mac-rom-simm-programmer/hal/m258ke/nuvoton/usbd.c

/**************************************************************************//**
 * @file     usbd.c
 * @version  V0.10
 * @brief    M251 series USBD driver source file
 *
 * SPDX-License-Identifier: Apache-2.0
 * @copyright (C) 2019 Nuvoton Technology Corp. All rights reserved.
*****************************************************************************/

#include <string.h>
#include "NuMicro.h"

#if 0
    #define DBG_PRINTF      printf
#else
    #define DBG_PRINTF(...)
#endif

#ifdef __cplusplus
extern "C"
{
#endif

/** @addtogroup Standard_Driver Standard Driver
  @{
*/

/** @addtogroup USBD_Driver USBD Driver
  @{
*/


/** @addtogroup USBD_EXPORTED_FUNCTIONS USBD Exported Functions
  @{
*/

/* Global variables for Control Pipe */
uint8_t g_USBD_au8SetupPacket[8]           = {0u};    /*!< Setup packet buffer */
volatile uint8_t g_USBD_u8RemoteWakeupEn  = 0u;     /*!< Remote wake up function enable flag */

/**
 * @cond HIDDEN_SYMBOLS
 */
static volatile uint8_t *s_USBD_pu8CtrlInPointer       = 0ul;
static volatile uint8_t *s_USBD_pu8CtrlOutPointer      = 0ul;
static volatile uint32_t s_USBD_u32CtrlInSize          = 0ul;
static volatile uint32_t s_USBD_u32CtrlOutSize         = 0ul;
static volatile uint32_t s_USBD_u32CtrlOutSizeLimit    = 0ul;
static volatile uint32_t s_USBD_u32UsbAddr             = 0ul;
static volatile uint32_t s_USBD_u32UsbConfig           = 0ul;
static volatile uint32_t s_USBD_u32CtrlMaxPktSize      = 8ul;
static volatile uint32_t s_USBD_u32UsbAltInterface     = 0ul;
static volatile uint8_t  s_USBD_u8CtrlInZeroFlag       = 0ul;
static volatile uint32_t s_USBD_u32CtrlOutToggle       = 0ul;
/**
 * @endcond
 */

const S_USBD_INFO_T *g_USBD_sINFO;                   /*!< A pointer for USB information structure */

VENDOR_REQ g_USBD_pfnVendorRequest          = NULL;  /*!< USB Vendor Request Functional Pointer */
CLASS_REQ g_USBD_pfnClassRequest            = NULL;  /*!< USB Class Request Functional Pointer */
SET_INTERFACE_REQ g_USBD_pfnSetInterface    = NULL;  /*!< USB Set Interface Functional Pointer */
SET_CONFIG_CB g_USBD_pfnSetConfigCallback   = NULL;  /*!< USB Set configuration callback function pointer */
uint32_t g_USBD_u32EpStallLock              =  0ul;  /*!< Bit map flag to lock specified EP when SET_FEATURE */

/**
  * @brief      This function makes USBD module to be ready to use
  *
  * @param[in]  param           The structure of USBD information.
  * @param[in]  pfnClassReq     USB Class request callback function.
  * @param[in]  pfnSetInterface USB Set Interface request callback function.
  *
  *
  * @details    This function will enable USB controller, USB PHY transceiver and pull-up resistor of USB_D+ pin. USB PHY will drive SE0 to bus.
  */
void USBD_Open(const S_USBD_INFO_T *param, CLASS_REQ pfnClassReq, SET_INTERFACE_REQ pfnSetInterface)
{
    g_USBD_sINFO            = param;
    g_USBD_pfnClassRequest  = pfnClassReq;
    g_USBD_pfnSetInterface  = pfnSetInterface;

    /* get EP0 maximum packet size */
    s_USBD_u32CtrlMaxPktSize = g_USBD_sINFO->gu8DevDesc[7];

    /* Initial USB engine */
#ifdef SUPPORT_LPM
    USBD->ATTR = 0x7D0UL | USBD_LPMACK;
#else
    USBD->ATTR = 0x7D0UL;
#endif
    /* Force SE0 */
    USBD_SET_SE0();
}

