How to set the firmware code ?

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Anonymous
Not applicable

Hi.

   

 

   

Please check attached my configure setting image.

   

I'd like to make slave fifo mode  8bit, and I2C

   

I want to know  how to make the code to my intend.

   

 

   

Would you help me what should I do?

   

 

   

-------

   

/*
 ## Cypress USB 3.0 Platform source file (cyfxslfifosync.c)
 ## ===========================
 ##
 ##  Copyright Cypress Semiconductor Corporation, 2010-2011,
 ##  All Rights Reserved
 ##  UNPUBLISHED, LICENSED SOFTWARE.
 ##
 ##  CONFIDENTIAL AND PROPRIETARY INFORMATION
 ##  WHICH IS THE PROPERTY OF CYPRESS.
 ##
 ##  Use of this file is governed
 ##  by the license agreement included in the file
 ##
 ##     <install>/license/license.txt
 ##
 ##  where <install> is the Cypress software
 ##  installation root directory path.
 ##
 ## ===========================
*/

   

/* This file illustrates the Slave FIFO Synchronous mode example */

   

/*
   This example comprises of two USB bulk endpoints. A bulk OUT endpoint acts as the
   producer of data from the host. A bulk IN endpoint acts as the consumer of data to
   the host. Appropriate vendor class USB enumeration descriptors with these two bulk
   endpoints are implemented.

   

   The GPIF configuration data for the Synchronous Slave FIFO operation is loaded onto
   the appropriate GPIF registers. The p-port data transfers are done via the producer
   p-port socket and the consumer p-port socket.

   

   This example implements two DMA Channels either in MANUAL mode or AUTO mode (depending
   on #define MANUAL in cyfxslfifosync.h) one for P to U data transfer and one for U to P
   data transfer.

   

   The U to P DMA channel connects the USB producer (OUT) endpoint to the consumer p-port
   socket. And the P to U DMA channel connects the producer p-port socket to the USB 
   consumer (IN) endpoint.

   

   In case of MANUAL DMA channel, Upon every reception of data in the DMA buffer from the
   host or from the p-port, the CPU is signaled using DMA callbacks. There are two DMA callback
   functions implemented each for U to P and P to U data paths. The CPU then commits the DMA buffer received so
   that the data is transferred to the consumer.

   

   In case of AUTO DMA channel, the data will be transferred between U and P ports automatically
   without any intervention from the CPU.

   

   The DMA buffer size is configured differently based on the usage. #define LOOPBACK_SHRT_ZLP in cyfxslfifosync.h
   configures the DMA buffers for doing data loopback. Also, DMA buffer for each channel is defined based on the
   USB speed. 64 bytes for full speed, 512 bytes for high speed and 1024 bytes for super speed.
   #define STREAM_IN_OUT in cyfxslfifosync.h configures the DMA buffers for higher bandwidth data transfers.
   16*64 bytes for full speed, 16*512 bytes for high speed and 16*1024 bytes for super speed.

   

   CY_FX_SLFIFO_DMA_BUF_COUNT_P_2_U in cyfxslfifosync.h defines the number of DMA buffers allocated for P to U data path.
   CY_FX_SLFIFO_DMA_BUF_COUNT_U_2_P in cyfxslfifosync.h defines the number of DMA buffers allocated for U to P data path.

   

   The constant CY_FX_SLFIFO_GPIF_16_32BIT_CONF_SELECT in the header file is used to
   select 16bit or 32bit GPIF data bus configuration.
 */

   

#include "cyu3system.h"
#include "cyu3os.h"
#include "cyu3dma.h"
#include "cyu3error.h"
#include "cyu3usb.h"
#include "cyu3uart.h"
#include "cyfxslfifosync.h"
#include "cyu3gpif.h"
#include "cyu3pib.h"
#include "pib_regs.h"
#include <cyu3gpio.h>

   

/* This file should be included only once as it contains
 * structure definitions. Including it in multiple places
 * can result in linker error. */

   

#include "cyfxgpif2config.h"

   


CyU3PThread slFifoAppThread;            /* Slave FIFO application thread structure */
CyU3PDmaChannel glChHandleSlFifoUtoP;   /* DMA Channel handle for U2P transfer. */
CyU3PDmaChannel glChHandleSlFifoPtoU;   /* DMA Channel handle for P2U transfer. */

   

uint32_t glDMARxCount = 0;               /* Counter to track the number of buffers received from USB. */
uint32_t glDMATxCount = 0;               /* Counter to track the number of buffers sent to USB. */
CyBool_t glIsApplnActive = CyFalse;      /* Whether the loopback application is active or not. */
uint8_t burstLength = 0;
/* Application Error Handler */
void
CyFxAppErrorHandler (
        CyU3PReturnStatus_t apiRetStatus    /* API return status */
        )
{
    /* Application failed with the error code apiRetStatus */

   

    /* Add custom debug or recovery actions here */

   

    /* Loop Indefinitely */
    for (;;)
    {
        /* Thread sleep : 100 ms */
        CyU3PThreadSleep (100);
    }
}

   

/* This function initializes the debug module. The debug prints
 * are routed to the UART and can be seen using a UART console
 * running at 115200 baud rate. */
void
CyFxSlFifoApplnDebugInit (void)
{
    CyU3PUartConfig_t uartConfig;
    CyU3PReturnStatus_t apiRetStatus = CY_U3P_SUCCESS;
    /* Initialize the UART for printing debug messages */
    apiRetStatus = CyU3PUartInit();
    if (apiRetStatus != CY_U3P_SUCCESS)
    {
        /* Error handling */
        CyFxAppErrorHandler(apiRetStatus);
    }

