/** * @file usbh_core.c * @brief * * Copyright (c) 2022 sakumisu * * Licensed to the Apache Software Foundation (ASF) under one or more * contributor license agreements. See the NOTICE file distributed with * this work for additional information regarding copyright ownership. The * ASF licenses this file to you under the Apache License, Version 2.0 (the * "License"); you may not use this file except in compliance with the * License. You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, WITHOUT * WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the * License for the specific language governing permissions and limitations * under the License. * */ #include "usbh_core.h" struct usbh_class_info *usbh_class_info_table_begin = NULL; struct usbh_class_info *usbh_class_info_table_end = NULL; static const char *speed_table[] = { "error speed", "low speed", "full speed", "high speed" }; static const struct usbh_class_driver *usbh_find_class_driver(uint8_t class, uint8_t subcalss, uint8_t protocol, uint16_t vid, uint16_t pid); /* general descriptor field offsets */ #define DESC_bLength 0 /** Length offset */ #define DESC_bDescriptorType 1 /** Descriptor type offset */ #define USB_DEV_ADDR_MAX 0x7f #define USB_DEV_ADDR_MARK_OFFSET 5 #define USB_DEV_ADDR_MARK_MASK 0x1f struct usbh_devaddr_priv { /** * alloctab[0]:addr from 0~31 * alloctab[1]:addr from 32~63 * alloctab[2]:addr from 64~95 * alloctab[3]:addr from 96~127 * */ uint8_t next; /* Next device address */ uint32_t alloctab[4]; /* Bit allocation table */ }; struct usbh_roothubport_priv { struct usbh_hubport hport; /* Common hub port definitions */ struct usbh_devaddr_priv devgen; /* Address generation data */ }; struct usbh_core_priv { struct usbh_roothubport_priv rhport[CONFIG_USBHOST_RHPORTS]; volatile struct usbh_hubport *active_hport; /* Used to pass external hub port events */ usb_osal_event_t pscevent; /* Semaphore to wait for a port event */ } usbh_core_cfg; static inline struct usbh_roothubport_priv *usbh_find_roothub_port(struct usbh_hubport *hport) { while (hport->parent != NULL) { hport = hport->parent->parent; } return (struct usbh_roothubport_priv *)hport; } static int usbh_allocate_devaddr(struct usbh_devaddr_priv *devgen) { uint8_t startaddr = devgen->next; uint8_t devaddr; int index; int bitno; /* Loop until we find a valid device address */ for (;;) { /* Try the next device address */ devaddr = devgen->next; if (devgen->next >= 0x7f) { devgen->next = 1; } else { devgen->next++; } /* Is this address already allocated? */ index = devaddr >> 5; bitno = devaddr & 0x1f; if ((devgen->alloctab[index] & (1 << bitno)) == 0) { /* No... allocate it now */ devgen->alloctab[index] |= (1 << bitno); return (int)devaddr; } /* This address has already been allocated. The following logic will * prevent (unexpected) infinite loops. */ if (startaddr == devaddr) { /* We are back where we started... the are no free device address */ return -ENOMEM; } } } static int usbh_free_devaddr(struct usbh_devaddr_priv *devgen, uint8_t devaddr) { int index; int bitno; if ((devaddr > 0) && (devaddr < USB_DEV_ADDR_MAX)) { index = devaddr >> USB_DEV_ADDR_MARK_OFFSET; bitno = devaddr & USB_DEV_ADDR_MARK_MASK; /* Free the address by clearing the associated bit in the alloctab[]; */ if ((devgen->alloctab[index] |= (1 << bitno)) != 0) { devgen->alloctab[index] &= ~(1 << bitno); } else { return -1; } /* Reset the next pointer if the one just released has a lower value */ if (devaddr < devgen->next) { devgen->next = devaddr; } } return 0; } static int usbh_devaddr_create(struct usbh_hubport *hport) { struct usbh_roothubport_priv *rhport; rhport = usbh_find_roothub_port(hport); return usbh_allocate_devaddr(&rhport->devgen); } static int usbh_devaddr_destroy(struct usbh_hubport *hport, uint8_t dev_addr) { struct usbh_roothubport_priv *rhport; rhport = usbh_find_roothub_port(hport); return usbh_free_devaddr(&rhport->devgen, dev_addr); } void usbh_hport_activate(struct usbh_hubport *hport) { struct usbh_endpoint_cfg ep0_cfg; memset(&ep0_cfg, 0, sizeof(struct usbh_endpoint_cfg)); ep0_cfg.ep_addr = 0x00; ep0_cfg.ep_interval = 0x00; ep0_cfg.ep_mps = 0x08; ep0_cfg.ep_type = USB_ENDPOINT_TYPE_CONTROL; ep0_cfg.hport = hport; /* Allocate memory for roothub port control endpoint */ usbh_ep_alloc(&hport->ep0, &ep0_cfg); } void usbh_hport_deactivate(struct usbh_hubport *hport) { size_t flags; /* Don't free the control pipe of root hub ports! */ if (hport->parent != NULL && hport->ep0 != NULL) { usb_ep_cancel(hport->ep0); usbh_ep_free(hport->ep0); hport->ep0 = NULL; } flags = usb_osal_enter_critical_section(); /* Free the device address if one has been assigned */ usbh_devaddr_destroy(hport, hport->dev_addr); hport->dev_addr = 0; usb_osal_leave_critical_section(flags); if (hport->setup) usb_iofree(hport->setup); hport->setup = NULL; } static int parse_device_descriptor(struct usbh_hubport *hport, struct usb_device_descriptor *desc, uint16_t length) { if (desc->bLength != USB_SIZEOF_DEVICE_DESC) { USB_LOG_ERR("invalid device bLength 0x%02x\r\n", desc->bLength); return -EINVAL; } else if (desc->bDescriptorType != USB_DESCRIPTOR_TYPE_DEVICE) { USB_LOG_ERR("unexpected device descriptor 0x%02x\r\n", desc->bDescriptorType); return -EINVAL; } else { if (length <= 8) { return 0; } #if 0 USB_LOG_DBG("Device Descriptor:\r\n"); USB_LOG_DBG("bLength: 0x%02x \r\n", desc->bLength); USB_LOG_DBG("bDescriptorType: 0x%02x \r\n", desc->bDescriptorType); USB_LOG_DBG("bcdUSB: 0x%04x \r\n", desc->bcdUSB); USB_LOG_DBG("bDeviceClass: 0x%02x \r\n", desc->bDeviceClass); USB_LOG_DBG("bDeviceSubClass: 0x%02x \r\n", desc->bDeviceSubClass); USB_LOG_DBG("bDeviceProtocol: 0x%02x \r\n", desc->bDeviceProtocol); USB_LOG_DBG("bMaxPacketSize0: 0x%02x \r\n", desc->bMaxPacketSize0); USB_LOG_DBG("idVendor: 0x%04x \r\n", desc->idVendor); USB_LOG_DBG("idProduct: 0x%04x \r\n", desc->idProduct); USB_LOG_DBG("bcdDevice: 0x%04x \r\n", desc->bcdDevice); USB_LOG_DBG("iManufacturer: 0x%02x \r\n", desc->iManufacturer); USB_LOG_DBG("iProduct: 0x%02x \r\n", desc->iProduct); USB_LOG_DBG("iSerialNumber: 0x%02x \r\n", desc->iSerialNumber); USB_LOG_DBG("bNumConfigurations: 0x%02x\r\n", desc->bNumConfigurations); #endif hport->device_desc.bLength = desc->bLength; hport->device_desc.bDescriptorType = desc->bDescriptorType; hport->device_desc.bcdUSB = desc->bcdUSB; hport->device_desc.bDeviceClass = desc->bDeviceClass; hport->device_desc.bDeviceSubClass = desc->bDeviceSubClass; hport->device_desc.bDeviceProtocol = desc->bDeviceProtocol; hport->device_desc.bMaxPacketSize0 = desc->bMaxPacketSize0; hport->device_desc.idVendor = desc->idVendor; hport->device_desc.idProduct = desc->idProduct; hport->device_desc.bcdDevice = desc->bcdDevice; hport->device_desc.iManufacturer = desc->iManufacturer; hport->device_desc.iProduct = desc->iProduct; hport->device_desc.iSerialNumber = desc->iSerialNumber; hport->device_desc.bNumConfigurations = desc->bNumConfigurations; } return 0; } static int parse_config_descriptor(struct usbh_hubport *hport, struct usb_configuration_descriptor *desc, uint16_t length) { uint32_t total_len = 0; uint8_t ep_num = 0; uint8_t intf_num = 0; uint8_t *p = (uint8_t *)desc; if (desc->bLength != USB_SIZEOF_CONFIG_DESC) { USB_LOG_ERR("invalid config bLength 0x%02x\r\n", desc->bLength); return -EINVAL; } else if (desc->bDescriptorType != USB_DESCRIPTOR_TYPE_CONFIGURATION) { USB_LOG_ERR("unexpected config descriptor 0x%02x\r\n", desc->bDescriptorType); return -EINVAL; } else { if (length <= USB_SIZEOF_CONFIG_DESC) { return 0; } #if 0 USB_LOG_DBG("Config Descriptor:\r\n"); USB_LOG_DBG("bLength: 0x%02x \r\n", desc->bLength); USB_LOG_DBG("bDescriptorType: 0x%02x \r\n", desc->bDescriptorType); USB_LOG_DBG("wTotalLength: 0x%04x \r\n", desc->wTotalLength); USB_LOG_DBG("bNumInterfaces: 0x%02x \r\n", desc->bNumInterfaces); USB_LOG_DBG("bConfigurationValue: 0x%02x \r\n", desc->bConfigurationValue); USB_LOG_DBG("iConfiguration: 0x%02x \r\n", desc->iConfiguration); USB_LOG_DBG("bmAttributes: 0x%02x \r\n", desc->bmAttributes); USB_LOG_DBG("bMaxPower: 0x%02x \r\n", desc->bMaxPower); #endif hport->config.config_desc.bLength = desc->bLength; hport->config.config_desc.bDescriptorType = desc->bDescriptorType; hport->config.config_desc.wTotalLength = desc->wTotalLength; hport->config.config_desc.bNumInterfaces = desc->bNumInterfaces; hport->config.config_desc.bConfigurationValue = desc->bConfigurationValue; hport->config.config_desc.iConfiguration = desc->iConfiguration; hport->config.config_desc.iConfiguration = desc->iConfiguration; hport->config.config_desc.bmAttributes = desc->bmAttributes; hport->config.config_desc.bMaxPower = desc->bMaxPower; if (length > USB_SIZEOF_CONFIG_DESC) { while (p[DESC_bLength] && (total_len < desc->wTotalLength) && (intf_num < desc->bNumInterfaces)) { p += p[DESC_bLength]; total_len += p[DESC_bLength]; if (p[DESC_bDescriptorType] == USB_DESCRIPTOR_TYPE_INTERFACE) { struct usb_interface_descriptor *intf_desc = (struct usb_interface_descriptor *)p; #if 0 USB_LOG_DBG("Interface Descriptor:\r\n"); USB_LOG_DBG("bLength: 0x%02x \r\n", intf_desc->bLength); USB_LOG_DBG("bDescriptorType: 