// SPDX-License-Identifier: GPL-2.0 /* * Renesas USBF USB Function driver * * Copyright 2022 Schneider Electric * Author: Herve Codina */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #define USBF_NUM_ENDPOINTS 16 #define USBF_EP0_MAX_PCKT_SIZE 64 /* EPC registers */ #define USBF_REG_USB_CONTROL 0x000 #define USBF_USB_PUE2 BIT(2) #define USBF_USB_CONNECTB BIT(3) #define USBF_USB_DEFAULT BIT(4) #define USBF_USB_CONF BIT(5) #define USBF_USB_SUSPEND BIT(6) #define USBF_USB_RSUM_IN BIT(7) #define USBF_USB_SOF_RCV BIT(8) #define USBF_USB_FORCEFS BIT(9) #define USBF_USB_INT_SEL BIT(10) #define USBF_USB_SOF_CLK_MODE BIT(11) #define USBF_REG_USB_STATUS 0x004 #define USBF_USB_RSUM_OUT BIT(1) #define USBF_USB_SPND_OUT BIT(2) #define USBF_USB_USB_RST BIT(3) #define USBF_USB_DEFAULT_ST BIT(4) #define USBF_USB_CONF_ST BIT(5) #define USBF_USB_SPEED_MODE BIT(6) #define USBF_USB_SOF_DELAY_STATUS BIT(31) #define USBF_REG_USB_ADDRESS 0x008 #define USBF_USB_SOF_STATUS BIT(15) #define USBF_USB_SET_USB_ADDR(_a) ((_a) << 16) #define USBF_USB_GET_FRAME(_r) ((_r) & 0x7FF) #define USBF_REG_SETUP_DATA0 0x018 #define USBF_REG_SETUP_DATA1 0x01C #define USBF_REG_USB_INT_STA 0x020 #define USBF_USB_RSUM_INT BIT(1) #define USBF_USB_SPND_INT BIT(2) #define USBF_USB_USB_RST_INT BIT(3) #define USBF_USB_SOF_INT BIT(4) #define USBF_USB_SOF_ERROR_INT BIT(5) #define USBF_USB_SPEED_MODE_INT BIT(6) #define USBF_USB_EPN_INT(_n) (BIT(8) << (_n)) /* n=0..15 */ #define USBF_REG_USB_INT_ENA 0x024 #define USBF_USB_RSUM_EN BIT(1) #define USBF_USB_SPND_EN BIT(2) #define USBF_USB_USB_RST_EN BIT(3) #define USBF_USB_SOF_EN BIT(4) #define USBF_USB_SOF_ERROR_EN BIT(5) #define USBF_USB_SPEED_MODE_EN BIT(6) #define USBF_USB_EPN_EN(_n) (BIT(8) << (_n)) /* n=0..15 */ #define USBF_BASE_EP0 0x028 /* EP0 registers offsets from Base + USBF_BASE_EP0 (EP0 regs area) */ #define USBF_REG_EP0_CONTROL 0x00 #define USBF_EP0_ONAK BIT(0) #define USBF_EP0_INAK BIT(1) #define USBF_EP0_STL BIT(2) #define USBF_EP0_PERR_NAK_CLR BIT(3) #define USBF_EP0_INAK_EN BIT(4) #define USBF_EP0_DW_MASK (0x3 << 5) #define USBF_EP0_DW(_s) ((_s) << 5) #define USBF_EP0_DEND BIT(7) #define USBF_EP0_BCLR BIT(8) #define USBF_EP0_PIDCLR BIT(9) #define USBF_EP0_AUTO BIT(16) #define USBF_EP0_OVERSEL BIT(17) #define USBF_EP0_STGSEL BIT(18) #define USBF_REG_EP0_STATUS 0x04 #define USBF_EP0_SETUP_INT BIT(0) #define USBF_EP0_STG_START_INT BIT(1) #define USBF_EP0_STG_END_INT BIT(2) #define USBF_EP0_STALL_INT BIT(3) #define USBF_EP0_IN_INT BIT(4) #define USBF_EP0_OUT_INT BIT(5) #define USBF_EP0_OUT_OR_INT BIT(6) #define USBF_EP0_OUT_NULL_INT BIT(7) #define USBF_EP0_IN_EMPTY BIT(8) #define USBF_EP0_IN_FULL BIT(9) #define USBF_EP0_IN_DATA BIT(10) #define USBF_EP0_IN_NAK_INT BIT(11) #define USBF_EP0_OUT_EMPTY BIT(12) #define USBF_EP0_OUT_FULL BIT(13) #define USBF_EP0_OUT_NULL BIT(14) #define USBF_EP0_OUT_NAK_INT BIT(15) #define USBF_EP0_PERR_NAK_INT BIT(16) #define USBF_EP0_PERR_NAK BIT(17) #define USBF_EP0_PID BIT(18) #define USBF_REG_EP0_INT_ENA 0x08 #define USBF_EP0_SETUP_EN BIT(0) #define USBF_EP0_STG_START_EN BIT(1) #define USBF_EP0_STG_END_EN BIT(2) #define USBF_EP0_STALL_EN BIT(3) #define USBF_EP0_IN_EN BIT(4) #define USBF_EP0_OUT_EN BIT(5) #define USBF_EP0_OUT_OR_EN BIT(6) #define USBF_EP0_OUT_NULL_EN BIT(7) #define USBF_EP0_IN_NAK_EN BIT(11) #define USBF_EP0_OUT_NAK_EN BIT(15) #define USBF_EP0_PERR_NAK_EN BIT(16) #define USBF_REG_EP0_LENGTH 0x0C #define USBF_EP0_LDATA (0x7FF << 0) #define USBF_REG_EP0_READ 0x10 #define USBF_REG_EP0_WRITE 0x14 #define USBF_BASE_EPN(_n) (0x040 + (_n) * 0x020) /* EPn registers offsets from Base + USBF_BASE_EPN(n-1). n=1..15 */ #define USBF_REG_EPN_CONTROL 0x000 #define USBF_EPN_ONAK BIT(0) #define USBF_EPN_OSTL BIT(2) #define USBF_EPN_ISTL BIT(3) #define USBF_EPN_OSTL_EN BIT(4) #define USBF_EPN_DW_MASK (0x3 << 5) #define USBF_EPN_DW(_s) ((_s) << 5) #define USBF_EPN_DEND BIT(7) #define USBF_EPN_CBCLR BIT(8) #define USBF_EPN_BCLR BIT(9) #define USBF_EPN_OPIDCLR BIT(10) #define USBF_EPN_IPIDCLR BIT(11) #define USBF_EPN_AUTO BIT(16) #define USBF_EPN_OVERSEL BIT(17) #define USBF_EPN_MODE_MASK (0x3 << 24) #define USBF_EPN_MODE_BULK (0x0 << 24) #define USBF_EPN_MODE_INTR (0x1 << 24) #define USBF_EPN_MODE_ISO (0x2 << 24) #define USBF_EPN_DIR0 BIT(26) #define USBF_EPN_BUF_TYPE_DOUBLE BIT(30) #define USBF_EPN_EN BIT(31) #define USBF_REG_EPN_STATUS 0x004 #define USBF_EPN_IN_EMPTY BIT(0) #define USBF_EPN_IN_FULL BIT(1) #define USBF_EPN_IN_DATA BIT(2) #define USBF_EPN_IN_INT BIT(3) #define USBF_EPN_IN_STALL_INT BIT(4) #define USBF_EPN_IN_NAK_ERR_INT BIT(5) #define USBF_EPN_IN_END_INT BIT(7) #define USBF_EPN_IPID BIT(10) #define USBF_EPN_OUT_EMPTY BIT(16) #define USBF_EPN_OUT_FULL BIT(17) #define USBF_EPN_OUT_NULL_INT BIT(18) #define USBF_EPN_OUT_INT BIT(19) #define USBF_EPN_OUT_STALL_INT BIT(20) #define USBF_EPN_OUT_NAK_ERR_INT BIT(21) #define USBF_EPN_OUT_OR_INT BIT(22) #define USBF_EPN_OUT_END_INT BIT(23) #define USBF_EPN_ISO_CRC BIT(24) #define USBF_EPN_ISO_OR BIT(26) #define USBF_EPN_OUT_NOTKN BIT(27) #define USBF_EPN_ISO_OPID BIT(28) #define USBF_EPN_ISO_PIDERR BIT(29) #define USBF_REG_EPN_INT_ENA 0x008 #define USBF_EPN_IN_EN BIT(3) #define USBF_EPN_IN_STALL_EN BIT(4) #define USBF_EPN_IN_NAK_ERR_EN BIT(5) #define USBF_EPN_IN_END_EN BIT(7) #define USBF_EPN_OUT_NULL_EN BIT(18) #define USBF_EPN_OUT_EN BIT(19) #define USBF_EPN_OUT_STALL_EN BIT(20) #define USBF_EPN_OUT_NAK_ERR_EN BIT(21) #define USBF_EPN_OUT_OR_EN BIT(22) #define USBF_EPN_OUT_END_EN BIT(23) #define USBF_REG_EPN_DMA_CTRL 0x00C #define USBF_EPN_DMAMODE0 BIT(0) #define USBF_EPN_DMA_EN BIT(4) #define USBF_EPN_STOP_SET BIT(8) #define USBF_EPN_BURST_SET BIT(9) #define USBF_EPN_DEND_SET BIT(10) #define USBF_EPN_STOP_MODE BIT(11) #define USBF_REG_EPN_PCKT_ADRS 0x010 #define USBF_EPN_MPKT(_l) ((_l) << 0) #define USBF_EPN_BASEAD(_a) ((_a) << 16) #define USBF_REG_EPN_LEN_DCNT 0x014 #define USBF_EPN_GET_LDATA(_r) ((_r) & 0x7FF) #define USBF_EPN_SET_DMACNT(_c) ((_c) << 16) #define USBF_EPN_GET_DMACNT(_r) (((_r) >> 16) & 0x1ff) #define USBF_REG_EPN_READ 0x018 #define USBF_REG_EPN_WRITE 0x01C /* AHB-EPC Bridge registers */ #define USBF_REG_AHBSCTR 0x1000 #define USBF_REG_AHBMCTR 0x1004 #define USBF_SYS_WBURST_TYPE BIT(2) #define USBF_SYS_ARBITER_CTR BIT(31) #define USBF_REG_AHBBINT 0x1008 #define USBF_SYS_ERR_MASTER (0x0F << 0) #define USBF_SYS_SBUS_ERRINT0 BIT(4) #define USBF_SYS_SBUS_ERRINT1 BIT(5) #define USBF_SYS_MBUS_ERRINT BIT(6) #define USBF_SYS_VBUS_INT BIT(13) #define USBF_SYS_DMA_ENDINT_EPN(_n) (BIT(16) << (_n)) /* _n=1..15 */ #define USBF_REG_AHBBINTEN 0x100C #define USBF_SYS_SBUS_ERRINT0EN BIT(4) #define USBF_SYS_SBUS_ERRINT1EN BIT(5) #define USBF_SYS_MBUS_ERRINTEN BIT(6) #define USBF_SYS_VBUS_INTEN BIT(13) #define USBF_SYS_DMA_ENDINTEN_EPN(_n) (BIT(16) << (_n)) /* _n=1..15 */ #define USBF_REG_EPCTR 0x1010 #define USBF_SYS_EPC_RST BIT(0) #define USBF_SYS_PLL_RST BIT(2) #define USBF_SYS_PLL_LOCK BIT(4) #define USBF_SYS_PLL_RESUME BIT(5) #define USBF_SYS_VBUS_LEVEL BIT(8) #define USBF_SYS_DIRPD BIT(12) #define USBF_REG_USBSSVER 0x1020 #define USBF_REG_USBSSCONF 0x1024 #define USBF_SYS_DMA_AVAILABLE(_n) (BIT(0) << (_n)) /* _n=0..15 */ #define USBF_SYS_EP_AVAILABLE(_n) (BIT(16) << (_n)) /* _n=0..15 */ #define USBF_BASE_DMA_EPN(_n) (0x1110 + (_n) * 0x010) /* EPn DMA registers offsets from Base USBF_BASE_DMA_EPN(n-1). n=1..15*/ #define USBF_REG_DMA_EPN_DCR1 0x00 #define USBF_SYS_EPN_REQEN BIT(0) #define USBF_SYS_EPN_DIR0 BIT(1) #define USBF_SYS_EPN_SET_DMACNT(_c) ((_c) << 16) #define USBF_SYS_EPN_GET_DMACNT(_r) (((_r) >> 16) & 0x0FF) #define USBF_REG_DMA_EPN_DCR2 0x04 #define USBF_SYS_EPN_MPKT(_s) ((_s) << 0) #define USBF_SYS_EPN_LMPKT(_l) ((_l) << 16) #define USBF_REG_DMA_EPN_TADR 0x08 /* USB request */ struct usbf_req { struct usb_request req; struct list_head queue; unsigned int is_zero_sent : 1; unsigned int is_mapped : 1; enum { USBF_XFER_START, USBF_XFER_WAIT_DMA, USBF_XFER_SEND_NULL, USBF_XFER_WAIT_END, USBF_XFER_WAIT_DMA_SHORT, USBF_XFER_WAIT_BRIDGE, } xfer_step; size_t dma_size; }; /* USB Endpoint */ struct usbf_ep { struct usb_ep ep; char name[32]; struct list_head queue; unsigned int is_processing : 1; unsigned int is_in : 1; struct usbf_udc *udc; void __iomem *regs; void __iomem *dma_regs; unsigned int id : 8; unsigned int disabled : 1; unsigned int is_wedged : 1; unsigned int delayed_status : 1; u32 status; void (*bridge_on_dma_end)(struct usbf_ep *ep); }; enum usbf_ep0state { EP0_IDLE, EP0_IN_DATA_PHASE, EP0_OUT_DATA_PHASE, EP0_OUT_STATUS_START_PHASE, EP0_OUT_STATUS_PHASE, EP0_OUT_STATUS_END_PHASE, EP0_IN_STATUS_START_PHASE, EP0_IN_STATUS_PHASE, EP0_IN_STATUS_END_PHASE, }; struct usbf_udc { struct usb_gadget gadget; struct usb_gadget_driver *driver; struct device *dev; void __iomem *regs; spinlock_t lock; bool is_remote_wakeup; bool is_usb_suspended; struct usbf_ep ep[USBF_NUM_ENDPOINTS]; /* for EP0 control messages */ enum usbf_ep0state ep0state; struct usbf_req setup_reply; u8 ep0_buf[USBF_EP0_MAX_PCKT_SIZE]; }; struct usbf_ep_info { const char *name; struct usb_ep_caps caps; u16 base_addr; unsigned int is_double : 1; u16 maxpacket_limit; }; #define USBF_SINGLE_BUFFER 0 #define USBF_DOUBLE_BUFFER 1 #define USBF_EP_INFO(_name, _caps, _base_addr, _is_double, _maxpacket_limit) \ { \ .name = _name, \ .caps = _caps, \ .base_addr = _base_addr, \ .is_double = _is_double, \ .maxpacket_limit = _maxpacket_limit, \ } /* This table is computed from the recommended values provided in the SOC * datasheet. The buffer type (single/double) and the endpoint type cannot * be changed. The mapping in internal RAM (base_addr and number of words) * for each endpoints depends on the max packet size and the buffer type. */ static const struct usbf_ep_info usbf_ep_info[USBF_NUM_ENDPOINTS] = { /* ep0: buf @0x0000 64 bytes, fixed 32 words */ [0] = USBF_EP_INFO("ep0-ctrl", USB_EP_CAPS(USB_EP_CAPS_TYPE_CONTROL, USB_EP_CAPS_DIR_ALL), 0x0000, USBF_SINGLE_BUFFER, USBF_EP0_MAX_PCKT_SIZE), /* ep1: buf @0x0020, 2 buffers 512 bytes -> (512 * 2 / 4) words */ [1] = USBF_EP_INFO("ep1-bulk", USB_EP_CAPS(USB_EP_CAPS_TYPE_BULK, USB_EP_CAPS_DIR_ALL), 0x0020, USBF_DOUBLE_BUFFER, 512), /* ep2: buf @0x0120, 2 buffers 512 bytes -> (512 * 2 / 4) words */ [2] = USBF_EP_INFO("ep2-bulk", USB_EP_CAPS(USB_EP_CAPS_TYPE_BULK, USB_EP_CAPS_DIR_ALL), 0x0120, USBF_DOUBLE_BUFFER, 512), /* ep3: buf @0x0220, 1 buffer 512 bytes -> (512 * 2 / 4) words */ [3] = USBF_EP_INFO("ep3-bulk", USB_EP_CAPS(USB_EP_CAPS_TYPE_BULK, USB_EP_CAPS_DIR_ALL), 0x0220, USBF_SINGLE_BUFFER, 512), /* ep4: buf @0x02A0, 1 buffer 512 bytes -> (512 * 1 / 4) words */ [4] = USBF_EP_INFO("ep4-bulk", USB_EP_CAPS(USB_EP_CAPS_TYPE_BULK, USB_EP_CAPS_DIR_ALL), 0x02A0, USBF_SINGLE_BUFFER, 512), /* ep5: buf @0x0320, 1 buffer 512 bytes -> (512 * 2 / 4) words */ [5] = USBF_EP_INFO("ep5-bulk", USB_EP_CAPS(USB_EP_CAPS_TYPE_BULK, USB_EP_CAPS_DIR_ALL), 0x0320, USBF_SINGLE_BUFFER, 512), /* ep6: buf @0x03A0, 1 buffer 1024 bytes -> (1024 * 1 / 4) words */ [6] = USBF_EP_INFO("ep6-int", USB_EP_CAPS(USB_EP_CAPS_TYPE_INT, USB_EP_CAPS_DIR_ALL), 0x03A0, USBF_SINGLE_BUFFER, 1024), /* ep7: buf @0x04A0, 1 buffer 1024 bytes -> (1024 * 1 / 4) words */ [7] = USBF_EP_INFO("ep7-int", USB_EP_CAPS(USB_EP_CAPS_TYPE_INT, USB_EP_CAPS_DIR_ALL), 0x04A0, USBF_SINGLE_BUFFER, 1024), /* ep8: buf @0x0520, 1 buffer 1024 bytes -> (1024 * 1 / 4) words */ [8] = USBF_EP_INFO("ep8-int", USB_EP_CAPS(USB_EP_CAPS_TYPE_INT, USB_EP_CAPS_DIR_ALL), 0x0520, USBF_SINGLE_BUFFER, 1024), /* ep9: buf @0x0620, 1 buffer 1024 bytes -> (1024 * 1 / 4) words */ [9] = USBF_EP_INFO("ep9-int", USB_EP_CAPS(USB_EP_CAPS_TYPE_INT, USB_EP_CAPS_DIR_ALL), 0x0620, USBF_SINGLE_BUFFER, 1024), /* ep10: buf @0x0720, 2 buffers 1024 bytes -> (1024 * 2 / 4) words */ [10] = USBF_EP_INFO("ep10-iso", USB_EP_CAPS(USB_EP_CAPS_TYPE_ISO, USB_EP_CAPS_DIR_ALL), 0x0720, USBF_DOUBLE_BUFFER, 1024), /* ep11: buf @0x0920, 2 buffers 1024 bytes -> (1024 * 2 / 4) words */ [11] = USBF_EP_INFO("ep11-iso", USB_EP_CAPS(USB_EP_CAPS_TYPE_ISO, USB_EP_CAPS_DIR_ALL), 0x0920, USBF_DOUBLE_BUFFER, 1024), /* ep12: buf @0x0B20, 2 buffers 1024 bytes -> (1024 * 2 / 4) words */ [12] = USBF_EP_INFO("ep12-iso", USB_EP_CAPS(USB_EP_CAPS_TYPE_ISO, USB_EP_CAPS_DIR_ALL), 0x0B20, USBF_DOUBLE_BUFFER, 1024), /* ep13: buf @0x0D20, 2 buffers 1024 bytes -> (1024 * 2 / 4) words */ [13] = USBF_EP_INFO("ep13-iso", USB_EP_CAPS(USB_EP_CAPS_TYPE_ISO, USB_EP_CAPS_DIR_ALL), 0x0D20, USBF_DOUBLE_BUFFER, 1024), /* ep14: buf @0x0F20, 2 buffers 1024 bytes -> (1024 * 2 / 4) words */ [14] = USBF_EP_INFO("ep14-iso", USB_EP_CAPS(USB_EP_CAPS_TYPE_ISO, USB_EP_CAPS_DIR_ALL), 0x0F20, USBF_DOUBLE_BUFFER, 1024), /* ep15: buf @0x1120, 2 buffers 1024 bytes -> (1024 * 2 / 4) words */ [15] = USBF_EP_INFO("ep15-iso", USB_EP_CAPS(USB_EP_CAPS_TYPE_ISO, USB_EP_CAPS_DIR_ALL), 0x1120, USBF_DOUBLE_BUFFER, 1024), }; static inline u32 usbf_reg_readl(struct usbf_udc *udc, uint offset) { return readl(udc->regs + offset); } static inline void usbf_reg_writel(struct usbf_udc *udc, uint offset, u32 val) { writel(val, udc->regs + offset); } static inline void usbf_reg_bitset(struct usbf_udc *udc, uint offset, u32 set) { u32 tmp; tmp = usbf_reg_readl(udc, offset); tmp |= set; usbf_reg_writel(udc, offset, tmp); } static inline void usbf_reg_bitclr(struct usbf_udc *udc, uint offset, u32 clr) { u32 tmp; tmp = usbf_reg_readl(udc, offset); tmp &= ~clr; usbf_reg_writel(udc, offset, tmp); } static inline void usbf_reg_clrset(struct usbf_udc *udc, uint offset, u32 clr, u32 set) { u32 tmp; tmp = usbf_reg_readl(udc, offset); tmp &= ~clr; tmp |= set; usbf_reg_writel(udc, offset, tmp); } static inline u32 usbf_ep_reg_readl(struct usbf_ep *ep, uint offset) { return readl(ep->regs + offset); } static inline void usbf_ep_reg_read_rep(struct usbf_ep *ep, uint offset, void *dst, uint count) { readsl(ep->regs + offset, dst, count); } static inline void usbf_ep_reg_writel(struct usbf_ep *ep, uint offset, u32 val) { writel(val, ep->regs + offset); } static inline void usbf_ep_reg_write_rep(struct usbf_ep *ep, uint offset, const void *src, uint count) { writesl(ep->regs + offset, src, count); } static inline void usbf_ep_reg_bitset(struct usbf_ep *ep, uint offset, u32 set) { u32 tmp; tmp = usbf_ep_reg_readl(ep, offset); tmp |= set; usbf_ep_reg_writel(ep, offset, tmp); } static inline void usbf_ep_reg_bitclr(struct usbf_ep *ep, uint offset, u32 clr) { u32 tmp; tmp = usbf_ep_reg_readl(ep, offset); tmp &= ~clr; usbf_ep_reg_writel(ep, offset, tmp); } static inline void usbf_ep_reg_clrset(struct usbf_ep *ep, uint offset, u32 clr, u32 set) { u32 tmp; tmp = usbf_ep_reg_readl(ep, offset); tmp &= ~clr; tmp |= set; usbf_ep_reg_writel(ep, offset, tmp); } static inline u32 usbf_ep_dma_reg_readl(struct usbf_ep *ep, uint offset) { return readl(ep->dma_regs + offset); } static inline void usbf_ep_dma_reg_writel(struct usbf_ep *ep, uint offset, u32 val) { writel(val, ep->dma_regs + offset); } static inline void usbf_ep_dma_reg_bitset(struct usbf_ep *ep, uint offset, u32 set) { u32 tmp; tmp = usbf_ep_dma_reg_readl(ep, offset); tmp |= set; usbf_ep_dma_reg_writel(ep, offset, tmp); } static inline void usbf_ep_dma_reg_bitclr(struct usbf_ep *ep, uint offset, u32 clr) { u32 tmp; tmp = usbf_ep_dma_reg_readl(ep, offset); tmp &= ~clr; usbf_ep_dma_reg_writel(ep, offset, tmp); } static void usbf_ep0_send_null(struct usbf_ep *ep0, bool is_data1) { u32 set; set = USBF_EP0_DEND; if (is_data1) set |= USBF_EP0_PIDCLR; usbf_ep_reg_bitset(ep0, USBF_REG_EP0_CONTROL, set); } static int usbf_ep0_pio_in(struct usbf_ep *ep0, struct usbf_req *req) { unsigned int left; unsigned int nb; const void *buf; u32 ctrl; u32 last; left = req->req.length - req->req.actual; if (left == 0) { if (!req->is_zero_sent) { if (req->req.length == 0) { dev_dbg(ep0->udc->dev, "ep0 send null\n"); usbf_ep0_send_null(ep0, false); req->is_zero_sent = 1; return -EINPROGRESS; } if ((req->req.actual % ep0->ep.maxpacket) == 0) { if (req->req.zero) { dev_dbg(ep0->udc->dev, "ep0 send null\n"); usbf_ep0_send_null(ep0, false); req->is_zero_sent = 1; return -EINPROGRESS; } } } return 0; } if (left > ep0->ep.maxpacket) left = ep0->ep.maxpacket; buf = req->req.buf; buf += req->req.actual; nb = left / sizeof(u32); if (nb) { usbf_ep_reg_write_rep(ep0, USBF_REG_EP0_WRITE, buf, nb); buf += (nb * sizeof(u32)); req->req.actual += (nb * sizeof(u32)); left -= (nb * sizeof(u32)); } ctrl = usbf_ep_reg_readl(ep0, USBF_REG_EP0_CONTROL); ctrl &= ~USBF_EP0_DW_MASK; if (left) { memcpy(&last, buf, left); usbf_ep_reg_writel(ep0, USBF_REG_EP0_WRITE, last); ctrl |= USBF_EP0_DW(left); req->req.actual += left; } usbf_ep_reg_writel(ep0, USBF_REG_EP0_CONTROL, ctrl | USBF_EP0_DEND); dev_dbg(ep0->udc->dev, "ep0 send %u/%u\n", req->req.actual, req->req.length); return -EINPROGRESS; } static int usbf_ep0_pio_out(struct usbf_ep *ep0, struct usbf_req *req) { int req_status = 0; unsigned int count; unsigned int recv; unsigned int left; unsigned int nb; void *buf; u32 last; if (ep0->status & USBF_EP0_OUT_INT) { recv = usbf_ep_reg_readl(ep0, USBF_REG_EP0_LENGTH) & USBF_EP0_LDATA; count = recv; buf = req->req.buf; buf += req->req.actual; left = req->req.length - req->req.actual; dev_dbg(ep0->udc->dev, "ep0 recv %u, left %u\n", count, left); if (left > ep0->ep.maxpacket) left = ep0->ep.maxpacket; if (count > left) { req_status = -EOVERFLOW; count = left; } if (count) { nb = count / sizeof(u32); if (nb) { usbf_ep_reg_read_rep(ep0, USBF_REG_EP0_READ, buf, nb); buf += (nb * sizeof(u32)); req->req.actual += (nb * sizeof(u32)); count -= (nb * sizeof(u32)); } if (count) { last = usbf_ep_reg_readl(ep0, USBF_REG_EP0_READ); memcpy(buf, &last, count); req->req.actual += count; } } dev_dbg(ep0->udc->dev, "ep0 recv %u/%u\n", req->req.actual, req->req.length); if (req_status) { dev_dbg(ep0->udc->dev, "ep0 req.status=%d\n", req_status); req->req.status = req_status; return 0; } if (recv < ep0->ep.maxpacket) { dev_dbg(ep0->udc->dev, "ep0 short packet\n"); /* This is a short packet -> It is the end */ req->req.status = 0; return 0; } /* The Data stage of a control transfer from an endpoint to the * host is complete when the endpoint does one of the following: * - Has transferred exactly the expected amount of data * - Transfers a packet with a payload size less than * wMaxPacketSize or transfers a zero-length packet */ if (req->req.actual == req->req.length) { req->req.status = 0; return 0; } } if (ep0->status & USBF_EP0_OUT_NULL_INT) { /* NULL packet received */ dev_dbg(ep0->udc->dev, "ep0 null packet\n"); if (req->req.actual != req->req.length) { req->req.status = req->req.short_not_ok ? -EREMOTEIO : 0; } else { req->req.status = 0; } return 0; } return -EINPROGRESS; } static void usbf_ep0_fifo_flush(struct usbf_ep *ep0) { u32 sts; int ret; usbf_ep_reg_bitset(ep0, USBF_REG_EP0_CONTROL, USBF_EP0_BCLR); ret = readl_poll_timeout_atomic(ep0->regs + USBF_REG_EP0_STATUS, sts, (sts & (USBF_EP0_IN_DATA | USBF_EP0_IN_EMPTY)) == USBF_EP0_IN_EMPTY, 0, 10000); if (ret) dev_err(ep0->udc->dev, "ep0 flush fifo timed out\n"); } static void usbf_epn_send_null(struct usbf_ep *epn) { usbf_ep_reg_bitset(epn, USBF_REG_EPN_CONTROL, USBF_EPN_DEND); } static void usbf_epn_send_residue(struct usbf_ep *epn, const void *buf, unsigned int size) { u32 tmp; memcpy(&tmp, buf, size); usbf_ep_reg_writel(epn, USBF_REG_EPN_WRITE, tmp); usbf_ep_reg_clrset(epn, USBF_REG_EPN_CONTROL, USBF_EPN_DW_MASK, USBF_EPN_DW(size) | USBF_EPN_DEND); } static int usbf_epn_pio_in(struct usbf_ep *epn, struct usbf_req *req) { unsigned int left; unsigned int nb; const void *buf; left = req->req.length - req->req.actual; if (left == 0) { if (!req->is_zero_sent) { if (req->req.length == 0) { dev_dbg(epn->udc->dev, "ep%u send_null\n", epn->id); usbf_epn_send_null(epn); req->is_zero_sent = 1; return -EINPROGRESS; } if ((req->req.actual % epn->ep.maxpacket) == 0) { if (req->req.zero) { dev_dbg(epn->udc->dev, "ep%u send_null\n", epn->id); usbf_epn_send_null(epn); req->is_zero_sent = 1; return -EINPROGRESS; } } } return 0; } if (left > epn->ep.maxpacket) left = epn->ep.maxpacket; buf = req->req.buf; buf += req->req.actual; nb = left / sizeof(u32); if (nb) { usbf_ep_reg_write_rep(epn, USBF_REG_EPN_WRITE, buf, nb); buf += (nb * sizeof(u32)); req->req.actual += (nb * sizeof(u32)); left -= (nb * sizeof(u32)); } if (left) { usbf_epn_send_residue(epn, buf, left); req->req.actual += left; } else { usbf_ep_reg_clrset(epn, USBF_REG_EPN_CONTROL, USBF_EPN_DW_MASK, USBF_EPN_DEND); } dev_dbg(epn->udc->dev, "ep%u send %u/%u\n", epn->id, req->req.actual, req->req.length); return -EINPROGRESS; } static void usbf_epn_enable_in_end_int(struct usbf_ep *epn) { usbf_ep_reg_bitset(epn, USBF_REG_EPN_INT_ENA, USBF_EPN_IN_END_EN); } static int usbf_epn_dma_in(struct usbf_ep *epn, struct usbf_req *req) { unsigned int left; u32 npkt; u32 lastpkt; int ret; if (!IS_ALIGNED((uintptr_t)req->req.buf, 4)) { dev_dbg(epn->udc->dev, "ep%u buf unaligned -> fallback pio\n", epn->id); return usbf_epn_pio_in(epn, req); } left = req->req.length - req->req.actual; switch (req->xfer_step) { default: case USBF_XFER_START: if (left == 0) { dev_dbg(epn->udc->dev, "ep%u send null\n", epn->id); usbf_epn_send_null(epn); req->xfer_step = USBF_XFER_WAIT_END; break; } if (left < 4) { dev_dbg(epn->udc->dev, "ep%u send residue %u\n", epn->id, left); usbf_epn_send_residue(epn, req->req.buf + req->req.actual, left); req->req.actual += left; req->xfer_step = USBF_XFER_WAIT_END; break; } ret = usb_gadget_map_request(&epn->udc->gadget, &req->req, 1); if (ret < 0) { dev_err(epn->udc->dev, "usb_gadget_map_request failed (%d)\n", ret); return ret; } req->is_mapped = 1; npkt = DIV_ROUND_UP(left, epn->ep.maxpacket); lastpkt = (left % epn->ep.maxpacket); if (lastpkt == 0) lastpkt = epn->ep.maxpacket; lastpkt &= ~0x3; /* DMA is done on 32bit units */ usbf_ep_dma_reg_writel(epn, USBF_REG_DMA_EPN_DCR2, USBF_SYS_EPN_MPKT(epn->ep.maxpacket) | USBF_SYS_EPN_LMPKT(lastpkt)); usbf_ep_dma_reg_writel(epn, USBF_REG_DMA_EPN_TADR, req->req.dma); usbf_ep_dma_reg_writel(epn, USBF_REG_DMA_EPN_DCR1, USBF_SYS_EPN_SET_DMACNT(npkt)); usbf_ep_dma_reg_bitset(epn, USBF_REG_DMA_EPN_DCR1, USBF_SYS_EPN_REQEN); usbf_ep_reg_writel(epn, USBF_REG_EPN_LEN_DCNT, USBF_EPN_SET_DMACNT(npkt)); usbf_ep_reg_bitset(epn, USBF_REG_EPN_CONTROL, USBF_EPN_AUTO); /* The end of DMA transfer at the USBF level needs to be handle * after the detection of the end of DMA transfer at the brige * level. * To force this sequence, EPN_IN_END_EN will be set by the * detection of the end of transfer at bridge level (ie. bridge * interrupt). */ usbf_ep_reg_bitclr(epn, USBF_REG_EPN_INT_ENA, USBF_EPN_IN_EN | USBF_EPN_IN_END_EN); epn->bridge_on_dma_end = usbf_epn_enable_in_end_int; /* Clear any pending IN_END interrupt */ usbf_ep_reg_writel(epn, USBF_REG_EPN_STATUS, ~(u32)USBF_EPN_IN_END_INT); usbf_ep_reg_writel(epn, USBF_REG_EPN_DMA_CTRL, USBF_EPN_BURST_SET | USBF_EPN_DMAMODE0); usbf_ep_reg_bitset(epn, USBF_REG_EPN_DMA_CTRL, USBF_EPN_DMA_EN); req->dma_size = (npkt - 1) * epn->ep.maxpacket + lastpkt; dev_dbg(epn->udc->dev, "ep%u dma xfer %zu\n", epn->id, req->dma_size); req->xfer_step = USBF_XFER_WAIT_DMA; break; case USBF_XFER_WAIT_DMA: if (!(epn->status & USBF_EPN_IN_END_INT)) { dev_dbg(epn->udc->dev, "ep%u dma not done\n", epn->id); break; } dev_dbg(epn->udc->dev, "ep%u dma done\n", epn->id); usb_gadget_unmap_request(&epn->udc->gadget, &req->req, 1); req->is_mapped = 0; usbf_ep_reg_bitclr(epn, USBF_REG_EPN_CONTROL, USBF_EPN_AUTO); usbf_ep_reg_clrset(epn, USBF_REG_EPN_INT_ENA, USBF_EPN_IN_END_EN, USBF_EPN_IN_EN); req->req.actual += req->dma_size; left = req->req.length - req->req.actual; if (left) { usbf_ep_reg_writel(epn, USBF_REG_EPN_STATUS, ~(u32)USBF_EPN_IN_INT); dev_dbg(epn->udc->dev, "ep%u send residue %u\n", epn->id, left); usbf_epn_send_residue(epn, req->req.buf + req->req.actual, left); req->req.actual += left; req->xfer_step = USBF_XFER_WAIT_END; break; } if (req->req.actual % epn->ep.maxpacket) { /* last packet was a short packet. Tell the hardware to * send it right now. */ dev_dbg(epn->udc->dev, "ep%u send short\n", epn->id); usbf_ep_reg_writel(epn, USBF_REG_EPN_STATUS, ~(u32)USBF_EPN_IN_INT); usbf_ep_reg_bitset(epn, USBF_REG_EPN_CONTROL, USBF_EPN_DEND); req->xfer_step = USBF_XFER_WAIT_END; break; } /* Last packet size was a maxpacket size * Send null packet if needed */ if (req->req.zero) { req->xfer_step = USBF_XFER_SEND_NULL; break; } /* No more action to do. Wait for the end of the USB transfer */ req->xfer_step = USBF_XFER_WAIT_END; break; case USBF_XFER_SEND_NULL: dev_dbg(epn->udc->dev, "ep%u send null\n", epn->id); usbf_epn_send_null(epn); req->xfer_step = USBF_XFER_WAIT_END; break; case USBF_XFER_WAIT_END: if (!(epn->status & USBF_EPN_IN_INT)) { dev_dbg(epn->udc->dev, "ep%u end not done\n", epn->id); break; } dev_dbg(epn->udc->dev, "ep%u send done %u/%u\n", epn->id, req->req.actual, req->req.length); req->xfer_step = USBF_XFER_START; return 0; } return -EINPROGRESS; } static void usbf_epn_recv_residue(struct usbf_ep *epn, void *buf, unsigned int size) { u32 last; last = usbf_ep_reg_readl(epn, USBF_REG_EPN_READ); memcpy(buf, &last, size); } static int usbf_epn_pio_out(struct usbf_ep *epn, struct usbf_req *req) { int req_status = 0; unsigned int count; unsigned int recv; unsigned int left; unsigned int nb; void *buf; if (epn->status & USBF_EPN_OUT_INT) { recv = USBF_EPN_GET_LDATA( usbf_ep_reg_readl(epn, USBF_REG_EPN_LEN_DCNT)); count = recv; buf = req->req.buf; buf += req->req.actual; left = req->req.length - req->req.actual; dev_dbg(epn->udc->dev, "ep%u recv %u, left %u, mpkt %u\n", epn->id, recv, left, epn->ep.maxpacket); if (left > epn->ep.maxpacket) left = epn->ep.maxpacket; if (count > left) { req_status = -EOVERFLOW; count = left; } if (count) { nb = count / sizeof(u32); if (nb) { usbf_ep_reg_read_rep(epn, USBF_REG_EPN_READ, buf, nb); buf += (nb * sizeof(u32)); req->req.actual += (nb * sizeof(u32)); count -= (nb * sizeof(u32)); } if (count) { usbf_epn_recv_residue(epn, buf, count); req->req.actual += count; } } dev_dbg(epn->udc->dev, "ep%u recv %u/%u\n", epn->id, req->req.actual, req->req.length); if (req_status) { dev_dbg(epn->udc->dev, "ep%u req.status=%d\n", epn->id, req_status); req->req.status = req_status; return 0; } if (recv < epn->ep.maxpacket) { dev_dbg(epn->udc->dev, "ep%u short packet\n", epn->id); /* This is a short packet -> It is the end */ req->req.status = 0; return 0; } /* Request full -> complete */ if (req->req.actual == req->req.length) { req->req.status = 0; return 0; } } if (epn->status & USBF_EPN_OUT_NULL_INT) { /* NULL packet received */ dev_dbg(epn->udc->dev, "ep%u null packet\n", epn->id); if (req->req.actual != req->req.length) { req->req.status = req->req.short_not_ok ? -EREMOTEIO : 0; } else { req->req.status = 0; } return 0; } return -EINPROGRESS; } static void usbf_epn_enable_out_end_int(struct usbf_ep *epn) { usbf_ep_reg_bitset(epn, USBF_REG_EPN_INT_ENA, USBF_EPN_OUT_END_EN); } static void usbf_epn_process_queue(struct usbf_ep *epn); static void usbf_epn_dma_out_send_dma(struct usbf_ep *epn, dma_addr_t addr, u32 npkt, bool is_short) { usbf_ep_dma_reg_writel(epn, USBF_REG_DMA_EPN_DCR2, USBF_SYS_EPN_MPKT(epn->ep.maxpacket)); usbf_ep_dma_reg_writel(epn, USBF_REG_DMA_EPN_TADR, addr); if (is_short) { usbf_ep_dma_reg_writel(epn, USBF_REG_DMA_EPN_DCR1, USBF_SYS_EPN_SET_DMACNT(1) | USBF_SYS_EPN_DIR0); usbf_ep_dma_reg_bitset(epn, USBF_REG_DMA_EPN_DCR1, USBF_SYS_EPN_REQEN); usbf_ep_reg_writel(epn, USBF_REG_EPN_LEN_DCNT, USBF_EPN_SET_DMACNT(0)); /* The end of DMA transfer at the USBF level needs to be handled * after the detection of the end of DMA transfer at the brige * level. * To force this sequence, enabling the OUT_END interrupt will * be donee by the detection of the end of transfer at bridge * level (ie. bridge interrupt). */ usbf_ep_reg_bitclr(epn, USBF_REG_EPN_INT_ENA, USBF_EPN_OUT_EN | USBF_EPN_OUT_NULL_EN | USBF_EPN_OUT_END_EN); epn->bridge_on_dma_end = usbf_epn_enable_out_end_int; /* Clear any pending OUT_END interrupt */ usbf_ep_reg_writel(epn, USBF_REG_EPN_STATUS, ~(u32)USBF_EPN_OUT_END_INT); usbf_ep_reg_writel(epn, USBF_REG_EPN_DMA_CTRL, USBF_EPN_STOP_MODE | USBF_EPN_STOP_SET | USBF_EPN_DMAMODE0); usbf_ep_reg_bitset(epn, USBF_REG_EPN_DMA_CTRL, USBF_EPN_DMA_EN); return; } usbf_ep_dma_reg_writel(epn, USBF_REG_DMA_EPN_DCR1, USBF_SYS_EPN_SET_DMACNT(npkt) | USBF_SYS_EPN_DIR0); usbf_ep_dma_reg_bitset(epn, USBF_REG_DMA_EPN_DCR1, USBF_SYS_EPN_REQEN); usbf_ep_reg_writel(epn, USBF_REG_EPN_LEN_DCNT, USBF_EPN_SET_DMACNT(npkt)); /* Here, the bridge may or may not generate an interrupt to signal the * end of DMA transfer. * Keep only OUT_END interrupt and let handle the bridge later during * the OUT_END processing. */ usbf_ep_reg_clrset(epn, USBF_REG_EPN_INT_ENA, USBF_EPN_OUT_EN | USBF_EPN_OUT_NULL_EN, USBF_EPN_OUT_END_EN); /* Disable bridge interrupt. It will be renabled later */ usbf_reg_bitclr(epn->udc, USBF_REG_AHBBINTEN, USBF_SYS_DMA_ENDINTEN_EPN(epn->id)); /* Clear any pending DMA_END interrupt at bridge level */ usbf_reg_writel(epn->udc, USBF_REG_AHBBINT, USBF_SYS_DMA_ENDINT_EPN(epn->id)); /* Clear any pending OUT_END interrupt */ usbf_ep_reg_writel(epn, USBF_REG_EPN_STATUS, ~(u32)USBF_EPN_OUT_END_INT); usbf_ep_reg_writel(epn, USBF_REG_EPN_DMA_CTRL, USBF_EPN_STOP_MODE | USBF_EPN_STOP_SET | USBF_EPN_DMAMODE0 | USBF_EPN_BURST_SET); usbf_ep_reg_bitset(epn, USBF_REG_EPN_DMA_CTRL, USBF_EPN_DMA_EN); } static size_t usbf_epn_dma_out_complete_dma(struct usbf_ep *epn, bool is_short) { u32 dmacnt; u32 tmp; int ret; /* Restore interrupt mask */ usbf_ep_reg_clrset(epn, USBF_REG_EPN_INT_ENA, USBF_EPN_OUT_END_EN, USBF_EPN_OUT_EN | USBF_EPN_OUT_NULL_EN); if (is_short) { /* Nothing more to do when the DMA was for a short packet */ return 0; } /* Enable the bridge interrupt */ usbf_reg_bitset(epn->udc, USBF_REG_AHBBINTEN, USBF_SYS_DMA_ENDINTEN_EPN(epn->id)); tmp = usbf_ep_reg_readl(epn, USBF_REG_EPN_LEN_DCNT); dmacnt = USBF_EPN_GET_DMACNT(tmp); if (dmacnt) { /* Some packet were not received (halted by a short or a null * packet. * The bridge never raises an interrupt in this case. * Wait for the end of transfer at bridge level */ ret = readl_poll_timeout_atomic( epn->dma_regs + USBF_REG_DMA_EPN_DCR1, tmp, (USBF_SYS_EPN_GET_DMACNT(tmp) == dmacnt), 0, 10000); if (ret) { dev_err(epn->udc->dev, "ep%u wait bridge timed out\n", epn->id); } usbf_ep_dma_reg_bitclr(epn, USBF_REG_DMA_EPN_DCR1, USBF_SYS_EPN_REQEN); /* The dmacnt value tells how many packet were not transferred * from the maximum number of packet we set for the DMA transfer. * Compute the left DMA size based on this value. */ return dmacnt * epn->ep.maxpacket; } return 0; } static int usbf_epn_dma_out(struct usbf_ep *epn, struct usbf_req *req) { unsigned int dma_left; unsigned int count; unsigned int recv; unsigned int left; u32 npkt; int ret; if (!IS_ALIGNED((uintptr_t)req->req.buf, 4)) { dev_dbg(epn->udc->dev, "ep%u buf unaligned -> fallback pio\n", epn->id); return usbf_epn_pio_out(epn, req); } switch (req->xfer_step) { default: case USBF_XFER_START: if (epn->status & USBF_EPN_OUT_NULL_INT) { dev_dbg(epn->udc->dev, "ep%u null packet\n", epn->id); if (req->req.actual != req->req.length) { req->req.status = req->req.short_not_ok ? -EREMOTEIO : 0; } else { req->req.status = 0; } return 0; } if (!