// SPDX-License-Identifier: GPL-2.0 /* * Cadence CDNSP DRD Driver. * * Copyright (C) 2020 Cadence. * * Author: Pawel Laszczak * */ #include #include #include #include #include #include #include #include #include #include #include "core.h" #include "gadget-export.h" #include "drd.h" #include "cdnsp-gadget.h" #include "cdnsp-trace.h" unsigned int cdnsp_port_speed(unsigned int port_status) { /*Detect gadget speed based on PORTSC register*/ if (DEV_SUPERSPEEDPLUS(port_status)) return USB_SPEED_SUPER_PLUS; else if (DEV_SUPERSPEED(port_status)) return USB_SPEED_SUPER; else if (DEV_HIGHSPEED(port_status)) return USB_SPEED_HIGH; else if (DEV_FULLSPEED(port_status)) return USB_SPEED_FULL; /* If device is detached then speed will be USB_SPEED_UNKNOWN.*/ return USB_SPEED_UNKNOWN; } /* * Given a port state, this function returns a value that would result in the * port being in the same state, if the value was written to the port status * control register. * Save Read Only (RO) bits and save read/write bits where * writing a 0 clears the bit and writing a 1 sets the bit (RWS). * For all other types (RW1S, RW1CS, RW, and RZ), writing a '0' has no effect. */ u32 cdnsp_port_state_to_neutral(u32 state) { /* Save read-only status and port state. */ return (state & CDNSP_PORT_RO) | (state & CDNSP_PORT_RWS); } /** * cdnsp_find_next_ext_cap - Find the offset of the extended capabilities * with capability ID id. * @base: PCI MMIO registers base address. * @start: Address at which to start looking, (0 or HCC_PARAMS to start at * beginning of list) * @id: Extended capability ID to search for. * * Returns the offset of the next matching extended capability structure. * Some capabilities can occur several times, * e.g., the EXT_CAPS_PROTOCOL, and this provides a way to find them all. */ int cdnsp_find_next_ext_cap(void __iomem *base, u32 start, int id) { u32 offset = start; u32 next; u32 val; if (!start || start == HCC_PARAMS_OFFSET) { val = readl(base + HCC_PARAMS_OFFSET); if (val == ~0) return 0; offset = HCC_EXT_CAPS(val) << 2; if (!offset) return 0; }; do { val = readl(base + offset); if (val == ~0) return 0; if (EXT_CAPS_ID(val) == id && offset != start) return offset; next = EXT_CAPS_NEXT(val); offset += next << 2; } while (next); return 0; } void cdnsp_set_link_state(struct cdnsp_device *pdev, __le32 __iomem *port_regs, u32 link_state) { int port_num = 0xFF; u32 temp; temp = readl(port_regs); temp = cdnsp_port_state_to_neutral(temp); temp |= PORT_WKCONN_E | PORT_WKDISC_E; writel(temp, port_regs); temp &= ~PORT_PLS_MASK; temp |= PORT_LINK_STROBE | link_state; if (pdev->active_port) port_num = pdev->active_port->port_num; trace_cdnsp_handle_port_status(port_num, readl(port_regs)); writel(temp, port_regs); trace_cdnsp_link_state_changed(port_num, readl(port_regs)); } static void cdnsp_disable_port(struct cdnsp_device *pdev, __le32 __iomem *port_regs) { u32 temp = cdnsp_port_state_to_neutral(readl(port_regs)); writel(temp | PORT_PED, port_regs); } static void cdnsp_clear_port_change_bit(struct cdnsp_device *pdev, __le32 __iomem *port_regs) { u32 portsc = readl(port_regs); writel(cdnsp_port_state_to_neutral(portsc) | (portsc & PORT_CHANGE_BITS), port_regs); } static void cdnsp_set_chicken_bits_2(struct cdnsp_device *pdev, u32 bit) { __le32 __iomem *reg; void __iomem *base; u32 offset = 0; base = &pdev->cap_regs->hc_capbase; offset = cdnsp_find_next_ext_cap(base, offset, D_XEC_PRE_REGS_CAP); reg = base + offset + REG_CHICKEN_BITS_2_OFFSET; bit = readl(reg) | bit; writel(bit, reg); } static void cdnsp_clear_chicken_bits_2(struct cdnsp_device *pdev, u32 bit) { __le32 __iomem *reg; void __iomem *base; u32 offset = 0; base = &pdev->cap_regs->hc_capbase; offset = cdnsp_find_next_ext_cap(base, offset, D_XEC_PRE_REGS_CAP); reg = base + offset + REG_CHICKEN_BITS_2_OFFSET; bit = readl(reg) & ~bit; writel(bit, reg); } /* * Disable interrupts and begin the controller halting process. */ static void cdnsp_quiesce(struct cdnsp_device *pdev) { u32 halted; u32 mask; u32 cmd; mask = ~(u32)(CDNSP_IRQS); halted = readl(&pdev->op_regs->status) & STS_HALT; if (!halted) mask &= ~(CMD_R_S | CMD_DEVEN); cmd = readl(&pdev->op_regs->command); cmd &= mask; writel(cmd, &pdev->op_regs->command); } /* * Force controller into halt state. * * Disable any IRQs and clear the run/stop bit. * Controller will complete any current and actively pipelined transactions, and * should halt within 16 ms of the run/stop bit being cleared. * Read controller Halted bit in the status register to see when the * controller is finished. */ int cdnsp_halt(struct cdnsp_device *pdev) { int ret; u32 val; cdnsp_quiesce(pdev); ret = readl_poll_timeout_atomic(&pdev->op_regs->status, val, val & STS_HALT, 1, CDNSP_MAX_HALT_USEC); if (ret) { dev_err(pdev->dev, "ERROR: Device halt failed\n"); return ret; } pdev->cdnsp_state |= CDNSP_STATE_HALTED; return 0; } /* * device controller died, register read returns 0xffffffff, or command never * ends. */ void cdnsp_died(struct cdnsp_device *pdev) { dev_err(pdev->dev, "ERROR: CDNSP controller not responding\n"); pdev->cdnsp_state |= CDNSP_STATE_DYING; cdnsp_halt(pdev); } /* * Set the run bit and wait for the device to be running. */ static int cdnsp_start(struct cdnsp_device *pdev) { u32 temp; int ret; temp = readl(&pdev->op_regs->command); temp |= (CMD_R_S | CMD_DEVEN); writel(temp, &pdev->op_regs->command); pdev->cdnsp_state = 0; /* * Wait for the STS_HALT Status bit to be 0 to indicate the device is * running. */ ret = readl_poll_timeout_atomic(&pdev->op_regs->status, temp, !(temp & STS_HALT), 1, CDNSP_MAX_HALT_USEC); if (ret) { pdev->cdnsp_state = CDNSP_STATE_DYING; dev_err(pdev->dev, "ERROR: Controller run failed\n"); } return ret; } /* * Reset a halted controller. * * This resets pipelines, timers, counters, state machines, etc. * Transactions will be terminated immediately, and operational registers * will be set to their defaults. */ int cdnsp_reset(struct cdnsp_device *pdev) { u32 command; u32 temp; int ret; temp = readl(&pdev->op_regs->status); if (temp == ~(u32)0) { dev_err(pdev->dev, "Device not accessible, reset failed.\n"); return -ENODEV; } if ((temp & STS_HALT) == 0) { dev_err(pdev->dev, "Controller not halted, aborting reset.\n"); return -EINVAL; } command = readl(&pdev->op_regs->command); command |= CMD_RESET; writel(command, &pdev->op_regs->command); ret = readl_poll_timeout_atomic(&pdev->op_regs->command, temp, !(temp & CMD_RESET), 1, 10 * 1000); if (ret) { dev_err(pdev->dev, "ERROR: Controller reset failed\n"); return ret; } /* * CDNSP cannot write any doorbells or operational registers other * than status until the "Controller Not Ready" flag is cleared. */ ret = readl_poll_timeout_atomic(&pdev->op_regs->status, temp, !(temp & STS_CNR), 1, 10 * 1000); if (ret) { dev_err(pdev->dev, "ERROR: Controller not ready to work\n"); return ret; } dev_dbg(pdev->dev, "Controller ready to work"); return ret; } /* * cdnsp_get_endpoint_index - Find the index for an endpoint given its * descriptor.Use the return value to right shift 1 for the bitmask. * * Index = (epnum * 2) + direction - 1, * where direction = 0 for OUT, 1 for IN. * For control endpoints, the IN index is used (OUT index is unused), so * index = (epnum * 2) + direction - 1 = (epnum * 2) + 1 - 1 = (epnum * 2) */ static unsigned int cdnsp_get_endpoint_index(const struct usb_endpoint_descriptor *desc) { unsigned int index = (unsigned int)usb_endpoint_num(desc); if (usb_endpoint_xfer_control(desc)) return index * 2; return (index * 2) + (usb_endpoint_dir_in(desc) ? 