   

    /* Set UART configuration */
    CyU3PMemSet ((uint8_t *)&uartConfig, 0, sizeof (uartConfig));
    uartConfig.baudRate = CY_U3P_UART_BAUDRATE_115200;
    uartConfig.stopBit = CY_U3P_UART_ONE_STOP_BIT;
    uartConfig.parity = CY_U3P_UART_NO_PARITY;
    uartConfig.txEnable = CyTrue;
    uartConfig.rxEnable = CyFalse;
    uartConfig.flowCtrl = CyFalse;
    uartConfig.isDma = CyTrue;

   

    apiRetStatus = CyU3PUartSetConfig (&uartConfig, NULL);
    if (apiRetStatus != CY_U3P_SUCCESS)
    {
        CyFxAppErrorHandler(apiRetStatus);
    }

   

    /* Set the UART transfer to a really large value. */
    apiRetStatus = CyU3PUartTxSetBlockXfer (0xFFFFFFFF);
    if (apiRetStatus != CY_U3P_SUCCESS)
    {
        CyFxAppErrorHandler(apiRetStatus);
    }

   

    /* Initialize the debug module. */
    apiRetStatus = CyU3PDebugInit (CY_U3P_LPP_SOCKET_UART_CONS, 8);
    if (apiRetStatus != CY_U3P_SUCCESS)
    {
        CyFxAppErrorHandler(apiRetStatus);
    }
}

   

/* DMA callback function to handle the produce events for U to P transfers. */
void
CyFxSlFifoUtoPDmaCallback (
        CyU3PDmaChannel   *chHandle,
        CyU3PDmaCbType_t  type,
        CyU3PDmaCBInput_t *input
        )
{
    CyU3PReturnStatus_t status = CY_U3P_SUCCESS;

   

    if (type == CY_U3P_DMA_CB_PROD_EVENT)
    {
        /* This is a produce event notification to the CPU. This notification is 
         * received upon reception of every buffer. The buffer will not be sent
         * out unless it is explicitly committed. The call shall fail if there
         * is a bus reset / usb disconnect or if there is any application error. */
        status = CyU3PDmaChannelCommitBuffer (chHandle, input->buffer_p.count, 0);
        if (status != CY_U3P_SUCCESS)
        {
            CyU3PDebugPrint (4, "CyU3PDmaChannelCommitBuffer failed, Error code = %d\n", status);
        }

   

        /* Increment the counter. */
        glDMARxCount++;
    }
}

   

/* DMA callback function to handle the produce events for P to U transfers. */
void
CyFxSlFifoPtoUDmaCallback (
        CyU3PDmaChannel   *chHandle,
        CyU3PDmaCbType_t  type,
        CyU3PDmaCBInput_t *input
        )
{
    CyU3PReturnStatus_t status = CY_U3P_SUCCESS;

   

    if (type == CY_U3P_DMA_CB_PROD_EVENT)
    {
        /* This is a produce event notification to the CPU. This notification is 
         * received upon reception of every buffer. The buffer will not be sent
         * out unless it is explicitly committed. The call shall fail if there
         * is a bus reset / usb disconnect or if there is any application error. */
        status = CyU3PDmaChannelCommitBuffer (chHandle, input->buffer_p.count, 0);
        if (status != CY_U3P_SUCCESS)
        {
            CyU3PDebugPrint (4, "CyU3PDmaChannelCommitBuffer failed, Error code = %d\n", status);
        }

   

        /* Increment the counter. */
        glDMATxCount++;
    }
}

   

/* This function starts the slave FIFO loop application. This is called
 * when a SET_CONF event is received from the USB host. The endpoints
 * are configured and the DMA pipe is setup in this function. */
void
CyFxSlFifoApplnStart (
        void)
{
    uint16_t size = 0;
    CyU3PEpConfig_t epCfg;
    CyU3PDmaChannelConfig_t dmaCfg;
    CyU3PReturnStatus_t apiRetStatus = CY_U3P_SUCCESS;
    CyU3PUSBSpeed_t usbSpeed = CyU3PUsbGetSpeed();

   

    /* First identify the usb speed. Once that is identified,
     * create a DMA channel and start the transfer on this. */

   

    /* Based on the Bus Speed configure the endpoint packet size */
    switch (usbSpeed)
    {
        case CY_U3P_FULL_SPEED:
            size = 64;
            break;

   

        case CY_U3P_HIGH_SPEED:
            size = 512;
            burstLength=1;

   

            break;

   

        case  CY_U3P_SUPER_SPEED:
            size = 1024;
            burstLength=16;
            break;

   

        default:
            CyU3PDebugPrint (4, "Error! Invalid USB speed.\n");
            CyFxAppErrorHandler (CY_U3P_ERROR_FAILURE);
            break;
    }

   

    CyU3PMemSet ((uint8_t *)&epCfg, 0, sizeof (epCfg));
    epCfg.enable = CyTrue;
    epCfg.epType = CY_U3P_USB_EP_BULK;
#ifdef STREAM_IN_OUT
    epCfg.burstLen = burstLength;
#else
    epCfg.burstLen = 1;
#endif
    epCfg.streams = 0;
    epCfg.pcktSize = size;