(epn->status & USBF_EPN_OUT_INT)) { dev_dbg(epn->udc->dev, "ep%u OUT_INT not set -> spurious\n", epn->id); break; } recv = USBF_EPN_GET_LDATA( usbf_ep_reg_readl(epn, USBF_REG_EPN_LEN_DCNT)); if (!recv) { dev_dbg(epn->udc->dev, "ep%u recv = 0 -> spurious\n", epn->id); break; } left = req->req.length - req->req.actual; dev_dbg(epn->udc->dev, "ep%u recv %u, left %u, mpkt %u\n", epn->id, recv, left, epn->ep.maxpacket); if (recv > left) { dev_err(epn->udc->dev, "ep%u overflow (%u/%u)\n", epn->id, recv, left); req->req.status = -EOVERFLOW; return -EOVERFLOW; } if (recv < epn->ep.maxpacket) { /* Short packet received */ dev_dbg(epn->udc->dev, "ep%u short packet\n", epn->id); if (recv <= 3) { usbf_epn_recv_residue(epn, req->req.buf + req->req.actual, recv); req->req.actual += recv; dev_dbg(epn->udc->dev, "ep%u recv done %u/%u\n", epn->id, req->req.actual, req->req.length); req->xfer_step = USBF_XFER_START; return 0; } ret = usb_gadget_map_request(&epn->udc->gadget, &req->req, 0); if (ret < 0) { dev_err(epn->udc->dev, "map request failed (%d)\n", ret); return ret; } req->is_mapped = 1; usbf_epn_dma_out_send_dma(epn, req->req.dma + req->req.actual, 1, true); req->dma_size = recv & ~0x3; dev_dbg(epn->udc->dev, "ep%u dma short xfer %zu\n", epn->id, req->dma_size); req->xfer_step = USBF_XFER_WAIT_DMA_SHORT; break; } ret = usb_gadget_map_request(&epn->udc->gadget, &req->req, 0); if (ret < 0) { dev_err(epn->udc->dev, "map request failed (%d)\n", ret); return ret; } req->is_mapped = 1; /* Use the maximum DMA size according to the request buffer. * We will adjust the received size later at the end of the DMA * transfer with the left size computed from * usbf_epn_dma_out_complete_dma(). */ npkt = left / epn->ep.maxpacket; usbf_epn_dma_out_send_dma(epn, req->req.dma + req->req.actual, npkt, false); req->dma_size = npkt * epn->ep.maxpacket; dev_dbg(epn->udc->dev, "ep%u dma xfer %zu (%u)\n", epn->id, req->dma_size, npkt); req->xfer_step = USBF_XFER_WAIT_DMA; break; case USBF_XFER_WAIT_DMA_SHORT: if (!(epn->status & USBF_EPN_OUT_END_INT)) { dev_dbg(epn->udc->dev, "ep%u dma short not done\n", epn->id); break; } dev_dbg(epn->udc->dev, "ep%u dma short done\n", epn->id); usbf_epn_dma_out_complete_dma(epn, true); usb_gadget_unmap_request(&epn->udc->gadget, &req->req, 0); req->is_mapped = 0; req->req.actual += req->dma_size; recv = USBF_EPN_GET_LDATA( usbf_ep_reg_readl(epn, USBF_REG_EPN_LEN_DCNT)); count = recv & 0x3; if (count) { dev_dbg(epn->udc->dev, "ep%u recv residue %u\n", epn->id, count); usbf_epn_recv_residue(epn, req->req.buf + req->req.actual, count); req->req.actual += count; } dev_dbg(epn->udc->dev, "ep%u recv done %u/%u\n", epn->id, req->req.actual, req->req.length); req->xfer_step = USBF_XFER_START; return 0; case USBF_XFER_WAIT_DMA: if (!(epn->status & USBF_EPN_OUT_END_INT)) { dev_dbg(epn->udc->dev, "ep%u dma not done\n", epn->id); break; } dev_dbg(epn->udc->dev, "ep%u dma done\n", epn->id); dma_left = usbf_epn_dma_out_complete_dma(epn, false); if (dma_left) { /* Adjust the final DMA size with */ count = req->dma_size - dma_left; dev_dbg(epn->udc->dev, "ep%u dma xfer done %u\n", epn->id, count); req->req.actual += count; if (epn->status & USBF_EPN_OUT_NULL_INT) { /* DMA was stopped by a null packet reception */ dev_dbg(epn->udc->dev, "ep%u dma stopped by null pckt\n", epn->id); usb_gadget_unmap_request(&epn->udc->gadget, &req->req, 0); req->is_mapped = 0; usbf_ep_reg_writel(epn, USBF_REG_EPN_STATUS, ~(u32)USBF_EPN_OUT_NULL_INT); if (req->req.actual != req->req.length) { req->req.status = req->req.short_not_ok ? -EREMOTEIO : 0; } else { req->req.status = 0; } dev_dbg(epn->udc->dev, "ep%u recv done %u/%u\n", epn->id, req->req.actual, req->req.length); req->xfer_step = USBF_XFER_START; return 0; } recv = USBF_EPN_GET_LDATA( usbf_ep_reg_readl(epn, USBF_REG_EPN_LEN_DCNT)); left = req->req.length - req->req.actual; if (recv > left) { dev_err(epn->udc->dev, "ep%u overflow (%u/%u)\n", epn->id, recv, left); req->req.status = -EOVERFLOW; usb_gadget_unmap_request(&epn->udc->gadget, &req->req, 0); req->is_mapped = 0; req->xfer_step = USBF_XFER_START; return -EOVERFLOW; } if (recv > 3) { usbf_epn_dma_out_send_dma(epn, req->req.dma + req->req.actual, 1, true); req->dma_size = recv & ~0x3; dev_dbg(epn->udc->dev, "ep%u dma short xfer %zu\n", epn->id, req->dma_size); req->xfer_step = USBF_XFER_WAIT_DMA_SHORT; break; } usb_gadget_unmap_request(&epn->udc->gadget, &req->req, 0); req->is_mapped = 0; count = recv & 0x3; if (count) { dev_dbg(epn->udc->dev, "ep%u recv residue %u\n", epn->id, count); usbf_epn_recv_residue(epn, req->req.buf + req->req.actual, count); req->req.actual += count; } dev_dbg(epn->udc->dev, "ep%u recv done %u/%u\n", epn->id, req->req.actual, req->req.length); req->xfer_step = USBF_XFER_START; return 0; } /* Process queue at bridge interrupt only */ usbf_ep_reg_bitclr(epn, USBF_REG_EPN_INT_ENA, USBF_EPN_OUT_END_EN | USBF_EPN_OUT_EN | USBF_EPN_OUT_NULL_EN); epn->status = 0; epn->bridge_on_dma_end = usbf_epn_process_queue; req->xfer_step = USBF_XFER_WAIT_BRIDGE; break; case USBF_XFER_WAIT_BRIDGE: dev_dbg(epn->udc->dev, "ep%u bridge transfers done\n", epn->id); /* Restore interrupt mask */ usbf_ep_reg_clrset(epn, USBF_REG_EPN_INT_ENA, USBF_EPN_OUT_END_EN, USBF_EPN_OUT_EN | USBF_EPN_OUT_NULL_EN); usb_gadget_unmap_request(&epn->udc->gadget, &req->req, 0); req->is_mapped = 0; req->req.actual += req->dma_size; req->xfer_step = USBF_XFER_START; left = req->req.length - req->req.actual; if (!left) { /* No more data can be added to the buffer */ dev_dbg(epn->udc->dev, "ep%u recv done %u/%u\n", epn->id, req->req.actual, req->req.length); return 0; } dev_dbg(epn->udc->dev, "ep%u recv done %u/%u, wait more data\n", epn->id, req->req.actual, req->req.length); break; } return -EINPROGRESS; } static void usbf_epn_dma_stop(struct usbf_ep *epn) { usbf_ep_dma_reg_bitclr(epn, USBF_REG_DMA_EPN_DCR1, USBF_SYS_EPN_REQEN); /* In the datasheet: * If EP[m]_REQEN = 0b is set during DMA transfer, AHB-EPC stops DMA * after 1 packet transfer completed. * Therefore, wait sufficient time for ensuring DMA transfer * completion. The WAIT time depends on the system, especially AHB * bus activity * So arbitrary 10ms would be sufficient. */ mdelay(10); usbf_ep_reg_bitclr(epn, USBF_REG_EPN_DMA_CTRL, USBF_EPN_DMA_EN); } static void usbf_epn_dma_abort(struct usbf_ep *epn, struct usbf_req *req) { dev_dbg(epn->udc->dev, "ep%u %s dma abort\n", epn->id, epn->is_in ? "in" : "out"); epn->bridge_on_dma_end = NULL; usbf_epn_dma_stop(epn); usb_gadget_unmap_request(&epn->udc->gadget, &req->req, epn->is_in ? 1 : 0); req->is_mapped = 0; usbf_ep_reg_bitclr(epn, USBF_REG_EPN_CONTROL, USBF_EPN_AUTO); if (epn->is_in) { usbf_ep_reg_clrset(epn, USBF_REG_EPN_INT_ENA, USBF_EPN_IN_END_EN, USBF_EPN_IN_EN); } else { usbf_ep_reg_clrset(epn, USBF_REG_EPN_INT_ENA, USBF_EPN_OUT_END_EN, USBF_EPN_OUT_EN | USBF_EPN_OUT_NULL_EN); } /* As dma is stopped, be sure that no DMA interrupt are pending */ usbf_ep_reg_writel(epn, USBF_REG_EPN_STATUS, USBF_EPN_IN_END_INT | USBF_EPN_OUT_END_INT); usbf_reg_writel(epn->udc, USBF_REG_AHBBINT, USBF_SYS_DMA_ENDINT_EPN(epn->id)); /* Enable DMA interrupt the bridge level */ usbf_reg_bitset(epn->udc, USBF_REG_AHBBINTEN, USBF_SYS_DMA_ENDINTEN_EPN(epn->id)); /* Reset transfer step */ req->xfer_step = USBF_XFER_START; } static void usbf_epn_fifo_flush(struct usbf_ep *epn) { u32 ctrl; u32 sts; int ret; dev_dbg(epn->udc->dev, "ep%u %s fifo flush\n", epn->id, epn->is_in ? "in" : "out"); ctrl = usbf_ep_reg_readl(epn, USBF_REG_EPN_CONTROL); usbf_ep_reg_writel(epn, USBF_REG_EPN_CONTROL, ctrl | USBF_EPN_BCLR); if (ctrl & USBF_EPN_DIR0) return; ret = readl_poll_timeout_atomic(epn->regs + USBF_REG_EPN_STATUS, sts, (sts & (USBF_EPN_IN_DATA | USBF_EPN_IN_EMPTY)) == USBF_EPN_IN_EMPTY, 0, 10000); if (ret) dev_err(epn->udc->dev, "ep%u flush fifo timed out\n", epn->id); } static void usbf_ep_req_done(struct usbf_ep *ep, struct usbf_req *req, int status) { list_del_init(&req->queue); if (status) { req->req.status = status; } else { if (req->req.status == -EINPROGRESS) req->req.status = status; } dev_dbg(ep->udc->dev, "ep%u %s req done length %u/%u, status=%d\n", ep->id, ep->is_in ? "in" : "out", req->req.actual, req->req.length, req->req.status); if (req->is_mapped) usbf_epn_dma_abort(ep, req); spin_unlock(&ep->udc->lock); usb_gadget_giveback_request(&ep->ep, &req->req); spin_lock(&ep->udc->lock); } static void usbf_ep_nuke(struct usbf_ep *ep, int status) { struct usbf_req *req; dev_dbg(ep->udc->dev, "ep%u %s nuke status %d\n", ep->id, ep->is_in ? "in" : "out", status); while (!list_empty(&ep->queue)) { req = list_first_entry(&ep->queue, struct usbf_req, queue); usbf_ep_req_done(ep, req, status); } if (ep->id == 0) usbf_ep0_fifo_flush(ep); else usbf_epn_fifo_flush(ep); } static bool usbf_ep_is_stalled(struct usbf_ep *ep) { u32 ctrl; if (ep->id == 0) { ctrl = usbf_ep_reg_readl(ep, USBF_REG_EP0_CONTROL); return (ctrl & USBF_EP0_STL) ? true : false; } ctrl = usbf_ep_reg_readl(ep, USBF_REG_EPN_CONTROL); if (ep->is_in) return (ctrl & USBF_EPN_ISTL) ? true : false; return (ctrl & USBF_EPN_OSTL) ? true : false; } static int usbf_epn_start_queue(struct usbf_ep *epn) { struct usbf_req *req; int ret; if (usbf_ep_is_stalled(epn)) return 0; req = list_first_entry_or_null(&epn->queue, struct usbf_req, queue); if (epn->is_in) { if (req && !epn->is_processing) { ret = epn->dma_regs ? usbf_epn_dma_in(epn, req) : usbf_epn_pio_in(epn, req); if (ret != -EINPROGRESS) { dev_err(epn->udc->dev, "queued next request not in progress\n"); /* The request cannot be completed (ie * ret == 0) on the first call. * stall and nuke the endpoint */ return ret ? ret : -EIO; } } } else { if (req) { /* Clear ONAK to accept OUT tokens */ usbf_ep_reg_bitclr(epn, USBF_REG_EPN_CONTROL, USBF_EPN_ONAK); /* Enable interrupts */ usbf_ep_reg_bitset(epn, USBF_REG_EPN_INT_ENA, USBF_EPN_OUT_INT | USBF_EPN_OUT_NULL_INT); } else { /* Disable incoming data and interrupt. * They will be enable on next usb_eb_queue call */ usbf_ep_reg_bitset(epn, USBF_REG_EPN_CONTROL, USBF_EPN_ONAK); usbf_ep_reg_bitclr(epn, USBF_REG_EPN_INT_ENA, USBF_EPN_OUT_INT | USBF_EPN_OUT_NULL_INT); } } return 0; } static int usbf_ep_process_queue(struct usbf_ep *ep) { int (*usbf_ep_xfer)(struct usbf_ep *ep, struct usbf_req *req); struct usbf_req *req; int is_processing; int ret; if (ep->is_in) { usbf_ep_xfer = usbf_ep0_pio_in; if (ep->id) { usbf_ep_xfer = ep->dma_regs ? usbf_epn_dma_in : usbf_epn_pio_in; } } else { usbf_ep_xfer = usbf_ep0_pio_out; if (ep->id) { usbf_ep_xfer = ep->dma_regs ? usbf_epn_dma_out : usbf_epn_pio_out; } } req = list_first_entry_or_null(&ep->queue, struct usbf_req, queue); if (!req) { dev_err(ep->udc->dev, "no request available for ep%u %s process\n", ep->id, ep->is_in ? "in" : "out"); return -ENOENT; } do { /* Were going to read the FIFO for this current request. * NAK any other incoming data to avoid a race condition if no * more request are available. */ if (!ep->is_in && ep->id != 0) { usbf_ep_reg_bitset(ep, USBF_REG_EPN_CONTROL, USBF_EPN_ONAK); } ret = usbf_ep_xfer(ep, req); if (ret == -EINPROGRESS) { if (!ep->is_in && ep->id != 0) { /* The current request needs more data. * Allow incoming data */ usbf_ep_reg_bitclr(ep, USBF_REG_EPN_CONTROL, USBF_EPN_ONAK); } return ret; } is_processing = ep->is_processing; ep->is_processing = 1; usbf_ep_req_done(ep, req, ret); ep->is_processing = is_processing; if (ret) { /* An error was detected during the request transfer. * Any pending DMA transfers were aborted by the * usbf_ep_req_done() call. * It's time to flush the fifo */ if (ep->id == 0) usbf_ep0_fifo_flush(ep); else usbf_epn_fifo_flush(ep); } req = list_first_entry_or_null(&ep->queue, struct usbf_req, queue); if (ep->is_in) continue; if (ep->id != 0) { if (req) { /* An other request is available. * Allow incoming data */ usbf_ep_reg_bitclr(ep, USBF_REG_EPN_CONTROL, USBF_EPN_ONAK); } else { /* No request queued. Disable interrupts. * They will be enabled on usb_ep_queue */ usbf_ep_reg_bitclr(ep, USBF_REG_EPN_INT_ENA, USBF_EPN_OUT_INT | USBF_EPN_OUT_NULL_INT); } } /* Do not recall usbf_ep_xfer() */ return req ? -EINPROGRESS : 0; } while (req); return 0; } static void usbf_ep_stall(struct usbf_ep *ep, bool stall) { struct usbf_req *first; dev_dbg(ep->udc->dev, "ep%u %s %s\n", ep->id, ep->is_in ? "in" : "out", stall ? "stall" : "unstall"); if (ep->id == 0) { if (stall) usbf_ep_reg_bitset(ep, USBF_REG_EP0_CONTROL, USBF_EP0_STL); else usbf_ep_reg_bitclr(ep, USBF_REG_EP0_CONTROL, USBF_EP0_STL); return; } if (stall) { if (ep->is_in) usbf_ep_reg_bitset(ep, USBF_REG_EPN_CONTROL, USBF_EPN_ISTL); else usbf_ep_reg_bitset(ep, USBF_REG_EPN_CONTROL, USBF_EPN_OSTL | USBF_EPN_OSTL_EN); } else { first = list_first_entry_or_null(&ep->queue, struct usbf_req, queue); if (first && first->is_mapped) { /* This can appear if the host halts an endpoint using * SET_FEATURE and then un-halts the endpoint */ usbf_epn_dma_abort(ep, first); } usbf_epn_fifo_flush(ep); if (ep->is_in) { usbf_ep_reg_clrset(ep, USBF_REG_EPN_CONTROL, USBF_EPN_ISTL, USBF_EPN_IPIDCLR); } else { usbf_ep_reg_clrset(ep, USBF_REG_EPN_CONTROL, USBF_EPN_OSTL, USBF_EPN_OSTL_EN | USBF_EPN_OPIDCLR); } usbf_epn_start_queue(ep); } } static void usbf_ep0_enable(struct usbf_ep *ep0) { usbf_ep_reg_writel(ep0, USBF_REG_EP0_CONTROL, USBF_EP0_INAK_EN | USBF_EP0_BCLR); usbf_ep_reg_writel(ep0, USBF_REG_EP0_INT_ENA, USBF_EP0_SETUP_EN | USBF_EP0_STG_START_EN | USBF_EP0_STG_END_EN | USBF_EP0_OUT_EN | USBF_EP0_OUT_NULL_EN | USBF_EP0_IN_EN); ep0->udc->ep0state = EP0_IDLE; ep0->disabled = 0; /* enable interrupts for the ep0 */ usbf_reg_bitset(ep0->udc, USBF_REG_USB_INT_ENA, USBF_USB_EPN_EN(0)); } static int usbf_epn_enable(struct usbf_ep *epn) { u32 base_addr; u32 ctrl; base_addr = usbf_ep_info[epn->id].base_addr; usbf_ep_reg_writel(epn, USBF_REG_EPN_PCKT_ADRS, USBF_EPN_BASEAD(base_addr) | USBF_EPN_MPKT(epn->ep.maxpacket)); /* OUT transfer interrupt are enabled during usb_ep_queue */ if (epn->is_in) { /* Will be changed in DMA processing */ usbf_ep_reg_writel(epn, USBF_REG_EPN_INT_ENA, USBF_EPN_IN_EN); } /* Clear, set endpoint direction, set IN/OUT STL, and enable * Send NAK for Data out as request are not queued yet */ ctrl = USBF_EPN_EN | USBF_EPN_BCLR; if (epn->is_in) ctrl |= USBF_EPN_OSTL | USBF_EPN_OSTL_EN; else ctrl |= USBF_EPN_DIR0 | USBF_EPN_ISTL | USBF_EPN_OSTL_EN | USBF_EPN_ONAK; usbf_ep_reg_writel(epn, USBF_REG_EPN_CONTROL, ctrl); return 0; } static int usbf_ep_enable(struct usb_ep *_ep, const struct usb_endpoint_descriptor *desc) { struct usbf_ep *ep = container_of(_ep, struct usbf_ep, ep); struct usbf_udc *udc = ep->udc; unsigned long flags; int ret; if (ep->id == 0) return -EINVAL; if (!desc || desc->bDescriptorType != USB_DT_ENDPOINT) return -EINVAL; dev_dbg(ep->udc->dev, "ep%u %s mpkts %d\n", ep->id, usb_endpoint_dir_in(desc) ? "in" : "out", usb_endpoint_maxp(desc)); spin_lock_irqsave(&ep->udc->lock, flags); ep->is_in = usb_endpoint_dir_in(desc); ep->ep.maxpacket = usb_endpoint_maxp(desc); ret = usbf_epn_enable(ep); if (ret) goto end; ep->disabled = 0; /* enable interrupts for this endpoint */ usbf_reg_bitset(udc, USBF_REG_USB_INT_ENA, USBF_USB_EPN_EN(ep->id)); /* enable DMA interrupt at bridge level if DMA is used */ if (ep->dma_regs) { ep->bridge_on_dma_end = NULL; usbf_reg_bitset(udc, USBF_REG_AHBBINTEN, USBF_SYS_DMA_ENDINTEN_EPN(ep->id)); } ret = 0; end: spin_unlock_irqrestore(&ep->udc->lock, flags); return ret; } static int usbf_epn_disable(struct usbf_ep *epn) { /* Disable interrupts */ usbf_ep_reg_writel(epn, USBF_REG_EPN_INT_ENA, 0); /* Disable endpoint */ usbf_ep_reg_bitclr(epn, USBF_REG_EPN_CONTROL, USBF_EPN_EN); /* remove anything that was pending */ usbf_ep_nuke(epn, -ESHUTDOWN); return 0; } static int usbf_ep_disable(struct usb_ep *_ep) { struct usbf_ep *ep = container_of(_ep, struct usbf_ep, ep); struct usbf_udc *udc = ep->udc; unsigned long flags; int ret; if (ep->id == 0) return -EINVAL; dev_dbg(ep->udc->dev, "ep%u %s mpkts %d\n", ep->id, ep->is_in ? "in" : "out", ep->ep.maxpacket); spin_lock_irqsave(&ep->udc->lock, flags); ep->disabled = 1; /* Disable DMA interrupt */ if (ep->dma_regs) { usbf_reg_bitclr(udc, USBF_REG_AHBBINTEN, USBF_SYS_DMA_ENDINTEN_EPN(ep->id)); ep->bridge_on_dma_end = NULL; } /* disable interrupts for this endpoint */ usbf_reg_bitclr(udc, USBF_REG_USB_INT_ENA, USBF_USB_EPN_EN(ep->id)); /* and the endpoint itself */ ret = usbf_epn_disable(ep); spin_unlock_irqrestore(&ep->udc->lock, flags); return ret; } static int usbf_ep0_queue(struct usbf_ep *ep0, struct usbf_req *req, gfp_t gfp_flags) { int ret; req->req.actual = 0; req->req.status = -EINPROGRESS; req->is_zero_sent = 0; list_add_tail(&req->queue, &ep0->queue); if (ep0->udc->ep0state == EP0_IN_STATUS_START_PHASE) return 0; if (!ep0->is_in) return 0; if (ep0->udc->ep0state == EP0_IN_STATUS_PHASE) { if (req->req.length) { dev_err(ep0->udc->dev, "request lng %u for ep0 in status phase\n", req->req.length); return -EINVAL; } ep0->delayed_status = 0; } if (!ep0->is_processing) { ret = usbf_ep0_pio_in(ep0, req); if (ret != -EINPROGRESS) { dev_err(ep0->udc->dev, "queued request not in progress\n"); /* The request cannot be completed (ie * ret == 0) on the first call */ return ret ? ret : -EIO; } } return 0; } static int usbf_epn_queue(struct usbf_ep *ep, struct usbf_req *req, gfp_t gfp_flags) { int was_empty; int ret; if (ep->disabled) { dev_err(ep->udc->dev, "ep%u request queue while disable\n", ep->id); return -ESHUTDOWN; } req->req.actual = 0; req->req.status = -EINPROGRESS; req->is_zero_sent = 0; req->xfer_step = USBF_XFER_START; was_empty = list_empty(&ep->queue); list_add_tail(&req->queue, &ep->queue); if (was_empty) { ret = usbf_epn_start_queue(ep); if (ret) return ret; } return 0; } static int usbf_ep_queue(struct usb_ep *_ep, struct usb_request *_req, gfp_t gfp_flags) { struct usbf_req *req = container_of(_req, struct usbf_req, req); struct usbf_ep *ep = container_of(_ep, struct usbf_ep, ep); struct usbf_udc *udc = ep->udc; unsigned long flags; int ret; if (!_req || !_req->buf) return -EINVAL; if (!udc || !udc->driver) return -EINVAL; dev_dbg(ep->udc->dev, "ep%u %s req queue length %u, zero %u, short_not_ok %u\n", ep->id, ep->is_in ? "in" : "out", req->req.length, req->req.zero, req->req.short_not_ok); spin_lock_irqsave(&ep->udc->lock, flags); if (ep->id == 0) ret = usbf_ep0_queue(ep, req, gfp_flags); else ret = usbf_epn_queue(ep, req, gfp_flags); spin_unlock_irqrestore(&ep->udc->lock, flags); return ret; } static int usbf_ep_dequeue(struct usb_ep *_ep, struct usb_request *_req) { struct usbf_req *req = container_of(_req, struct usbf_req, req); struct usbf_ep *ep = container_of(_ep, struct usbf_ep, ep); unsigned long flags; int is_processing; int first; int ret; spin_lock_irqsave(&ep->udc->lock, flags); dev_dbg(ep->udc->dev, "ep%u %s req dequeue length %u/%u\n", ep->id, ep->is_in ? "in" : "out", req->req.actual, req->req.length); first = list_is_first(&req->queue, &ep->queue); /* Complete the request but avoid any operation that could be done * if a new request is queued during the request completion */ is_processing = ep->is_processing; ep->is_processing = 1; usbf_ep_req_done(ep, req, -ECONNRESET); ep->is_processing = is_processing; if (first) { /* The first item in the list was dequeued. * This item could already be submitted to the hardware. * So, flush the fifo */ if (ep->id) usbf_epn_fifo_flush(ep); else usbf_ep0_fifo_flush(ep); } if (ep->id == 0) { /* We dequeue a request on ep0. On this endpoint, we can have * 1 request related to the data stage and/or 1 request * related to the status stage. * We dequeue one of them and so the USB control transaction * is no more coherent. The simple way to be consistent after * dequeuing is to stall and nuke the endpoint and wait the * next SETUP packet. */ usbf_ep_stall(ep, true); usbf_ep_nuke(ep, -ECONNRESET); ep->udc->ep0state = EP0_IDLE; goto end; } if (!first) goto end; ret = usbf_epn_start_queue(ep); if (ret) { usbf_ep_stall(ep, true); usbf_ep_nuke(ep, -EIO); } end: spin_unlock_irqrestore(&ep->udc->lock, flags); return 0; } static struct usb_request *usbf_ep_alloc_request(struct usb_ep *_ep, gfp_t gfp_flags) { struct usbf_req *req; if (!