1 : 0) - 1; } /* * Find the flag for this endpoint (for use in the control context). Use the * endpoint index to create a bitmask. The slot context is bit 0, endpoint 0 is * bit 1, etc. */ static unsigned int cdnsp_get_endpoint_flag(const struct usb_endpoint_descriptor *desc) { return 1 << (cdnsp_get_endpoint_index(desc) + 1); } int cdnsp_ep_enqueue(struct cdnsp_ep *pep, struct cdnsp_request *preq) { struct cdnsp_device *pdev = pep->pdev; struct usb_request *request; int ret; if (preq->epnum == 0 && !list_empty(&pep->pending_list)) { trace_cdnsp_request_enqueue_busy(preq); return -EBUSY; } request = &preq->request; request->actual = 0; request->status = -EINPROGRESS; preq->direction = pep->direction; preq->epnum = pep->number; preq->td.drbl = 0; ret = usb_gadget_map_request_by_dev(pdev->dev, request, pep->direction); if (ret) { trace_cdnsp_request_enqueue_error(preq); return ret; } list_add_tail(&preq->list, &pep->pending_list); trace_cdnsp_request_enqueue(preq); switch (usb_endpoint_type(pep->endpoint.desc)) { case USB_ENDPOINT_XFER_CONTROL: ret = cdnsp_queue_ctrl_tx(pdev, preq); break; case USB_ENDPOINT_XFER_BULK: case USB_ENDPOINT_XFER_INT: ret = cdnsp_queue_bulk_tx(pdev, preq); break; case USB_ENDPOINT_XFER_ISOC: ret = cdnsp_queue_isoc_tx_prepare(pdev, preq); } if (ret) goto unmap; return 0; unmap: usb_gadget_unmap_request_by_dev(pdev->dev, &preq->request, pep->direction); list_del(&preq->list); trace_cdnsp_request_enqueue_error(preq); return ret; } /* * Remove the request's TD from the endpoint ring. This may cause the * controller to stop USB transfers, potentially stopping in the middle of a * TRB buffer. The controller should pick up where it left off in the TD, * unless a Set Transfer Ring Dequeue Pointer is issued. * * The TRBs that make up the buffers for the canceled request will be "removed" * from the ring. Since the ring is a contiguous structure, they can't be * physically removed. Instead, there are two options: * * 1) If the controller is in the middle of processing the request to be * canceled, we simply move the ring's dequeue pointer past those TRBs * using the Set Transfer Ring Dequeue Pointer command. This will be * the common case, when drivers timeout on the last submitted request * and attempt to cancel. * * 2) If the controller is in the middle of a different TD, we turn the TRBs * into a series of 1-TRB transfer no-op TDs. No-ops shouldn't be chained. * The controller will need to invalidate the any TRBs it has cached after * the stop endpoint command. * * 3) The TD may have completed by the time the Stop Endpoint Command * completes, so software needs to handle that case too. * */ int cdnsp_ep_dequeue(struct cdnsp_ep *pep, struct cdnsp_request *preq) { struct cdnsp_device *pdev = pep->pdev; int ret_stop = 0; int ret_rem; trace_cdnsp_request_dequeue(preq); if (GET_EP_CTX_STATE(pep->out_ctx) == EP_STATE_RUNNING) ret_stop = cdnsp_cmd_stop_ep(pdev, pep); ret_rem = cdnsp_remove_request(pdev, preq, pep); return ret_rem ? ret_rem : ret_stop; } static void cdnsp_zero_in_ctx(struct cdnsp_device *pdev) { struct cdnsp_input_control_ctx *ctrl_ctx; struct cdnsp_slot_ctx *slot_ctx; struct cdnsp_ep_ctx *ep_ctx; int i; ctrl_ctx = cdnsp_get_input_control_ctx(&pdev->in_ctx); /* * When a device's add flag and drop flag are zero, any subsequent * configure endpoint command will leave that endpoint's state * untouched. Make sure we don't leave any old state in the input * endpoint contexts. */ ctrl_ctx->drop_flags = 0; ctrl_ctx->add_flags = 0; slot_ctx = cdnsp_get_slot_ctx(&pdev->in_ctx); slot_ctx->dev_info &= cpu_to_le32(~LAST_CTX_MASK); /* Endpoint 0 is always valid */ slot_ctx->dev_info |= cpu_to_le32(LAST_CTX(1)); for (i = 1; i < CDNSP_ENDPOINTS_NUM; ++i) { ep_ctx = cdnsp_get_ep_ctx(&pdev->in_ctx, i); ep_ctx->ep_info = 0; ep_ctx->ep_info2 = 0; ep_ctx->deq = 0; ep_ctx->tx_info = 0; } } /* Issue a configure endpoint command and wait for it to finish. */ static int cdnsp_configure_endpoint(struct cdnsp_device *pdev) { int ret; cdnsp_queue_configure_endpoint(pdev, pdev->cmd.in_ctx->dma); cdnsp_ring_cmd_db(pdev); ret = cdnsp_wait_for_cmd_compl(pdev); if (ret) { dev_err(pdev->dev, "ERR: unexpected command completion code 0x%x.