false, kSPIFI_DataInput, 0, kSPIFI_CommandAllSerial, kSPIFI_CommandOpcodeOnly, 0x05},
[RDCR] = {4, false, kSPIFI_DataInput, 0, kSPIFI_CommandAllSerial, kSPIFI_CommandOpcodeOnly, 0x15},
[WREN] = {0, false, kSPIFI_DataOutput, 0, kSPIFI_CommandAllSerial, kSPIFI_CommandOpcodeOnly, 0x06},
[WRDI] = {0, false, kSPIFI_DataOutput, 0, kSPIFI_CommandAllSerial, kSPIFI_CommandOpcodeOnly, 0x04},
[WRSR] = {3, false, kSPIFI_DataOutput, 0, kSPIFI_CommandAllSerial, kSPIFI_CommandOpcodeOnly, 0x01},
[PP4] = {PAGE_SIZE, false, kSPIFI_DataOutput, 0, kSPIFI_CommandOpcodeSerial, kSPIFI_CommandOpcodeAddrThreeBytes,
0x38},
[QPP] = {PAGE_SIZE, false, kSPIFI_DataOutput, 0, kSPIFI_CommandDataQuad, kSPIFI_CommandOpcodeAddrThreeBytes, 0x32},
[QREAD] = {PAGE_SIZE, false, kSPIFI_DataInput, 1, kSPIFI_CommandDataQuad, kSPIFI_CommandOpcodeAddrThreeBytes, 0x6B},
[SE] = {0, false, kSPIFI_DataOutput, 0, kSPIFI_CommandAllSerial, kSPIFI_CommandOpcodeAddrThreeBytes, 0x20},
[READ] = {PAGE_SIZE, false, kSPIFI_DataInput, 0, kSPIFI_CommandAllSerial, kSPIFI_CommandOpcodeAddrThreeBytes, 0x03},
[DREAD] = {PAGE_SIZE, false, kSPIFI_DataInput, 1, kSPIFI_CommandDataQuad, kSPIFI_CommandOpcodeAddrThreeBytes, 0x3B},
[READ2] = {PAGE_SIZE, false, kSPIFI_DataInput, 1, kSPIFI_CommandOpcodeSerial, kSPIFI_CommandOpcodeAddrThreeBytes,
0xBB},
[PP] = {PAGE_SIZE, false, kSPIFI_DataOutput, 0, kSPIFI_CommandAllSerial, kSPIFI_CommandOpcodeAddrThreeBytes, 0x02},
[READ4] = {PAGE_SIZE, false, kSPIFI_DataInput, 3, kSPIFI_CommandOpcodeSerial, kSPIFI_CommandOpcodeAddrThreeBytes,
0xEB},
[BE64K] = {0, false, kSPIFI_DataOutput, 0, kSPIFI_CommandAllSerial, kSPIFI_CommandOpcodeAddrThreeBytes, 0xD8},
[BE32K] = {0, false, kSPIFI_DataOutput, 0, kSPIFI_CommandAllSerial, kSPIFI_CommandOpcodeAddrThreeBytes, 0x52},
[CE] = {0, false, kSPIFI_DataOutput, 0, kSPIFI_CommandAllSerial, kSPIFI_CommandOpcodeOnly, 0x60},
[DP] = {0, false, kSPIFI_DataOutput, 0, kSPIFI_CommandAllSerial, kSPIFI_CommandOpcodeOnly, 0xB9},
[RSTEN] = {0, false, kSPIFI_DataOutput, 0, kSPIFI_CommandAllSerial, kSPIFI_CommandOpcodeOnly, 0x66},
[RST] = {0, false, kSPIFI_DataOutput, 0, kSPIFI_CommandAllSerial, kSPIFI_CommandOpcodeOnly, 0x99},
};

/*******************************************************************************
* Code
******************************************************************************/
uint32_t get_status_register(void)
{
int32_t val = 0;

SPIFI_SetCommand(EXAMPLE_SPIFI, &command[RDSR]);
while ((EXAMPLE_SPIFI->STAT & SPIFI_STAT_INTRQ_MASK) == 0U)
{
}

val = SPIFI_ReadPartialWord(SPIFI, command[RDSR].dataLen);

return val;
}

void check_if_finish()
{
int32_t val = 0;
/* Polling the WIP bit to make sure SPIFI flash is not in write operation */
do
{
val = get_status_register();
} while (val & SR_WIP_MASK);
}

void enable_quad_mode()
{
int32_t val = 0;