_ep) return NULL; req = kzalloc(sizeof(*req), gfp_flags); if (!req) return NULL; INIT_LIST_HEAD(&req->queue); return &req->req; } static void usbf_ep_free_request(struct usb_ep *_ep, struct usb_request *_req) { struct usbf_req *req; unsigned long flags; struct usbf_ep *ep; if (!_ep || !_req) return; req = container_of(_req, struct usbf_req, req); ep = container_of(_ep, struct usbf_ep, ep); spin_lock_irqsave(&ep->udc->lock, flags); list_del_init(&req->queue); spin_unlock_irqrestore(&ep->udc->lock, flags); kfree(req); } static int usbf_ep_set_halt(struct usb_ep *_ep, int halt) { struct usbf_ep *ep = container_of(_ep, struct usbf_ep, ep); unsigned long flags; int ret; if (ep->id == 0) return -EINVAL; spin_lock_irqsave(&ep->udc->lock, flags); if (!list_empty(&ep->queue)) { ret = -EAGAIN; goto end; } usbf_ep_stall(ep, halt); if (!halt) ep->is_wedged = 0; ret = 0; end: spin_unlock_irqrestore(&ep->udc->lock, flags); return ret; } static int usbf_ep_set_wedge(struct usb_ep *_ep) { struct usbf_ep *ep = container_of(_ep, struct usbf_ep, ep); unsigned long flags; int ret; if (ep->id == 0) return -EINVAL; spin_lock_irqsave(&ep->udc->lock, flags); if (!list_empty(&ep->queue)) { ret = -EAGAIN; goto end; } usbf_ep_stall(ep, 1); ep->is_wedged = 1; ret = 0; end: spin_unlock_irqrestore(&ep->udc->lock, flags); return ret; } static struct usb_ep_ops usbf_ep_ops = { .enable = usbf_ep_enable, .disable = usbf_ep_disable, .queue = usbf_ep_queue, .dequeue = usbf_ep_dequeue, .set_halt = usbf_ep_set_halt, .set_wedge = usbf_ep_set_wedge, .alloc_request = usbf_ep_alloc_request, .free_request = usbf_ep_free_request, }; static void usbf_ep0_req_complete(struct usb_ep *_ep, struct usb_request *_req) { } static void usbf_ep0_fill_req(struct usbf_ep *ep0, struct usbf_req *req, void *buf, unsigned int length, void (*complete)(struct usb_ep *_ep, struct usb_request *_req)) { if (buf && length) memcpy(ep0->udc->ep0_buf, buf, length); req->req.buf = ep0->udc->ep0_buf; req->req.length = length; req->req.dma = 0; req->req.zero = true; req->req.complete = complete ? complete : usbf_ep0_req_complete; req->req.status = -EINPROGRESS; req->req.context = NULL; req->req.actual = 0; } static struct usbf_ep *usbf_get_ep_by_addr(struct usbf_udc *udc, u8 address) { struct usbf_ep *ep; unsigned int i; if ((address & USB_ENDPOINT_NUMBER_MASK) == 0) return &udc->ep[0]; for (i = 1; i < ARRAY_SIZE(udc->ep); i++) { ep = &udc->ep[i]; if (!ep->ep.desc) continue; if (ep->ep.desc->bEndpointAddress == address) return ep; } return NULL; } static int usbf_req_delegate(struct usbf_udc *udc, const struct usb_ctrlrequest *ctrlrequest) { int ret; spin_unlock(&udc->lock); ret = udc->driver->setup(&udc->gadget, ctrlrequest); spin_lock(&udc->lock); if (ret < 0) { dev_dbg(udc->dev, "udc driver setup failed %d\n", ret); return ret; } if (ret == USB_GADGET_DELAYED_STATUS) { dev_dbg(udc->dev, "delayed status set\n"); udc->ep[0].delayed_status = 1; return 0; } return ret; } static int usbf_req_get_status(struct usbf_udc *udc, const struct usb_ctrlrequest *ctrlrequest) { struct usbf_ep *ep; u16 status_data; u16 wLength; u16 wValue; u16 wIndex; wValue = le16_to_cpu(ctrlrequest->wValue); wLength = le16_to_cpu(ctrlrequest->wLength); wIndex = le16_to_cpu(ctrlrequest->wIndex); switch (ctrlrequest->bRequestType) { case USB_DIR_IN | USB_RECIP_DEVICE | USB_TYPE_STANDARD: if ((wValue != 0) || (wIndex != 0) || (wLength != 2)) goto delegate; status_data = 0; if (udc->gadget.is_selfpowered) status_data |= BIT(USB_DEVICE_SELF_POWERED); if (udc->is_remote_wakeup) status_data |= BIT(USB_DEVICE_REMOTE_WAKEUP); break; case USB_DIR_IN | USB_RECIP_ENDPOINT | USB_TYPE_STANDARD: if ((wValue != 0) || (wLength != 2)) goto delegate; ep = usbf_get_ep_by_addr(udc, wIndex); if (!ep) return -EINVAL; status_data = 0; if (usbf_ep_is_stalled(ep)) status_data |= cpu_to_le16(1); break; case USB_DIR_IN | USB_RECIP_INTERFACE | USB_TYPE_STANDARD: if ((wValue != 0) || (wLength != 2)) goto delegate; status_data = 0; break; default: goto delegate; } usbf_ep0_fill_req(&udc->ep[0], &udc->setup_reply, &status_data, sizeof(status_data), NULL); usbf_ep0_queue(&udc->ep[0], &udc->setup_reply, GFP_ATOMIC); return 0; delegate: return usbf_req_delegate(udc, ctrlrequest); } static int usbf_req_clear_set_feature(struct usbf_udc *udc, const struct usb_ctrlrequest *ctrlrequest, bool is_set) { struct usbf_ep *ep; u16 wLength; u16 wValue; u16 wIndex; wValue = le16_to_cpu(ctrlrequest->wValue); wLength = le16_to_cpu(ctrlrequest->wLength); wIndex = le16_to_cpu(ctrlrequest->wIndex); switch (ctrlrequest->bRequestType) { case USB_DIR_OUT | USB_RECIP_DEVICE: if ((wIndex != 0) || (wLength != 0)) goto delegate; if (wValue != cpu_to_le16(USB_DEVICE_REMOTE_WAKEUP)) goto delegate; udc->is_remote_wakeup = is_set; break; case USB_DIR_OUT | USB_RECIP_ENDPOINT: if (wLength != 0) goto delegate; ep = usbf_get_ep_by_addr(udc, wIndex); if (!ep) return -EINVAL; if ((ep->id == 0) && is_set) { /* Endpoint 0 cannot be halted (stalled) * Returning an error code leads to a STALL on this ep0 * but keep the automate in a consistent state. */ return -EINVAL; } if (ep->is_wedged && !is_set) { /* Ignore CLEAR_FEATURE(HALT ENDPOINT) when the * endpoint is wedged */ break; } usbf_ep_stall(ep, is_set); break; default: goto delegate; } return 0; delegate: return usbf_req_delegate(udc, ctrlrequest); } static void usbf_ep0_req_set_address_complete(struct usb_ep *_ep, struct usb_request *_req) { struct usbf_ep *ep = container_of(_ep, struct usbf_ep, ep); /* The status phase of the SET_ADDRESS request is completed ... */ if (_req->status == 0) { /* ... without any errors -> Signaled the state to the core. */ usb_gadget_set_state(&ep->udc->gadget, USB_STATE_ADDRESS); } /* In case of request failure, there is no need to revert the address * value set to the hardware as the hardware will take care of the * value only if the status stage is completed normally. */ } static int usbf_req_set_address(struct usbf_udc *udc, const struct usb_ctrlrequest *ctrlrequest) { u16 wLength; u16 wValue; u16 wIndex; u32 addr; wValue = le16_to_cpu(ctrlrequest->wValue); wLength = le16_to_cpu(ctrlrequest->wLength); wIndex = le16_to_cpu(ctrlrequest->wIndex); if (ctrlrequest->bRequestType != (USB_DIR_OUT | USB_RECIP_DEVICE)) goto delegate; if ((wIndex != 0) || (wLength != 0) || (wValue > 127)) return -EINVAL; addr = wValue; /* The hardware will take care of this USB address after the status * stage of the SET_ADDRESS request is completed normally. * It is safe to write it now */ usbf_reg_writel(udc, USBF_REG_USB_ADDRESS, USBF_USB_SET_USB_ADDR(addr)); /* Queued the status request */ usbf_ep0_fill_req(&udc->ep[0], &udc->setup_reply, NULL, 0, usbf_ep0_req_set_address_complete); usbf_ep0_queue(&udc->ep[0], &udc->setup_reply, GFP_ATOMIC); return 0; delegate: return usbf_req_delegate(udc, ctrlrequest); } static int usbf_req_set_configuration(struct usbf_udc *udc, const struct usb_ctrlrequest *ctrlrequest) { u16 wLength; u16 wValue; u16 wIndex; int ret; ret = usbf_req_delegate(udc, ctrlrequest); if (ret) return ret; wValue = le16_to_cpu(ctrlrequest->wValue); wLength = le16_to_cpu(ctrlrequest->wLength); wIndex = le16_to_cpu(ctrlrequest->wIndex); if ((ctrlrequest->bRequestType != (USB_DIR_OUT | USB_RECIP_DEVICE)) || (wIndex != 0) || (wLength != 0)) { /* No error detected by driver->setup() but it is not an USB2.0 * Ch9 SET_CONFIGURATION. * Nothing more to do */ return 0; } if (wValue & 0x00FF) { usbf_reg_bitset(udc, USBF_REG_USB_CONTROL, USBF_USB_CONF); } else { usbf_reg_bitclr(udc, USBF_REG_USB_CONTROL, USBF_USB_CONF); /* Go back to Address State */ spin_unlock(&udc->lock); usb_gadget_set_state(&udc->gadget, USB_STATE_ADDRESS); spin_lock(&udc->lock); } return 0; } static int usbf_handle_ep0_setup(struct usbf_ep *ep0) { union { struct usb_ctrlrequest ctrlreq; u32 raw[2]; } crq; struct usbf_udc *udc = ep0->udc; int ret; /* Read setup data (ie the USB control request) */ crq.raw[0] = usbf_reg_readl(udc, USBF_REG_SETUP_DATA0); crq.raw[1] = usbf_reg_readl(udc, USBF_REG_SETUP_DATA1); dev_dbg(ep0->udc->dev, "ep0 req%02x.