\n", ret); return -EINVAL; } return ret; } static void cdnsp_invalidate_ep_events(struct cdnsp_device *pdev, struct cdnsp_ep *pep) { struct cdnsp_segment *segment; union cdnsp_trb *event; u32 cycle_state; u32 data; event = pdev->event_ring->dequeue; segment = pdev->event_ring->deq_seg; cycle_state = pdev->event_ring->cycle_state; while (1) { data = le32_to_cpu(event->trans_event.flags); /* Check the owner of the TRB. */ if ((data & TRB_CYCLE) != cycle_state) break; if (TRB_FIELD_TO_TYPE(data) == TRB_TRANSFER && TRB_TO_EP_ID(data) == (pep->idx + 1)) { data |= TRB_EVENT_INVALIDATE; event->trans_event.flags = cpu_to_le32(data); } if (cdnsp_last_trb_on_seg(segment, event)) { cycle_state ^= 1; segment = pdev->event_ring->deq_seg->next; event = segment->trbs; } else { event++; } } } int cdnsp_wait_for_cmd_compl(struct cdnsp_device *pdev) { struct cdnsp_segment *event_deq_seg; union cdnsp_trb *cmd_trb; dma_addr_t cmd_deq_dma; union cdnsp_trb *event; u32 cycle_state; int ret, val; u64 cmd_dma; u32 flags; cmd_trb = pdev->cmd.command_trb; pdev->cmd.status = 0; trace_cdnsp_cmd_wait_for_compl(pdev->cmd_ring, &cmd_trb->generic); ret = readl_poll_timeout_atomic(&pdev->op_regs->cmd_ring, val, !CMD_RING_BUSY(val), 1, CDNSP_CMD_TIMEOUT); if (ret) { dev_err(pdev->dev, "ERR: Timeout while waiting for command\n"); trace_cdnsp_cmd_timeout(pdev->cmd_ring, &cmd_trb->generic); pdev->cdnsp_state = CDNSP_STATE_DYING; return -ETIMEDOUT; } event = pdev->event_ring->dequeue; event_deq_seg = pdev->event_ring->deq_seg; cycle_state = pdev->event_ring->cycle_state; cmd_deq_dma = cdnsp_trb_virt_to_dma(pdev->cmd_ring->deq_seg, cmd_trb); if (!cmd_deq_dma) return -EINVAL; while (1) { flags = le32_to_cpu(event->event_cmd.flags); /* Check the owner of the TRB. */ if ((flags & TRB_CYCLE) != cycle_state) return -EINVAL; cmd_dma = le64_to_cpu(event->event_cmd.cmd_trb); /* * Check whether the completion event is for last queued * command. */ if (TRB_FIELD_TO_TYPE(flags) != TRB_COMPLETION || cmd_dma != (u64)cmd_deq_dma) { if (!cdnsp_last_trb_on_seg(event_deq_seg, event)) { event++; continue; } if (cdnsp_last_trb_on_ring(pdev->event_ring, event_deq_seg, event)) cycle_state ^= 1; event_deq_seg = event_deq_seg->next; event = event_deq_seg->trbs; continue; } trace_cdnsp_handle_command(pdev->cmd_ring, &cmd_trb->generic); pdev->cmd.status = GET_COMP_CODE(le32_to_cpu(event->event_cmd.status)); if (pdev->cmd.status == COMP_SUCCESS) return 0; return -pdev->cmd.status; } } int cdnsp_halt_endpoint(struct cdnsp_device *pdev, struct cdnsp_ep *pep, int value) { int ret; trace_cdnsp_ep_halt(value ? "Set" : "Clear"); ret = cdnsp_cmd_stop_ep(pdev, pep); if (ret) return ret; if (value) { if (GET_EP_CTX_STATE(pep->out_ctx) == EP_STATE_STOPPED) { cdnsp_queue_halt_endpoint(pdev, pep->idx); cdnsp_ring_cmd_db(pdev); ret = cdnsp_wait_for_cmd_compl(pdev); } pep->ep_state |= EP_HALTED; } else { cdnsp_queue_reset_ep(pdev, pep->idx); cdnsp_ring_cmd_db(pdev); ret = cdnsp_wait_for_cmd_compl(pdev); trace_cdnsp_handle_cmd_reset_ep(pep->out_ctx); if (ret) return ret; pep->ep_state &= ~EP_HALTED; if (pep->idx != 0 && !(pep->ep_state & EP_WEDGE)) cdnsp_ring_doorbell_for_active_rings(pdev, pep); pep->ep_state &= ~EP_WEDGE; } return 0; } static int cdnsp_update_eps_configuration(struct cdnsp_device *pdev, struct cdnsp_ep *pep) { struct cdnsp_input_control_ctx *ctrl_ctx; struct cdnsp_slot_ctx *slot_ctx; int ret = 0; u32 ep_sts; int i; ctrl_ctx = cdnsp_get_input_control_ctx(&pdev->in_ctx); /* Don't issue the command if there's no endpoints to update. */ if (ctrl_ctx->add_flags == 0 && ctrl_ctx->drop_flags == 0) return 0; ctrl_ctx->add_flags |= cpu_to_le32(SLOT_FLAG); ctrl_ctx->add_flags &= cpu_to_le32(~EP0_FLAG); ctrl_ctx->drop_flags &= cpu_to_le32(~(SLOT_FLAG | EP0_FLAG)); /* Fix up Context Entries field. Minimum value is EP0 == BIT(1). */ slot_ctx = cdnsp_get_slot_ctx(&pdev->in_ctx); for (i = CDNSP_ENDPOINTS_NUM; i >= 1; i--) { __le32 le32 = cpu_to_le32(BIT(i)); if ((pdev->eps[i - 1].ring && !