/**************************************************************************//** * * @copyright (C) 2020 Nuvoton Technology Corp. All rights reserved. * * SPDX-License-Identifier: Apache-2.0 * * Change Logs: * Date Author Notes * 2020-09-17 CHChen First version * ******************************************************************************/ #include #ifdef BSP_USING_USBD #include #include #include #include "NuMicro.h" #define LOG_TAG "drv.usbd" #define DBG_ENABLE #define DBG_SECTION_NAME "drv.usbd" #define DBG_LEVEL DBG_ERROR #define DBG_COLOR #include /* Private define ---------------------------------------------------------------*/ /* Define EP maximum packet size */ #define EP0_MAX_PKT_SIZE 64 #define EP1_MAX_PKT_SIZE EP0_MAX_PKT_SIZE /* EP0 and EP1 are assigned the same size for control endpoint */ #define EP2_MAX_PKT_SIZE 64 #define EP3_MAX_PKT_SIZE 64 #define EP4_MAX_PKT_SIZE 64 #define EP5_MAX_PKT_SIZE 64 #define EP6_MAX_PKT_SIZE 64 #define EP7_MAX_PKT_SIZE 64 #define EP8_MAX_PKT_SIZE 64 #define EP9_MAX_PKT_SIZE 64 #define EP10_MAX_PKT_SIZE 64 #define EP11_MAX_PKT_SIZE 64 #define SETUP_BUF_BASE 0 #define SETUP_BUF_LEN 8 #define EP0_BUF_BASE (SETUP_BUF_BASE + SETUP_BUF_LEN) #define EP0_BUF_LEN EP0_MAX_PKT_SIZE #define EP1_BUF_BASE (SETUP_BUF_BASE + SETUP_BUF_LEN) #define EP1_BUF_LEN EP1_MAX_PKT_SIZE #define EP2_BUF_BASE (EP1_BUF_BASE + EP1_BUF_LEN) #define EP2_BUF_LEN EP2_MAX_PKT_SIZE #define EP3_BUF_BASE (EP2_BUF_BASE + EP2_BUF_LEN) #define EP3_BUF_LEN EP3_MAX_PKT_SIZE #define EP4_BUF_BASE (EP3_BUF_BASE + EP3_BUF_LEN) #define EP4_BUF_LEN EP4_MAX_PKT_SIZE #define EP5_BUF_BASE (EP4_BUF_BASE + EP4_BUF_LEN) #define EP5_BUF_LEN EP5_MAX_PKT_SIZE #define EP6_BUF_BASE (EP5_BUF_BASE + EP5_BUF_LEN) #define EP6_BUF_LEN EP6_MAX_PKT_SIZE #define EP7_BUF_BASE (EP6_BUF_BASE + EP6_BUF_LEN) #define EP7_BUF_LEN EP7_MAX_PKT_SIZE #define EP8_BUF_BASE (EP7_BUF_BASE + EP7_BUF_LEN) #define EP8_BUF_LEN EP8_MAX_PKT_SIZE #define EP9_BUF_BASE (EP8_BUF_BASE + EP8_BUF_LEN) #define EP9_BUF_LEN EP9_MAX_PKT_SIZE #define EP10_BUF_BASE (EP9_BUF_BASE + EP9_BUF_LEN) #define EP10_BUF_LEN EP10_MAX_PKT_SIZE #define EP11_BUF_BASE (EP10_BUF_BASE + EP10_BUF_LEN) #define EP11_BUF_LEN EP11_MAX_PKT_SIZE #define EPADR_SW2HW(address) ((((address & USB_EPNO_MASK) * 2) + (!(address & USB_DIR_IN)))) #define EPADR_HW2SW(address) ((address & USB_EPNO_MASK) / 2) /* Private typedef --------------------------------------------------------------*/ typedef struct _nu_usbd_t { USBD_T *Instance; /* REG base */ uint8_t address_tmp; /* Keep assigned address for flow control */ } nu_usbd_t; /* Private variables ------------------------------------------------------------*/ static nu_usbd_t nu_usbd = { .Instance = USBD, .address_tmp = 0, }; static struct udcd _rt_obj_udc; static struct ep_id _ep_pool[] = { {EPADR_HW2SW(EP0), USB_EP_ATTR_CONTROL, USB_DIR_INOUT, EP0_MAX_PKT_SIZE, ID_ASSIGNED }, {EPADR_HW2SW(EP2), USB_EP_ATTR_BULK, USB_DIR_IN, EP2_MAX_PKT_SIZE, ID_UNASSIGNED}, {EPADR_HW2SW(EP3), USB_EP_ATTR_BULK, USB_DIR_OUT, EP3_MAX_PKT_SIZE, ID_UNASSIGNED}, {EPADR_HW2SW(EP4), USB_EP_ATTR_INT, USB_DIR_IN, EP4_MAX_PKT_SIZE, ID_UNASSIGNED}, {EPADR_HW2SW(EP5), USB_EP_ATTR_INT, USB_DIR_OUT, EP5_MAX_PKT_SIZE, ID_UNASSIGNED}, {EPADR_HW2SW(EP6), USB_EP_ATTR_BULK, USB_DIR_IN, EP6_MAX_PKT_SIZE, ID_UNASSIGNED}, {EPADR_HW2SW(EP7), USB_EP_ATTR_BULK, USB_DIR_OUT, EP7_MAX_PKT_SIZE, ID_UNASSIGNED}, {EPADR_HW2SW(EP8), USB_EP_ATTR_INT, USB_DIR_IN, EP8_MAX_PKT_SIZE, ID_UNASSIGNED}, {EPADR_HW2SW(EP9), USB_EP_ATTR_INT, USB_DIR_OUT, EP9_MAX_PKT_SIZE, ID_UNASSIGNED}, {EPADR_HW2SW(EP10), USB_EP_ATTR_BULK, USB_DIR_IN, EP6_MAX_PKT_SIZE, ID_UNASSIGNED}, {EPADR_HW2SW(EP11), USB_EP_ATTR_BULK, USB_DIR_OUT, EP7_MAX_PKT_SIZE, ID_UNASSIGNED}, {0xFF, USB_EP_ATTR_TYPE_MASK, USB_DIR_MASK, 0, ID_ASSIGNED }, }; static void _nu_ep_partition(void) { /* Init setup packet buffer */ /* Buffer range for setup packet -> [0 ~ 0x7] */ USBD->STBUFSEG = SETUP_BUF_BASE; /*****************************************************/ /* EP0 ==> control IN endpoint, address 0 */ USBD_CONFIG_EP(EP0, USBD_CFG_CSTALL | USBD_CFG_EPMODE_IN | EPADR_HW2SW(EP0)); /* Buffer range for EP0 */ USBD_SET_EP_BUF_ADDR(EP0, EP0_BUF_BASE); /* EP1 ==> control OUT endpoint, address 0 */ USBD_CONFIG_EP(EP1, USBD_CFG_CSTALL | USBD_CFG_EPMODE_OUT | EPADR_HW2SW(EP1)); /* Buffer range for EP1 */ USBD_SET_EP_BUF_ADDR(EP1, EP1_BUF_BASE); /*****************************************************/ /* EP2 ==> Bulk IN endpoint, address 1 */ USBD_CONFIG_EP(EP2, USBD_CFG_EPMODE_IN | EPADR_HW2SW(EP2)); /* Buffer range for EP2 */ USBD_SET_EP_BUF_ADDR(EP2, EP2_BUF_BASE); /* EP3 ==> Bulk OUT endpoint, address 1 */ USBD_CONFIG_EP(EP3, USBD_CFG_EPMODE_OUT | EPADR_HW2SW(EP3)); /* Buffer range for EP3 */ USBD_SET_EP_BUF_ADDR(EP3, EP3_BUF_BASE); /*****************************************************/ /* EP4 ==> Interrupt IN endpoint, address 2 */ USBD_CONFIG_EP(EP4, USBD_CFG_EPMODE_IN | EPADR_HW2SW(EP4)); /* Buffer range for EP4 */ USBD_SET_EP_BUF_ADDR(EP4, EP4_BUF_BASE); /* EP5 ==> Interrupt Out endpoint, address 2 */ USBD_CONFIG_EP(EP5, USBD_CFG_EPMODE_OUT | EPADR_HW2SW(EP5)); /* Buffer range for EP5 */ USBD_SET_EP_BUF_ADDR(EP5, EP5_BUF_BASE); /*****************************************************/ /* EP6 ==> Bulk IN endpoint, address 3 */ USBD_CONFIG_EP(EP6, USBD_CFG_EPMODE_IN | EPADR_HW2SW(EP6)); /* Buffer range for EP4 */ USBD_SET_EP_BUF_ADDR(EP6, EP6_BUF_BASE); /* EP7 ==> Bulk Out endpoint, address 3 */ USBD_CONFIG_EP(EP7, USBD_CFG_EPMODE_OUT | EPADR_HW2SW(EP7)); /* Buffer range for EP5 */ USBD_SET_EP_BUF_ADDR(EP7, EP7_BUF_BASE); /*****************************************************/ /* EP8 ==> Interrupt IN