/**************************************************************************//** * @file usbd.c * @version V1.00 * $Revision: 5 $ * $Date: 18/06/12 9:23a $ * @brief M031 series USBD driver source file * * @note * SPDX-License-Identifier: Apache-2.0 * Copyright (C) 2018 Nuvoton Technology Corp. All rights reserved. *****************************************************************************/ #include #include "NuMicro.h" #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_SetupPacket[8] = {0ul}; /*!< Setup packet buffer */ volatile uint8_t g_usbd_RemoteWakeupEn = 0ul; /*!< Remote wake up function enable flag */ /** * @cond HIDDEN_SYMBOLS */ static uint8_t *g_usbd_CtrlInPointer = 0; static uint8_t *g_usbd_CtrlOutPointer = 0; static volatile uint32_t g_usbd_CtrlInSize = 0ul; static volatile uint32_t g_usbd_CtrlOutSize = 0ul; static volatile uint32_t g_usbd_CtrlOutSizeLimit = 0ul; static volatile uint32_t g_usbd_UsbAddr = 0ul; static volatile uint32_t g_usbd_UsbConfig = 0ul; static volatile uint32_t g_usbd_CtrlMaxPktSize = 8ul; static volatile uint32_t g_usbd_UsbAltInterface = 0ul; static volatile uint8_t g_usbd_CtrlInZeroFlag = 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_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. * * @return None * * @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 */ g_usbd_CtrlMaxPktSize = g_usbd_sInfo->gu8DevDesc[7]; /* Initial USB engine */ USBD->ATTR = 0x6D0ul; /* Force SE0 */ USBD_SET_SE0(); } /** * @brief This function makes USB host to recognize the device * * @param None * * @return None * * @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(); USBD->ATTR = 0x7D0ul; /* 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. * * @return None * * @details Store SETUP packet to a user-specified buffer. * */ void USBD_GetSetupPacket(uint8_t *buf) { USBD_MemCopy(buf, g_usbd_SetupPacket, 8ul); } /** * @brief Process SETUP packet * * @param None * * @return None * * @details Parse SETUP packet and perform the corresponding action. * */ void USBD_ProcessSetupPacket(void) { /* Get SETUP packet from USB buffer */ USBD_MemCopy(g_usbd_SetupPacket, (uint8_t *)USBD_BUF_BASE, 8ul); /* Check the request type */ switch(g_usbd_SetupPacket[0] & 0x60ul) { case REQ_STANDARD: { USBD_StandardRequest(); break; } case REQ_CLASS: { if(g_usbd_pfnClassRequest != NULL) { g_usbd_pfnClassRequest(); } break; } case REQ_VENDOR: { if(g_usbd_pfnVendorRequest != NULL) { g_usbd_pfnVendorRequest(); } break; } default: { /* Setup error, stall the device */ USBD_SET_EP_STALL(EP0); USBD_SET_EP_STALL(EP1); break; } } } /** * @brief Process GetDescriptor request * * @param None * * @return None * * @details Parse GetDescriptor request and perform the corresponding action. * */ void USBD_GetDescriptor(void) { uint32_t u32Len; u32Len = 0ul; u32Len = g_usbd_SetupPacket[7]; u32Len <<= 8ul; u32Len += g_usbd_SetupPacket[6]; switch(g_usbd_SetupPacket[3]) { /* Get Device Descriptor */ case DESC_DEVICE: { u32Len = USBD_Minimum(u32Len, (uint32_t)LEN_DEVICE); USBD_PrepareCtrlIn((uint8_t *)g_usbd_sInfo->gu8DevDesc, u32Len); break; } /* Get