   

    /* Producer endpoint configuration */
    apiRetStatus = CyU3PSetEpConfig(CY_FX_EP_PRODUCER, &epCfg);
    if (apiRetStatus != CY_U3P_SUCCESS)
    {
        CyU3PDebugPrint (4, "CyU3PSetEpConfig failed, Error code = %d\n", apiRetStatus);
        CyFxAppErrorHandler (apiRetStatus);
    }

   

    /* Consumer endpoint configuration */
    apiRetStatus = CyU3PSetEpConfig(CY_FX_EP_CONSUMER, &epCfg);
    if (apiRetStatus != CY_U3P_SUCCESS)
    {
        CyU3PDebugPrint (4, "CyU3PSetEpConfig failed, Error code = %d\n", apiRetStatus);
        CyFxAppErrorHandler (apiRetStatus);
    }

   

#ifdef MANUAL
    /* Create a DMA MANUAL channel for U2P transfer.
     * DMA size is set based on the USB speed. */
    dmaCfg.size  = DMA_BUF_SIZE* size;
    dmaCfg.count = CY_FX_SLFIFO_DMA_BUF_COUNT_U_2_P;
    dmaCfg.prodSckId = CY_FX_PRODUCER_USB_SOCKET;
    dmaCfg.consSckId = CY_FX_CONSUMER_PPORT_SOCKET;
    dmaCfg.dmaMode = CY_U3P_DMA_MODE_BYTE;
    /* Enabling the callback for produce event. */
    dmaCfg.notification = CY_U3P_DMA_CB_PROD_EVENT;
    dmaCfg.cb = CyFxSlFifoUtoPDmaCallback;
    dmaCfg.prodHeader = 0;
    dmaCfg.prodFooter = 0;
    dmaCfg.consHeader = 0;
    dmaCfg.prodAvailCount = 0;

   

    apiRetStatus = CyU3PDmaChannelCreate (&glChHandleSlFifoUtoP,
            CY_U3P_DMA_TYPE_MANUAL, &dmaCfg);
    if (apiRetStatus != CY_U3P_SUCCESS)
    {
        CyU3PDebugPrint (4, "CyU3PDmaChannelCreate failed, Error code = %d\n", apiRetStatus);
        CyFxAppErrorHandler(apiRetStatus);
    }

   

    /* Create a DMA MANUAL channel for P2U transfer. */
    dmaCfg.prodSckId = CY_FX_PRODUCER_PPORT_SOCKET;
    dmaCfg.consSckId = CY_FX_CONSUMER_USB_SOCKET;
    dmaCfg.count = CY_FX_SLFIFO_DMA_BUF_COUNT_P_2_U;
    dmaCfg.cb = CyFxSlFifoPtoUDmaCallback;
    apiRetStatus = CyU3PDmaChannelCreate (&glChHandleSlFifoPtoU,
            CY_U3P_DMA_TYPE_MANUAL, &dmaCfg);

   

#else
    /* Create a DMA AUTO channel for U2P transfer.
       DMA size is set based on the USB speed. */
    dmaCfg.size  = DMA_BUF_SIZE* size;
    dmaCfg.count = CY_FX_SLFIFO_DMA_BUF_COUNT_U_2_P;
    dmaCfg.prodSckId = CY_FX_PRODUCER_USB_SOCKET;
    dmaCfg.consSckId = CY_FX_CONSUMER_PPORT_SOCKET;
    dmaCfg.dmaMode = CY_U3P_DMA_MODE_BYTE;
    /* Enabling the callback for produce event. */
    dmaCfg.notification = 0;
    dmaCfg.cb = NULL;
    dmaCfg.prodHeader = 0;
    dmaCfg.prodFooter = 0;
    dmaCfg.consHeader = 0;
    dmaCfg.prodAvailCount = 0;

   

    apiRetStatus = CyU3PDmaChannelCreate (&glChHandleSlFifoUtoP,
               CY_U3P_DMA_TYPE_AUTO, &dmaCfg);
    if (apiRetStatus != CY_U3P_SUCCESS)
    {
       CyU3PDebugPrint (4, "CyU3PDmaChannelCreate failed, Error code = %d\n", apiRetStatus);
       CyFxAppErrorHandler(apiRetStatus);
    }

   

    /* Create a DMA AUTO channel for P2U transfer. */
    dmaCfg.size  = DMA_BUF_SIZE*size; //increase buffer size for higher performance
    dmaCfg.count = CY_FX_SLFIFO_DMA_BUF_COUNT_P_2_U; // increase buffer count for higher performance
    dmaCfg.prodSckId = CY_FX_PRODUCER_PPORT_SOCKET;
    dmaCfg.consSckId = CY_FX_CONSUMER_USB_SOCKET;
    dmaCfg.cb = NULL;
    apiRetStatus = CyU3PDmaChannelCreate (&glChHandleSlFifoPtoU,
               CY_U3P_DMA_TYPE_AUTO, &dmaCfg);

   

    if (apiRetStatus != CY_U3P_SUCCESS)
    {
        CyU3PDebugPrint (4, "CyU3PDmaChannelCreate failed, Error code = %d\n", apiRetStatus);
        CyFxAppErrorHandler(apiRetStatus);
    }

   

#endif

   