0x%02x \r\n", intf_desc->bDescriptorType); USB_LOG_DBG("bInterfaceNumber: 0x%02x \r\n", intf_desc->bInterfaceNumber); USB_LOG_DBG("bAlternateSetting: 0x%02x \r\n", intf_desc->bAlternateSetting); USB_LOG_DBG("bNumEndpoints: 0x%02x \r\n", intf_desc->bNumEndpoints); USB_LOG_DBG("bInterfaceClass: 0x%02x \r\n", intf_desc->bInterfaceClass); USB_LOG_DBG("bInterfaceSubClass: 0x%02x \r\n", intf_desc->bInterfaceSubClass); USB_LOG_DBG("bInterfaceProtocol: 0x%02x \r\n", intf_desc->bInterfaceProtocol); USB_LOG_DBG("iInterface: 0x%02x \r\n", intf_desc->iInterface); #endif memset(&hport->config.intf[intf_num], 0, sizeof(struct usbh_interface)); hport->config.intf[intf_num].intf_desc.bLength = intf_desc->bLength; hport->config.intf[intf_num].intf_desc.bDescriptorType = intf_desc->bDescriptorType; hport->config.intf[intf_num].intf_desc.bInterfaceNumber = intf_desc->bInterfaceNumber; hport->config.intf[intf_num].intf_desc.bAlternateSetting = intf_desc->bAlternateSetting; hport->config.intf[intf_num].intf_desc.bNumEndpoints = intf_desc->bNumEndpoints; hport->config.intf[intf_num].intf_desc.bInterfaceClass = intf_desc->bInterfaceClass; hport->config.intf[intf_num].intf_desc.bInterfaceSubClass = intf_desc->bInterfaceSubClass; hport->config.intf[intf_num].intf_desc.bInterfaceProtocol = intf_desc->bInterfaceProtocol; hport->config.intf[intf_num].intf_desc.iInterface = intf_desc->iInterface; ep_num = 0; while (p[DESC_bLength] && (total_len < desc->wTotalLength) && (ep_num < intf_desc->bNumEndpoints)) { p += p[DESC_bLength]; total_len += p[DESC_bLength]; if (p[DESC_bDescriptorType] == USB_DESCRIPTOR_TYPE_ENDPOINT) { struct usb_endpoint_descriptor *ep_desc = (struct usb_endpoint_descriptor *)p; #if 0 USB_LOG_DBG("Endpoint Descriptor:\r\n"); USB_LOG_DBG("bLength: 0x%02x \r\n", ep_desc->bLength); USB_LOG_DBG("bDescriptorType: 0x%02x \r\n", ep_desc->bDescriptorType); USB_LOG_DBG("bEndpointAddress: 0x%02x \r\n", ep_desc->bEndpointAddress); USB_LOG_DBG("bmAttributes: 0x%02x \r\n", ep_desc->bmAttributes); USB_LOG_DBG("wMaxPacketSize: 0x%04x \r\n", ep_desc->wMaxPacketSize); USB_LOG_DBG("bInterval: 0x%02x \r\n", ep_desc->bInterval); #endif memset(&hport->config.intf[intf_num].ep[ep_num], 0, sizeof(struct usbh_endpoint)); hport->config.intf[intf_num].ep[ep_num].ep_desc.bLength = ep_desc->bLength; hport->config.intf[intf_num].ep[ep_num].ep_desc.bDescriptorType = ep_desc->bDescriptorType; hport->config.intf[intf_num].ep[ep_num].ep_desc.bEndpointAddress = ep_desc->bEndpointAddress; hport->config.intf[intf_num].ep[ep_num].ep_desc.bmAttributes = ep_desc->bmAttributes; hport->config.intf[intf_num].ep[ep_num].ep_desc.wMaxPacketSize = ep_desc->wMaxPacketSize; hport->config.intf[intf_num].ep[ep_num].ep_desc.bInterval = ep_desc->bInterval; ep_num++; } } intf_num++; } } } } return 0; } #ifdef CONFIG_USBHOST_GET_STRING_DESC static int parse_string_descriptor(struct usbh_hubport *hport, struct usb_string_descriptor *desc, uint8_t str_idx) { uint8_t string[64 + 1] = { 0 }; uint8_t *p = (uint8_t *)desc; if (desc->bDescriptorType != USB_DESCRIPTOR_TYPE_STRING) { USB_LOG_ERR("unexpected string descriptor 0x%02x\r\n", desc->bDescriptorType); return -2; } else { p += 2; for (uint32_t i = 0; i < (desc->bLength - 2) / 2; i++) { string[i] = *p; p += 2; } if (str_idx == USB_STRING_MFC_INDEX) { USB_LOG_INFO("Manufacturer :%s\r\n", string); } else if (str_idx == USB_STRING_PRODUCT_INDEX) { USB_LOG_INFO("Product :%s\r\n", string); } else if (str_idx == USB_STRING_SERIAL_INDEX) { USB_LOG_INFO("SerialNumber :%s\r\n", string); } else { } } return 0; } #endif static void usbh_print_hubport_info(struct usbh_hubport *hport) { USB_LOG_RAW("Device Descriptor:\r\n"); USB_LOG_RAW("bLength: 0x%02x \r\n", hport->device_desc.bLength); USB_LOG_RAW("bDescriptorType: 0x%02x \r\n", hport->device_desc.bDescriptorType); USB_LOG_RAW("bcdUSB: 0x%04x \r\n", hport->device_desc.bcdUSB); USB_LOG_RAW("bDeviceClass: 0x%02x \r\n", hport->device_desc.bDeviceClass); USB_LOG_RAW("bDeviceSubClass: 0x%02x \r\n", hport->device_desc.bDeviceSubClass); USB_LOG_RAW("bDeviceProtocol: 0x%02x \r\n", hport->device_desc.bDeviceProtocol); USB_LOG_RAW("bMaxPacketSize0: 0x%02x \r\n", hport->device_desc.bMaxPacketSize0); USB_LOG_RAW("idVendor: 0x%04x \r\n", hport->device_desc.idVendor); USB_LOG_RAW("idProduct: 0x%04x \r\n", hport->device_desc.idProduct); USB_LOG_RAW("bcdDevice: 0x%04x \r\n", hport->device_desc.bcdDevice); USB_LOG_RAW("iManufacturer: 0x%02x \r\n", hport->device_desc.iManufacturer); USB_LOG_RAW("iProduct: 0x%02x \r\n", hport->device_desc.iProduct); USB_LOG_RAW("iSerialNumber: 