/**
  * @brief    This function makes USB host to recognize the device
  *
  *
  *
  * @details  Enable WAKEUP, FLDET, USB and BUS interrupts. Disable software-disconnect function after 100ms delay with SysTick timer.
  */
void USBD_Start(void)
{
    /* Disable software-disconnect function */
    USBD_CLR_SE0();

    /* Clear USB-related interrupts before enable interrupt */
    USBD_CLR_INT_FLAG(USBD_INT_BUS | USBD_INT_USB | USBD_INT_FLDET | USBD_INT_WAKEUP);

    /* Enable USB-related interrupts. */
    USBD_ENABLE_INT(USBD_INT_BUS | USBD_INT_USB | USBD_INT_FLDET | USBD_INT_WAKEUP);
}

/**
  * @brief      Get the received SETUP packet
  *
  * @param[in]  buf A buffer pointer used to store 8-byte SETUP packet.
  *
  *
  * @details    Store SETUP packet to a user-specified buffer.
  *
  */
void USBD_GetSetupPacket(uint8_t *buf)
{
    USBD_MemCopy(buf, g_USBD_au8SetupPacket, 8ul);
}

/**
  * @brief    Process SETUP packet
  *
  *
  *
  * @details  Parse SETUP packet and perform the corresponding action.
  *
  */
void USBD_ProcessSetupPacket(void)
{
    s_USBD_u32CtrlOutToggle = 0;
    /* Get SETUP packet from USB buffer */
    USBD_MemCopy(g_USBD_au8SetupPacket, (uint8_t *)USBD_BUF_BASE, 8ul);

    /* Check the request type */
    switch (g_USBD_au8SetupPacket[0] & 0x60ul)
    {
        case REQ_STANDARD:   /* Standard */
        {
            USBD_StandardRequest();
            break;
        }

        case REQ_CLASS:   /* Class */
        {
            if (g_USBD_pfnClassRequest != NULL)
            {
                g_USBD_pfnClassRequest();
            }

            break;
        }

        case REQ_VENDOR:   /* Vendor */
        {
            if (g_USBD_pfnVendorRequest != NULL)
            {
                g_USBD_pfnVendorRequest();
            }

            break;
        }

        default:   /* reserved */
        {
            /* Setup error, stall the device */
            USBD_SET_EP_STALL(EP0);
            USBD_SET_EP_STALL(EP1);
            break;
        }
    }
}

/**
  * @brief    Process GetDescriptor request
  *
  *
  *
  * @details  Parse GetDescriptor request and perform the corresponding action.
  *
  */
void USBD_GetDescriptor(void)
{
    uint32_t u32Len;

    s_USBD_u8CtrlInZeroFlag = (uint8_t)0ul;

    u32Len   = 0ul;
    u32Len   = g_USBD_au8SetupPacket[7];
    u32Len <<= 8ul;
    u32Len  += g_USBD_au8SetupPacket[6];

    switch (g_USBD_au8SetupPacket[3])
    {
        /* Get Device Descriptor */
        case DESC_DEVICE:
        {
            u32Len = USBD_Minimum(u32Len, LEN_DEVICE);
            DBG_PRINTF("Get device desc, %d\n", u32Len);

            USBD_PrepareCtrlIn((uint8_t *)g_USBD_sINFO->gu8DevDesc, u32Len);

            break;
        }

        /* Get Configuration Descriptor */
        case DESC_CONFIG:
        {
            uint32_t u32TotalLen;

            DBG_PRINTF("Get config desc len %d, acture len %d\n", u32Len, u32TotalLen);
            u32TotalLen = g_USBD_sINFO->gu8ConfigDesc[3];
            u32TotalLen = g_USBD_sINFO->gu8ConfigDesc[2] + (u32TotalLen << 8U);

            DBG_PRINTF("Get config desc len %d, acture len %d\n", u32Len, u32TotalLen);

            if (u32Len > u32TotalLen)
            {
                u32Len = u32TotalLen;

                if ((u32Len % s_USBD_u32CtrlMaxPktSize) == 0ul)
                {
                    s_USBD_u8CtrlInZeroFlag = (uint8_t)1ul;
                }
            }