Configuration Descriptor */ case DESC_CONFIG: { uint32_t u32TotalLen; u32TotalLen = g_usbd_sInfo->gu8ConfigDesc[3]; u32TotalLen = g_usbd_sInfo->gu8ConfigDesc[2] + (u32TotalLen << 8); u32Len = USBD_Minimum(u32Len, u32TotalLen); 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_BOSCAP); USBD_PrepareCtrlIn((uint8_t *)g_usbd_sInfo->gu8BosDesc, u32Len); } else { /* Not support. Reply STALL. */ 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); u32ConfigDescOffset = g_usbd_sInfo->gu32ConfigHidDescIdx[g_usbd_SetupPacket[4]]; USBD_PrepareCtrlIn((uint8_t *)&g_usbd_sInfo->gu8ConfigDesc[u32ConfigDescOffset], u32Len); break; } /* Get Report Descriptor */ case DESC_HID_RPT: { u32Len = USBD_Minimum(u32Len, g_usbd_sInfo->gu32HidReportSize[g_usbd_SetupPacket[4]]); USBD_PrepareCtrlIn((uint8_t *)g_usbd_sInfo->gu8HidReportDesc[g_usbd_SetupPacket[4]], u32Len); break; } /* Get String Descriptor */ case DESC_STRING: { /* Get String Descriptor */ if(g_usbd_SetupPacket[2] < 4ul) { u32Len = USBD_Minimum(u32Len, g_usbd_sInfo->gu8StringDesc[g_usbd_SetupPacket[2]][0]); USBD_PrepareCtrlIn((uint8_t *)g_usbd_sInfo->gu8StringDesc[g_usbd_SetupPacket[2]], u32Len); break; } else { /* Not support. Reply STALL. */ USBD_SET_EP_STALL(EP0); USBD_SET_EP_STALL(EP1); break; } } default: /* Not support. Reply STALL.*/ USBD_SET_EP_STALL(EP0); USBD_SET_EP_STALL(EP1); break; } } /** * @brief Process standard request * * @param None * * @return None * * @details Parse standard request and perform the corresponding action. * */ void USBD_StandardRequest(void) { uint32_t addr; /* clear global variables for new request */ g_usbd_CtrlInPointer = 0; g_usbd_CtrlInSize = 0ul; if((g_usbd_SetupPacket[0] & 0x80ul) == 0x80ul) /* request data transfer direction */ { /* Device to host */ switch(g_usbd_SetupPacket[1]) { case GET_CONFIGURATION: { /* Return current configuration setting */ /* Data stage */ addr = USBD_BUF_BASE + USBD_GET_EP_BUF_ADDR(EP0); M8(addr) = (uint8_t)g_usbd_UsbConfig; USBD_SET_DATA1(EP0); USBD_SET_PAYLOAD_LEN(EP0, 1ul); /* Status stage */ USBD_PrepareCtrlOut(0, 0ul); break; } case GET_DESCRIPTOR: { USBD_GetDescriptor(); USBD_PrepareCtrlOut(0, 0ul); /* For status stage */ break; } case GET_INTERFACE: { /* Return current interface setting */ /* Data stage */ addr = USBD_BUF_BASE + USBD_GET_EP_BUF_ADDR(EP0); M8(addr) = (uint8_t)g_usbd_UsbAltInterface; USBD_SET_DATA1(EP0); USBD_SET_PAYLOAD_LEN(EP0, 1ul); /* Status stage */ USBD_PrepareCtrlOut(0, 0ul); break; } case GET_STATUS: { /* Device */ if(g_usbd_SetupPacket[0] == 0x80ul) { uint8_t u8Tmp; u8Tmp = (uint8_t)0ul; if ((g_usbd_sInfo->gu8ConfigDesc[7] & 0x40ul) == 0x40ul) { u8Tmp |= (uint8_t)1ul; /* Self-Powered/Bus-Powered.*/ } if ((g_usbd_sInfo->gu8ConfigDesc[7] & 0x20ul) == 0x20ul) { u8Tmp |= (uint8_t)(g_usbd_RemoteWakeupEn << 1ul); /* Remote wake up */ } addr = USBD_BUF_BASE + USBD_GET_EP_BUF_ADDR(EP0); M8(addr) = u8Tmp; } /* Interface */ else if(g_usbd_SetupPacket[0] == 0x81ul) { addr = USBD_BUF_BASE + USBD_GET_EP_BUF_ADDR(EP0); M8(addr) = (uint8_t)0ul; } /* Endpoint */ else if(g_usbd_SetupPacket[0] == 0x82ul) { uint8_t ep = (uint8_t)(g_usbd_SetupPacket[4] & 0xFul); addr = USBD_BUF_BASE + USBD_GET_EP_BUF_ADDR(EP0); M8(addr) = (uint8_t)(USBD_GetStall(ep) ? 