/* Send the WREN command and polling the WEL bit */
do
{
SPIFI_SetCommand(EXAMPLE_SPIFI, &command[WREN]);

val = get_status_register();
} while (!(val & SR_WEL_MASK));

/* Set write register command */
SPIFI_SetCommand(EXAMPLE_SPIFI, &command[WRSR]);

SPIFI_WritePartialWord(EXAMPLE_SPIFI, SR_QE(1U), command[WRSR].dataLen);

/* Polling the WIP bit to make sure SPIFI flash is not in write operation */
do
{
val = get_status_register();
} while (val & SR_WIP_MASK);

/* Check the QE bit of the status register to make sure quad mode is enabled */
do
{
val = get_status_register();
} while (!(val & SR_QE_MASK));
}

int main(void)
{
spifi_config_t config = {0};
int32_t i = 0, j = 0, data = 0, page = 0, err = 0;
int8_t *val = (int8_t *)FSL_FEATURE_SPIFI_START_ADDR;

/* Init the boards */
/* Security code to allow debug access */
SYSCON->CODESECURITYPROT = 0x87654320;

/* attach clock for USART(debug console) */
CLOCK_AttachClk(BOARD_DEBUG_UART_CLK_ATTACH);

/* reset FLEXCOMM for USART */
RESET_PeripheralReset(kFC0_RST_SHIFT_RSTn);

#if (BOARD_BOOTCLOCKRUN_CORE_CLOCK > 32000000U)
/* When the CPU clock frequency is increased,
* the Set Read command shall be called before the frequency change. */
FLASH_SetReadMode(FLASH, true);
#endif
BOARD_BootClockRUN();
BOARD_InitDebugConsole();
BOARD_InitPins();

uint32_t sourceClockFreq;

/* Set SPIFI clock source */
CLOCK_AttachClk(EXAMPLE_SPIFI_CLK_SRC);
sourceClockFreq = CLOCK_GetSpifiClkFreq();
/* Set the clock divider */
uint32_t divisor;
/* Do not set null divisor value */
divisor = sourceClockFreq / EXAMPLE_SPI_BAUDRATE;
CLOCK_SetClkDiv(kCLOCK_DivSpifiClk, divisor ? divisor : 1, false);

PRINTF("SPIFI flash polling example started\r\n");

/* Initialize SPIFI */
SPIFI_GetDefaultConfig(&config);
SPIFI_Init(EXAMPLE_SPIFI, &config);

/* Reset the SPIFI to switch to command mode */
SPIFI_ResetCommand(EXAMPLE_SPIFI);
EnableIRQ(SPIFI0_IRQn);

/* Reset Device*/
SPIFI_SetCommand(EXAMPLE_SPIFI, &command[RSTEN]);
SPIFI_SetCommand(EXAMPLE_SPIFI, &command[RST]);
check_if_finish();

/* Enable Quad mode */
enable_quad_mode();

/* Setup memory command */
SPIFI_SetMemoryCommand(EXAMPLE_SPIFI, &command[QREAD]);

/* Set the buffer */
for (i = 0; i < 256; i++)
{
g_buffer[i] =3;
PRINTF("%d", g_buffer[i]);
}
/* Reset the SPIFI to switch to command mode */
SPIFI_ResetCommand(EXAMPLE_SPIFI);
/* Write enable */
SPIFI_SetCommand(EXAMPLE_SPIFI, &command[WREN]);
/* Set address */
SPIFI_SetCommandAddress(EXAMPLE_SPIFI, FSL_FEATURE_SPIFI_START_ADDR);
/* Erase sector */
SPIFI_SetCommand(EXAMPLE_SPIFI, &command[SE]);
/* Check if finished */
check_if_finish();