    /* Flush the Endpoint memory */
    CyU3PUsbFlushEp(CY_FX_EP_PRODUCER);
    CyU3PUsbFlushEp(CY_FX_EP_CONSUMER);

   

    /* Set DMA channel transfer size. */
    apiRetStatus = CyU3PDmaChannelSetXfer (&glChHandleSlFifoUtoP, CY_FX_SLFIFO_DMA_TX_SIZE);
    if (apiRetStatus != CY_U3P_SUCCESS)
    {
        CyU3PDebugPrint (4, "CyU3PDmaChannelSetXfer Failed, Error code = %d\n", apiRetStatus);
        CyFxAppErrorHandler(apiRetStatus);
    }
    apiRetStatus = CyU3PDmaChannelSetXfer (&glChHandleSlFifoPtoU, CY_FX_SLFIFO_DMA_RX_SIZE);
    if (apiRetStatus != CY_U3P_SUCCESS)
    {
        CyU3PDebugPrint (4, "CyU3PDmaChannelSetXfer Failed, Error code = %d\n", apiRetStatus);
        CyFxAppErrorHandler(apiRetStatus);
    }

   

    /* Update the status flag. */
    glIsApplnActive = CyTrue;
    CyU3PGpioSetValue (59, CyFalse);
}

   

/* This function stops the slave FIFO loop application. This shall be called
 * whenever a RESET or DISCONNECT event is received from the USB host. The
 * endpoints are disabled and the DMA pipe is destroyed by this function. */
void
CyFxSlFifoApplnStop (
        void)
{
    CyU3PEpConfig_t epCfg;
    CyU3PReturnStatus_t apiRetStatus = CY_U3P_SUCCESS;

   

    /* Update the flag. */
    glIsApplnActive = CyFalse;

   

    /* Flush the endpoint memory */
    CyU3PUsbFlushEp(CY_FX_EP_PRODUCER);
    CyU3PUsbFlushEp(CY_FX_EP_CONSUMER);

   

    /* Destroy the channel */
    CyU3PDmaChannelDestroy (&glChHandleSlFifoUtoP);
    CyU3PDmaChannelDestroy (&glChHandleSlFifoPtoU);

   

    /* Disable endpoints. */
    CyU3PMemSet ((uint8_t *)&epCfg, 0, sizeof (epCfg));
    epCfg.enable = CyFalse;

   

    /* Producer endpoint configuration. */
    apiRetStatus = CyU3PSetEpConfig(CY_FX_EP_PRODUCER, &epCfg);
    if (apiRetStatus != CY_U3P_SUCCESS)
    {
        CyU3PDebugPrint (4, "CyU3PSetEpConfig failed, Error code = %d\n", apiRetStatus);
        CyFxAppErrorHandler (apiRetStatus);
    }

   

    /* Consumer endpoint configuration. */
    apiRetStatus = CyU3PSetEpConfig(CY_FX_EP_CONSUMER, &epCfg);
    if (apiRetStatus != CY_U3P_SUCCESS)
    {
        CyU3PDebugPrint (4, "CyU3PSetEpConfig failed, Error code = %d\n", apiRetStatus);
        CyFxAppErrorHandler (apiRetStatus);
    }
}

   

/* Callback to handle the USB setup requests. */
CyBool_t
CyFxSlFifoApplnUSBSetupCB (
        uint32_t setupdat0,
        uint32_t setupdat1
    )
{
    /* Fast enumeration is used. Only requests addressed to the interface, class,
     * vendor and unknown control requests are received by this function.
     * This application does not support any class or vendor requests. */

   

    uint8_t  bRequest, bReqType;
    uint8_t  bType, bTarget;
    uint16_t wValue, wIndex;
    CyBool_t isHandled = CyFalse;

   

    /* Decode the fields from the setup request. */
    bReqType = (setupdat0 & CY_U3P_USB_REQUEST_TYPE_MASK);
    bType    = (bReqType & CY_U3P_USB_TYPE_MASK);
    bTarget  = (bReqType & CY_U3P_USB_TARGET_MASK);
    bRequest = ((setupdat0 & CY_U3P_USB_REQUEST_MASK) >> CY_U3P_USB_REQUEST_POS);
    wValue   = ((setupdat0 & CY_U3P_USB_VALUE_MASK)   >> CY_U3P_USB_VALUE_POS);
    wIndex   = ((setupdat1 & CY_U3P_USB_INDEX_MASK)   >> CY_U3P_USB_INDEX_POS);

   

    if (bType == CY_U3P_USB_STANDARD_RQT)
    {
        /* Handle SET_FEATURE(FUNCTION_SUSPEND) and CLEAR_FEATURE(FUNCTION_SUSPEND)
         * requests here. It should be allowed to pass if the device is in configured
         * state and failed otherwise. */
        if ((bTarget == CY_U3P_USB_TARGET_INTF) && ((bRequest == CY_U3P_USB_SC_SET_FEATURE)
                    || (bRequest == CY_U3P_USB_SC_CLEAR_FEATURE)) && (wValue == 0))
        {
            if (glIsApplnActive)
                CyU3PUsbAckSetup ();
            else
                CyU3PUsbStall (0, CyTrue, CyFalse);

   

            isHandled = CyTrue;
        }

   

