/* ChibiOS/RT - Copyright (C) 2006,2007,2008,2009,2010, 2011,2012,2013 Giovanni Di Sirio. This file is part of ChibiOS/RT. ChibiOS/RT is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version. ChibiOS/RT is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . --- A special exception to the GPL can be applied should you wish to distribute a combined work that includes ChibiOS/RT, without being obliged to provide the source code for any proprietary components. See the file exception.txt for full details of how and when the exception can be applied. */ /** * @file usb.c * @brief USB Driver code. * * @addtogroup USB * @{ */ #include #include "ch.h" #include "hal.h" #include "usb.h" #if HAL_USE_USB || defined(__DOXYGEN__) /*===========================================================================*/ /* Driver local definitions. */ /*===========================================================================*/ /*===========================================================================*/ /* Driver exported variables. */ /*===========================================================================*/ /*===========================================================================*/ /* Driver local variables and types. */ /*===========================================================================*/ static const uint8_t zero_status[] = {0x00, 0x00}; static const uint8_t active_status[] ={0x00, 0x00}; static const uint8_t halted_status[] = {0x01, 0x00}; /*===========================================================================*/ /* Driver local functions. */ /*===========================================================================*/ /** * @brief SET ADDRESS transaction callback. * * @param[in] usbp pointer to the @p USBDriver object */ static void set_address(USBDriver *usbp) { usbp->address = usbp->setup[2]; usb_lld_set_address(usbp); _usb_isr_invoke_event_cb(usbp, USB_EVENT_ADDRESS); usbp->state = USB_SELECTED; } /** * @brief Standard requests handler. * @details This is the standard requests default handler, most standard * requests are handled here, the user can override the standard * handling using the @p requests_hook_cb hook in the * @p USBConfig structure. * * @param[in] usbp pointer to the @p USBDriver object * @return The request handling exit code. * @retval FALSE Request not recognized by the handler or error. * @retval TRUE Request handled. */ static bool_t default_handler(USBDriver *usbp) { const USBDescriptor *dp; /* Decoding the request.*/ switch (((usbp->setup[0] & (USB_RTYPE_RECIPIENT_MASK | USB_RTYPE_TYPE_MASK)) | (usbp->setup[1] << 8))) { case USB_RTYPE_RECIPIENT_DEVICE | (USB_REQ_GET_STATUS << 8): /* Just returns the current status word.*/ usbSetupTransfer(usbp, (uint8_t *)&usbp->status, 2, NULL); return TRUE; case USB_RTYPE_RECIPIENT_DEVICE | (USB_REQ_CLEAR_FEATURE << 8): /* Only the DEVICE_REMOTE_WAKEUP is handled here, any other feature number is handled as an error.*/ if (usbp->setup[2] == USB_FEATURE_DEVICE_REMOTE_WAKEUP) { usbp->status &= ~2; usbSetupTransfer(usbp, NULL, 0, NULL); return TRUE; } return FALSE; case USB_RTYPE_RECIPIENT_DEVICE | (USB_REQ_SET_FEATURE << 8): /* Only the DEVICE_REMOTE_WAKEUP is handled here, any other feature number is handled as an error.*/ if (usbp->setup[2] == USB_FEATURE_DEVICE_REMOTE_WAKEUP) { usbp->status |= 2; usbSetupTransfer(usbp, NULL, 0, NULL); return TRUE; } return FALSE; case USB_RTYPE_RECIPIENT_DEVICE | (USB_REQ_SET_ADDRESS << 8): /* The SET_ADDRESS handling can be performed here or postponed after the status packed depending on the USB_SET_ADDRESS_MODE low driver setting.