endpoint, address 4 */ USBD_CONFIG_EP(EP8, USBD_CFG_EPMODE_IN | EPADR_HW2SW(EP8)); /* Buffer range for EP4 */ USBD_SET_EP_BUF_ADDR(EP8, EP8_BUF_BASE); /* EP9 ==> Interrupt Out endpoint, address 4 */ USBD_CONFIG_EP(EP9, USBD_CFG_EPMODE_OUT | EPADR_HW2SW(EP9)); /* Buffer range for EP9 */ USBD_SET_EP_BUF_ADDR(EP9, EP9_BUF_BASE); /*****************************************************/ /* EP10 ==> Bulk IN endpoint, address 5 */ USBD_CONFIG_EP(EP10, USBD_CFG_EPMODE_IN | EPADR_HW2SW(EP10)); /* Buffer range for EP10 */ USBD_SET_EP_BUF_ADDR(EP10, EP10_BUF_BASE); /* EP11 ==> Bulk Out endpoint, address 5 */ USBD_CONFIG_EP(EP11, USBD_CFG_EPMODE_OUT | EPADR_HW2SW(EP11)); /* Buffer range for EP11 */ USBD_SET_EP_BUF_ADDR(EP11, EP11_BUF_BASE); } static rt_err_t _ep_set_stall(rt_uint8_t address) { USBD_SET_EP_STALL(EPADR_SW2HW(address)); return RT_EOK; } static rt_err_t _ep_clear_stall(rt_uint8_t address) { USBD_ClearStall(EPADR_SW2HW(address)); return RT_EOK; } static rt_err_t _set_address(rt_uint8_t address) { if (0 != address) { nu_usbd.address_tmp = address; } return RT_EOK; } static rt_err_t _set_config(rt_uint8_t address) { return RT_EOK; } static rt_err_t _ep_enable(uep_t ep) { RT_ASSERT(ep != RT_NULL); RT_ASSERT(ep->ep_desc != RT_NULL); USBD_CONFIG_EP(EPADR_SW2HW(EP_ADDRESS(ep)), USBD_CFG_CSTALL | ((EP_ADDRESS(ep) & USB_DIR_IN) ? USBD_CFG_EPMODE_IN : USBD_CFG_EPMODE_OUT) | (EP_ADDRESS(ep) & USB_EPNO_MASK)); return RT_EOK; } static rt_err_t _ep_disable(uep_t ep) { RT_ASSERT(ep != RT_NULL); RT_ASSERT(ep->ep_desc != RT_NULL); USBD_CONFIG_EP(EPADR_SW2HW(EP_ADDRESS(ep)), USBD_CFG_EPMODE_DISABLE); return RT_EOK; } static rt_size_t _ep_read(rt_uint8_t address, void *buffer) { rt_size_t size = 0; rt_uint8_t *buf; rt_uint32_t hw_ep_num = EPADR_SW2HW(address); RT_ASSERT(!(address & USB_DIR_IN)); RT_ASSERT(buffer != RT_NULL); size = USBD_GET_PAYLOAD_LEN(hw_ep_num); buf = (uint8_t *)(USBD_BUF_BASE + USBD_GET_EP_BUF_ADDR(hw_ep_num)); USBD_MemCopy(buffer, (uint8_t *)buf, size); return size; } static rt_size_t _ep_read_prepare(rt_uint8_t address, void *buffer, rt_size_t size) { RT_ASSERT(!(address & USB_DIR_IN)); USBD_SET_PAYLOAD_LEN(EPADR_SW2HW(address), size); return size; } static rt_size_t _ep_write(rt_uint8_t address, void *buffer, rt_size_t size) { RT_ASSERT((address & USB_DIR_IN)); /* even number is for IN endpoint */ rt_uint32_t hw_ep_num = EPADR_SW2HW(address); uint8_t *buf; buf = (uint8_t *)(USBD_BUF_BASE + USBD_GET_EP_BUF_ADDR(hw_ep_num)); USBD_MemCopy(buf, (uint8_t *)buffer, size); USBD_SET_PAYLOAD_LEN(hw_ep_num, size); return size; } static rt_err_t _ep0_send_status(void) { /* Status stage */ USBD_SET_DATA1(EP0); USBD_SET_PAYLOAD_LEN(EP0, 0); return RT_EOK; } static rt_err_t _suspend(void) { return RT_EOK; } static rt_err_t _wakeup(void) { return RT_EOK; } __STATIC_INLINE void _USBD_IRQHandler(void) { rt_uint32_t u32IntSts = USBD_GET_INT_FLAG(); rt_uint32_t u32State = USBD_GET_BUS_STATE(); //------------------------------------------------------------------ if (u32IntSts & USBD_INTSTS_VBDETIF_Msk) { // Floating detect USBD_CLR_INT_FLAG(USBD_INTSTS_VBDETIF_Msk); if (USBD_IS_ATTACHED()) { /* USB Plug In */ USBD_ENABLE_USB(); rt_usbd_connect_handler(&_rt_obj_udc); } else { /* USB Unplug */ USBD_DISABLE_USB(); rt_usbd_disconnect_handler(&_rt_obj_udc); } } if (u32IntSts & USBD_INTSTS_SOFIF_Msk) { USBD_CLR_INT_FLAG(USBD_INTSTS_SOFIF_Msk); rt_usbd_sof_handler(&_rt_obj_udc); } //------------------------------------------------------------------ if (u32IntSts & USBD_INTSTS_BUSIF_Msk) { /* Clear event flag */ USBD_CLR_INT_FLAG(USBD_INTSTS_BUSIF_Msk); if (u32State & USBD_ATTR_USBRST_Msk) { USBD_ENABLE_USB(); /* Reset PID DATA0 */ for (rt_uint32_t i = 0ul; i < USBD_MAX_EP; i++) { nu_usbd.Instance->EP[i].CFG &= ~USBD_CFG_DSQSYNC_Msk; } /* Reset USB device address */ USBD_SET_ADDR(0ul); /* Bus reset */ rt_usbd_reset_handler(&_rt_obj_udc); } if (u32State & USBD_ATTR_SUSPEND_Msk) { /* Enable USB but disable PHY */ USBD_DISABLE_PHY(); } if (u32State & USBD_ATTR_RESUME_Msk) { /* Enable USB and enable PHY */ USBD_ENABLE_USB(); } } //------------------------------------------------------------------ if (u32IntSts & USBD_INTSTS_WAKEUP) { /* Clear event flag */ USBD_CLR_INT_FLAG(USBD_INTSTS_WAKEUP); USBD_ENABLE_USB(); } if (u32IntSts & USBD_INTSTS_USBIF_Msk) { // USB event if (u32IntSts & USBD_INTSTS_SETUP_Msk) { // Setup packet /* Clear event flag */ USBD_CLR_INT_FLAG(USBD_INTSTS_SETUP_Msk); /* Clear the data IN/OUT ready flag of control end-points */ USBD_STOP_TRANSACTION(EP0); USBD_STOP_TRANSACTION(EP1); USBD_SET_DATA1(EP0); rt_usbd_ep0_setup_handler(&_rt_obj_udc, (struct urequest *)USBD_BUF_BASE); } // EP events if (u32IntSts & USBD_INTSTS_EP0) { /* Clear event flag */ USBD_CLR_INT_FLAG(USBD_INTSTS_EP0); if ((USBD_GET_ADDR() == 0) && (nu_usbd.address_tmp) ) { USBD_SET_ADDR(nu_usbd.address_tmp); LOG_I("SET ADDR: 0x%02x", nu_usbd.address_tmp); nu_usbd.address_tmp = 0; } rt_usbd_ep0_in_handler(&_rt_obj_udc); } if (u32IntSts & USBD_INTSTS_EP1) { /* Clear event flag */ USBD_CLR_INT_FLAG(USBD_INTSTS_EP1); rt_usbd_ep0_out_handler(&_rt_obj_udc, 0); } if (u32IntSts & USBD_INTSTS_EP2) { /* Clear event flag */ USBD_CLR_INT_FLAG(USBD_INTSTS_EP2); rt_usbd_ep_in_handler(&_rt_obj_udc, USB_DIR_IN | EPADR_HW2SW(EP2), 0); } if (u32IntSts & USBD_INTSTS_EP3) { /* Clear event flag */ USBD_CLR_INT_FLAG(USBD_INTSTS_EP3); rt_usbd_ep_out_handler(&_rt_obj_udc, USB_DIR_OUT | EPADR_HW2SW(EP3), 0); } if (u32IntSts & USBD_INTSTS_EP4) { /* Clear event flag */ USBD_CLR_INT_FLAG(USBD_INTSTS_EP4); rt_usbd_ep_in_handler(&_rt_obj_udc, USB_DIR_IN | EPADR_HW2SW(EP4), 0); } if (u32IntSts & USBD_INTSTS_EP5) { /* Clear event