        /* CLEAR_FEATURE request for endpoint is always passed to the setup callback
         * regardless of the enumeration model used. When a clear feature is received,
         * the previous transfer has to be flushed and cleaned up. This is done at the
         * protocol level. Since this is just a loopback operation, there is no higher
         * level protocol. So flush the EP memory and reset the DMA channel associated
         * with it. If there are more than one EP associated with the channel reset both
         * the EPs. The endpoint stall and toggle / sequence number is also expected to be
         * reset. Return CyFalse to make the library clear the stall and reset the endpoint
         * toggle. Or invoke the CyU3PUsbStall (ep, CyFalse, CyTrue) and return CyTrue.
         * Here we are clearing the stall. */
        if ((bTarget == CY_U3P_USB_TARGET_ENDPT) && (bRequest == CY_U3P_USB_SC_CLEAR_FEATURE)
                && (wValue == CY_U3P_USBX_FS_EP_HALT))
        {
            if (glIsApplnActive)
            {
                if (wIndex == CY_FX_EP_PRODUCER)
                {
                    CyU3PDmaChannelReset (&glChHandleSlFifoUtoP);
                    CyU3PUsbFlushEp(CY_FX_EP_PRODUCER);
                    CyU3PUsbResetEp (CY_FX_EP_PRODUCER);
                    CyU3PDmaChannelSetXfer (&glChHandleSlFifoUtoP, CY_FX_SLFIFO_DMA_TX_SIZE);
                }

   

                if (wIndex == CY_FX_EP_CONSUMER)
                {
                    CyU3PDmaChannelReset (&glChHandleSlFifoPtoU);
                    CyU3PUsbFlushEp(CY_FX_EP_CONSUMER);
                    CyU3PUsbResetEp (CY_FX_EP_CONSUMER);
                    CyU3PDmaChannelSetXfer (&glChHandleSlFifoPtoU, CY_FX_SLFIFO_DMA_RX_SIZE);
                }

   

                CyU3PUsbStall (wIndex, CyFalse, CyTrue);
                isHandled = CyTrue;
            }
        }
    }

   

    return isHandled;
}

   

/* This is the callback function to handle the USB events. */
void
CyFxSlFifoApplnUSBEventCB (
    CyU3PUsbEventType_t evtype,
    uint16_t            evdata
    )
{
    switch (evtype)
    {
        case CY_U3P_USB_EVENT_SETCONF:
            /* Stop the application before re-starting. */
            if (glIsApplnActive)
            {
                CyFxSlFifoApplnStop ();
            }
            CyU3PUsbLPMDisable();
            /* Start the loop back function. */
            CyFxSlFifoApplnStart ();
            break;

   

        case CY_U3P_USB_EVENT_RESET:
        case CY_U3P_USB_EVENT_DISCONNECT:
            /* Stop the loop back function. */
            if (glIsApplnActive)
            {
                CyFxSlFifoApplnStop ();
            }
            break;

   

        default:
            break;
    }
}

   

/* Callback function to handle LPM requests from the USB 3.0 host. This function is invoked by the API
   whenever a state change from U0 -> U1 or U0 -> U2 happens. If we return CyTrue from this function, the
   FX3 device is retained in the low power state. If we return CyFalse, the FX3 device immediately tries
   to trigger an exit back to U0.

   

   This application does not have any state in which we should not allow U1/U2 transitions; and therefore
   the function always return CyTrue.
 */
CyBool_t
CyFxApplnLPMRqtCB (
        CyU3PUsbLinkPowerMode link_mode)
{
    return CyTrue;
}

   

void
gpif_error_cb(CyU3PPibIntrType cbType, uint16_t cbArg)
{

   

if(cbType==CYU3P_PIB_INTR_ERROR)
{
    switch (CYU3P_GET_PIB_ERROR_TYPE(cbArg))
    {
        case CYU3P_PIB_ERR_THR0_WR_OVERRUN:
        CyU3PDebugPrint (4, "CYU3P_PIB_ERR_THR0_WR_OVERRUN");
        break;
        case CYU3P_PIB_ERR_THR1_WR_OVERRUN:
        CyU3PDebugPrint (4, "CYU3P_PIB_ERR_THR1_WR_OVERRUN");
        break;
        case CYU3P_PIB_ERR_THR2_WR_OVERRUN:
        CyU3PDebugPrint (4, "CYU3P_PIB_ERR_THR2_WR_OVERRUN");
        break;
        case CYU3P_PIB_ERR_THR3_WR_OVERRUN:
        CyU3PDebugPrint (4, "CYU3P_PIB_ERR_THR3_WR_OVERRUN");
        break;

   

        case CYU3P_PIB_ERR_THR0_RD_UNDERRUN:
        CyU3PDebugPrint (4, "CYU3P_PIB_ERR_THR0_RD_UNDERRUN");
        break;
        case CYU3P_PIB_ERR_THR1_RD_UNDERRUN:
        CyU3PDebugPrint (4, "CYU3P_PIB_ERR_THR1_RD_UNDERRUN");
        break;
        case CYU3P_PIB_ERR_THR2_RD_UNDERRUN:
        CyU3PDebugPrint (4, "CYU3P_PIB_ERR_THR2_RD_UNDERRUN");
        break;
        case CYU3P_PIB_ERR_THR3_RD_UNDERRUN:
        CyU3PDebugPrint (4, "CYU3P_PIB_ERR_THR3_RD_UNDERRUN");
        break;

   

        default:
        CyU3PDebugPrint (4, "No Error :%d\n ",CYU3P_GET_PIB_ERROR_TYPE(cbArg));
            break;
    }
}