*/ #if USB_SET_ADDRESS_MODE == USB_EARLY_SET_ADDRESS if ((usbp->setup[0] == USB_RTYPE_RECIPIENT_DEVICE) && (usbp->setup[1] == USB_REQ_SET_ADDRESS)) set_address(usbp); usbSetupTransfer(usbp, NULL, 0, NULL); #else usbSetupTransfer(usbp, NULL, 0, set_address); #endif return TRUE; case USB_RTYPE_RECIPIENT_DEVICE | (USB_REQ_GET_DESCRIPTOR << 8): /* Handling descriptor requests from the host.*/ dp = usbp->config->get_descriptor_cb( usbp, usbp->setup[3], usbp->setup[2], usbFetchWord(&usbp->setup[4])); if (dp == NULL) return FALSE; usbSetupTransfer(usbp, (uint8_t *)dp->ud_string, dp->ud_size, NULL); return TRUE; case USB_RTYPE_RECIPIENT_DEVICE | (USB_REQ_GET_CONFIGURATION << 8): /* Returning the last selected configuration.*/ usbSetupTransfer(usbp, &usbp->configuration, 1, NULL); return TRUE; case USB_RTYPE_RECIPIENT_DEVICE | (USB_REQ_SET_CONFIGURATION << 8): /* Handling configuration selection from the host.*/ usbp->configuration = usbp->setup[2]; if (usbp->configuration == 0) usbp->state = USB_SELECTED; else usbp->state = USB_ACTIVE; _usb_isr_invoke_event_cb(usbp, USB_EVENT_CONFIGURED); usbSetupTransfer(usbp, NULL, 0, NULL); return TRUE; case USB_RTYPE_RECIPIENT_INTERFACE | (USB_REQ_GET_STATUS << 8): case USB_RTYPE_RECIPIENT_ENDPOINT | (USB_REQ_SYNCH_FRAME << 8): /* Just sending two zero bytes, the application can change the behavior using a hook..*/ usbSetupTransfer(usbp, (uint8_t *)zero_status, 2, NULL); return TRUE; case USB_RTYPE_RECIPIENT_ENDPOINT | (USB_REQ_GET_STATUS << 8): /* Sending the EP status.*/ if (usbp->setup[4] & 0x80) { switch (usb_lld_get_status_in(usbp, usbp->setup[4] & 0x0F)) { case EP_STATUS_STALLED: usbSetupTransfer(usbp, (uint8_t *)halted_status, 2, NULL); return TRUE; case EP_STATUS_ACTIVE: usbSetupTransfer(usbp, (uint8_t *)active_status, 2, NULL); return TRUE; default: return FALSE; } } else { switch (usb_lld_get_status_out(usbp, usbp->setup[4] & 0x0F)) { case EP_STATUS_STALLED: usbSetupTransfer(usbp, (uint8_t *)halted_status, 2, NULL); return TRUE; case EP_STATUS_ACTIVE: usbSetupTransfer(usbp, (uint8_t *)active_status, 2, NULL); return TRUE; default: return FALSE; } } case USB_RTYPE_RECIPIENT_ENDPOINT | (USB_REQ_CLEAR_FEATURE << 8): /* Only ENDPOINT_HALT is handled as feature.*/ if (usbp->setup[2] != USB_FEATURE_ENDPOINT_HALT) return FALSE; /* Clearing the EP status, not valid for EP0, it is ignored in that case.*/ if ((usbp->setup[4] & 0x0F) > 0) { if (usbp->setup[4] & 0x80) usb_lld_clear_in(usbp, usbp->setup[4] & 0x0F); else usb_lld_clear_out(usbp, usbp->setup[4] & 0x0F); } usbSetupTransfer(usbp, NULL, 0, NULL); return TRUE; case USB_RTYPE_RECIPIENT_ENDPOINT | (USB_REQ_SET_FEATURE << 8): /* Only ENDPOINT_HALT is handled as feature.*/ if (usbp->setup[2] != USB_FEATURE_ENDPOINT_HALT) return FALSE; /* Stalling the EP, not valid for EP0, it is ignored in that case.*/ if ((usbp->setup[4] & 0x0F) > 0) { if (usbp->setup[4] & 0x80) usb_lld_stall_in(usbp, usbp->setup[4] & 0x0F); else usb_lld_stall_out(usbp, usbp->setup[4] & 0x0F); } usbSetupTransfer(usbp, NULL, 0, NULL); return TRUE; case USB_RTYPE_RECIPIENT_DEVICE | (USB_REQ_SET_DESCRIPTOR << 8): case USB_RTYPE_RECIPIENT_INTERFACE | (USB_REQ_CLEAR_FEATURE << 8): case USB_RTYPE_RECIPIENT_INTERFACE | (USB_REQ_SET_FEATURE << 8): case USB_RTYPE_RECIPIENT_INTERFACE | (USB_REQ_GET_INTERFACE << 8): case USB_RTYPE_RECIPIENT_INTERFACE | (USB_REQ_SET_INTERFACE << 8): /* All the above requests are not handled here, if you need them then use the hook mechanism and provide handling.