(ctrl_ctx->drop_flags & le32)) || (ctrl_ctx->add_flags & le32) || i == 1) { slot_ctx->dev_info &= cpu_to_le32(~LAST_CTX_MASK); slot_ctx->dev_info |= cpu_to_le32(LAST_CTX(i)); break; } } ep_sts = GET_EP_CTX_STATE(pep->out_ctx); if ((ctrl_ctx->add_flags != cpu_to_le32(SLOT_FLAG) && ep_sts == EP_STATE_DISABLED) || (ep_sts != EP_STATE_DISABLED && ctrl_ctx->drop_flags)) ret = cdnsp_configure_endpoint(pdev); trace_cdnsp_configure_endpoint(cdnsp_get_slot_ctx(&pdev->out_ctx)); trace_cdnsp_handle_cmd_config_ep(pep->out_ctx); cdnsp_zero_in_ctx(pdev); return ret; } /* * This submits a Reset Device Command, which will set the device state to 0, * set the device address to 0, and disable all the endpoints except the default * control endpoint. The USB core should come back and call * cdnsp_setup_device(), and then re-set up the configuration. */ int cdnsp_reset_device(struct cdnsp_device *pdev) { struct cdnsp_slot_ctx *slot_ctx; int slot_state; int ret, i; slot_ctx = cdnsp_get_slot_ctx(&pdev->in_ctx); slot_ctx->dev_info = 0; pdev->device_address = 0; /* If device is not setup, there is no point in resetting it. */ slot_ctx = cdnsp_get_slot_ctx(&pdev->out_ctx); slot_state = GET_SLOT_STATE(le32_to_cpu(slot_ctx->dev_state)); trace_cdnsp_reset_device(slot_ctx); if (slot_state <= SLOT_STATE_DEFAULT && pdev->eps[0].ep_state & EP_HALTED) { cdnsp_halt_endpoint(pdev, &pdev->eps[0], 0); } /* * During Reset Device command controller shall transition the * endpoint ep0 to the Running State. */ pdev->eps[0].ep_state &= ~(EP_STOPPED | EP_HALTED); pdev->eps[0].ep_state |= EP_ENABLED; if (slot_state <= SLOT_STATE_DEFAULT) return 0; cdnsp_queue_reset_device(pdev); cdnsp_ring_cmd_db(pdev); ret = cdnsp_wait_for_cmd_compl(pdev); /* * After Reset Device command all not default endpoints * are in Disabled state. */ for (i = 1; i < CDNSP_ENDPOINTS_NUM; ++i) pdev->eps[i].ep_state |= EP_STOPPED | EP_UNCONFIGURED; trace_cdnsp_handle_cmd_reset_dev(slot_ctx); if (ret) dev_err(pdev->dev, "Reset device failed with error code %d", ret); return ret; } /* * Sets the MaxPStreams field and the Linear Stream Array field. * Sets the dequeue pointer to the stream context array. */ static void cdnsp_setup_streams_ep_input_ctx(struct cdnsp_device *pdev, struct cdnsp_ep_ctx *ep_ctx, struct cdnsp_stream_info *stream_info) { u32 max_primary_streams; /* MaxPStreams is the number of stream context array entries, not the * number we're actually using. Must be in 2^(MaxPstreams + 1) format. * fls(0) = 0, fls(0x1) = 1, fls(0x10) = 2, fls(0x100) = 3, etc. */ max_primary_streams = fls(stream_info->num_stream_ctxs) - 2; ep_ctx->ep_info &= cpu_to_le32(~EP_MAXPSTREAMS_MASK); ep_ctx->ep_info |= cpu_to_le32(EP_MAXPSTREAMS(max_primary_streams) | EP_HAS_LSA); ep_ctx->deq = cpu_to_le64(stream_info->ctx_array_dma); } /* * The drivers use this function to prepare a bulk endpoints to use streams. * * Don't allow the call to succeed if endpoint only supports one stream * (which means it doesn't support streams at all). */ int cdnsp_alloc_streams(struct cdnsp_device *pdev, struct cdnsp_ep *pep) { unsigned int num_streams = usb_ss_max_streams(pep->endpoint.comp_desc); unsigned int num_stream_ctxs; int ret; if (num_streams == 0) return 0; if (num_streams > STREAM_NUM_STREAMS) return -EINVAL; /* * Add two to the number of streams requested to account for * stream 0 that is reserved for controller usage and one additional * for TASK SET FULL response. */ num_streams += 2; /* The stream context array size must be a power of two */ num_stream_ctxs = roundup_pow_of_two(num_streams); trace_cdnsp_stream_number(pep, num_stream_ctxs, num_streams); ret = cdnsp_alloc_stream_info(pdev, pep, num_stream_ctxs, num_streams); if (ret) return ret; cdnsp_setup_streams_ep_input_ctx(pdev, pep->in_ctx, &pep->stream_info); pep->ep_state |= EP_HAS_STREAMS; pep->stream_info.td_count = 0; pep->stream_info.first_prime_det = 0; /* Subtract 1 for stream 0, which drivers can't use. */ return num_streams - 1; } int cdnsp_disable_slot(struct cdnsp_device *pdev) { int ret; cdnsp_queue_slot_control(pdev, TRB_DISABLE_SLOT); cdnsp_ring_cmd_db(pdev); ret = cdnsp_wait_for_cmd_compl(pdev); pdev->slot_id = 0; pdev->active_port = NULL; trace_cdnsp_handle_cmd_disable_slot(cdnsp_get_slot_ctx(&pdev->out_ctx)); memset(pdev->in_ctx.bytes, 0, CDNSP_CTX_SIZE); memset(pdev->out_ctx.bytes, 0, CDNSP_CTX_SIZE); return