flag */ USBD_CLR_INT_FLAG(USBD_INTSTS_EP5); rt_usbd_ep_out_handler(&_rt_obj_udc, USB_DIR_OUT | EPADR_HW2SW(EP5), 0); } if (u32IntSts & USBD_INTSTS_EP6) { /* Clear event flag */ USBD_CLR_INT_FLAG(USBD_INTSTS_EP6); rt_usbd_ep_in_handler(&_rt_obj_udc, USB_DIR_IN | EPADR_HW2SW(EP6), 0); } if (u32IntSts & USBD_INTSTS_EP7) { /* Clear event flag */ USBD_CLR_INT_FLAG(USBD_INTSTS_EP7); rt_usbd_ep_out_handler(&_rt_obj_udc, USB_DIR_OUT | EPADR_HW2SW(EP7), 0); } if (u32IntSts & USBD_INTSTS_EP8) { /* Clear event flag */ USBD_CLR_INT_FLAG(USBD_INTSTS_EP8); rt_usbd_ep_in_handler(&_rt_obj_udc, USB_DIR_IN | EPADR_HW2SW(EP8), 0); } if (u32IntSts & USBD_INTSTS_EP9) { /* Clear event flag */ USBD_CLR_INT_FLAG(USBD_INTSTS_EP9); rt_usbd_ep_out_handler(&_rt_obj_udc, USB_DIR_OUT | EPADR_HW2SW(EP9), 0); } if (u32IntSts & USBD_INTSTS_EP10) { /* Clear event flag */ USBD_CLR_INT_FLAG(USBD_INTSTS_EP10); rt_usbd_ep_in_handler(&_rt_obj_udc, USB_DIR_IN | EPADR_HW2SW(EP10), 0); } if (u32IntSts & USBD_INTSTS_EP11) { /* Clear event flag */ USBD_CLR_INT_FLAG(USBD_INTSTS_EP11); rt_usbd_ep_out_handler(&_rt_obj_udc, USB_DIR_OUT | EPADR_HW2SW(EP11), 0); } } } void USBD_IRQHandler(void) { rt_interrupt_enter(); _USBD_IRQHandler(); rt_interrupt_leave(); } static rt_err_t _init(rt_device_t device) { nu_usbd_t *nu_usbd = (nu_usbd_t *)device->user_data; #if !defined(BSP_USING_OTG) /* Initialize USB PHY */ SYS_UnlockReg(); /* Select USBD */ SYS->USBPHY = (SYS->USBPHY & ~SYS_USBPHY_USBROLE_Msk) | SYS_USBPHY_OTGPHYEN_Msk | SYS_USBPHY_SBO_Msk; SYS_ResetModule(USBD_RST); SYS_LockReg(); #endif _nu_ep_partition(); /* Initial USB engine */ nu_usbd->Instance->ATTR = 0x6D0ul; /* Force SE0 */ USBD_SET_SE0(); NVIC_EnableIRQ(USBD_IRQn); USBD_Start(); return RT_EOK; } const static struct udcd_ops _udc_ops = { _set_address, _set_config, _ep_set_stall, _ep_clear_stall, _ep_enable, _ep_disable, _ep_read_prepare, _ep_read, _ep_write, _ep0_send_status, _suspend, _wakeup, }; #ifdef RT_USING_DEVICE_OPS const static struct rt_device_ops _ops = { _init, RT_NULL, RT_NULL, RT_NULL, RT_NULL, RT_NULL, }; #endif int nu_usbd_register(void) { if (RT_NULL != rt_device_find("usbd")) { LOG_E("\nUSBD Register failed. Another USBD device registered\n"); return -RT_ERROR; } rt_memset((void *)&_rt_obj_udc, 0, sizeof(struct udcd)); _rt_obj_udc.parent.type = RT_Device_Class_USBDevice; #ifdef RT_USING_DEVICE_OPS _rt_obj_udc.parent.ops = &_ops; #else _rt_obj_udc.parent.init = _init; #endif _rt_obj_udc.parent.user_data = &nu_usbd; _rt_obj_udc.ops = &_udc_ops; /* Register endpoint information */ _rt_obj_udc.ep_pool = _ep_pool; _rt_obj_udc.ep0.id = &_ep_pool[0]; _rt_obj_udc.device_is_hs = RT_FALSE; /* Support Full-Speed only */ rt_device_register((rt_device_t)&_rt_obj_udc, "usbd", 0); rt_usb_device_init(); return RT_EOK; } INIT_DEVICE_EXPORT(nu_usbd_register); #endif