            DBG_PRINTF("Minimum len %d\n", u32Len);

            USBD_PrepareCtrlIn((uint8_t *)g_USBD_sINFO->gu8ConfigDesc, u32Len);

            break;
        }


        /* Get BOS Descriptor */
        case DESC_BOS:
        {
            if (g_USBD_sINFO->gu8BosDesc)
            {
                u32Len = USBD_Minimum(u32Len, LEN_BOS + LEN_DEVCAP);
                USBD_PrepareCtrlIn((uint8_t *)g_USBD_sINFO->gu8BosDesc, u32Len);
            }
            else
            {
                USBD_SET_EP_STALL(EP0);
                USBD_SET_EP_STALL(EP1);
            }

            break;
        }

        /* Get HID Descriptor */
        case DESC_HID:
        {
            /* CV3.0 HID Class Descriptor Test,
               Need to indicate index of the HID Descriptor within gu8ConfigDescriptor, specifically HID Composite device. */
            uint32_t u32ConfigDescOffset;   /* u32ConfigDescOffset is configuration descriptor offset (HID descriptor start index) */
            u32Len = USBD_Minimum(u32Len, LEN_HID);
            DBG_PRINTF("Get HID desc, %d\n", u32Len);

            u32ConfigDescOffset = g_USBD_sINFO->gu32ConfigHidDescIdx[g_USBD_au8SetupPacket[4]];
            USBD_PrepareCtrlIn((uint8_t *)&g_USBD_sINFO->gu8ConfigDesc[u32ConfigDescOffset], u32Len);

            break;
        }

        /* Get Report Descriptor */
        case DESC_HID_RPT:
        {
            DBG_PRINTF("Get HID report, %d\n", u32Len);

            if (u32Len > g_USBD_sINFO->gu32HidReportSize[g_USBD_au8SetupPacket[4]])
            {
                u32Len = g_USBD_sINFO->gu32HidReportSize[g_USBD_au8SetupPacket[4]];

                if ((u32Len % s_USBD_u32CtrlMaxPktSize) == 0ul)
                {
                    s_USBD_u8CtrlInZeroFlag = (uint8_t)1ul;
                }
            }

            USBD_PrepareCtrlIn((uint8_t *)g_USBD_sINFO->gu8HidReportDesc[g_USBD_au8SetupPacket[4]], u32Len);
            break;
        }

        /* Get String Descriptor */
        case DESC_STRING:
        {
            /* Get String Descriptor */
            if (g_USBD_au8SetupPacket[2] < 4ul)
            {
                if (u32Len > g_USBD_sINFO->gu8StringDesc[g_USBD_au8SetupPacket[2]][0])
                {
                    u32Len = g_USBD_sINFO->gu8StringDesc[g_USBD_au8SetupPacket[2]][0];

                    if ((u32Len % s_USBD_u32CtrlMaxPktSize) == 0ul)
                    {
                        s_USBD_u8CtrlInZeroFlag = (uint8_t)1ul;
                    }
                }

                DBG_PRINTF("Get string desc %d\n", u32Len);

                USBD_PrepareCtrlIn((uint8_t *)g_USBD_sINFO->gu8StringDesc[g_USBD_au8SetupPacket[2]], u32Len);


                break;
            }
            else
            {
                /* Not support. Reply STALL. */
                USBD_SET_EP_STALL(EP0);
                USBD_SET_EP_STALL(EP1);

                DBG_PRINTF("Unsupported string desc (%d). Stall ctrl pipe.\n", g_USBD_au8SetupPacket[2]);

                break;
            }
        }

        default:
            /* Not support. Reply STALL. */
            USBD_SET_EP_STALL(EP0);
            USBD_SET_EP_STALL(EP1);

            DBG_PRINTF("Unsupported get desc type. stall ctrl pipe\n");

            break;
    }
}

/**
  * @brief    Process standard request
  *
  *
  *
  * @details  Parse standard request and perform the corresponding action.
  *
  */
void USBD_StandardRequest(void)
{
    DBG_PRINTF("USBD_StandardRequest\n");