   

}

   

 

   

/* This function initializes the GPIF interface and initializes
 * the USB interface. */
void
CyFxSlFifoApplnInit (void)
{
    CyU3PPibClock_t pibClock;
    CyU3PGpioClock_t gpioClock;
    CyU3PGpioSimpleConfig_t gpioConfig;
    CyU3PReturnStatus_t apiRetStatus = CY_U3P_SUCCESS;

   

    /* Initialize the p-port block. */
    pibClock.clkDiv = 2;
    pibClock.clkSrc = CY_U3P_SYS_CLK;
    pibClock.isHalfDiv = CyFalse;
    /* Disable DLL for sync GPIF */
    pibClock.isDllEnable = CyFalse;
    apiRetStatus = CyU3PPibInit(CyTrue, &pibClock);
    if (apiRetStatus != CY_U3P_SUCCESS)
    {
        CyU3PDebugPrint (4, "P-port Initialization failed, Error Code = %d\n",apiRetStatus);
        CyFxAppErrorHandler(apiRetStatus);
    }

   

    /* Load the GPIF configuration for Slave FIFO sync mode. */
    apiRetStatus = CyU3PGpifLoad (&CyFxGpifConfig);
    if (apiRetStatus != CY_U3P_SUCCESS)
    {
        CyU3PDebugPrint (4, "CyU3PGpifLoad failed, Error Code = %d\n",apiRetStatus);
        CyFxAppErrorHandler(apiRetStatus);
    }

   

    CyU3PGpifSocketConfigure (0,CY_U3P_PIB_SOCKET_0,6,CyFalse,1);

   

   CyU3PGpifSocketConfigure (3,CY_U3P_PIB_SOCKET_3,6,CyFalse,1);

   

    /* Start the state machine. */
    apiRetStatus = CyU3PGpifSMStart (RESET,ALPHA_RESET);
    if (apiRetStatus != CY_U3P_SUCCESS)
    {
        CyU3PDebugPrint (4, "CyU3PGpifSMStart failed, Error Code = %d\n",apiRetStatus);
        CyFxAppErrorHandler(apiRetStatus);
    }

   

    /* Init the GPIO module */
    gpioClock.fastClkDiv = 2;
    gpioClock.slowClkDiv = 0;
    gpioClock.simpleDiv = CY_U3P_GPIO_SIMPLE_DIV_BY_2;
    gpioClock.clkSrc = CY_U3P_SYS_CLK;
    gpioClock.halfDiv = 0;

   

    apiRetStatus = CyU3PGpioInit(&gpioClock, NULL);
    if (apiRetStatus != 0)
    {
        /* Error Handling */
        CyU3PDebugPrint (4, "CyU3PGpioInit failed, error code = %d\n", apiRetStatus);
        CyFxAppErrorHandler(apiRetStatus);
    }

   

    /* Configure GPIO 59 as output */
    gpioConfig.outValue = CyTrue;
    gpioConfig.driveLowEn = CyTrue;
    gpioConfig.driveHighEn = CyTrue;
    gpioConfig.inputEn = CyFalse;
    gpioConfig.intrMode = CY_U3P_GPIO_NO_INTR;
    apiRetStatus = CyU3PGpioSetSimpleConfig(59, &gpioConfig);
    if (apiRetStatus != CY_U3P_SUCCESS)
    {
        /* Error handling */
        CyU3PDebugPrint (4, "CyU3PGpioSetSimpleConfig failed, error code = %d\n",apiRetStatus);
        CyFxAppErrorHandler(apiRetStatus);
    }

   

    /* Start the USB functionality. */
    apiRetStatus = CyU3PUsbStart();
    if (apiRetStatus != CY_U3P_SUCCESS)
    {
        CyU3PDebugPrint (4, "CyU3PUsbStart failed to Start, Error code = %d\n", apiRetStatus);
        CyFxAppErrorHandler(apiRetStatus);
    }
    /* callback to see if there is any overflow of data on the GPIF II side*/
    CyU3PPibRegisterCallback(gpif_error_cb,0xffff);

   

    /* The fast enumeration is the easiest way to setup a USB connection,
     * where all enumeration phase is handled by the library. Only the
     * class / vendor requests need to be handled by the application. */
    CyU3PUsbRegisterSetupCallback(CyFxSlFifoApplnUSBSetupCB, CyTrue);

   

    /* Setup the callback to handle the USB events. */
    CyU3PUsbRegisterEventCallback(CyFxSlFifoApplnUSBEventCB);

   

    /* Register a callback to handle LPM requests from the USB 3.0 host. */
    CyU3PUsbRegisterLPMRequestCallback(CyFxApplnLPMRqtCB);    

   

    /* Set the USB Enumeration descriptors */

   

    /* Super speed device descriptor. */
    apiRetStatus = CyU3PUsbSetDesc(CY_U3P_USB_SET_SS_DEVICE_DESCR, NULL, (uint8_t *)CyFxUSB30DeviceDscr);
    if (apiRetStatus != CY_U3P_SUCCESS)
    {
        CyU3PDebugPrint (4, "USB set device descriptor failed, Error code = %d\n", apiRetStatus);
        CyFxAppErrorHandler(apiRetStatus);
    }

   