1ul : 0ul); } addr = USBD_BUF_BASE + USBD_GET_EP_BUF_ADDR(EP0) + 1ul; M8(addr) = (uint8_t)0ul; /* Data stage */ USBD_SET_DATA1(EP0); USBD_SET_PAYLOAD_LEN(EP0, 2ul); /* Status stage */ USBD_PrepareCtrlOut(0, 0ul); break; } default: { /* Setup error, stall the device */ USBD_SET_EP_STALL(EP0); USBD_SET_EP_STALL(EP1); break; } } } else { /* Host to device */ switch(g_usbd_SetupPacket[1]) { case CLEAR_FEATURE: { if(g_usbd_SetupPacket[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_u32EpStallLock is added to support it */ epNum = (uint8_t)(g_usbd_SetupPacket[4] & 0xFul); for(i = 0ul; i < USBD_MAX_EP; i++) { if(((USBD->EP[i].CFG & 0xFul) == epNum) && ((g_u32EpStallLock & (1ul << i)) == 0ul)) { USBD->EP[i].CFGP &= ~USBD_CFGP_SSTALL_Msk; } } } else if(g_usbd_SetupPacket[2] == FEATURE_DEVICE_REMOTE_WAKEUP) { g_usbd_RemoteWakeupEn = (uint8_t)0; } /* Status stage */ USBD_SET_DATA1(EP0); USBD_SET_PAYLOAD_LEN(EP0, 0ul); break; } case SET_ADDRESS: { g_usbd_UsbAddr = g_usbd_SetupPacket[2]; /* Status Stage */ USBD_SET_DATA1(EP0); USBD_SET_PAYLOAD_LEN(EP0, 0ul); break; } case SET_CONFIGURATION: { g_usbd_UsbConfig = g_usbd_SetupPacket[2]; if(g_usbd_pfnSetConfigCallback) { g_usbd_pfnSetConfigCallback(); } /* Status stage */ USBD_SET_DATA1(EP0); USBD_SET_PAYLOAD_LEN(EP0, 0ul); break; } case SET_FEATURE: { if(g_usbd_SetupPacket[2] == FEATURE_ENDPOINT_HALT) { USBD_SetStall((uint8_t)(g_usbd_SetupPacket[4] & 0xFul)); } else if(g_usbd_SetupPacket[2] == FEATURE_DEVICE_REMOTE_WAKEUP) { g_usbd_RemoteWakeupEn = (uint8_t)1ul; } /* Status stage */ USBD_SET_DATA1(EP0); USBD_SET_PAYLOAD_LEN(EP0, 0ul); break; } case SET_INTERFACE: { g_usbd_UsbAltInterface = g_usbd_SetupPacket[2]; if(g_usbd_pfnSetInterface != NULL) { g_usbd_pfnSetInterface(g_usbd_UsbAltInterface); } /* Status stage */ USBD_SET_DATA1(EP0); USBD_SET_PAYLOAD_LEN(EP0, 0ul); break; } default: { /* Setup error, stall the device */ USBD_SET_EP_STALL(EP0); USBD_SET_EP_STALL(EP1); 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. * * @return None * * @details Prepare data for Control IN transfer. * */ void USBD_PrepareCtrlIn(uint8_t pu8Buf[], uint32_t u32Size) { uint32_t addr; if(u32Size > g_usbd_CtrlMaxPktSize) { /* Data size > MXPLD */ g_usbd_CtrlInPointer = pu8Buf + g_usbd_CtrlMaxPktSize; g_usbd_CtrlInSize = u32Size - g_usbd_CtrlMaxPktSize; USBD_SET_DATA1(EP0); addr = USBD_BUF_BASE + USBD_GET_EP_BUF_ADDR(EP0); USBD_MemCopy((uint8_t *)addr, pu8Buf, g_usbd_CtrlMaxPktSize); USBD_SET_PAYLOAD_LEN(EP0, g_usbd_CtrlMaxPktSize); } else { /* Data size <= MXPLD */ g_usbd_CtrlInPointer = 0; g_usbd_CtrlInSize = 0ul; if (u32Size == g_usbd_CtrlMaxPktSize) g_usbd_CtrlInZeroFlag = 1ul; USBD_SET_DATA1(EP0); addr = USBD_BUF_BASE + USBD_GET_EP_BUF_ADDR(EP0); USBD_MemCopy((uint8_t *)addr, pu8Buf, u32Size); USBD_SET_PAYLOAD_LEN(EP0, u32Size); } } /** * @brief Repeat Control IN pipe * * @param None * * @return None * * @details This function