*/ default: return FALSE; } } /*===========================================================================*/ /* Driver exported functions. */ /*===========================================================================*/ /** * @brief USB Driver initialization. * @note This function is implicitly invoked by @p halInit(), there is * no need to explicitly initialize the driver. * * @init */ void usbInit(void) { usb_lld_init(); } /** * @brief Initializes the standard part of a @p USBDriver structure. * * @param[out] usbp pointer to the @p USBDriver object * * @init */ void usbObjectInit(USBDriver *usbp) { unsigned i; usbp->state = USB_STOP; usbp->config = NULL; for (i = 0; i < USB_MAX_ENDPOINTS; i++) { usbp->in_params[i] = NULL; usbp->out_params[i] = NULL; } usbp->transmitting = 0; usbp->receiving = 0; } /** * @brief Configures and activates the USB peripheral. * * @param[in] usbp pointer to the @p USBDriver object * @param[in] config pointer to the @p USBConfig object * * @api */ void usbStart(USBDriver *usbp, const USBConfig *config) { unsigned i; chDbgCheck((usbp != NULL) && (config != NULL), "usbStart"); chSysLock(); chDbgAssert((usbp->state == USB_STOP) || (usbp->state == USB_READY), "usbStart(), #1", "invalid state"); usbp->config = config; for (i = 0; i <= USB_MAX_ENDPOINTS; i++) usbp->epc[i] = NULL; usb_lld_start(usbp); usbp->state = USB_READY; chSysUnlock(); } /** * @brief Deactivates the USB peripheral. * * @param[in] usbp pointer to the @p USBDriver object * * @api */ void usbStop(USBDriver *usbp) { chDbgCheck(usbp != NULL, "usbStop"); chSysLock(); chDbgAssert((usbp->state == USB_STOP) || (usbp->state == USB_READY) || (usbp->state == USB_SELECTED) || (usbp->state == USB_ACTIVE), "usbStop(), #1", "invalid state"); usb_lld_stop(usbp); usbp->state = USB_STOP; chSysUnlock(); } /** * @brief Enables an endpoint. * @details This function enables an endpoint, both IN and/or OUT directions * depending on the configuration structure. * @note This function must be invoked in response of a SET_CONFIGURATION * or SET_INTERFACE message. * * @param[in] usbp pointer to the @p USBDriver object * @param[in] ep endpoint number * @param[in] epcp the endpoint configuration * * @iclass */ void usbInitEndpointI(USBDriver *usbp, usbep_t ep, const USBEndpointConfig *epcp) { chDbgCheckClassI(); chDbgCheck((usbp != NULL) && (epcp != NULL), "usbInitEndpointI"); chDbgAssert(usbp->state == USB_ACTIVE, "usbEnableEndpointI(), #1", "invalid state"); chDbgAssert(usbp->epc[ep] == NULL, "usbEnableEndpointI(), #2", "already initialized"); /* Logically enabling the endpoint in the USBDriver structure.*/ if (epcp->in_state != NULL) memset(epcp->in_state, 0, sizeof(USBInEndpointState)); if (epcp->out_state != NULL) memset(epcp->out_state, 0, sizeof(USBOutEndpointState)); usbp->epc[ep] = epcp; /* Low level endpoint activation.*/ usb_lld_init_endpoint(usbp, ep); } /** * @brief Disables all the active endpoints. * @details This function disables all the active endpoints except the * endpoint zero. * @note This function must be invoked in response of a SET_CONFIGURATION * message with configuration number zero. * * @param[in] usbp pointer to the @p USBDriver object * * @iclass */ void usbDisableEndpointsI(USBDriver *usbp) { unsigned i; chDbgCheckClassI(); chDbgCheck(usbp != NULL, "usbDisableEndpointsI"); chDbgAssert(usbp->state == USB_SELECTED, "usbDisableEndpointsI(), #1", "invalid state"); usbp->transmitting &= ~1; usbp->receiving &= ~1; for (i = 1; i <= USB_MAX_ENDPOINTS; i++) usbp->epc[i] = NULL; /* Low level endpoints deactivation.