    /* clear global variables for new request */
    s_USBD_pu8CtrlInPointer = 0ul;
    s_USBD_u32CtrlInSize    = 0ul;

    if (g_USBD_au8SetupPacket[0] & 0x80ul)   /* request data transfer direction */
    {
        /* Device to host */
        switch (g_USBD_au8SetupPacket[1])
        {
            case GET_CONFIGURATION:
            {
                /* Return current configuration setting */
                /* Data stage */
                M8(USBD_BUF_BASE + USBD_GET_EP_BUF_ADDR(EP0)) = (uint8_t)s_USBD_u32UsbConfig;
                USBD_SET_DATA1(EP0);
                USBD_SET_PAYLOAD_LEN(EP0, 1ul);
                /* Status stage */
                USBD_PrepareCtrlOut(0, 0ul);

                DBG_PRINTF("Get configuration\n");

                break;
            }

            case GET_DESCRIPTOR:
            {
                USBD_GetDescriptor();
                USBD_PrepareCtrlOut(0, 0ul); /* For status stage */
                break;
            }

            case GET_INTERFACE:
            {
                /* Return current interface setting */
                /* Data stage */
                M8(USBD_BUF_BASE + USBD_GET_EP_BUF_ADDR(EP0)) = (uint8_t)s_USBD_u32UsbAltInterface;
                USBD_SET_DATA1(EP0);
                USBD_SET_PAYLOAD_LEN(EP0, 1ul);
                /* Status stage */
                USBD_PrepareCtrlOut(0, 0ul);

                DBG_PRINTF("Get interface\n");

                break;
            }

            case GET_STATUS:
            {
                /* Device */
                if (g_USBD_au8SetupPacket[0] == 0x80ul)
                {
                    uint8_t u8Tmp;

                    u8Tmp = (uint8_t)0ul;

                    if (g_USBD_sINFO->gu8ConfigDesc[7] & 0x40ul) u8Tmp |= (uint8_t)1ul; /* Self-Powered/Bus-Powered. */

                    if (g_USBD_sINFO->gu8ConfigDesc[7] & 0x20)   u8Tmp |= (uint8_t)(g_USBD_u8RemoteWakeupEn << 1ul); /* Remote wake up */

                    M8(USBD_BUF_BASE + USBD_GET_EP_BUF_ADDR(EP0)) = u8Tmp;

                }
                /* Interface */
                else if (g_USBD_au8SetupPacket[0] == 0x81ul)
                    M8(USBD_BUF_BASE + USBD_GET_EP_BUF_ADDR(EP0)) = (uint8_t)0ul;
                /* Endpoint */
                else if (g_USBD_au8SetupPacket[0] == 0x82ul)
                {
                    uint8_t ep = (uint8_t)g_USBD_au8SetupPacket[4] & 0xFul;
                    M8(USBD_BUF_BASE + USBD_GET_EP_BUF_ADDR(EP0)) = (uint8_t)(USBD_GetStall(ep) ? 1ul : 0ul);
                }

                M8(USBD_BUF_BASE + USBD_GET_EP_BUF_ADDR(EP0) + 1) = (uint8_t)0ul;
                /* Data stage */
                USBD_SET_DATA1(EP0);
                USBD_SET_PAYLOAD_LEN(EP0, 2ul);
                /* Status stage */
                USBD_PrepareCtrlOut(0, 0ul);

                DBG_PRINTF("Get status\n");

                break;
            }

            default:
            {
                /* Setup error, stall the device */
                USBD_SET_EP_STALL(EP0);
                USBD_SET_EP_STALL(EP1);

                DBG_PRINTF("Unknown request. stall ctrl pipe.\n");

                break;
            }
        }
    }
    else
    {
        /* Host to device */
        switch (g_USBD_au8SetupPacket[1])
        {
            case CLEAR_FEATURE:
            {
                if (g_USBD_au8SetupPacket[2] == FEATURE_ENDPOINT_HALT)
                {
                    uint32_t epNum, i;