0x%02x \r\n", hport->device_desc.iSerialNumber); USB_LOG_RAW("bNumConfigurations: 0x%02x\r\n", hport->device_desc.bNumConfigurations); USB_LOG_RAW("Config Descriptor:\r\n"); USB_LOG_RAW("bLength: 0x%02x \r\n", hport->config.config_desc.bLength); USB_LOG_RAW("bDescriptorType: 0x%02x \r\n", hport->config.config_desc.bDescriptorType); USB_LOG_RAW("wTotalLength: 0x%04x \r\n", hport->config.config_desc.wTotalLength); USB_LOG_RAW("bNumInterfaces: 0x%02x \r\n", hport->config.config_desc.bNumInterfaces); USB_LOG_RAW("bConfigurationValue: 0x%02x \r\n", hport->config.config_desc.bConfigurationValue); USB_LOG_RAW("iConfiguration: 0x%02x \r\n", hport->config.config_desc.iConfiguration); USB_LOG_RAW("bmAttributes: 0x%02x \r\n", hport->config.config_desc.bmAttributes); USB_LOG_RAW("bMaxPower: 0x%02x \r\n", hport->config.config_desc.bMaxPower); for (uint8_t i = 0; i < hport->config.config_desc.bNumInterfaces; i++) { USB_LOG_RAW("Interface Descriptor:\r\n"); USB_LOG_RAW("bLength: 0x%02x \r\n", hport->config.intf[i].intf_desc.bLength); USB_LOG_RAW("bDescriptorType: 0x%02x \r\n", hport->config.intf[i].intf_desc.bDescriptorType); USB_LOG_RAW("bInterfaceNumber: 0x%02x \r\n", hport->config.intf[i].intf_desc.bInterfaceNumber); USB_LOG_RAW("bAlternateSetting: 0x%02x \r\n", hport->config.intf[i].intf_desc.bAlternateSetting); USB_LOG_RAW("bNumEndpoints: 0x%02x \r\n", hport->config.intf[i].intf_desc.bNumEndpoints); USB_LOG_RAW("bInterfaceClass: 0x%02x \r\n", hport->config.intf[i].intf_desc.bInterfaceClass); USB_LOG_RAW("bInterfaceSubClass: 0x%02x \r\n", hport->config.intf[i].intf_desc.bInterfaceSubClass); USB_LOG_RAW("bInterfaceProtocol: 0x%02x \r\n", hport->config.intf[i].intf_desc.bInterfaceProtocol); USB_LOG_RAW("iInterface: 0x%02x \r\n", hport->config.intf[i].intf_desc.iInterface); for (uint8_t j = 0; j < hport->config.intf[i].intf_desc.bNumEndpoints; j++) { USB_LOG_RAW("Endpoint Descriptor:\r\n"); USB_LOG_RAW("bLength: 0x%02x \r\n", hport->config.intf[i].ep[j].ep_desc.bLength); USB_LOG_RAW("bDescriptorType: 0x%02x \r\n", hport->config.intf[i].ep[j].ep_desc.bDescriptorType); USB_LOG_RAW("bEndpointAddress: 0x%02x \r\n", hport->config.intf[i].ep[j].ep_desc.bEndpointAddress); USB_LOG_RAW("bmAttributes: 0x%02x \r\n", hport->config.intf[i].ep[j].ep_desc.bmAttributes); USB_LOG_RAW("wMaxPacketSize: 0x%04x \r\n", hport->config.intf[i].ep[j].ep_desc.wMaxPacketSize); USB_LOG_RAW("bInterval: 0x%02x \r\n", hport->config.intf[i].ep[j].ep_desc.bInterval); } } } static int usbh_enumerate(struct usbh_hubport *hport) { struct usb_interface_descriptor *intf_desc; struct usb_setup_packet *setup; uint8_t *ep0_buffer; uint8_t descsize; int dev_addr; uint8_t ep_mps; int ret; #define USB_REQUEST_BUFFER_SIZE 256 /* Allocate buffer for setup and data buffer */ if (hport->setup == NULL) { hport->setup = usb_iomalloc(sizeof(struct usb_setup_packet)); if (hport->setup == NULL) { USB_LOG_ERR("Fail to alloc setup\r\n"); return -ENOMEM; } } setup = hport->setup; ep0_buffer = usb_iomalloc(USB_REQUEST_BUFFER_SIZE); if (ep0_buffer == NULL) { USB_LOG_ERR("Fail to alloc ep0_buffer\r\n"); return -ENOMEM; } /* Pick an appropriate packet size for this device * * USB 2.0, Paragraph 5.5.3 "Control Transfer Packet Size Constraints" * * "An endpoint for control transfers specifies the maximum data * payload size that the endpoint can accept from or transmit to * the bus. The allowable maximum control transfer data payload * sizes for full-speed devices is 8, 16, 32, or 64 bytes; for * high-speed devices, it is 64 bytes and for low-speed devices, * it is 8 bytes. This maximum applies to the data payloads of the * Data packets following a Setup..." */ if (hport->speed == USB_SPEED_HIGH) { /* For high-speed, we must use 64 bytes */ ep_mps = 64; descsize = USB_SIZEOF_DEVICE_DESC; } else { /* Eight will work for both low- and full-speed */ ep_mps = 8; descsize = 8; } /* Configure EP0 with the initial maximum packet size */ usbh_ep0_reconfigure(hport->ep0, 0, ep_mps, hport->speed); /* Read the first 8 bytes of the device descriptor */ setup->bmRequestType = USB_REQUEST_DIR_IN | USB_REQUEST_STANDARD | USB_REQUEST_RECIPIENT_DEVICE; setup->bRequest = USB_REQUEST_GET_DESCRIPTOR; setup->wValue = (uint16_t)((USB_DESCRIPTOR_TYPE_DEVICE << 8) | 0); setup->wIndex = 0; setup->wLength = descsize; ret = usbh_control_transfer(hport->ep0, setup, ep0_buffer); if (ret < 0) { USB_LOG_ERR("Failed to get device descriptor,errorcode:%d\r\n", ret); goto errout; } parse_device_descriptor(hport, (struct usb_device_descriptor *)ep0_buffer, descsize); if ((hport->parent == NULL) && (hport->speed != USB_SPEED_HIGH)) { usbh_reset_port(hport->port); } /* Extract the correct max packetsize from the device descriptor */ ep_mps = ((struct usb_device_descriptor *)ep0_buffer)->bMaxPacketSize0; /* And reconfigure EP0 with the correct maximum packet size */ usbh_ep0_reconfigure(hport->ep0, 0, ep_mps, hport->speed); /* Assign a function address to the device connected to this port */ dev_addr = usbh_devaddr_create(hport); if (dev_addr < 0) { USB_LOG_ERR("Failed to allocate devaddr,errorcode:%d\r\n", ret); goto errout; } /* Set the USB device address */ setup->bmRequestType = USB_REQUEST_DIR_OUT | USB_REQUEST_STANDARD | USB_REQUEST_RECIPIENT_DEVICE; setup->bRequest = USB_REQUEST_SET_ADDRESS; setup->wValue = dev_addr; setup->wIndex = 0; setup->wLength = 0; ret = usbh_control_transfer(hport->ep0, setup, NULL); if (ret < 0) { USB_LOG_ERR("Failed to set devaddr,errorcode:%d\r\n", ret); goto errout; } /* wait device address set completely */ usb_osal_msleep(2); /* Assign the function address to the port */ hport->dev_addr = dev_addr; /* And reconfigure EP0 with the correct address */ usbh_ep0_reconfigure(hport->ep0, dev_addr, ep_mps, hport->speed); /* Read the full device descriptor */ setup->bmRequestType = USB_REQUEST_DIR_IN | USB_REQUEST_STANDARD | USB_REQUEST_RECIPIENT_DEVICE; setup->bRequest = USB_REQUEST_GET_DESCRIPTOR; setup->wValue = (uint16_t)((USB_DESCRIPTOR_TYPE_DEVICE << 8) | 0); setup->wIndex = 0; setup->wLength = USB_SIZEOF_DEVICE_DESC; ret = usbh_control_transfer(hport->ep0, setup, ep0_buffer); if (ret < 0) { USB_LOG_ERR("Failed to get full device descriptor,errorcode:%d\r\n", ret); goto errout; } parse_device_descriptor(hport, (struct usb_device_descriptor *)ep0_buffer, USB_SIZEOF_DEVICE_DESC); USB_LOG_INFO("New device found,idVendor:%04x,idProduct:%04x,bcdDevice:%04x\r\n", ((struct usb_device_descriptor *)ep0_buffer)->idVendor, ((struct usb_device_descriptor *)ep0_buffer)->idProduct, ((struct usb_device_descriptor *)ep0_buffer)->bcdDevice); /* Read the first 9 bytes of the config descriptor */ setup->bmRequestType = USB_REQUEST_DIR_IN | USB_REQUEST_STANDARD | USB_REQUEST_RECIPIENT_DEVICE; setup->bRequest = USB_REQUEST_GET_DESCRIPTOR; setup->wValue = (uint16_t)((USB_DESCRIPTOR_TYPE_CONFIGURATION << 8) | 0); setup->wIndex = 0; setup->wLength = USB_SIZEOF_CONFIG_DESC; ret = usbh_control_transfer(hport->ep0, setup, ep0_buffer); if (ret < 0) { USB_LOG_ERR("Failed to get config descriptor,errorcode:%d\r\n", ret); goto errout; } parse_config_descriptor(hport, (struct usb_configuration_descriptor *)ep0_buffer, USB_SIZEOF_CONFIG_DESC); /* Read the full size of the configuration data */ uint16_t wTotalLength = ((struct usb_configuration_descriptor *)ep0_buffer)->wTotalLength; setup->bmRequestType = USB_REQUEST_DIR_IN | USB_REQUEST_STANDARD | USB_REQUEST_RECIPIENT_DEVICE; setup->bRequest = USB_REQUEST_GET_DESCRIPTOR; setup->wValue = (uint16_t)((USB_DESCRIPTOR_TYPE_CONFIGURATION << 8) | 0); setup->wIndex = 0; setup->wLength = wTotalLength; ret = usbh_control_transfer(hport->ep0, setup, ep0_buffer); if (ret < 0) { USB_LOG_ERR("Failed to get full config descriptor,errorcode:%d\r\n", ret); goto errout; } parse_config_descriptor(hport, (struct usb_configuration_descriptor *)ep0_buffer, wTotalLength); USB_LOG_INFO("The device has %d interfaces\r\n", ((struct usb_configuration_descriptor *)ep0_buffer)->bNumInterfaces); #ifdef CONFIG_USBHOST_GET_STRING_DESC /* Get Manufacturer string */ setup->bmRequestType = USB_REQUEST_DIR_IN | USB_REQUEST_STANDARD | USB_REQUEST_RECIPIENT_DEVICE; setup->bRequest = USB_REQUEST_GET_DESCRIPTOR; setup->wValue = (uint16_t)((USB_DESCRIPTOR_TYPE_STRING << 8) | USB_STRING_MFC_INDEX); setup->wIndex = 0x0409; setup->wLength = 255; ret = usbh_control_transfer(hport->ep0, setup, ep0_buffer); if (ret < 0) { USB_LOG_ERR("Failed to get Manufacturer string,errorcode:%d\r\n", ret); goto errout; } parse_string_descriptor(hport, (struct usb_string_descriptor *)ep0_buffer, USB_STRING_MFC_INDEX); /* Get Product string */ setup->bmRequestType = USB_REQUEST_DIR_IN | USB_REQUEST_STANDARD | USB_REQUEST_RECIPIENT_DEVICE; setup->bRequest = USB_REQUEST_GET_DESCRIPTOR; setup->wValue = (uint16_t)((USB_DESCRIPTOR_TYPE_STRING << 8) | USB_STRING_PRODUCT_INDEX); setup->wIndex = 0x0409; setup->wLength = 255; ret = usbh_control_transfer(hport->ep0, setup, ep0_buffer); if (ret < 0) { USB_LOG_ERR("Failed to get get Product string,errorcode:%d\r\n", ret); goto errout; } parse_string_descriptor(hport, (struct usb_string_descriptor *)ep0_buffer, USB_STRING_PRODUCT_INDEX); /* Get