processes the remained data of Control IN transfer. * */ void USBD_CtrlIn(void) { uint32_t addr; if(g_usbd_CtrlInSize) { /* Process remained data */ if(g_usbd_CtrlInSize > g_usbd_CtrlMaxPktSize) { /* Data size > MXPLD */ addr = USBD_BUF_BASE + USBD_GET_EP_BUF_ADDR(EP0); USBD_MemCopy((uint8_t *)addr, (uint8_t *)g_usbd_CtrlInPointer, g_usbd_CtrlMaxPktSize); USBD_SET_PAYLOAD_LEN(EP0, g_usbd_CtrlMaxPktSize); g_usbd_CtrlInPointer += g_usbd_CtrlMaxPktSize; g_usbd_CtrlInSize -= g_usbd_CtrlMaxPktSize; } else { /* Data size <= MXPLD */ addr = USBD_BUF_BASE + USBD_GET_EP_BUF_ADDR(EP0); USBD_MemCopy((uint8_t *)addr, (uint8_t *)g_usbd_CtrlInPointer, g_usbd_CtrlInSize); USBD_SET_PAYLOAD_LEN(EP0, g_usbd_CtrlInSize); if(g_usbd_CtrlInSize == g_usbd_CtrlMaxPktSize) g_usbd_CtrlInZeroFlag = 1ul; g_usbd_CtrlInPointer = 0ul; g_usbd_CtrlInSize = 0ul; } } else { /* In ACK for Set address */ if((g_usbd_SetupPacket[0] == REQ_STANDARD) && (g_usbd_SetupPacket[1] == SET_ADDRESS)) { addr = USBD_GET_ADDR(); if((addr != g_usbd_UsbAddr) && (addr == 0ul)) USBD_SET_ADDR(g_usbd_UsbAddr); } /* For the case of data size is integral times maximum packet size */ if (g_usbd_CtrlInZeroFlag) { USBD_SET_PAYLOAD_LEN(EP0, 0ul); g_usbd_CtrlInZeroFlag = 0ul; } } } /** * @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. * * @return None * * @details This function is used to prepare the first Control OUT transfer. * */ void USBD_PrepareCtrlOut(uint8_t *pu8Buf, uint32_t u32Size) { g_usbd_CtrlOutPointer = pu8Buf; g_usbd_CtrlOutSize = 0ul; g_usbd_CtrlOutSizeLimit = u32Size; USBD_SET_PAYLOAD_LEN(EP1, g_usbd_CtrlMaxPktSize); } /** * @brief Repeat Control OUT pipe * * @param None * * @return None * * @details This function processes the successive Control OUT transfer. * */ void USBD_CtrlOut(void) { uint32_t u32Size; uint32_t addr; if(g_usbd_CtrlOutSize < g_usbd_CtrlOutSizeLimit) { u32Size = USBD_GET_PAYLOAD_LEN(EP1); addr = USBD_BUF_BASE + USBD_GET_EP_BUF_ADDR(EP1); USBD_MemCopy((uint8_t *)g_usbd_CtrlOutPointer, (uint8_t *)addr, u32Size); g_usbd_CtrlOutPointer += u32Size; g_usbd_CtrlOutSize += u32Size; if(g_usbd_CtrlOutSize < g_usbd_CtrlOutSizeLimit) { USBD_SET_PAYLOAD_LEN(EP1, g_usbd_CtrlMaxPktSize); } } } /** * @brief Reset software flags * * @param None * * @return None * * @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 */ g_usbd_CtrlInPointer = 0; g_usbd_CtrlInSize = 0ul; g_usbd_CtrlOutPointer = 0; g_usbd_CtrlOutSize = 0ul; g_usbd_CtrlOutSizeLimit = 0ul; g_u32EpStallLock = 0ul; memset(g_usbd_SetupPacket, 0, 8ul); /* Reset PID DATA0 */ for(i=0ul; iEP[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 * * @return None * * @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 * * @return None * * @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 * * @return None * * @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_u32EpStallLock = u32EpBitmap; } /*@}*/ /* end of group USBD_EXPORTED_FUNCTIONS */ /*@}*/ /* end of group USBD_Driver */ /*@}*/ /* end of group Standard_Driver */ #ifdef __cplusplus } #endif /*** (C) COPYRIGHT 2018 Nuvoton Technology Corp. ***/