    /* High speed device descriptor. */
    apiRetStatus = CyU3PUsbSetDesc(CY_U3P_USB_SET_HS_DEVICE_DESCR, NULL, (uint8_t *)CyFxUSB20DeviceDscr);
    if (apiRetStatus != CY_U3P_SUCCESS)
    {
        CyU3PDebugPrint (4, "USB set device descriptor failed, Error code = %d\n", apiRetStatus);
        CyFxAppErrorHandler(apiRetStatus);
    }

   

    /* BOS descriptor */
    apiRetStatus = CyU3PUsbSetDesc(CY_U3P_USB_SET_SS_BOS_DESCR, NULL, (uint8_t *)CyFxUSBBOSDscr);
    if (apiRetStatus != CY_U3P_SUCCESS)
    {
        CyU3PDebugPrint (4, "USB set configuration descriptor failed, Error code = %d\n", apiRetStatus);
        CyFxAppErrorHandler(apiRetStatus);
    }

   

    /* Device qualifier descriptor */
    apiRetStatus = CyU3PUsbSetDesc(CY_U3P_USB_SET_DEVQUAL_DESCR, NULL, (uint8_t *)CyFxUSBDeviceQualDscr);
    if (apiRetStatus != CY_U3P_SUCCESS)
    {
        CyU3PDebugPrint (4, "USB set device qualifier descriptor failed, Error code = %d\n", apiRetStatus);
        CyFxAppErrorHandler(apiRetStatus);
    }

   

    /* Super speed configuration descriptor */
    apiRetStatus = CyU3PUsbSetDesc(CY_U3P_USB_SET_SS_CONFIG_DESCR, NULL, (uint8_t *)CyFxUSBSSConfigDscr);
    if (apiRetStatus != CY_U3P_SUCCESS)
    {
        CyU3PDebugPrint (4, "USB set configuration descriptor failed, Error code = %d\n", apiRetStatus);
        CyFxAppErrorHandler(apiRetStatus);
    }

   

    /* High speed configuration descriptor */
    apiRetStatus = CyU3PUsbSetDesc(CY_U3P_USB_SET_HS_CONFIG_DESCR, NULL, (uint8_t *)CyFxUSBHSConfigDscr);
    if (apiRetStatus != CY_U3P_SUCCESS)
    {
        CyU3PDebugPrint (4, "USB Set Other Speed Descriptor failed, Error Code = %d\n", apiRetStatus);
        CyFxAppErrorHandler(apiRetStatus);
    }

   

    /* Full speed configuration descriptor */
    apiRetStatus = CyU3PUsbSetDesc(CY_U3P_USB_SET_FS_CONFIG_DESCR, NULL, (uint8_t *)CyFxUSBFSConfigDscr);
    if (apiRetStatus != CY_U3P_SUCCESS)
    {
        CyU3PDebugPrint (4, "USB Set Configuration Descriptor failed, Error Code = %d\n", apiRetStatus);
        CyFxAppErrorHandler(apiRetStatus);
    }

   

    /* String descriptor 0 */
    apiRetStatus = CyU3PUsbSetDesc(CY_U3P_USB_SET_STRING_DESCR, 0, (uint8_t *)CyFxUSBStringLangIDDscr);
    if (apiRetStatus != CY_U3P_SUCCESS)
    {
        CyU3PDebugPrint (4, "USB set string descriptor failed, Error code = %d\n", apiRetStatus);
        CyFxAppErrorHandler(apiRetStatus);
    }

   

    /* String descriptor 1 */
    apiRetStatus = CyU3PUsbSetDesc(CY_U3P_USB_SET_STRING_DESCR, 1, (uint8_t *)CyFxUSBManufactureDscr);
    if (apiRetStatus != CY_U3P_SUCCESS)
    {
        CyU3PDebugPrint (4, "USB set string descriptor failed, Error code = %d\n", apiRetStatus);
        CyFxAppErrorHandler(apiRetStatus);
    }

   

    /* String descriptor 2 */
    apiRetStatus = CyU3PUsbSetDesc(CY_U3P_USB_SET_STRING_DESCR, 2, (uint8_t *)CyFxUSBProductDscr);
    if (apiRetStatus != CY_U3P_SUCCESS)
    {
        CyU3PDebugPrint (4, "USB set string descriptor failed, Error code = %d\n", apiRetStatus);
        CyFxAppErrorHandler(apiRetStatus);
    }

   

    /* Connect the USB Pins with super speed operation enabled. */
    apiRetStatus = CyU3PConnectState(CyTrue, CyTrue);
    if (apiRetStatus != CY_U3P_SUCCESS)
    {
        CyU3PDebugPrint (4, "USB Connect failed, Error code = %d\n", apiRetStatus);
        CyFxAppErrorHandler(apiRetStatus);
    }
}

   

/* Entry function for the slFifoAppThread. */
void
SlFifoAppThread_Entry (
        uint32_t input)
{
    /* Initialize the debug module */
    CyFxSlFifoApplnDebugInit();

   

    /* Initialize the slave FIFO application */
    CyFxSlFifoApplnInit();

   

    for (;;)
    {

   

        CyU3PThreadSleep (1000);
        if (glIsApplnActive)
        {
            /* Print the number of buffers received so far from the USB host.
            CyU3PDebugPrint (6, "Data tracker: buffers received: %d, buffers sent: %d.\n",
                    glDMARxCount, glDMATxCount);*/
        }
    }
}

   