ret; } int cdnsp_enable_slot(struct cdnsp_device *pdev) { struct cdnsp_slot_ctx *slot_ctx; int slot_state; int ret; /* If device is not setup, there is no point in resetting it */ slot_ctx = cdnsp_get_slot_ctx(&pdev->out_ctx); slot_state = GET_SLOT_STATE(le32_to_cpu(slot_ctx->dev_state)); if (slot_state != SLOT_STATE_DISABLED) return 0; cdnsp_queue_slot_control(pdev, TRB_ENABLE_SLOT); cdnsp_ring_cmd_db(pdev); ret = cdnsp_wait_for_cmd_compl(pdev); if (ret) goto show_trace; pdev->slot_id = 1; show_trace: trace_cdnsp_handle_cmd_enable_slot(cdnsp_get_slot_ctx(&pdev->out_ctx)); return ret; } /* * Issue an Address Device command with BSR=0 if setup is SETUP_CONTEXT_ONLY * or with BSR = 1 if set_address is SETUP_CONTEXT_ADDRESS. */ int cdnsp_setup_device(struct cdnsp_device *pdev, enum cdnsp_setup_dev setup) { struct cdnsp_input_control_ctx *ctrl_ctx; struct cdnsp_slot_ctx *slot_ctx; int dev_state = 0; int ret; if (!pdev->slot_id) { trace_cdnsp_slot_id("incorrect"); return -EINVAL; } if (!pdev->active_port->port_num) return -EINVAL; slot_ctx = cdnsp_get_slot_ctx(&pdev->out_ctx); dev_state = GET_SLOT_STATE(le32_to_cpu(slot_ctx->dev_state)); if (setup == SETUP_CONTEXT_ONLY && dev_state == SLOT_STATE_DEFAULT) { trace_cdnsp_slot_already_in_default(slot_ctx); return 0; } slot_ctx = cdnsp_get_slot_ctx(&pdev->in_ctx); ctrl_ctx = cdnsp_get_input_control_ctx(&pdev->in_ctx); if (!slot_ctx->dev_info || dev_state == SLOT_STATE_DEFAULT) { ret = cdnsp_setup_addressable_priv_dev(pdev); if (ret) return ret; } cdnsp_copy_ep0_dequeue_into_input_ctx(pdev); ctrl_ctx->add_flags = cpu_to_le32(SLOT_FLAG | EP0_FLAG); ctrl_ctx->drop_flags = 0; trace_cdnsp_setup_device_slot(slot_ctx); cdnsp_queue_address_device(pdev, pdev->in_ctx.dma, setup); cdnsp_ring_cmd_db(pdev); ret = cdnsp_wait_for_cmd_compl(pdev); trace_cdnsp_handle_cmd_addr_dev(cdnsp_get_slot_ctx(&pdev->out_ctx)); /* Zero the input context control for later use. */ ctrl_ctx->add_flags = 0; ctrl_ctx->drop_flags = 0; return ret; } void cdnsp_set_usb2_hardware_lpm(struct cdnsp_device *pdev, struct usb_request *req, int enable) { if (pdev->active_port != &pdev->usb2_port || !pdev->gadget.lpm_capable) return; trace_cdnsp_lpm(enable); if (enable) writel(PORT_BESL(CDNSP_DEFAULT_BESL) | PORT_L1S_NYET | PORT_HLE, &pdev->active_port->regs->portpmsc); else writel(PORT_L1S_NYET, &pdev->active_port->regs->portpmsc); } static int cdnsp_get_frame(struct cdnsp_device *pdev) { return readl(&pdev->run_regs->microframe_index) >> 3; } static int cdnsp_gadget_ep_enable(struct usb_ep *ep, const struct usb_endpoint_descriptor *desc) { struct cdnsp_input_control_ctx *ctrl_ctx; struct cdnsp_device *pdev; struct cdnsp_ep *pep; unsigned long flags; u32 added_ctxs; int ret; if (!ep || !desc || desc->bDescriptorType != USB_DT_ENDPOINT || !desc->wMaxPacketSize) return -EINVAL; pep = to_cdnsp_ep(ep); pdev = pep->pdev; pep->ep_state &= ~EP_UNCONFIGURED; if (dev_WARN_ONCE(pdev->dev, pep->ep_state & EP_ENABLED, "%s is already enabled\n", pep->name)) return 0; spin_lock_irqsave(&pdev->lock, flags); added_ctxs = cdnsp_get_endpoint_flag(desc); if (added_ctxs == SLOT_FLAG || added_ctxs == EP0_FLAG) { dev_err(pdev->dev, "ERROR: Bad endpoint number\n"); ret = -EINVAL; goto unlock; } pep->interval = desc->bInterval ? BIT(desc->bInterval - 1) : 0; if (pdev->gadget.speed == USB_SPEED_FULL) { if (usb_endpoint_type(desc) == USB_ENDPOINT_XFER_INT) pep->interval = desc->bInterval << 3; if (usb_endpoint_type(desc) == USB_ENDPOINT_XFER_ISOC) pep->interval = BIT(desc->bInterval - 1) << 3; } if (usb_endpoint_type(desc) == USB_ENDPOINT_XFER_ISOC) { if (pep->interval > BIT(12)) { dev_err(pdev->dev, "bInterval %d not supported\n", desc->bInterval); ret = -EINVAL; goto unlock; } cdnsp_set_chicken_bits_2(pdev, CHICKEN_XDMA_2_TP_CACHE_DIS); } ret = cdnsp_endpoint_init(pdev, pep, GFP_ATOMIC); if (ret) goto unlock; ctrl_ctx = cdnsp_get_input_control_ctx(&pdev->in_ctx); ctrl_ctx->add_flags = cpu_to_le32(added_ctxs); ctrl_ctx->drop_flags = 0; ret = cdnsp_update_eps_configuration(pdev, pep); if (ret) { cdnsp_free_endpoint_rings(pdev, pep); goto unlock; } pep->ep_state |= EP_ENABLED; pep->ep_state &= ~EP_STOPPED; unlock: trace_cdnsp_ep_enable_end(pep, 0); spin_unlock_irqrestore(&pdev->lock, flags); return ret; } static int cdnsp_gadget_ep_disable(struct usb_ep *ep) { struct cdnsp_input_control_ctx *ctrl_ctx; struct cdnsp_request *preq; struct cdnsp_device *pdev; struct cdnsp_ep *pep; unsigned long flags; u32 drop_flag; int ret = 0; if (!ep) return -EINVAL; pep = to_cdnsp_ep(ep); pdev = pep->pdev; spin_lock_irqsave(&pdev->lock, flags); if (!