                    /* EP number stall is not allow to be clear in MSC class "Error Recovery Test".
                       a flag: g_USBD_u32EpStallLock is added to support it */
                    epNum = (uint8_t)(g_USBD_au8SetupPacket[4] & 0xFul);

                    for (i = 0ul; i < USBD_MAX_EP; i++)
                    {
                        if (((USBD->EP[i].CFG & 0xFul) == epNum) && ((g_USBD_u32EpStallLock & (1ul << i)) == 0ul))
                        {
                            USBD->EP[i].CFGP &= ~USBD_CFGP_SSTALL_Msk;
                            USBD->EP[i].CFG  &= ~USBD_CFG_DSQSYNC_Msk;
                            DBG_PRINTF("Clr stall ep%d %x\n", i, USBD->EP[i].CFGP);
                        }
                    }
                }
                else if (g_USBD_au8SetupPacket[2] == FEATURE_DEVICE_REMOTE_WAKEUP)
                    g_USBD_u8RemoteWakeupEn = (uint8_t)0;

                /* Status stage */
                USBD_SET_DATA1(EP0);
                USBD_SET_PAYLOAD_LEN(EP0, 0ul);

                DBG_PRINTF("Clear feature op %d\n", g_USBD_au8SetupPacket[2]);

                break;
            }

            case SET_ADDRESS:
            {
                s_USBD_u32UsbAddr = g_USBD_au8SetupPacket[2];
                DBG_PRINTF("Set addr to %d\n", s_USBD_u32UsbAddr);

                /* DATA IN for end of setup */
                /* Status Stage */
                USBD_SET_DATA1(EP0);
                USBD_SET_PAYLOAD_LEN(EP0, 0ul);

                break;
            }

            case SET_CONFIGURATION:
            {
                s_USBD_u32UsbConfig = g_USBD_au8SetupPacket[2];

                if (g_USBD_pfnSetConfigCallback)
                    g_USBD_pfnSetConfigCallback();

                /* Status stage */
                USBD_SET_DATA1(EP0);
                USBD_SET_PAYLOAD_LEN(EP0, 0ul);

                DBG_PRINTF("Set config to %d\n", s_USBD_u32UsbConfig);

                break;
            }

            case SET_FEATURE:
            {
                if (g_USBD_au8SetupPacket[2] == FEATURE_ENDPOINT_HALT)
                {
                    USBD_SetStall((uint8_t)(g_USBD_au8SetupPacket[4] & 0xFul));
                    DBG_PRINTF("Set feature. stall ep %d\n", g_USBD_au8SetupPacket[4] & 0xFul);
                }
                else if (g_USBD_au8SetupPacket[2] == FEATURE_DEVICE_REMOTE_WAKEUP)
                {
                    g_USBD_u8RemoteWakeupEn = (uint8_t)1ul;
                    DBG_PRINTF("Set feature. enable remote wakeup\n");
                }

                /* Status stage */
                USBD_SET_DATA1(EP0);
                USBD_SET_PAYLOAD_LEN(EP0, 0ul);

                break;
            }

            case SET_INTERFACE:
            {
                s_USBD_u32UsbAltInterface = g_USBD_au8SetupPacket[2];

                if (g_USBD_pfnSetInterface != NULL)
                {
                    g_USBD_pfnSetInterface(s_USBD_u32UsbAltInterface);
                }

                /* Status stage */
                USBD_SET_DATA1(EP0);
                USBD_SET_PAYLOAD_LEN(EP0, 0ul);

                DBG_PRINTF("Set interface to %d\n", s_USBD_u32UsbAltInterface);

                break;
            }

            default:
            {

                /* Setup error, stall the device */
                USBD_SET_EP_STALL(EP0);
                USBD_SET_EP_STALL(EP1);

                DBG_PRINTF("Unsupported request. stall ctrl pipe.\n");

                break;
            }
        }
    }
}

/**
  * @brief      Prepare the first Control IN pipe
  *
  * @param[in]  pu8Buf  The pointer of data sent to USB host.
  * @param[in]  u32Size The IN transfer size.
  *
  *
  * @details    Prepare data for Control IN transfer.
  *
  */
void USBD_PrepareCtrlIn(uint8_t pu8Buf[], uint32_t u32Size)
{
    DBG_PRINTF("Prepare Ctrl In %d\n", u32Size);