%02x, wValue 0x%04x, wIndex 0x%04x, wLength 0x%04x\n", crq.ctrlreq.bRequestType, crq.ctrlreq.bRequest, crq.ctrlreq.wValue, crq.ctrlreq.wIndex, crq.ctrlreq.wLength); /* Set current EP0 state according to the received request */ if (crq.ctrlreq.wLength) { if (crq.ctrlreq.bRequestType & USB_DIR_IN) { udc->ep0state = EP0_IN_DATA_PHASE; usbf_ep_reg_clrset(ep0, USBF_REG_EP0_CONTROL, USBF_EP0_INAK, USBF_EP0_INAK_EN); ep0->is_in = 1; } else { udc->ep0state = EP0_OUT_DATA_PHASE; usbf_ep_reg_bitclr(ep0, USBF_REG_EP0_CONTROL, USBF_EP0_ONAK); ep0->is_in = 0; } } else { udc->ep0state = EP0_IN_STATUS_START_PHASE; ep0->is_in = 1; } /* We starts a new control transfer -> Clear the delayed status flag */ ep0->delayed_status = 0; if ((crq.ctrlreq.bRequestType & USB_TYPE_MASK) != USB_TYPE_STANDARD) { /* This is not a USB standard request -> delelate */ goto delegate; } switch (crq.ctrlreq.bRequest) { case USB_REQ_GET_STATUS: ret = usbf_req_get_status(udc, &crq.ctrlreq); break; case USB_REQ_CLEAR_FEATURE: ret = usbf_req_clear_set_feature(udc, &crq.ctrlreq, false); break; case USB_REQ_SET_FEATURE: ret = usbf_req_clear_set_feature(udc, &crq.ctrlreq, true); break; case USB_REQ_SET_ADDRESS: ret = usbf_req_set_address(udc, &crq.ctrlreq); break; case USB_REQ_SET_CONFIGURATION: ret = usbf_req_set_configuration(udc, &crq.ctrlreq); break; default: goto delegate; } return ret; delegate: return usbf_req_delegate(udc, &crq.ctrlreq); } static int usbf_handle_ep0_data_status(struct usbf_ep *ep0, const char *ep0state_name, enum usbf_ep0state next_ep0state) { struct usbf_udc *udc = ep0->udc; int ret; ret = usbf_ep_process_queue(ep0); switch (ret) { case -ENOENT: dev_err(udc->dev, "no request available for ep0 %s phase\n", ep0state_name); break; case -EINPROGRESS: /* More data needs to be processed */ ret = 0; break; case 0: /* All requests in the queue are processed */ udc->ep0state = next_ep0state; break; default: dev_err(udc->dev, "process queue failed for ep0 %s phase (%d)\n", ep0state_name, ret); break; } return ret; } static int usbf_handle_ep0_out_status_start(struct usbf_ep *ep0) { struct usbf_udc *udc = ep0->udc; struct usbf_req *req; usbf_ep_reg_clrset(ep0, USBF_REG_EP0_CONTROL, USBF_EP0_ONAK, USBF_EP0_PIDCLR); ep0->is_in = 0; req = list_first_entry_or_null(&ep0->queue, struct usbf_req, queue); if (!req) { usbf_ep0_fill_req(ep0, &udc->setup_reply, NULL, 0, NULL); usbf_ep0_queue(ep0, &udc->setup_reply, GFP_ATOMIC); } else { if (req->req.length) { dev_err(udc->dev, "queued request length %u for ep0 out status phase\n", req->req.length); } } udc->ep0state = EP0_OUT_STATUS_PHASE; return 0; } static int usbf_handle_ep0_in_status_start(struct usbf_ep *ep0) { struct usbf_udc *udc = ep0->udc; struct usbf_req *req; int ret; usbf_ep_reg_clrset(ep0, USBF_REG_EP0_CONTROL, USBF_EP0_INAK, USBF_EP0_INAK_EN | USBF_EP0_PIDCLR); ep0->is_in = 1; /* Queue request for status if needed */ req = list_first_entry_or_null(&ep0->queue, struct usbf_req, queue); if (!req) { if (ep0->delayed_status) { dev_dbg(ep0->udc->dev, "EP0_IN_STATUS_START_PHASE ep0->delayed_status set\n"); udc->ep0state = EP0_IN_STATUS_PHASE; return 0; } usbf_ep0_fill_req(ep0, &udc->setup_reply, NULL, 0, NULL); usbf_ep0_queue(ep0, &udc->setup_reply, GFP_ATOMIC); req = list_first_entry_or_null(&ep0->queue, struct usbf_req, queue); } else { if (req->req.length) { dev_err(udc->dev, "queued request length %u for ep0 in status phase\n", req->req.length); } } ret = usbf_ep0_pio_in(ep0, req); if (ret != -EINPROGRESS) { usbf_ep_req_done(ep0, req, ret); udc->ep0state = EP0_IN_STATUS_END_PHASE; return 0; } udc->ep0state = EP0_IN_STATUS_PHASE; return 0; } static void usbf_ep0_interrupt(struct usbf_ep *ep0) { struct usbf_udc *udc = ep0->udc; u32 sts, prev_sts; int prev_ep0state; int ret; ep0->status = usbf_ep_reg_readl(ep0, USBF_REG_EP0_STATUS); usbf_ep_reg_writel(ep0, USBF_REG_EP0_STATUS, ~ep0->status); dev_dbg(ep0->udc->dev, "ep0 status=0x%08x, enable=%08x\n, ctrl=0x%08x\n", ep0->status, usbf_ep_reg_readl(ep0, USBF_REG_EP0_INT_ENA), usbf_ep_reg_readl(ep0, USBF_REG_EP0_CONTROL)); sts = ep0->status & (USBF_EP0_SETUP_INT | USBF_EP0_IN_INT | USBF_EP0_OUT_INT | USBF_EP0_OUT_NULL_INT | USBF_EP0_STG_START_INT | USBF_EP0_STG_END_INT); ret = 0; do { dev_dbg(ep0->udc->dev, "udc->ep0state=%d\n", udc->ep0state); prev_sts = sts; prev_ep0state = udc->ep0state; switch (udc->ep0state) { case EP0_IDLE: if (!(sts & USBF_EP0_SETUP_INT)) break; sts &= ~USBF_EP0_SETUP_INT; dev_dbg(ep0->udc->dev, "ep0 handle setup\n"); ret = usbf_handle_ep0_setup(ep0); break; case EP0_IN_DATA_PHASE: if (!(sts & USBF_EP0_IN_INT)) break; sts &= ~USBF_EP0_IN_INT; dev_dbg(ep0->udc->dev, "ep0 handle in data phase\n"); ret = usbf_handle_ep0_data_status(ep0, "in data", EP0_OUT_STATUS_START_PHASE); break; case EP0_OUT_STATUS_START_PHASE: if (!(sts & USBF_EP0_STG_START_INT)) break; sts &= ~USBF_EP0_STG_START_INT; dev_dbg(ep0->udc->dev, "ep0 handle out status start phase\n"); ret = usbf_handle_ep0_out_status_start(ep0); break; case EP0_OUT_STATUS_PHASE: if (!(sts & (USBF_EP0_OUT_INT | USBF_EP0_OUT_NULL_INT))) break; sts &= ~(USBF_EP0_OUT_INT | USBF_EP0_OUT_NULL_INT); dev_dbg(ep0->udc->dev, "ep0 handle out status phase\n"); ret = usbf_handle_ep0_data_status(ep0, "out status", EP0_OUT_STATUS_END_PHASE); break; case EP0_OUT_STATUS_END_PHASE: if (!(sts & (USBF_EP0_STG_END_INT | USBF_EP0_SETUP_INT))) break; sts &= ~USBF_EP0_STG_END_INT; dev_dbg(ep0->udc->dev, "ep0 handle out status end phase\n"); udc->ep0state = EP0_IDLE; break; case EP0_OUT_DATA_PHASE: if (!(sts & (USBF_EP0_OUT_INT | USBF_EP0_OUT_NULL_INT))) break; sts &= ~(USBF_EP0_OUT_INT | USBF_EP0_OUT_NULL_INT); dev_dbg(ep0->udc->dev, "ep0 handle out data phase\n"); ret = usbf_handle_ep0_data_status(ep0, "out data", EP0_IN_STATUS_START_PHASE); break; case EP0_IN_STATUS_START_PHASE: if (!(sts & USBF_EP0_STG_START_INT)) break; sts &= ~USBF_EP0_STG_START_INT; dev_dbg(ep0->udc->dev, "ep0 handle in status start phase\n"); ret = usbf_handle_ep0_in_status_start(ep0); break; case EP0_IN_STATUS_PHASE: if (!(sts & USBF_EP0_IN_INT)) break; sts &= ~USBF_EP0_IN_INT; dev_dbg(ep0->udc->dev, "ep0 handle in status phase\n"); ret = usbf_handle_ep0_data_status(ep0, "in status", EP0_IN_STATUS_END_PHASE); break; case EP0_IN_STATUS_END_PHASE: if (!(sts & (USBF_EP0_STG_END_INT | USBF_EP0_SETUP_INT))) break; sts &= ~USBF_EP0_STG_END_INT; dev_dbg(ep0->udc->dev, "ep0 handle in status end\n"); udc->ep0state = EP0_IDLE; break; default: udc->ep0state = EP0_IDLE; break; } if (ret) { dev_dbg(ep0->udc->dev, "ep0 failed (%d)\n", ret); /* Failure -> stall. * This stall state will be automatically cleared when * the IP receives the next SETUP packet */ usbf_ep_stall(ep0, true); /* Remove anything that was pending */ usbf_ep_nuke(ep0, -EPROTO); udc->ep0state = EP0_IDLE; break; } } while ((prev_ep0state != udc->ep0state) || (prev_sts != sts)); dev_dbg(ep0->udc->dev, "ep0 done udc->ep0state=%d, status=0x%08x. next=0x%08x\n", udc->ep0state, sts, usbf_ep_reg_readl(ep0, USBF_REG_EP0_STATUS)); } static void usbf_epn_process_queue(struct usbf_ep *epn) { int ret; ret = usbf_ep_process_queue(epn); switch (ret) { case -ENOENT: dev_warn(epn->udc->dev, "ep%u %s, no request available\n", epn->id, epn->is_in ? "in" : "out"); break; case -EINPROGRESS: /* More data needs to be processed */ ret = 0; break; case 0: /* All requests in the queue are processed */ break; default: dev_err(epn->udc->dev, "ep%u %s, process queue failed (%d)\n", epn->id, epn->is_in ? "in" : "out", ret); break; } if (ret) { dev_dbg(epn->udc->dev, "ep%u %s failed (%d)\n", epn->id, epn->is_in ? "in" : "out", ret); usbf_ep_stall(epn, true); usbf_ep_nuke(epn, ret); } } static void usbf_epn_interrupt(struct usbf_ep *epn) { u32 sts; u32 ena; epn->status = usbf_ep_reg_readl(epn, USBF_REG_EPN_STATUS); ena = usbf_ep_reg_readl(epn, USBF_REG_EPN_INT_ENA); usbf_ep_reg_writel(epn, USBF_REG_EPN_STATUS, ~(epn->status & ena)); dev_dbg(epn->udc->dev, "ep%u %s status=0x%08x, enable=%08x\n, ctrl=0x%08x\n", epn->id, epn->is_in ? "in" : "out", epn->status, ena, usbf_ep_reg_readl(epn, USBF_REG_EPN_CONTROL)); if (epn->disabled) { dev_warn(epn->udc->dev, "ep%u %s, interrupt while disabled\n", epn->id, epn->is_in ? "in" : "out"); return; } sts = epn->status & ena; if (sts & (USBF_EPN_IN_END_INT | USBF_EPN_IN_INT)) { sts &= ~(USBF_EPN_IN_END_INT | USBF_EPN_IN_INT); dev_dbg(epn->udc->dev, "ep%u %s process queue (in interrupts)\n", epn->id, epn->is_in ? "in" : "out"); usbf_epn_process_queue(epn); } if (sts & (USBF_EPN_OUT_END_INT | USBF_EPN_OUT_INT | USBF_EPN_OUT_NULL_INT)) { sts &= ~(USBF_EPN_OUT_END_INT | USBF_EPN_OUT_INT | USBF_EPN_OUT_NULL_INT); dev_dbg(epn->udc->dev, "ep%u %s process queue (out interrupts)\n", epn->id, epn->is_in ? "in" : "out"); usbf_epn_process_queue(epn); } dev_dbg(epn->udc->dev, "ep%u %s done status=0x%08x. next=0x%08x\n", epn->id, epn->is_in ? "in" : "out", sts, usbf_ep_reg_readl(epn, USBF_REG_EPN_STATUS)); } static void usbf_ep_reset(struct usbf_ep *ep) { ep->status = 0; /* Remove anything that was pending */ usbf_ep_nuke(ep, -ESHUTDOWN); } static void usbf_reset(struct usbf_udc *udc) { int i; for (i = 0; i < ARRAY_SIZE(udc->ep); i++) { if (udc->ep[i].disabled) continue; usbf_ep_reset(&udc->ep[i]); } if (usbf_reg_readl(udc, USBF_REG_USB_STATUS) & USBF_USB_SPEED_MODE) udc->gadget.speed = USB_SPEED_HIGH; else udc->gadget.speed = USB_SPEED_FULL; /* Remote wakeup feature must be disabled on USB bus reset */ udc->is_remote_wakeup = false; /* Enable endpoint zero */ usbf_ep0_enable(&udc->ep[0]); if (udc->driver) { /* Signal the reset */ spin_unlock(&udc->lock); usb_gadget_udc_reset(&udc->gadget, udc->driver); spin_lock(&udc->lock); } } static void usbf_driver_suspend(struct usbf_udc *udc) { if (udc->is_usb_suspended) { dev_dbg(udc->dev, "already suspended\n"); return; } dev_dbg(udc->dev, "do usb suspend\n"); udc->is_usb_suspended = true; if (udc->driver && udc->driver->suspend) { spin_unlock(&udc->lock); udc->driver->suspend(&udc->gadget); spin_lock(&udc->lock); /* The datasheet tells to set the USB_CONTROL register SUSPEND * bit when the USB bus suspend is detected. * This bit stops the clocks (clocks for EPC, SIE, USBPHY) but * these clocks seems not used only by the USB device. Some * UARTs can be lost ... * So, do not set the USB_CONTROL register SUSPEND bit. */ } } static void usbf_driver_resume(struct usbf_udc *udc) { if (!udc->is_usb_suspended) return; dev_dbg(udc->dev, "do usb resume\n"); udc->is_usb_suspended = false; if (udc->driver && udc->driver->resume) { spin_unlock(&udc->lock); udc->driver->resume(&udc->gadget); spin_lock(&udc->lock); } } static irqreturn_t usbf_epc_irq(int irq, void *_udc) { struct usbf_udc *udc = (struct usbf_udc *)_udc; unsigned long flags; struct usbf_ep *ep; u32 int_sts; u32 int_en; int i; spin_lock_irqsave(&udc->lock, flags); int_en = usbf_reg_readl(udc, USBF_REG_USB_INT_ENA); int_sts = usbf_reg_readl(udc, USBF_REG_USB_INT_STA) & int_en; usbf_reg_writel(udc, USBF_REG_USB_INT_STA, ~int_sts); dev_dbg(udc->dev, "int_sts=0x%08x\n", int_sts); if (int_sts & USBF_USB_RSUM_INT) { dev_dbg(udc->dev, "handle resume\n"); usbf_driver_resume(udc); } if (int_sts & USBF_USB_USB_RST_INT) { dev_dbg(udc->dev, "handle bus reset\n"); usbf_driver_resume(udc); usbf_reset(udc); } if (int_sts & USBF_USB_SPEED_MODE_INT) { if (usbf_reg_readl(udc, USBF_REG_USB_STATUS) & USBF_USB_SPEED_MODE) udc->gadget.speed = USB_SPEED_HIGH; else udc->gadget.speed = USB_SPEED_FULL; dev_dbg(udc->dev, "handle speed change (%s)\n", udc->gadget.speed == USB_SPEED_HIGH ? "High" : "Full"); } if (int_sts & USBF_USB_EPN_INT(0)) { usbf_driver_resume(udc); usbf_ep0_interrupt(&udc->ep[0]); } for (i = 1; i < ARRAY_SIZE(udc->ep); i++) { ep = &udc->ep[i]; if (int_sts & USBF_USB_EPN_INT(i)) { usbf_driver_resume(udc); usbf_epn_interrupt(ep); } } if (int_sts & USBF_USB_SPND_INT) { dev_dbg(udc->dev, "handle suspend\n"); usbf_driver_suspend(udc); } spin_unlock_irqrestore(&udc->lock, flags); return IRQ_HANDLED; } static irqreturn_t usbf_ahb_epc_irq(int irq, void *_udc) { struct usbf_udc *udc = (struct usbf_udc *)_udc; unsigned long flags; struct usbf_ep *epn; u32 sysbint; void (*ep_action)(struct usbf_ep *epn); int i; spin_lock_irqsave(&udc->lock, flags); /* Read and ack interrupts */ sysbint = usbf_reg_readl(udc, USBF_REG_AHBBINT); usbf_reg_writel(udc, USBF_REG_AHBBINT, sysbint); if ((sysbint & USBF_SYS_VBUS_INT) == USBF_SYS_VBUS_INT) { if (usbf_reg_readl(udc, USBF_REG_EPCTR) & USBF_SYS_VBUS_LEVEL) { dev_dbg(udc->dev, "handle vbus (1)\n"); spin_unlock(&udc->lock); usb_udc_vbus_handler(&udc->gadget, true); usb_gadget_set_state(&udc->gadget, USB_STATE_POWERED); spin_lock(&udc->lock); } else { dev_dbg(udc->dev, "handle vbus (0)\n"); udc->is_usb_suspended = false; spin_unlock(&udc->lock); usb_udc_vbus_handler(&udc->gadget, false); usb_gadget_set_state(&udc->gadget, USB_STATE_NOTATTACHED); spin_lock(&udc->lock); } } for (i = 1; i < ARRAY_SIZE(udc->ep); i++) { if (sysbint & USBF_SYS_DMA_ENDINT_EPN(i)) { epn = &udc->ep[i]; dev_dbg(epn->udc->dev, "ep%u handle DMA complete. action=%ps\n", epn->id, epn->bridge_on_dma_end); ep_action = epn->bridge_on_dma_end; if (ep_action) { epn->bridge_on_dma_end = NULL; ep_action(epn); } } } spin_unlock_irqrestore(&udc->lock, flags); return IRQ_HANDLED; } static int usbf_udc_start(struct usb_gadget *gadget, struct usb_gadget_driver *driver) { struct usbf_udc *udc = container_of(gadget, struct usbf_udc, gadget); unsigned long flags; dev_info(udc->dev, "start (driver '%s')\n", driver->driver.name); spin_lock_irqsave(&udc->lock, flags); /* hook up the driver */ udc->driver = driver; /* Enable VBUS interrupt */ usbf_reg_writel(udc, USBF_REG_AHBBINTEN, USBF_SYS_VBUS_INTEN); spin_unlock_irqrestore(&udc->lock, flags); return 0; } static int usbf_udc_stop(struct usb_gadget *gadget) { struct usbf_udc *udc = container_of(gadget, struct usbf_udc, gadget); unsigned long flags; spin_lock_irqsave(&udc->lock, flags); /* Disable VBUS interrupt */ usbf_reg_writel(udc, USBF_REG_AHBBINTEN, 0); udc->driver = NULL; spin_unlock_irqrestore(&udc->lock, flags); dev_info(udc->dev, "stopped\n"); return 0; } static int usbf_get_frame(struct usb_gadget *gadget) { struct usbf_udc *udc = container_of(gadget, struct usbf_udc, gadget); return USBF_USB_GET_FRAME(usbf_reg_readl(udc, USBF_REG_USB_ADDRESS)); } static void usbf_attach(struct usbf_udc *udc) { /* Enable USB signal to Function PHY * D+ signal Pull-up * Disable endpoint 0, it will be automatically enable when a USB reset * is received. * Disable the other endpoints */ usbf_reg_clrset(udc, USBF_REG_USB_CONTROL, USBF_USB_CONNECTB | USBF_USB_DEFAULT | USBF_USB_CONF, USBF_USB_PUE2); /* Enable reset and mode change interrupts */ usbf_reg_bitset(udc, USBF_REG_USB_INT_ENA, USBF_USB_USB_RST_EN | USBF_USB_SPEED_MODE_EN | USBF_USB_RSUM_EN | USBF_USB_SPND_EN); } static void usbf_detach(struct usbf_udc *udc) { int i; /* Disable interrupts */ usbf_reg_writel(udc, USBF_REG_USB_INT_ENA, 0); for (i = 0; i < ARRAY_SIZE(udc->ep); i++) { if (udc->ep[i].disabled) continue; usbf_ep_reset(&udc->ep[i]); } /* Disable USB signal to Function PHY * Do not Pull-up D+ signal * Disable endpoint 0 * Disable the other endpoints */ usbf_reg_clrset(udc, USBF_REG_USB_CONTROL, USBF_USB_PUE2 | USBF_USB_DEFAULT | USBF_USB_CONF, USBF_USB_CONNECTB); } static int usbf_pullup(struct usb_gadget *gadget, int is_on) { struct usbf_udc *udc = container_of(gadget, struct usbf_udc, gadget); unsigned long flags; dev_dbg(udc->dev, "pullup %d\n", is_on); spin_lock_irqsave(&udc->lock, flags); if (is_on) usbf_attach(udc); else usbf_detach(udc); spin_unlock_irqrestore(&udc->lock, flags); return 0; } static int usbf_udc_set_selfpowered(struct usb_gadget *gadget, int is_selfpowered) { struct usbf_udc *udc = container_of(gadget, struct usbf_udc, gadget); unsigned long flags; spin_lock_irqsave(&udc->lock, flags); gadget->is_selfpowered = (is_selfpowered != 0); spin_unlock_irqrestore(&udc->lock, flags); return 0; } static int usbf_udc_wakeup(struct usb_gadget *gadget) { struct usbf_udc *udc = container_of(gadget, struct usbf_udc, gadget); unsigned long flags; int ret; spin_lock_irqsave(&udc->lock, flags); if (!udc->is_remote_wakeup) { dev_dbg(udc->dev, "remote wakeup not allowed\n"); ret = -EINVAL; goto end; } dev_dbg(udc->dev, "do wakeup\n"); /* Send the resume signal */ usbf_reg_bitset(udc, USBF_REG_USB_CONTROL, USBF_USB_RSUM_IN); usbf_reg_bitclr(udc, USBF_REG_USB_CONTROL, USBF_USB_RSUM_IN); ret = 0; end: spin_unlock_irqrestore(&udc->lock, flags); return ret; } static struct usb_gadget_ops usbf_gadget_ops = { .get_frame = usbf_get_frame, .pullup = usbf_pullup, .udc_start = usbf_udc_start, .udc_stop = usbf_udc_stop, .set_selfpowered = usbf_udc_set_selfpowered, .wakeup = usbf_udc_wakeup, }; static int usbf_epn_check(struct usbf_ep *epn) { const char *type_txt; const char *buf_txt; int ret = 0; u32 ctrl; ctrl = usbf_ep_reg_readl(epn, USBF_REG_EPN_CONTROL); switch (ctrl & USBF_EPN_MODE_MASK) { case USBF_EPN_MODE_BULK: type_txt = "bulk"; if (epn->ep.caps.type_control || epn->ep.caps.type_iso || !epn->ep.caps.type_bulk || epn->ep.caps.type_int) { dev_err(epn->udc->dev, "ep%u caps mismatch, bulk expected\n", epn->id); ret = -EINVAL; } break; case USBF_EPN_MODE_INTR: type_txt = "intr"; if (epn->ep.caps.type_control || epn->ep.caps.type_iso || epn->ep.caps.type_bulk || !epn->ep.caps.type_int) { dev_err(epn->udc->dev, "ep%u caps mismatch, int expected\n", epn->id); ret = -EINVAL; } break; case USBF_EPN_MODE_ISO: type_txt = "iso"; if (epn->ep.caps.type_control || !epn->ep.caps.type_iso || epn->ep.caps.type_bulk || epn->ep.caps.type_int) { dev_err(epn->udc->dev, "ep%u caps mismatch, iso expected\n", epn->id); ret = -EINVAL; } break; default: type_txt = "unknown"; dev_err(epn->udc->dev, "ep%u unknown type\n", epn->id); ret = -EINVAL; break; } if (ctrl & USBF_EPN_BUF_TYPE_DOUBLE) { buf_txt = "double"; if (!usbf_ep_info[epn->id].is_double) { dev_err(epn->udc->dev, "ep%u buffer mismatch, double expected\n", epn->id); ret = -EINVAL; } } else { buf_txt = "single"; if (usbf_ep_info[epn->id].is_double) { dev_err(epn->udc->dev, "ep%u buffer mismatch, single expected\n", epn->id); ret = -EINVAL; } } dev_dbg(epn->udc->dev, "ep%u (%s) %s, %s buffer %u, checked %s\n", epn->id, epn->ep.name, type_txt, buf_txt, epn->ep.maxpacket_limit, ret ? "failed" : "ok"); return ret; } static int usbf_probe(struct platform_device *pdev) { struct device *dev = &pdev->dev; struct usbf_udc *udc; struct usbf_ep *ep; unsigned int i; int irq; int ret; udc = devm_kzalloc(dev, sizeof(*udc), GFP_KERNEL); if (!udc) return -ENOMEM; platform_set_drvdata(pdev, udc); udc->dev = dev; spin_lock_init(&udc->lock); udc->regs = devm_platform_ioremap_resource(pdev, 0); if (IS_ERR(udc->regs)) return PTR_ERR(udc->regs); devm_pm_runtime_enable(&pdev->dev); ret = pm_runtime_resume_and_get(&pdev->dev); if (ret < 0) return ret; dev_info(dev, "USBF version: %08x\n", usbf_reg_readl(udc, USBF_REG_USBSSVER)); /* Resetting the PLL is handled via the clock driver as it has common * registers with USB Host */ usbf_reg_bitclr(udc, USBF_REG_EPCTR, USBF_SYS_EPC_RST); /* modify in register gadget process */ udc->gadget.speed = USB_SPEED_FULL; udc->gadget.max_speed = USB_SPEED_HIGH; udc->gadget.ops = &usbf_gadget_ops; udc->gadget.name = dev->driver->name; udc->gadget.dev.parent = dev; udc->gadget.ep0 = &udc->ep[0].ep; /* The hardware DMA controller needs dma addresses aligned on 32bit. * A fallback to pio is done if DMA addresses are not aligned. */ udc->gadget.quirk_avoids_skb_reserve = 1; INIT_LIST_HEAD(&udc->gadget.ep_list); /* we have a canned request structure to allow sending packets as reply * to get_status requests */ INIT_LIST_HEAD(&udc->setup_reply.queue); for (i = 0; i < ARRAY_SIZE(udc->ep); i++) { ep = &udc->ep[i]; if (!(usbf_reg_readl(udc, USBF_REG_USBSSCONF) & USBF_SYS_EP_AVAILABLE(i))) { continue; } INIT_LIST_HEAD(&ep->queue); ep->id = i; ep->disabled = 1; ep->udc = udc; ep->ep.ops = &usbf_ep_ops; ep->ep.name = usbf_ep_info[i].name; ep->ep.caps = usbf_ep_info[i].caps; usb_ep_set_maxpacket_limit(&ep->ep, usbf_ep_info[i].maxpacket_limit); if (ep->id == 0) { ep->regs = ep->udc->regs + USBF_BASE_EP0; } else { ep->regs = ep->udc->regs + USBF_BASE_EPN(ep->id - 1); ret = usbf_epn_check(ep); if (ret) return ret; if (usbf_reg_readl(udc, USBF_REG_USBSSCONF) & USBF_SYS_DMA_AVAILABLE(i)) { ep->dma_regs = ep->udc->regs + USBF_BASE_DMA_EPN(ep->id - 1); } list_add_tail(&ep->ep.ep_list, &udc->gadget.ep_list); } } irq = platform_get_irq(pdev, 0); if (irq < 0) return irq; ret = devm_request_irq(dev, irq, usbf_epc_irq, 0, "usbf-epc", udc); if (ret) { dev_err(dev, "cannot request irq %d err %d\n", irq, ret); return ret; } irq = platform_get_irq(pdev, 1); if (irq < 0) return irq; ret = devm_request_irq(dev, irq, usbf_ahb_epc_irq, 0, "usbf-ahb-epc", udc); if (ret) { dev_err(dev, "cannot request irq %d err %d\n", irq, ret); return ret; } usbf_reg_bitset(udc, USBF_REG_AHBMCTR, USBF_SYS_WBURST_TYPE); usbf_reg_bitset(udc, USBF_REG_USB_CONTROL, USBF_USB_INT_SEL | USBF_USB_SOF_RCV | USBF_USB_SOF_CLK_MODE); ret = usb_add_gadget_udc(dev, &udc->gadget); if (ret) return ret; return 0; } static int usbf_remove(struct platform_device *pdev) { struct usbf_udc *udc = platform_get_drvdata(pdev); usb_del_gadget_udc(&udc->gadget); pm_runtime_put(&pdev->dev); return 0; } static const struct of_device_id usbf_match[] = { { .compatible = "renesas,rzn1-usbf" }, {} /* sentinel */ }; MODULE_DEVICE_TABLE(of, usbf_match); static struct platform_driver udc_driver = { .driver = { .name = "usbf_renesas", .owner = THIS_MODULE, .of_match_table = usbf_match, }, .probe = usbf_probe, .remove = usbf_remove, }; module_platform_driver(udc_driver); MODULE_AUTHOR("Herve Codina "); MODULE_DESCRIPTION("Renesas R-Car Gen3 & RZ/N1 USB Function driver"); MODULE_LICENSE("GPL");