SerialNumber string */ setup->bmRequestType = USB_REQUEST_DIR_IN | USB_REQUEST_STANDARD | USB_REQUEST_RECIPIENT_DEVICE; setup->bRequest = USB_REQUEST_GET_DESCRIPTOR; setup->wValue = (uint16_t)((USB_DESCRIPTOR_TYPE_STRING << 8) | USB_STRING_SERIAL_INDEX); setup->wIndex = 0x0409; setup->wLength = 255; ret = usbh_control_transfer(hport->ep0, setup, ep0_buffer); if (ret < 0) { USB_LOG_ERR("Failed to get get SerialNumber string,errorcode:%d\r\n", ret); goto errout; } parse_string_descriptor(hport, (struct usb_string_descriptor *)ep0_buffer, USB_STRING_SERIAL_INDEX); #endif /* Select device configuration 1 */ setup->bmRequestType = USB_REQUEST_DIR_OUT | USB_REQUEST_STANDARD | USB_REQUEST_RECIPIENT_DEVICE; setup->bRequest = USB_REQUEST_SET_CONFIGURATION; setup->wValue = 1; setup->wIndex = 0; setup->wLength = 0; ret = usbh_control_transfer(hport->ep0, setup, NULL); if (ret < 0) { USB_LOG_ERR("Failed to set configuration,errorcode:%d\r\n", ret); goto errout; } USB_LOG_INFO("Enumeration success, start loading class driver\r\n"); /*search supported class driver*/ for (uint8_t i = 0; i < hport->config.config_desc.bNumInterfaces; i++) { intf_desc = &hport->config.intf[i].intf_desc; struct usbh_class_driver *class_driver = (struct usbh_class_driver *)usbh_find_class_driver(intf_desc->bInterfaceClass, intf_desc->bInterfaceSubClass, intf_desc->bInterfaceProtocol, hport->device_desc.idVendor, hport->device_desc.idProduct); if (class_driver == NULL) { USB_LOG_ERR("do not support Class:0x%02x,Subclass:0x%02x,Protocl:0x%02x\r\n", intf_desc->bInterfaceClass, intf_desc->bInterfaceSubClass, intf_desc->bInterfaceProtocol); continue; } hport->config.intf[i].class_driver = class_driver; USB_LOG_INFO("Loading %s class driver\r\n", class_driver->driver_name); ret = CLASS_CONNECT(hport, i); if (ret < 0) { ret = CLASS_DISCONNECT(hport, i); goto errout; } } errout: if (ret < 0) { usbh_hport_deactivate(hport); } if (ep0_buffer) { usb_iofree(ep0_buffer); } return ret; } static int usbh_portchange_wait(struct usbh_hubport **hport) { struct usbh_hubport *connport = NULL; uint32_t recved_event; size_t flags; int ret; /* Loop until a change in connection state is detected */ while (1) { ret = usb_osal_event_recv(usbh_core_cfg.pscevent, USBH_EVENT_CONNECTED | USBH_EVENT_DISCONNECTED, &recved_event); if (ret < 0) { continue; } flags = usb_osal_enter_critical_section(); for (uint8_t port = USBH_HUB_PORT_START_INDEX; port <= CONFIG_USBHOST_RHPORTS; port++) { /* Check for a change in the connection state on any root hub port */ connport = &usbh_core_cfg.rhport[port - 1].hport; if (connport->port_change) { connport->port_change = false; /* debounce for port,in order to keep port connect status stability*/ usb_osal_msleep(100); if (recved_event & USBH_EVENT_CONNECTED) { if (usbh_get_port_connect_status(port)) { if (!connport->connected) { connport->connected = true; *hport = connport; usb_osal_leave_critical_section(flags); return 0; } } } if (recved_event & USBH_EVENT_DISCONNECTED) { if (!usbh_get_port_connect_status(port)) { if (connport->connected) { connport->connected = false; *hport = connport; usb_osal_leave_critical_section(flags); return 0; } } } } } #ifdef CONFIG_USBHOST_HUB /* Is a device connected to an external hub? */ if (usbh_core_cfg.active_hport) { connport = (struct usbh_hubport *)usbh_core_cfg.active_hport; usbh_core_cfg.active_hport = NULL; *hport = connport; usb_osal_leave_critical_section(flags); return 0; } #endif usb_osal_leave_critical_section(flags); } } static void usbh_portchange_detect_thread(void *argument) { struct usbh_hubport *hport = NULL; usb_hc_sw_init(); for (uint8_t port = USBH_HUB_PORT_START_INDEX; port <= CONFIG_USBHOST_RHPORTS; port++) { usbh_core_cfg.rhport[port - 1].hport.port = port; usbh_core_cfg.rhport[port - 1].devgen.next = 1; usbh_hport_activate(&usbh_core_cfg.rhport[port - 1].hport); } usb_hc_hw_init(); while (1) { usbh_portchange_wait(&hport); if (hport->connected) { /*if roothub port,reset port first*/ if (ROOTHUB(hport)) { /* Reset the host port */ usbh_reset_port(hport->port); usb_osal_msleep(200); /* Get the current device speed */ hport->speed = usbh_get_port_speed(hport->port); USB_LOG_INFO("Hub %u, Port %u connected, %s\r\n", 1, hport->port, speed_table[hport->speed]); } else { USB_LOG_INFO("Hub %u, Port %u connected, %s\r\n", hport->parent->index, hport->port, speed_table[hport->speed]); } usbh_enumerate(hport); } else { usbh_hport_deactivate(hport); for (uint8_t i = 0; i < hport->config.config_desc.bNumInterfaces; i++) { if (hport->config.intf[i].class_driver && hport->config.intf[i].class_driver->disconnect) { CLASS_DISCONNECT(hport, i); } } hport->config.config_desc.bNumInterfaces = 0; if (ROOTHUB(hport)) { USB_LOG_INFO("Hub %u,Port:%u disconnected\r\n", 1, hport->port); } else { USB_LOG_INFO("Hub %u,Port:%u disconnected\r\n", hport->parent->index, hport->port); } } } } void usbh_external_hport_connect(struct usbh_hubport *hport) { size_t flags; usbh_hport_activate(hport); flags = usb_osal_enter_critical_section(); hport->connected = true; usbh_core_cfg.active_hport = hport; usb_osal_leave_critical_section(flags); usb_osal_event_send(usbh_core_cfg.pscevent, USBH_EVENT_CONNECTED); } void usbh_external_hport_disconnect(struct usbh_hubport *hport) { size_t flags; flags = usb_osal_enter_critical_section(); hport->connected = false; usbh_core_cfg.active_hport = hport; usb_osal_leave_critical_section(flags); usb_osal_event_send(usbh_core_cfg.pscevent, USBH_EVENT_DISCONNECTED); } void usbh_event_notify_handler(uint8_t event, uint8_t rhport) { usbh_core_cfg.rhport[rhport - 1].hport.port_change = true; usb_osal_event_send(usbh_core_cfg.pscevent, event); } int usbh_initialize(void) { usb_osal_thread_t usb_thread; memset(&usbh_core_cfg, 0, sizeof(struct usbh_core_priv)); #ifdef __ARMCC_VERSION /* ARM C Compiler */ extern const int usbh_class_info$$Base; extern const int usbh_class_info$$Limit; usbh_class_info_table_begin = (struct usbh_class_info *)&usbh_class_info$$Base; usbh_class_info_table_end = (struct usbh_class_info *)&usbh_class_info$$Limit; #elif defined(__GNUC__) extern uint32_t _usbh_class_info_start; extern uint32_t _usbh_class_info_end; usbh_class_info_table_begin = (struct usbh_class_info *)&_usbh_class_info_start; usbh_class_info_table_end = (struct usbh_class_info *)&_usbh_class_info_end; #endif usbh_workq_initialize(); usbh_core_cfg.pscevent = usb_osal_event_create(); if (usbh_core_cfg.pscevent == NULL) { return -1; } usb_thread = usb_osal_thread_create("usbh_psc", CONFIG_USBHOST_PSC_STACKSIZE, CONFIG_USBHOST_PSC_PRIO, usbh_portchange_detect_thread, NULL); if (usb_thread == NULL) { return -1; } return 0; } int lsusb(int argc, char **argv) { #ifdef CONFIG_USBHOST_HUB usb_slist_t *hub_list; #endif uint8_t port; if (argc < 2) { USB_LOG_RAW("Usage: lsusb [options]...\r\n"); USB_LOG_RAW("List USB devices\r\n"); USB_LOG_RAW(" -v, --verbose\r\n"); USB_LOG_RAW(" Increase verbosity (show descriptors)\r\n"); USB_LOG_RAW(" -s [[bus]:[devnum]]\r\n"); USB_LOG_RAW(" Show only devices with specified device and/or bus numbers (in decimal)\r\n"); USB_LOG_RAW(" -d vendor:[product]\r\n"); USB_LOG_RAW(" Show only devices with the specified vendor and product ID numbers (in hexadecimal)\r\n"); USB_LOG_RAW(" -t, --tree\r\n"); USB_LOG_RAW(" Dump the physical USB device hierachy as a tree\r\n"); USB_LOG_RAW(" -V, --version\r\n"); USB_LOG_RAW(" Show version of program\r\n"); USB_LOG_RAW(" -h, --help\r\n"); USB_LOG_RAW(" Show usage and help\r\n"); return 0; } if (argc > 3) { return 0; } if (strcmp(argv[1], "-t") == 0) { for (port = USBH_HUB_PORT_START_INDEX; port <= CONFIG_USBHOST_RHPORTS; port++) { if (usbh_core_cfg.rhport[port - 1].hport.connected) { USB_LOG_RAW("/: Hub %02u,VID:PID 0x%04x:0x%04x\r\n", USBH_ROOT_HUB_INDEX, usbh_core_cfg.rhport[port - 1].hport.device_desc.idVendor, usbh_core_cfg.rhport[port - 1].hport.device_desc.idProduct); for (uint8_t i = 0; i < usbh_core_cfg.rhport[port - 1].hport.config.config_desc.bNumInterfaces; i++) { if (usbh_core_cfg.rhport[port - 1].hport.config.intf[i].class_driver->driver_name) { USB_LOG_RAW(" |__Port %u,Port addr:0x%02x,If %u,ClassDriver=%s\r\n", usbh_core_cfg.rhport[port - 1].hport.port, usbh_core_cfg.rhport[port - 1].hport.dev_addr, i, usbh_core_cfg.rhport[port - 1].hport.config.intf[i].class_driver->driver_name); } } } } #ifdef CONFIG_USBHOST_HUB usb_slist_for_each(hub_list, &hub_class_head) { usbh_hub_t *hub_class = usb_slist_entry(hub_list, struct usbh_hub, list); for (port = USBH_HUB_PORT_START_INDEX; port <= hub_class->nports; port++) { if (hub_class->child[port - 1].connected) { USB_LOG_RAW("/: Hub %02u,VID:PID 0x%04x:0x%04x\r\n", hub_class->index, hub_class->child[port - 1].device_desc.idVendor, hub_class->child[port - 1].device_desc.idProduct); for (uint8_t i = 0; i < hub_class->child[port - 1].config.config_desc.bNumInterfaces; i++) { if (hub_class->child[port - 1].config.intf[i].class_driver->driver_name) { USB_LOG_RAW(" |__Port %u,Port addr:0x%02x,If %u,ClassDriver=%s\r\n", hub_class->child[port - 1].port, hub_class->child[port - 1].dev_addr, i, hub_class->child[port - 