    if (u32Size > s_USBD_u32CtrlMaxPktSize)
    {
        // Data size > MXPLD
        s_USBD_pu8CtrlInPointer = pu8Buf + s_USBD_u32CtrlMaxPktSize;
        s_USBD_u32CtrlInSize = u32Size - s_USBD_u32CtrlMaxPktSize;
        USBD_SET_DATA1(EP0);
        USBD_MemCopy((uint8_t *)USBD_BUF_BASE + USBD_GET_EP_BUF_ADDR(EP0), pu8Buf, s_USBD_u32CtrlMaxPktSize);
        USBD_SET_PAYLOAD_LEN(EP0, s_USBD_u32CtrlMaxPktSize);
    }
    else
    {
        // Data size <= MXPLD
        s_USBD_pu8CtrlInPointer = 0ul;
        s_USBD_u32CtrlInSize = 0ul;

        USBD_SET_DATA1(EP0);
        USBD_MemCopy((uint8_t *)USBD_BUF_BASE + USBD_GET_EP_BUF_ADDR(EP0), pu8Buf, u32Size);
        USBD_SET_PAYLOAD_LEN(EP0, u32Size);
    }
}

/**
  * @brief    Repeat Control IN pipe
  *
  *
  *
  * @details  This function processes the remained data of Control IN transfer.
  *
  */
void USBD_CtrlIn(void)
{

    DBG_PRINTF("Ctrl In Ack. residue %d\n", s_USBD_u32CtrlInSize);

    if (s_USBD_u32CtrlInSize)
    {
        // Process remained data
        if (s_USBD_u32CtrlInSize > s_USBD_u32CtrlMaxPktSize)
        {
            // Data size > MXPLD
            USBD_MemCopy((uint8_t *)USBD_BUF_BASE + USBD_GET_EP_BUF_ADDR(EP0), (uint8_t *)s_USBD_pu8CtrlInPointer, s_USBD_u32CtrlMaxPktSize);
            USBD_SET_PAYLOAD_LEN(EP0, s_USBD_u32CtrlMaxPktSize);
            s_USBD_pu8CtrlInPointer += s_USBD_u32CtrlMaxPktSize;
            s_USBD_u32CtrlInSize -= s_USBD_u32CtrlMaxPktSize;
        }
        else
        {
            // Data size <= MXPLD
            USBD_MemCopy((uint8_t *)USBD_BUF_BASE + USBD_GET_EP_BUF_ADDR(EP0), (uint8_t *)s_USBD_pu8CtrlInPointer, s_USBD_u32CtrlInSize);
            USBD_SET_PAYLOAD_LEN(EP0, s_USBD_u32CtrlInSize);

            s_USBD_pu8CtrlInPointer = 0ul;
            s_USBD_u32CtrlInSize    = 0ul;
        }
    }
    else     // No more data for IN token
    {
        // In ACK for Set address
        if ((g_USBD_au8SetupPacket[0] == REQ_STANDARD) && (g_USBD_au8SetupPacket[1] == SET_ADDRESS))
        {
            if ((USBD_GET_ADDR() != s_USBD_u32UsbAddr) && (USBD_GET_ADDR() == 0ul))
            {
                USBD_SET_ADDR(s_USBD_u32UsbAddr);
            }
        }

        /* For the case of data size is integral times maximum packet size */
        if (s_USBD_u8CtrlInZeroFlag)
        {
            USBD_SET_PAYLOAD_LEN(EP0, 0ul);
            s_USBD_u8CtrlInZeroFlag  = (uint8_t)0ul;
        }

        DBG_PRINTF("Ctrl In done.\n");

    }
}

/**
  * @brief      Prepare the first Control OUT pipe
  *
  * @param[in]  pu8Buf  The pointer of data received from USB host.
  * @param[in]  u32Size The OUT transfer size.
  *
  *
  * @details    This function is used to prepare the first Control OUT transfer.
  *
  */
void USBD_PrepareCtrlOut(uint8_t *pu8Buf, uint32_t u32Size)
{
    s_USBD_pu8CtrlOutPointer = pu8Buf;
    s_USBD_u32CtrlOutSize = 0ul;
    s_USBD_u32CtrlOutSizeLimit = u32Size;
    USBD_SET_PAYLOAD_LEN(EP1, s_USBD_u32CtrlMaxPktSize);
}

