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USBDevice/USBDevice.cpp
- Committer:
- mbed_official
- Date:
- 2015-04-20
- Revision:
- 51:a3c50882f2c5
- Parent:
- 43:c0605f23f916
File content as of revision 51:a3c50882f2c5:
/* Copyright (c) 2010-2011 mbed.org, MIT License * * Permission is hereby granted, free of charge, to any person obtaining a copy of this software * and associated documentation files (the "Software"), to deal in the Software without * restriction, including without limitation the rights to use, copy, modify, merge, publish, * distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in all copies or * substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING * BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND * NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, * DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ #include "stdint.h" #include "USBEndpoints.h" #include "USBDevice.h" #include "USBDescriptor.h" //#define DEBUG /* Device status */ #define DEVICE_STATUS_SELF_POWERED (1U<<0) #define DEVICE_STATUS_REMOTE_WAKEUP (1U<<1) /* Endpoint status */ #define ENDPOINT_STATUS_HALT (1U<<0) /* Standard feature selectors */ #define DEVICE_REMOTE_WAKEUP (1) #define ENDPOINT_HALT (0) /* Macro to convert wIndex endpoint number to physical endpoint number */ #define WINDEX_TO_PHYSICAL(endpoint) (((endpoint & 0x0f) << 1) + \ ((endpoint & 0x80) ? 1 : 0)) bool USBDevice::requestGetDescriptor(void) { bool success = false; #ifdef DEBUG printf("get descr: type: %d\r\n", DESCRIPTOR_TYPE(transfer.setup.wValue)); #endif switch (DESCRIPTOR_TYPE(transfer.setup.wValue)) { case DEVICE_DESCRIPTOR: if (deviceDesc() != NULL) { if ((deviceDesc()[0] == DEVICE_DESCRIPTOR_LENGTH) \ && (deviceDesc()[1] == DEVICE_DESCRIPTOR)) { #ifdef DEBUG printf("device descr\r\n"); #endif transfer.remaining = DEVICE_DESCRIPTOR_LENGTH; transfer.ptr = deviceDesc(); transfer.direction = DEVICE_TO_HOST; success = true; } } break; case CONFIGURATION_DESCRIPTOR: if (configurationDesc() != NULL) { if ((configurationDesc()[0] == CONFIGURATION_DESCRIPTOR_LENGTH) \ && (configurationDesc()[1] == CONFIGURATION_DESCRIPTOR)) { #ifdef DEBUG printf("conf descr request\r\n"); #endif /* Get wTotalLength */ transfer.remaining = configurationDesc()[2] \ | (configurationDesc()[3] << 8); transfer.ptr = configurationDesc(); transfer.direction = DEVICE_TO_HOST; success = true; } } break; case STRING_DESCRIPTOR: #ifdef DEBUG printf("str descriptor\r\n"); #endif switch (DESCRIPTOR_INDEX(transfer.setup.wValue)) { case STRING_OFFSET_LANGID: #ifdef DEBUG printf("1\r\n"); #endif transfer.remaining = stringLangidDesc()[0]; transfer.ptr = stringLangidDesc(); transfer.direction = DEVICE_TO_HOST; success = true; break; case STRING_OFFSET_IMANUFACTURER: #ifdef DEBUG printf("2\r\n"); #endif transfer.remaining = stringImanufacturerDesc()[0]; transfer.ptr = stringImanufacturerDesc(); transfer.direction = DEVICE_TO_HOST; success = true; break; case STRING_OFFSET_IPRODUCT: #ifdef DEBUG printf("3\r\n"); #endif transfer.remaining = stringIproductDesc()[0]; transfer.ptr = stringIproductDesc(); transfer.direction = DEVICE_TO_HOST; success = true; break; case STRING_OFFSET_ISERIAL: #ifdef DEBUG printf("4\r\n"); #endif transfer.remaining = stringIserialDesc()[0]; transfer.ptr = stringIserialDesc(); transfer.direction = DEVICE_TO_HOST; success = true; break; case STRING_OFFSET_ICONFIGURATION: #ifdef DEBUG printf("5\r\n"); #endif transfer.remaining = stringIConfigurationDesc()[0]; transfer.ptr = stringIConfigurationDesc(); transfer.direction = DEVICE_TO_HOST; success = true; break; case STRING_OFFSET_IINTERFACE: #ifdef DEBUG printf("6\r\n"); #endif transfer.remaining = stringIinterfaceDesc()[0]; transfer.ptr = stringIinterfaceDesc(); transfer.direction = DEVICE_TO_HOST; success = true; break; } break; case INTERFACE_DESCRIPTOR: #ifdef DEBUG printf("interface descr\r\n"); #endif case ENDPOINT_DESCRIPTOR: #ifdef DEBUG printf("endpoint descr\r\n"); #endif /* TODO: Support is optional, not implemented here */ break; default: #ifdef DEBUG printf("ERROR\r\n"); #endif break; } return success; } void USBDevice::decodeSetupPacket(uint8_t *data, SETUP_PACKET *packet) { /* Fill in the elements of a SETUP_PACKET structure from raw data */ packet->bmRequestType.dataTransferDirection = (data[0] & 0x80) >> 7; packet->bmRequestType.Type = (data[0] & 0x60) >> 5; packet->bmRequestType.Recipient = data[0] & 0x1f; packet->bRequest = data[1]; packet->wValue = (data[2] | (uint16_t)data[3] << 8); packet->wIndex = (data[4] | (uint16_t)data[5] << 8); packet->wLength = (data[6] | (uint16_t)data[7] << 8); } bool USBDevice::controlOut(void) { /* Control transfer data OUT stage */ uint8_t buffer[MAX_PACKET_SIZE_EP0]; uint32_t packetSize; /* Check we should be transferring data OUT */ if (transfer.direction != HOST_TO_DEVICE) { #if defined(TARGET_KL25Z) | defined(TARGET_KL43Z) | defined(TARGET_KL46Z) | defined(TARGET_K20D5M) | defined(TARGET_K64F) | defined(TARGET_K22F) | defined(TARGET_TEENSY3_1) /* * We seem to have a pending device-to-host transfer. The host must have * sent a new control request without waiting for us to finish processing * the previous one. This appears to happen when we're connected to certain * USB 3.0 host chip set. Do a zeor-length send to tell the host we're not * ready for the new request - that'll make it resend - and then just * pretend we were successful here so that the pending transfer can finish. */ uint8_t buf[1] = { 0 }; EP0write(buf, 0); /* execute our pending ttransfer */ controlIn(); /* indicate success */ return true; #else /* for other platforms, count on the HAL to handle this case */ return false; #endif } /* Read from endpoint */ packetSize = EP0getReadResult(buffer); /* Check if transfer size is valid */ if (packetSize > transfer.remaining) { /* Too big */ return false; } /* Update transfer */ transfer.ptr += packetSize; transfer.remaining -= packetSize; /* Check if transfer has completed */ if (transfer.remaining == 0) { /* Transfer completed */ if (transfer.notify) { /* Notify class layer. */ USBCallback_requestCompleted(buffer, packetSize); transfer.notify = false; } /* Status stage */ EP0write(NULL, 0); } else { EP0read(); } return true; } bool USBDevice::controlIn(void) { /* Control transfer data IN stage */ uint32_t packetSize; /* Check if transfer has completed (status stage transactions */ /* also have transfer.remaining == 0) */ if (transfer.remaining == 0) { if (transfer.zlp) { /* Send zero length packet */ EP0write(NULL, 0); transfer.zlp = false; } /* Transfer completed */ if (transfer.notify) { /* Notify class layer. */ USBCallback_requestCompleted(NULL, 0); transfer.notify = false; } EP0read(); EP0readStage(); /* Completed */ return true; } /* Check we should be transferring data IN */ if (transfer.direction != DEVICE_TO_HOST) { return false; } packetSize = transfer.remaining; if (packetSize > MAX_PACKET_SIZE_EP0) { packetSize = MAX_PACKET_SIZE_EP0; } /* Write to endpoint */ EP0write(transfer.ptr, packetSize); /* Update transfer */ transfer.ptr += packetSize; transfer.remaining -= packetSize; return true; } bool USBDevice::requestSetAddress(void) { /* Set the device address */ setAddress(transfer.setup.wValue); if (transfer.setup.wValue == 0) { device.state = DEFAULT; } else { device.state = ADDRESS; } return true; } bool USBDevice::requestSetConfiguration(void) { device.configuration = transfer.setup.wValue; /* Set the device configuration */ if (device.configuration == 0) { /* Not configured */ unconfigureDevice(); device.state = ADDRESS; } else { if (USBCallback_setConfiguration(device.configuration)) { /* Valid configuration */ configureDevice(); device.state = CONFIGURED; } else { return false; } } return true; } bool USBDevice::requestGetConfiguration(void) { /* Send the device configuration */ transfer.ptr = &device.configuration; transfer.remaining = sizeof(device.configuration); transfer.direction = DEVICE_TO_HOST; return true; } bool USBDevice::requestGetInterface(void) { /* Return the selected alternate setting for an interface */ if (device.state != CONFIGURED) { return false; } /* Send the alternate setting */ transfer.setup.wIndex = currentInterface; transfer.ptr = ¤tAlternate; transfer.remaining = sizeof(currentAlternate); transfer.direction = DEVICE_TO_HOST; return true; } bool USBDevice::requestSetInterface(void) { bool success = false; if(USBCallback_setInterface(transfer.setup.wIndex, transfer.setup.wValue)) { success = true; currentInterface = transfer.setup.wIndex; currentAlternate = transfer.setup.wValue; } return success; } bool USBDevice::requestSetFeature() { bool success = false; if (device.state != CONFIGURED) { /* Endpoint or interface must be zero */ if (transfer.setup.wIndex != 0) { return false; } } switch (transfer.setup.bmRequestType.Recipient) { case DEVICE_RECIPIENT: /* TODO: Remote wakeup feature not supported */ break; case ENDPOINT_RECIPIENT: if (transfer.setup.wValue == ENDPOINT_HALT) { /* TODO: We should check that the endpoint number is valid */ stallEndpoint( WINDEX_TO_PHYSICAL(transfer.setup.wIndex)); success = true; } break; default: break; } return success; } bool USBDevice::requestClearFeature() { bool success = false; if (device.state != CONFIGURED) { /* Endpoint or interface must be zero */ if (transfer.setup.wIndex != 0) { return false; } } switch (transfer.setup.bmRequestType.Recipient) { case DEVICE_RECIPIENT: /* TODO: Remote wakeup feature not supported */ break; case ENDPOINT_RECIPIENT: /* TODO: We should check that the endpoint number is valid */ if (transfer.setup.wValue == ENDPOINT_HALT) { unstallEndpoint( WINDEX_TO_PHYSICAL(transfer.setup.wIndex)); success = true; } break; default: break; } return success; } bool USBDevice::requestGetStatus(void) { static uint16_t status; bool success = false; if (device.state != CONFIGURED) { /* Endpoint or interface must be zero */ if (transfer.setup.wIndex != 0) { return false; } } switch (transfer.setup.bmRequestType.Recipient) { case DEVICE_RECIPIENT: /* TODO: Currently only supports self powered devices */ status = DEVICE_STATUS_SELF_POWERED; success = true; break; case INTERFACE_RECIPIENT: status = 0; success = true; break; case ENDPOINT_RECIPIENT: /* TODO: We should check that the endpoint number is valid */ if (getEndpointStallState( WINDEX_TO_PHYSICAL(transfer.setup.wIndex))) { status = ENDPOINT_STATUS_HALT; } else { status = 0; } success = true; break; default: break; } if (success) { /* Send the status */ transfer.ptr = (uint8_t *)&status; /* Assumes little endian */ transfer.remaining = sizeof(status); transfer.direction = DEVICE_TO_HOST; } return success; } bool USBDevice::requestSetup(void) { bool success = false; /* Process standard requests */ if ((transfer.setup.bmRequestType.Type == STANDARD_TYPE)) { switch (transfer.setup.bRequest) { case GET_STATUS: success = requestGetStatus(); break; case CLEAR_FEATURE: success = requestClearFeature(); break; case SET_FEATURE: success = requestSetFeature(); break; case SET_ADDRESS: success = requestSetAddress(); break; case GET_DESCRIPTOR: success = requestGetDescriptor(); break; case SET_DESCRIPTOR: /* TODO: Support is optional, not implemented here */ success = false; break; case GET_CONFIGURATION: success = requestGetConfiguration(); break; case SET_CONFIGURATION: success = requestSetConfiguration(); break; case GET_INTERFACE: success = requestGetInterface(); break; case SET_INTERFACE: success = requestSetInterface(); break; default: break; } } return success; } bool USBDevice::controlSetup(void) { bool success = false; /* Control transfer setup stage */ uint8_t buffer[MAX_PACKET_SIZE_EP0]; EP0setup(buffer); /* Initialise control transfer state */ decodeSetupPacket(buffer, &transfer.setup); transfer.ptr = NULL; transfer.remaining = 0; transfer.direction = 0; transfer.zlp = false; transfer.notify = false; #ifdef DEBUG printf("dataTransferDirection: %d\r\nType: %d\r\nRecipient: %d\r\nbRequest: %d\r\nwValue: %d\r\nwIndex: %d\r\nwLength: %d\r\n",transfer.setup.bmRequestType.dataTransferDirection, transfer.setup.bmRequestType.Type, transfer.setup.bmRequestType.Recipient, transfer.setup.bRequest, transfer.setup.wValue, transfer.setup.wIndex, transfer.setup.wLength); #endif /* Class / vendor specific */ success = USBCallback_request(); if (!success) { /* Standard requests */ if (!requestSetup()) { #ifdef DEBUG printf("fail!!!!\r\n"); #endif return false; } } /* Check transfer size and direction */ if (transfer.setup.wLength>0) { if (transfer.setup.bmRequestType.dataTransferDirection \ == DEVICE_TO_HOST) { /* IN data stage is required */ if (transfer.direction != DEVICE_TO_HOST) { return false; } /* Transfer must be less than or equal to the size */ /* requested by the host */ if (transfer.remaining > transfer.setup.wLength) { transfer.remaining = transfer.setup.wLength; } } else { /* OUT data stage is required */ if (transfer.direction != HOST_TO_DEVICE) { return false; } /* Transfer must be equal to the size requested by the host */ if (transfer.remaining != transfer.setup.wLength) { return false; } } } else { /* No data stage; transfer size must be zero */ if (transfer.remaining != 0) { return false; } } /* Data or status stage if applicable */ if (transfer.setup.wLength>0) { if (transfer.setup.bmRequestType.dataTransferDirection \ == DEVICE_TO_HOST) { /* Check if we'll need to send a zero length packet at */ /* the end of this transfer */ if (transfer.setup.wLength > transfer.remaining) { /* Device wishes to transfer less than host requested */ if ((transfer.remaining % MAX_PACKET_SIZE_EP0) == 0) { /* Transfer is a multiple of EP0 max packet size */ transfer.zlp = true; } } /* IN stage */ controlIn(); } else { /* OUT stage */ EP0read(); } } else { /* Status stage */ EP0write(NULL, 0); } return true; } void USBDevice::busReset(void) { device.state = DEFAULT; device.configuration = 0; device.suspended = false; /* Call class / vendor specific busReset function */ USBCallback_busReset(); } void USBDevice::EP0setupCallback(void) { /* Endpoint 0 setup event */ if (!controlSetup()) { /* Protocol stall */ EP0stall(); } /* Return true if an OUT data stage is expected */ } void USBDevice::EP0out(void) { /* Endpoint 0 OUT data event */ if (!controlOut()) { /* Protocol stall; this will stall both endpoints */ EP0stall(); } } void USBDevice::EP0in(void) { #ifdef DEBUG printf("EP0IN\r\n"); #endif /* Endpoint 0 IN data event */ if (!controlIn()) { /* Protocol stall; this will stall both endpoints */ EP0stall(); } } bool USBDevice::configured(void) { /* Returns true if device is in the CONFIGURED state */ return (device.state == CONFIGURED); } void USBDevice::connect(bool blocking) { /* Connect device */ USBHAL::connect(); if (blocking) { /* Block if not configured */ while (!configured()); } } void USBDevice::disconnect(void) { /* Disconnect device */ USBHAL::disconnect(); /* Set initial device state */ device.state = POWERED; device.configuration = 0; device.suspended = false; } CONTROL_TRANSFER * USBDevice::getTransferPtr(void) { return &transfer; } bool USBDevice::addEndpoint(uint8_t endpoint, uint32_t maxPacket) { return realiseEndpoint(endpoint, maxPacket, 0); } bool USBDevice::addRateFeedbackEndpoint(uint8_t endpoint, uint32_t maxPacket) { /* For interrupt endpoints only */ return realiseEndpoint(endpoint, maxPacket, RATE_FEEDBACK_MODE); } uint8_t * USBDevice::findDescriptor(uint8_t descriptorType) { /* Find a descriptor within the list of descriptors */ /* following a configuration descriptor. */ uint16_t wTotalLength; uint8_t *ptr; if (configurationDesc() == NULL) { return NULL; } /* Check this is a configuration descriptor */ if ((configurationDesc()[0] != CONFIGURATION_DESCRIPTOR_LENGTH) \ || (configurationDesc()[1] != CONFIGURATION_DESCRIPTOR)) { return NULL; } wTotalLength = configurationDesc()[2] | (configurationDesc()[3] << 8); /* Check there are some more descriptors to follow */ if (wTotalLength <= (CONFIGURATION_DESCRIPTOR_LENGTH+2)) /* +2 is for bLength and bDescriptorType of next descriptor */ { return NULL; } /* Start at first descriptor after the configuration descriptor */ ptr = &(configurationDesc()[CONFIGURATION_DESCRIPTOR_LENGTH]); do { if (ptr[1] /* bDescriptorType */ == descriptorType) { /* Found */ return ptr; } /* Skip to next descriptor */ ptr += ptr[0]; /* bLength */ } while (ptr < (configurationDesc() + wTotalLength)); /* Reached end of the descriptors - not found */ return NULL; } void USBDevice::connectStateChanged(unsigned int connected) { } void USBDevice::suspendStateChanged(unsigned int suspended) { } USBDevice::USBDevice(uint16_t vendor_id, uint16_t product_id, uint16_t product_release){ VENDOR_ID = vendor_id; PRODUCT_ID = product_id; PRODUCT_RELEASE = product_release; /* Set initial device state */ device.state = POWERED; device.configuration = 0; device.suspended = false; }; bool USBDevice::readStart(uint8_t endpoint, uint32_t maxSize) { return endpointRead(endpoint, maxSize) == EP_PENDING; } bool USBDevice::write(uint8_t endpoint, uint8_t * buffer, uint32_t size, uint32_t maxSize) { EP_STATUS result; if (size > maxSize) { return false; } if(!configured()) { return false; } /* Send report */ result = endpointWrite(endpoint, buffer, size); if (result != EP_PENDING) { return false; } /* Wait for completion */ do { result = endpointWriteResult(endpoint); } while ((result == EP_PENDING) && configured()); return (result == EP_COMPLETED); } bool USBDevice::writeNB(uint8_t endpoint, uint8_t * buffer, uint32_t size, uint32_t maxSize) { EP_STATUS result; if (size > maxSize) { return false; } if(!configured()) { return false; } /* Send report */ result = endpointWrite(endpoint, buffer, size); if (result != EP_PENDING) { return false; } result = endpointWriteResult(endpoint); return (result == EP_COMPLETED); } bool USBDevice::readEP(uint8_t endpoint, uint8_t * buffer, uint32_t * size, uint32_t maxSize) { EP_STATUS result; if(!configured()) { return false; } /* Wait for completion */ do { result = endpointReadResult(endpoint, buffer, size); } while ((result == EP_PENDING) && configured()); return (result == EP_COMPLETED); } bool USBDevice::readEP_NB(uint8_t endpoint, uint8_t * buffer, uint32_t * size, uint32_t maxSize) { EP_STATUS result; if(!configured()) { return false; } result = endpointReadResult(endpoint, buffer, size); return (result == EP_COMPLETED); } uint8_t * USBDevice::deviceDesc() { static uint8_t deviceDescriptor[] = { DEVICE_DESCRIPTOR_LENGTH, /* bLength */ DEVICE_DESCRIPTOR, /* bDescriptorType */ LSB(USB_VERSION_2_0), /* bcdUSB (LSB) */ MSB(USB_VERSION_2_0), /* bcdUSB (MSB) */ 0x00, /* bDeviceClass */ 0x00, /* bDeviceSubClass */ 0x00, /* bDeviceprotocol */ MAX_PACKET_SIZE_EP0, /* bMaxPacketSize0 */ (uint8_t)(LSB(VENDOR_ID)), /* idVendor (LSB) */ (uint8_t)(MSB(VENDOR_ID)), /* idVendor (MSB) */ (uint8_t)(LSB(PRODUCT_ID)), /* idProduct (LSB) */ (uint8_t)(MSB(PRODUCT_ID)), /* idProduct (MSB) */ (uint8_t)(LSB(PRODUCT_RELEASE)), /* bcdDevice (LSB) */ (uint8_t)(MSB(PRODUCT_RELEASE)), /* bcdDevice (MSB) */ STRING_OFFSET_IMANUFACTURER, /* iManufacturer */ STRING_OFFSET_IPRODUCT, /* iProduct */ STRING_OFFSET_ISERIAL, /* iSerialNumber */ 0x01 /* bNumConfigurations */ }; return deviceDescriptor; } uint8_t * USBDevice::stringLangidDesc() { static uint8_t stringLangidDescriptor[] = { 0x04, /*bLength*/ STRING_DESCRIPTOR, /*bDescriptorType 0x03*/ 0x09,0x04, /*bString Lang ID - 0x0409 - English*/ }; return stringLangidDescriptor; } uint8_t * USBDevice::stringImanufacturerDesc() { static uint8_t stringImanufacturerDescriptor[] = { 0x12, /*bLength*/ STRING_DESCRIPTOR, /*bDescriptorType 0x03*/ 'm',0,'b',0,'e',0,'d',0,'.',0,'o',0,'r',0,'g',0, /*bString iManufacturer - mbed.org*/ }; return stringImanufacturerDescriptor; } uint8_t * USBDevice::stringIserialDesc() { static uint8_t stringIserialDescriptor[] = { 0x16, /*bLength*/ STRING_DESCRIPTOR, /*bDescriptorType 0x03*/ '0',0,'1',0,'2',0,'3',0,'4',0,'5',0,'6',0,'7',0,'8',0,'9',0, /*bString iSerial - 0123456789*/ }; return stringIserialDescriptor; } uint8_t * USBDevice::stringIConfigurationDesc() { static uint8_t stringIconfigurationDescriptor[] = { 0x06, /*bLength*/ STRING_DESCRIPTOR, /*bDescriptorType 0x03*/ '0',0,'1',0, /*bString iConfiguration - 01*/ }; return stringIconfigurationDescriptor; } uint8_t * USBDevice::stringIinterfaceDesc() { static uint8_t stringIinterfaceDescriptor[] = { 0x08, /*bLength*/ STRING_DESCRIPTOR, /*bDescriptorType 0x03*/ 'U',0,'S',0,'B',0, /*bString iInterface - USB*/ }; return stringIinterfaceDescriptor; } uint8_t * USBDevice::stringIproductDesc() { static uint8_t stringIproductDescriptor[] = { 0x16, /*bLength*/ STRING_DESCRIPTOR, /*bDescriptorType 0x03*/ 'U',0,'S',0,'B',0,' ',0,'D',0,'E',0,'V',0,'I',0,'C',0,'E',0 /*bString iProduct - USB DEVICE*/ }; return stringIproductDescriptor; }