/* Program page */

while (page < (SECTOR_SIZE / PAGE_SIZE))
{
SPIFI_SetCommand(EXAMPLE_SPIFI, &command[WREN]);
SPIFI_SetCommandAddress(EXAMPLE_SPIFI, FSL_FEATURE_SPIFI_START_ADDR + page * PAGE_SIZE);
SPIFI_SetCommand(EXAMPLE_SPIFI, &command[PP]);
for (i = 0; i < PAGE_SIZE; i += 4)
{
for (j = 0; j < 4; j++)
{
data |= ((int32_t)(g_buffer[i + j])) << (j * 8);
}
SPIFI_WriteData(EXAMPLE_SPIFI, data);
data = 0;
}
page++;
check_if_finish();
}

/* Reset to memory command mode */
SPIFI_ResetCommand(EXAMPLE_SPIFI);

SPIFI_SetMemoryCommand(EXAMPLE_SPIFI, &command[READ]);

for (i = 0; i < SECTOR_SIZE; i++)
{
val = (int8_t *)(FSL_FEATURE_SPIFI_START_ADDR + i);
if(*val <0)
{
PRINTF("%d", *val);
}
if (*val != g_buffer[i % PAGE_SIZE])
{
PRINTF("Data error in address 0x%x, the value in memory is 0x%x\r\n", i, *val);
err++;
}
}

if (err == 0)
{
PRINTF("All data written is correct!\r\n");
}

PRINTF("SPIFI Polling example Finished!\r\n");

while (1)
{
}
}
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EduardoZamora
NXP TechSupport
NXP TechSupport

Hi,

Some of the arrays used to initialize, write or read the values may be declared as an uint (unsigned int) type, and you may need to change those declarations to some type of signed int in order to work with signed integer values.

You can try changing, for example, g_buffer, val, data from uint to a signed integer (int) type; the same should apply for the corresponding type castings.

Regards,
Eduardo.

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paidaxing
Contributor III
Hi,
I have followed your advice,change the g_buffer ,val ,data from uint to a signed integer (int) type; but it can not work.

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EduardoZamora
NXP TechSupport
NXP TechSupport

Hi,

How are you testing the application?

What is the output you are getting?

Also, there should be a newer SDK version for this device. Please, consider testing the application using the latest JN5189 SDK version that can be downloaded from the MCUXpresso SDK Builder.

Regards,
Eduardo.

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paidaxing
Contributor III
Hi,
I change the code as follows:

for (i = 0; i < 256; i++)
{
g_buffer[i] =-1;
PRINTF("%d", g_buffer[i]);
}
and use the terminal to output the results. it can not output it correctly.
thanks
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EduardoZamora
NXP TechSupport
NXP TechSupport

Hi,

Could you please provide more details on the behavior you are observing in your application? What information is being printed on the serial terminal? Can you share a screenshot of the output?

For example, the following lines should be printed to the serial terminal when the demo is executed successfully:

EduardoZamora_0-1701357327936.png

Regards,
Eduardo.

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paidaxing
Contributor III

 

Hi,

Here is the output,I only change the g_buffer[i] form unint to int ,and assign a negative value to the number to be stored.

 

1701410680480.png1701411316256.png

thanks

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EduardoZamora
NXP TechSupport
NXP TechSupport

Hi,

You can try, for example, changing the following line:

data |= ((uint32_t)(g_buffer[i + j])) << (j * 8);

to:

data |= ((int32_t)(g_buffer[i + j] & 0xFF)) << (j * 8);

when programming the page.

Regards,
Eduardo.

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paidaxing
Contributor III
Hi,
Using your method, only the negative of the original negative number is obtained. Can you use this method to store and read out smoothly? If so, please tell me your program.
thanks
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EduardoZamora
NXP TechSupport
NXP TechSupport

Hi,

Can you clarify what you mean by "only the negative of the original negative number is obtained"?

Regards,
Eduardo.

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paidaxing
Contributor III
Hi,
It means that I can only obtain the the opposite of a negative number for example, i want to store -5 it only obtain 5.
thanks.
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EduardoZamora
NXP TechSupport
NXP TechSupport

Hi,

Are you referring to the serial terminal output? If that is the case, you can try the following to print negative numbers in console:

In project/utilities/fsl_debug_console_conf.h file, change #define PRINTF_ADVANCED_ENABLE from 0U to 1U.

Regards,
Eduardo.

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paidaxing
Contributor III
Hi,
I mean that the data written is consistent with the data read,they are the opposite of each other.So ,I want to know if you successfully write and read correctly.
thanks.
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