*/ usb_lld_disable_endpoints(usbp); } /** * @brief Prepares for a receive transaction on an OUT endpoint. * @post The endpoint is ready for @p usbStartReceiveI(). * @note This function can be called both in ISR and thread context. * * @param[in] usbp pointer to the @p USBDriver object * @param[in] ep endpoint number * @param[out] buf buffer where to copy the received data * @param[in] n transaction size * * @special */ void usbPrepareReceive(USBDriver *usbp, usbep_t ep, uint8_t *buf, size_t n) { USBOutEndpointState *osp = usbp->epc[ep]->out_state; osp->rxqueued = FALSE; osp->mode.linear.rxbuf = buf; osp->rxsize = n; osp->rxcnt = 0; usb_lld_prepare_receive(usbp, ep); } /** * @brief Prepares for a transmit transaction on an IN endpoint. * @post The endpoint is ready for @p usbStartTransmitI(). * @note This function can be called both in ISR and thread context. * @note The queue must contain at least the amount of data specified * as transaction size. * * @param[in] usbp pointer to the @p USBDriver object * @param[in] ep endpoint number * @param[in] buf buffer where to fetch the data to be transmitted * @param[in] n transaction size * * @special */ void usbPrepareTransmit(USBDriver *usbp, usbep_t ep, const uint8_t *buf, size_t n) { USBInEndpointState *isp = usbp->epc[ep]->in_state; isp->txqueued = FALSE; isp->mode.linear.txbuf = buf; isp->txsize = n; isp->txcnt = 0; usb_lld_prepare_transmit(usbp, ep); } /** * @brief Prepares for a receive transaction on an OUT endpoint. * @post The endpoint is ready for @p usbStartReceiveI(). * @note This function can be called both in ISR and thread context. * @note The queue must have enough free space to accommodate the * specified transaction size rounded to the next packet size * boundary. For example if the transaction size is 1 and the * packet size is 64 then the queue must have space for at least * 64 bytes. * * @param[in] usbp pointer to the @p USBDriver object * @param[in] ep endpoint number * @param[in] iqp input queue to be filled with incoming data * @param[in] n transaction size * * @special */ void usbPrepareQueuedReceive(USBDriver *usbp, usbep_t ep, InputQueue *iqp, size_t n) { USBOutEndpointState *osp = usbp->epc[ep]->out_state; osp->rxqueued = TRUE; osp->mode.queue.rxqueue = iqp; osp->rxsize = n; osp->rxcnt = 0; usb_lld_prepare_receive(usbp, ep); } /** * @brief Prepares for a transmit transaction on an IN endpoint. * @post The endpoint is ready for @p usbStartTransmitI(). * @note This function can be called both in ISR and thread context. * @note The transmit transaction size is equal to the data contained * in the queue. * * @param[in] usbp pointer to the @p USBDriver object * @param[in] ep endpoint number * @param[in] oqp output queue to be fetched for outgoing data * @param[in] n transaction size * * @special */ void usbPrepareQueuedTransmit(USBDriver *usbp, usbep_t ep, OutputQueue *oqp, size_t n) { USBInEndpointState *isp = usbp->epc[ep]->in_state; isp->txqueued = TRUE; isp->mode.queue.txqueue = oqp; isp->txsize = n; isp->txcnt = 0; usb_lld_prepare_transmit(usbp, ep); } /** * @brief Starts a receive transaction on an OUT endpoint. * @post The endpoint callback is invoked when the transfer has been * completed. * * @param[in] usbp pointer to the @p USBDriver object * @param[in] ep endpoint number * * @return The operation status. * @retval FALSE Operation started successfully. * @retval TRUE Endpoint busy, operation not started. * * @iclass */ bool_t usbStartReceiveI(USBDriver *usbp, usbep_t ep) { chDbgCheckClassI(); chDbgCheck(usbp != NULL, "usbStartReceiveI"); if (usbGetReceiveStatusI(usbp, ep)) return TRUE; usbp->receiving |= (1 << ep); usb_lld_start_out(usbp, ep); return FALSE; } /** * @brief Starts a transmit transaction on an IN endpoint. * @post The endpoint callback is invoked when the transfer has been * completed. * * @param[in] usbp pointer to the @p USBDriver object * @param[in] ep endpoint number * * @return The operation status. * @retval FALSE Operation started successfully. * @retval TRUE Endpoint busy, operation not started. * * @iclass */ bool_t usbStartTransmitI(USBDriver *usbp, usbep_t ep) { chDbgCheckClassI(); chDbgCheck(usbp != NULL, "usbStartTransmitI"); if (usbGetTransmitStatusI(usbp, ep)) return TRUE; usbp->transmitting |= (1 << ep); usb_lld_start_in(usbp, ep); return FALSE; } /** * @brief Stalls an OUT endpoint. * * @param[in] usbp pointer to the @p USBDriver object * @param[in] ep endpoint number * * @return The operation status. * @retval FALSE Endpoint stalled. * @retval TRUE Endpoint busy, not stalled. * * @iclass */ bool_t usbStallReceiveI(USBDriver *usbp, usbep_t ep) { chDbgCheckClassI(); chDbgCheck(usbp != NULL, "usbStallReceiveI"); if (usbGetReceiveStatusI(usbp, ep)) return TRUE; usb_lld_stall_out(usbp, ep); return FALSE; } /** * @brief Stalls an IN endpoint. * * @param[in] usbp pointer to the @p USBDriver object * @param[in] ep endpoint number * * @return The operation status. * @retval FALSE Endpoint stalled. * @retval TRUE Endpoint busy, not stalled. * * @iclass */ bool_t usbStallTransmitI(USBDriver *usbp, usbep_t ep) { chDbgCheckClassI(); chDbgCheck(usbp != NULL, "usbStallTransmitI"); if (usbGetTransmitStatusI(usbp, ep)) return TRUE; usb_lld_stall_in(usbp, ep); return FALSE; } /** * @brief USB reset routine. * @details This function must be invoked when an USB bus reset condition is * detected. * * @param[in] usbp pointer to the @p USBDriver object * * @notapi */ void _usb_reset(USBDriver *usbp) { unsigned i; usbp->state = USB_READY; usbp->status = 0; usbp->address = 0; usbp->configuration = 0; usbp->transmitting = 0; usbp->receiving = 0; /* Invalidates all endpoints into the USBDriver structure.*/ for (i = 0; i <= USB_MAX_ENDPOINTS; i++) usbp->epc[i] = NULL; /* EP0 state machine initialization.*/ usbp->ep0state = USB_EP0_WAITING_SETUP; /* Low level reset.*/ usb_lld_reset(usbp); } /** * @brief Default EP0 SETUP callback. * @details This function is used by the low level driver as default handler * for EP0 SETUP events. * * @param[in] usbp pointer to the @p USBDriver object * @param[in] ep endpoint number, always zero * * @notapi */ void _usb_ep0setup(USBDriver *usbp, usbep_t ep) { size_t max; usbp->ep0state = USB_EP0_WAITING_SETUP; usbReadSetup(usbp, ep, usbp->setup); /* First verify if the application has an handler installed for this request.*/ if (!(usbp->config->requests_hook_cb) || !(usbp->config->requests_hook_cb(usbp))) { /* Invoking the default handler, if this fails then stalls the endpoint zero as error.*/ if (((usbp->setup[0] & USB_RTYPE_TYPE_MASK) != USB_RTYPE_TYPE_STD) || !default_handler(usbp)) { /* Error response, the state machine goes into an error state, the low level layer will have to reset it to USB_EP0_WAITING_SETUP after receiving a SETUP packet.*/ usb_lld_stall_in(usbp, 0); usb_lld_stall_out(usbp, 0); _usb_isr_invoke_event_cb(usbp, USB_EVENT_STALLED); usbp->ep0state = USB_EP0_ERROR; return; } } #if (USB_SET_ADDRESS_ACK_HANDLING == USB_SET_ADDRESS_ACK_HW) if (usbp->setup[1] == USB_REQ_SET_ADDRESS) { /* Zero-length packet sent by hardware */ return; } #endif /* Transfer preparation. The request handler must have populated correctly the fields ep0next, ep0n and ep0endcb using the macro usbSetupTransfer().*/ max = usbFetchWord(&usbp->setup[6]); /* The transfer size cannot exceed the specified amount.*/ if (usbp->ep0n > max) usbp->ep0n = max; if ((usbp->setup[0] & USB_RTYPE_DIR_MASK) == USB_RTYPE_DIR_DEV2HOST) { /* IN phase.*/ if (usbp->ep0n > 0) { /* Starts the transmit phase.*/ usbp->ep0state = USB_EP0_TX; usbPrepareTransmit(usbp, 0, usbp->ep0next, usbp->ep0n); chSysLockFromIsr(); usbStartTransmitI(usbp, 0); chSysUnlockFromIsr(); } else { /* No transmission phase, directly receiving the zero sized status packet.