1].config.intf[i].class_driver->driver_name); } } } } } #endif } else if (strcmp(argv[1], "-v") == 0) { for (port = USBH_HUB_PORT_START_INDEX; port <= CONFIG_USBHOST_RHPORTS; port++) { if (usbh_core_cfg.rhport[port - 1].hport.connected) { USB_LOG_RAW("Hub %02u,Port %u,Port addr:0x%02x,VID:PID 0x%04x:0x%04x\r\n", USBH_ROOT_HUB_INDEX, usbh_core_cfg.rhport[port - 1].hport.port, usbh_core_cfg.rhport[port - 1].hport.dev_addr, usbh_core_cfg.rhport[port - 1].hport.device_desc.idVendor, usbh_core_cfg.rhport[port - 1].hport.device_desc.idProduct); usbh_print_hubport_info(&usbh_core_cfg.rhport[port - 1].hport); } } #ifdef CONFIG_USBHOST_HUB usb_slist_for_each(hub_list, &hub_class_head) { usbh_hub_t *hub_class = usb_slist_entry(hub_list, struct usbh_hub, list); for (port = USBH_HUB_PORT_START_INDEX; port <= hub_class->nports; port++) { if (hub_class->child[port - 1].connected) { USB_LOG_RAW("Hub %02u,Port %u,Port addr:0x%02x,VID:PID 0x%04x:0x%04x\r\n", hub_class->index, hub_class->child[port - 1].port, hub_class->child[port - 1].dev_addr, hub_class->child[port - 1].device_desc.idVendor, hub_class->child[port - 1].device_desc.idProduct); usbh_print_hubport_info(&hub_class->child[port - 1]); } } } #endif } return 0; } struct usbh_hubport *usbh_find_hubport(uint8_t dev_addr) { #ifdef CONFIG_USBHOST_HUB usb_slist_t *hub_list; #endif uint8_t port; for (port = USBH_HUB_PORT_START_INDEX; port <= CONFIG_USBHOST_RHPORTS; port++) { if (usbh_core_cfg.rhport[port - 1].hport.connected) { if (usbh_core_cfg.rhport[port - 1].hport.dev_addr == dev_addr) { return &usbh_core_cfg.rhport[port - 1].hport; } } } #ifdef CONFIG_USBHOST_HUB usb_slist_for_each(hub_list, &hub_class_head) { usbh_hub_t *hub_class = usb_slist_entry(hub_list, struct usbh_hub, list); for (port = USBH_HUB_PORT_START_INDEX; port <= hub_class->nports; port++) { if (hub_class->child[port - 1].connected) { if (hub_class->child[port - 1].dev_addr == dev_addr) { return &hub_class->child[port - 1]; } } } } #endif return NULL; } void *usbh_find_class_instance(const char *devname) { #ifdef CONFIG_USBHOST_HUB usb_slist_t *hub_list; #endif struct usbh_hubport *hport; uint8_t port; for (port = USBH_HUB_PORT_START_INDEX; port <= CONFIG_USBHOST_RHPORTS; port++) { hport = &usbh_core_cfg.rhport[port - 1].hport; if (hport->connected) { for (uint8_t itf = 0; itf < hport->config.config_desc.bNumInterfaces; itf++) { if (strncmp(hport->config.intf[itf].devname, devname, CONFIG_USBHOST_DEV_NAMELEN) == 0) return hport->config.intf[itf].priv; } } } #ifdef CONFIG_USBHOST_HUB usb_slist_for_each(hub_list, &hub_class_head) { usbh_hub_t *hub_class = usb_slist_entry(hub_list, struct usbh_hub, list); for (port = USBH_HUB_PORT_START_INDEX; port <= hub_class->nports; port++) { hport = &hub_class->child[port - 1]; if (hport->connected) { for (uint8_t itf = 0; itf < hport->config.config_desc.bNumInterfaces; itf++) { if (strncmp(hport->config.intf[itf].devname, devname, CONFIG_USBHOST_DEV_NAMELEN) == 0) return hport->config.intf[itf].priv; } } } } #endif return NULL; } static const struct usbh_class_driver *usbh_find_class_driver(uint8_t class, uint8_t subclass, uint8_t protocol, uint16_t vid, uint16_t pid) { struct usbh_class_info *index = NULL; for (index = usbh_class_info_table_begin; index < usbh_class_info_table_end; index++) { if ((index->match_flags & (USB_CLASS_MATCH_VENDOR | USB_CLASS_MATCH_PRODUCT | USB_CLASS_MATCH_INTF_CLASS | USB_CLASS_MATCH_INTF_SUBCLASS | USB_CLASS_MATCH_INTF_PROTOCOL)) == (USB_CLASS_MATCH_VENDOR | USB_CLASS_MATCH_PRODUCT | USB_CLASS_MATCH_INTF_CLASS | USB_CLASS_MATCH_INTF_SUBCLASS | USB_CLASS_MATCH_INTF_PROTOCOL)) { if (index->vid == vid && index->pid == pid && index->class == class && index->subclass == subclass && index->protocol == protocol) { return index->class_driver; } } else if ((index->match_flags & (USB_CLASS_MATCH_INTF_CLASS | USB_CLASS_MATCH_INTF_SUBCLASS | USB_CLASS_MATCH_INTF_PROTOCOL)) == (USB_CLASS_MATCH_INTF_CLASS | USB_CLASS_MATCH_INTF_SUBCLASS | USB_CLASS_MATCH_INTF_PROTOCOL)) { if (index->class == class && index->subclass == subclass && index->protocol == protocol) { return index->class_driver; } } else if ((index->match_flags & (USB_CLASS_MATCH_VENDOR | USB_CLASS_MATCH_PRODUCT | USB_CLASS_MATCH_INTF_CLASS)) == (USB_CLASS_MATCH_VENDOR | USB_CLASS_MATCH_PRODUCT | USB_CLASS_MATCH_INTF_CLASS)) { if (index->vid == vid && index->pid == pid && index->class == class) { return index->class_driver; } } else if (index->match_flags & (USB_CLASS_MATCH_INTF_CLASS)) { if (index->class == class) { return index->class_driver; } } } return NULL; }