(pep->ep_state & EP_ENABLED)) { dev_err(pdev->dev, "%s is already disabled\n", pep->name); ret = -EINVAL; goto finish; } pep->ep_state |= EP_DIS_IN_RROGRESS; /* Endpoint was unconfigured by Reset Device command. */ if (!(pep->ep_state & EP_UNCONFIGURED)) { cdnsp_cmd_stop_ep(pdev, pep); cdnsp_cmd_flush_ep(pdev, pep); } /* Remove all queued USB requests. */ while (!list_empty(&pep->pending_list)) { preq = next_request(&pep->pending_list); cdnsp_ep_dequeue(pep, preq); } cdnsp_invalidate_ep_events(pdev, pep); pep->ep_state &= ~EP_DIS_IN_RROGRESS; drop_flag = cdnsp_get_endpoint_flag(pep->endpoint.desc); ctrl_ctx = cdnsp_get_input_control_ctx(&pdev->in_ctx); ctrl_ctx->drop_flags = cpu_to_le32(drop_flag); ctrl_ctx->add_flags = 0; cdnsp_endpoint_zero(pdev, pep); if (!(pep->ep_state & EP_UNCONFIGURED)) ret = cdnsp_update_eps_configuration(pdev, pep); cdnsp_free_endpoint_rings(pdev, pep); pep->ep_state &= ~(EP_ENABLED | EP_UNCONFIGURED); pep->ep_state |= EP_STOPPED; finish: trace_cdnsp_ep_disable_end(pep, 0); spin_unlock_irqrestore(&pdev->lock, flags); return ret; } static struct usb_request *cdnsp_gadget_ep_alloc_request(struct usb_ep *ep, gfp_t gfp_flags) { struct cdnsp_ep *pep = to_cdnsp_ep(ep); struct cdnsp_request *preq; preq = kzalloc(sizeof(*preq), gfp_flags); if (!preq) return NULL; preq->epnum = pep->number; preq->pep = pep; trace_cdnsp_alloc_request(preq); return &preq->request; } static void cdnsp_gadget_ep_free_request(struct usb_ep *ep, struct usb_request *request) { struct cdnsp_request *preq = to_cdnsp_request(request); trace_cdnsp_free_request(preq); kfree(preq); } static int cdnsp_gadget_ep_queue(struct usb_ep *ep, struct usb_request *request, gfp_t gfp_flags) { struct cdnsp_request *preq; struct cdnsp_device *pdev; struct cdnsp_ep *pep; unsigned long flags; int ret; if (!request || !ep) return -EINVAL; pep = to_cdnsp_ep(ep); pdev = pep->pdev; if (!(pep->ep_state & EP_ENABLED)) { dev_err(pdev->dev, "%s: can't queue to disabled endpoint\n", pep->name); return -EINVAL; } preq = to_cdnsp_request(request); spin_lock_irqsave(&pdev->lock, flags); ret = cdnsp_ep_enqueue(pep, preq); spin_unlock_irqrestore(&pdev->lock, flags); return ret; } static int cdnsp_gadget_ep_dequeue(struct usb_ep *ep, struct usb_request *request) { struct cdnsp_ep *pep = to_cdnsp_ep(ep); struct cdnsp_device *pdev = pep->pdev; unsigned long flags; int ret; if (request->status != -EINPROGRESS) return 0; if (!pep->endpoint.desc) { dev_err(pdev->dev, "%s: can't dequeue to disabled endpoint\n", pep->name); return -ESHUTDOWN; } /* Requests has been dequeued during disabling endpoint. */ if (!(pep->ep_state & EP_ENABLED)) return 0; spin_lock_irqsave(&pdev->lock, flags); ret = cdnsp_ep_dequeue(pep, to_cdnsp_request(request)); spin_unlock_irqrestore(&pdev->lock, flags); return ret; } static int cdnsp_gadget_ep_set_halt(struct usb_ep *ep, int value) { struct cdnsp_ep *pep = to_cdnsp_ep(ep); struct cdnsp_device *pdev = pep->pdev; struct cdnsp_request *preq; unsigned long flags; int ret; spin_lock_irqsave(&pdev->lock, flags); preq = next_request(&pep->pending_list); if (value) { if (preq) { trace_cdnsp_ep_busy_try_halt_again(pep, 0); ret = -EAGAIN; goto done; } } ret = cdnsp_halt_endpoint(pdev, pep, value); done: spin_unlock_irqrestore(&pdev->lock, flags); return ret; } static int cdnsp_gadget_ep_set_wedge(struct usb_ep *ep) { struct cdnsp_ep *pep = to_cdnsp_ep(ep); struct cdnsp_device *pdev = pep->pdev; unsigned long flags; int