*/ usbp->ep0state = USB_EP0_WAITING_STS; #if (USB_EP0_STATUS_STAGE == USB_EP0_STATUS_STAGE_SW) usbPrepareReceive(usbp, 0, NULL, 0); chSysLockFromIsr(); usbStartReceiveI(usbp, 0); chSysUnlockFromIsr(); #else usb_lld_end_setup(usbp, ep); #endif } } else { /* OUT phase.*/ if (usbp->ep0n > 0) { /* Starts the receive phase.*/ usbp->ep0state = USB_EP0_RX; usbPrepareReceive(usbp, 0, usbp->ep0next, usbp->ep0n); chSysLockFromIsr(); usbStartReceiveI(usbp, 0); chSysUnlockFromIsr(); } else { /* No receive phase, directly sending the zero sized status packet.*/ usbp->ep0state = USB_EP0_SENDING_STS; #if (USB_EP0_STATUS_STAGE == USB_EP0_STATUS_STAGE_SW) usbPrepareTransmit(usbp, 0, NULL, 0); chSysLockFromIsr(); usbStartTransmitI(usbp, 0); chSysUnlockFromIsr(); #else usb_lld_end_setup(usbp, ep); #endif } } } /** * @brief Default EP0 IN callback. * @details This function is used by the low level driver as default handler * for EP0 IN events. * * @param[in] usbp pointer to the @p USBDriver object * @param[in] ep endpoint number, always zero * * @notapi */ void _usb_ep0in(USBDriver *usbp, usbep_t ep) { size_t max; (void)ep; switch (usbp->ep0state) { case USB_EP0_TX: max = usbFetchWord(&usbp->setup[6]); /* If the transmitted size is less than the requested size and it is a multiple of the maximum packet size then a zero size packet must be transmitted.*/ if ((usbp->ep0n < max) && ((usbp->ep0n % usbp->epc[0]->in_maxsize) == 0)) { usbPrepareTransmit(usbp, 0, NULL, 0); chSysLockFromIsr(); usbStartTransmitI(usbp, 0); chSysUnlockFromIsr(); usbp->ep0state = USB_EP0_WAITING_TX0; return; } /* Falls into, it is intentional.*/ case USB_EP0_WAITING_TX0: /* Transmit phase over, receiving the zero sized status packet.*/ usbp->ep0state = USB_EP0_WAITING_STS; #if (USB_EP0_STATUS_STAGE == USB_EP0_STATUS_STAGE_SW) usbPrepareReceive(usbp, 0, NULL, 0); chSysLockFromIsr(); usbStartReceiveI(usbp, 0); chSysUnlockFromIsr(); #else usb_lld_end_setup(usbp, ep); #endif return; case USB_EP0_SENDING_STS: /* Status packet sent, invoking the callback if defined.*/ if (usbp->ep0endcb != NULL) usbp->ep0endcb(usbp); usbp->ep0state = USB_EP0_WAITING_SETUP; return; default: ; } /* Error response, the state machine goes into an error state, the low level layer will have to reset it to USB_EP0_WAITING_SETUP after receiving a SETUP packet.*/ usb_lld_stall_in(usbp, 0); usb_lld_stall_out(usbp, 0); _usb_isr_invoke_event_cb(usbp, USB_EVENT_STALLED); usbp->ep0state = USB_EP0_ERROR; } /** * @brief Default EP0 OUT callback. * @details This function is used by the low level driver as default handler * for EP0 OUT events. * * @param[in] usbp pointer to the @p USBDriver object * @param[in] ep endpoint number, always zero * * @notapi */ void _usb_ep0out(USBDriver *usbp, usbep_t ep) { (void)ep; switch (usbp->ep0state) { case USB_EP0_RX: /* Receive phase over, sending the zero sized status packet.*/ usbp->ep0state = USB_EP0_SENDING_STS; #if (USB_EP0_STATUS_STAGE == USB_EP0_STATUS_STAGE_SW) usbPrepareTransmit(usbp, 0, NULL, 0); chSysLockFromIsr(); usbStartTransmitI(usbp, 0); chSysUnlockFromIsr(); #else usb_lld_end_setup(usbp, ep); #endif return; case USB_EP0_WAITING_STS: /* Status packet received, it must be zero sized, invoking the callback if defined.*/ #if (USB_EP0_STATUS_STAGE == USB_EP0_STATUS_STAGE_SW) if (usbGetReceiveTransactionSizeI(usbp, 0) != 0) break; #endif if (usbp->ep0endcb != NULL) usbp->ep0endcb(usbp); usbp->ep0state = USB_EP0_WAITING_SETUP; return; default: ; } /* Error response, the state machine goes into an error state, the low level layer will have to reset it to USB_EP0_WAITING_SETUP after receiving a SETUP packet.*/ usb_lld_stall_in(usbp, 0); usb_lld_stall_out(usbp, 0); _usb_isr_invoke_event_cb(usbp, USB_EVENT_STALLED); usbp->ep0state = USB_EP0_ERROR; } #endif /* HAL_USE_USB */ /** @} */