/* Application define function which creates the threads. */
void
CyFxApplicationDefine (
        void)
{
    void *ptr = NULL;
    uint32_t retThrdCreate = CY_U3P_SUCCESS;

   

    /* Allocate the memory for the thread */
    ptr = CyU3PMemAlloc (CY_FX_SLFIFO_THREAD_STACK);

   

    /* Create the thread for the application */
    retThrdCreate = CyU3PThreadCreate (&slFifoAppThread,           /* Slave FIFO app thread structure */
                          "21:Slave_FIFO_sync",                    /* Thread ID and thread name */
                          SlFifoAppThread_Entry,                   /* Slave FIFO app thread entry function */
                          0,                                       /* No input parameter to thread */
                          ptr,                                     /* Pointer to the allocated thread stack */
                          CY_FX_SLFIFO_THREAD_STACK,               /* App Thread stack size */
                          CY_FX_SLFIFO_THREAD_PRIORITY,            /* App Thread priority */
                          CY_FX_SLFIFO_THREAD_PRIORITY,            /* App Thread pre-emption threshold */
                          CYU3P_NO_TIME_SLICE,                     /* No time slice for the application thread */
                          CYU3P_AUTO_START                         /* Start the thread immediately */
                          );

   

    /* Check the return code */
    if (retThrdCreate != 0)
    {
        /* Thread Creation failed with the error code retThrdCreate */

   

        /* Add custom recovery or debug actions here */

   

        /* Application cannot continue */
        /* Loop indefinitely */
        while(1);
    }
}

   

/*
 * Main function
 */
int
main (void)
{
    CyU3PIoMatrixConfig_t io_cfg;
    CyU3PReturnStatus_t status = CY_U3P_SUCCESS;
    CyU3PSysClockConfig_t clkCfg;

   

        /* setSysClk400 clock configurations */
        clkCfg.setSysClk400 = CyTrue;   /* FX3 device's master clock is set to a frequency > 400 MHz */
        clkCfg.cpuClkDiv = 2;           /* CPU clock divider */
        clkCfg.dmaClkDiv = 2;           /* DMA clock divider */
        clkCfg.mmioClkDiv = 2;          /* MMIO clock divider */
        clkCfg.useStandbyClk = CyFalse; /* device has no 32KHz clock supplied */
        clkCfg.clkSrc = CY_U3P_SYS_CLK; /* Clock source for a peripheral block  */

   

    /* Initialize the device */
    status = CyU3PDeviceInit (&clkCfg);
    if (status != CY_U3P_SUCCESS)
    {
        goto handle_fatal_error;
    }

   

    /* Initialize the caches. Enable instruction cache and keep data cache disabled.
     * The data cache is useful only when there is a large amount of CPU based memory
     * accesses. When used in simple cases, it can decrease performance due to large 
     * number of cache flushes and cleans and also it adds to the complexity of the
     * code. */
    status = CyU3PDeviceCacheControl (CyTrue, CyFalse, CyFalse);
    if (status != CY_U3P_SUCCESS)
    {
        goto handle_fatal_error;
    }

   

    /* Configure the IO matrix for the device. On the FX3 DVK board, the COM port 
     * is connected to the IO(53:56). This means that either DQ32 mode should be
     * selected or lppMode should be set to UART_ONLY. Here we are choosing
     * UART_ONLY configuration for 16 bit slave FIFO configuration and setting
     * isDQ32Bit for 32-bit slave FIFO configuration. */
    io_cfg.useUart   = CyTrue;
    io_cfg.useI2C    = CyFalse;
    io_cfg.useI2S    = CyFalse;
    io_cfg.useSpi    = CyFalse;
#if (CY_FX_SLFIFO_GPIF_16_32BIT_CONF_SELECT == 0)
    io_cfg.isDQ32Bit = CyFalse;
    io_cfg.lppMode   = CY_U3P_IO_MATRIX_LPP_UART_ONLY;
#else
    io_cfg.isDQ32Bit = CyTrue;
    io_cfg.lppMode   = CY_U3P_IO_MATRIX_LPP_DEFAULT;
#endif
    /* No GPIOs are enabled. */
    io_cfg.gpioSimpleEn[0]  = 0;
    io_cfg.gpioSimpleEn[1]  = 0x08000000; /* GPIO 59 */
    io_cfg.gpioComplexEn[0] = 0;
    io_cfg.gpioComplexEn[1] = 0;
    status = CyU3PDeviceConfigureIOMatrix (&io_cfg);
    if (status != CY_U3P_SUCCESS)
    {
        goto handle_fatal_error;
    }

   

    /* This is a non returnable call for initializing the RTOS kernel */
    CyU3PKernelEntry ();

   

    /* Dummy return to make the compiler happy */
    return 0;

   

handle_fatal_error:

   

    /* Cannot recover from this error. */
    while (1);
}

   

/* [ ] */

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2 Replies
Anonymous
Not applicable

Hi,

   

For 8-Bit FIFO, you need to set the CY_FX_SLFIFO_GPIF_16_32BIT_CONF_SELECT = 0 in the cyfxslfifosync.h file.

   

Also, I2C Interface configuration needs to be added in the cyfxslfifosync.c file. We will add that in the Tech Support Case you created and shre it to you.

   

Also, the watermark values need to be changed according to the 8 Bit. Please refer to the formula in An65974 application note for configuring the watermark values.

   

Regards,

   

-Madhu Sudhan

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Anonymous
Not applicable

Thanks

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