/**
  * @brief    Repeat Control OUT pipe
  *
  *
  *
  * @details  This function processes the successive Control OUT transfer.
  *
  */
void USBD_CtrlOut(void)
{
    if (s_USBD_u32CtrlOutToggle != (USBD->EPSTS0 & 0xf0))
    {
        s_USBD_u32CtrlOutToggle = USBD->EPSTS0 & 0xf0; //keep H/W EP1 toggle status

        if (s_USBD_u32CtrlOutSize < s_USBD_u32CtrlOutSizeLimit)
        {
            uint32_t u32Size;
            uint32_t addr;

            u32Size = USBD_GET_PAYLOAD_LEN(EP1);
            addr = USBD_BUF_BASE + USBD_GET_EP_BUF_ADDR(EP1);
            USBD_MemCopy((uint8_t *)s_USBD_pu8CtrlOutPointer, (uint8_t *)addr, u32Size);
            s_USBD_pu8CtrlOutPointer += u32Size;
            s_USBD_u32CtrlOutSize += u32Size;

            if (s_USBD_u32CtrlOutSize < s_USBD_u32CtrlOutSizeLimit)
            {
                USBD_SET_PAYLOAD_LEN(EP1, s_USBD_u32CtrlMaxPktSize);
            }
        }
    }
    else
    {
        USBD_SET_PAYLOAD_LEN(EP1, s_USBD_u32CtrlMaxPktSize);
    }
}

/**
  * @brief    Reset software flags
  *
  *
  *
  * @details  This function resets all variables for protocol and resets USB device address to 0.
  *
  */
void USBD_SwReset(void)
{
    uint32_t i;

    // Reset all variables for protocol
    s_USBD_pu8CtrlInPointer    = 0ul;
    s_USBD_u32CtrlInSize       = 0ul;
    s_USBD_pu8CtrlOutPointer   = 0ul;
    s_USBD_u32CtrlOutSize      = 0ul;
    s_USBD_u32CtrlOutSizeLimit = 0ul;
    g_USBD_u32EpStallLock      = 0ul;
    memset(g_USBD_au8SetupPacket, 0, 8ul);

    /* Reset PID DATA0 */
    for (i = 0ul; i < USBD_MAX_EP; i++)
        USBD->EP[i].CFG &= ~USBD_CFG_DSQSYNC_Msk;

    // Reset USB device address
    USBD_SET_ADDR(0ul);
}

/**
 * @brief       USBD Set Vendor Request
 *
 * @param[in]   pfnVendorReq    Vendor Request Callback Function
 *
 *
 * @details     This function is used to set USBD vendor request callback function
 */
void USBD_SetVendorRequest(VENDOR_REQ pfnVendorReq)
{
    g_USBD_pfnVendorRequest = pfnVendorReq;
}

/**
 * @brief       The callback function which called when get SET CONFIGURATION request
 *
 * @param[in]   pfnSetConfigCallback    Callback function pointer for SET CONFIGURATION request
 *
 *
 * @details     This function is used to set the callback function which will be called at SET CONFIGURATION request.
 */
void USBD_SetConfigCallback(SET_CONFIG_CB pfnSetConfigCallback)
{
    g_USBD_pfnSetConfigCallback = pfnSetConfigCallback;
}


/**
 * @brief       EP stall lock function to avoid stall clear by USB SET FEATURE request.
 *
 * @param[in]   u32EpBitmap    Use bitmap to select which endpoints will be locked
 *
 *
 * @details     This function is used to lock relative endpoint to avoid stall clear by SET FEATURE request.
 *              If ep stall locked, user needs to reset USB device or re-configure device to clear it.
 */
void USBD_LockEpStall(uint32_t u32EpBitmap)
{
    g_USBD_u32EpStallLock = u32EpBitmap;
}

/** @} end of group USBD_EXPORTED_FUNCTIONS */

/** @} end of group USBD_Driver */

/** @} end of group Standard_Driver */

#ifdef __cplusplus
}
#endif

/*** (C) COPYRIGHT 2019 Nuvoton Technology Corp. ***/