ret; spin_lock_irqsave(&pdev->lock, flags); pep->ep_state |= EP_WEDGE; ret = cdnsp_halt_endpoint(pdev, pep, 1); spin_unlock_irqrestore(&pdev->lock, flags); return ret; } static const struct usb_ep_ops cdnsp_gadget_ep0_ops = { .enable = cdnsp_gadget_ep_enable, .disable = cdnsp_gadget_ep_disable, .alloc_request = cdnsp_gadget_ep_alloc_request, .free_request = cdnsp_gadget_ep_free_request, .queue = cdnsp_gadget_ep_queue, .dequeue = cdnsp_gadget_ep_dequeue, .set_halt = cdnsp_gadget_ep_set_halt, .set_wedge = cdnsp_gadget_ep_set_wedge, }; static const struct usb_ep_ops cdnsp_gadget_ep_ops = { .enable = cdnsp_gadget_ep_enable, .disable = cdnsp_gadget_ep_disable, .alloc_request = cdnsp_gadget_ep_alloc_request, .free_request = cdnsp_gadget_ep_free_request, .queue = cdnsp_gadget_ep_queue, .dequeue = cdnsp_gadget_ep_dequeue, .set_halt = cdnsp_gadget_ep_set_halt, .set_wedge = cdnsp_gadget_ep_set_wedge, }; void cdnsp_gadget_giveback(struct cdnsp_ep *pep, struct cdnsp_request *preq, int status) { struct cdnsp_device *pdev = pep->pdev; list_del(&preq->list); if (preq->request.status == -EINPROGRESS) preq->request.status = status; usb_gadget_unmap_request_by_dev(pdev->dev, &preq->request, preq->direction); trace_cdnsp_request_giveback(preq); if (preq != &pdev->ep0_preq) { spin_unlock(&pdev->lock); usb_gadget_giveback_request(&pep->endpoint, &preq->request); spin_lock(&pdev->lock); } } static struct usb_endpoint_descriptor cdnsp_gadget_ep0_desc = { .bLength = USB_DT_ENDPOINT_SIZE, .bDescriptorType = USB_DT_ENDPOINT, .bmAttributes = USB_ENDPOINT_XFER_CONTROL, }; static int cdnsp_run(struct cdnsp_device *pdev, enum usb_device_speed speed) { u32 fs_speed = 0; u64 temp_64; u32 temp; int ret; temp_64 = cdnsp_read_64(&pdev->ir_set->erst_dequeue); temp_64 &= ~ERST_PTR_MASK; temp = readl(&pdev->ir_set->irq_control); temp &= ~IMOD_INTERVAL_MASK; temp |= ((IMOD_DEFAULT_INTERVAL / 250) & IMOD_INTERVAL_MASK); writel(temp, &pdev->ir_set->irq_control); temp = readl(&pdev->port3x_regs->mode_addr); switch (speed) { case USB_SPEED_SUPER_PLUS: temp |= CFG_3XPORT_SSP_SUPPORT; break; case USB_SPEED_SUPER: temp &= ~CFG_3XPORT_SSP_SUPPORT; break; case USB_SPEED_HIGH: break; case USB_SPEED_FULL: fs_speed = PORT_REG6_FORCE_FS; break; default: dev_err(pdev->dev, "invalid maximum_speed parameter %d\n", speed); fallthrough; case USB_SPEED_UNKNOWN: /* Default to superspeed. */ speed = USB_SPEED_SUPER; break; } if (speed >= USB_SPEED_SUPER) { writel(temp, &pdev->port3x_regs->mode_addr); cdnsp_set_link_state(pdev, &pdev->usb3_port.regs->portsc, XDEV_RXDETECT); } else { cdnsp_disable_port(pdev, &pdev->usb3_port.regs->portsc); } cdnsp_set_link_state(pdev, &pdev->usb2_port.regs->portsc, XDEV_RXDETECT); cdnsp_gadget_ep0_desc.wMaxPacketSize = cpu_to_le16(512); writel(PORT_REG6_L1_L0_HW_EN | fs_speed, &pdev->port20_regs->port_reg6); ret = cdnsp_start(pdev); if (ret) { ret = -ENODEV; goto err; } temp = readl(&pdev->op_regs->command); temp |= (CMD_INTE); writel(temp, &pdev->op_regs->command); temp = readl(&pdev->ir_set->irq_pending); writel(IMAN_IE_SET(temp), &pdev->ir_set->irq_pending); trace_cdnsp_init("Controller ready to work"); return 0; err: cdnsp_halt(pdev); return ret; } static int cdnsp_gadget_udc_start(struct usb_gadget *g, struct usb_gadget_driver *driver) { enum usb_device_speed max_speed = driver->max_speed; struct cdnsp_device *pdev = gadget_to_cdnsp(g); unsigned long flags; int ret; spin_lock_irqsave(&pdev->lock, flags); pdev->gadget_driver = driver; /* limit speed if necessary */ max_speed = min(driver->max_speed, g->max_speed); ret = cdnsp_run(pdev, max_speed); spin_unlock_irqrestore(&pdev->lock, flags); return ret; } /* * Update Event Ring Dequeue Pointer: * - When all events have finished * - To avoid "Event Ring Full Error" condition */ void cdnsp_update_erst_dequeue(struct cdnsp_device *pdev, union cdnsp_trb *event_ring_deq, u8 clear_ehb) { u64 temp_64; dma_addr_t deq; temp_64 = cdnsp_read_64(&pdev->ir_set->erst_dequeue); /* If necessary, update the HW's version of the event ring deq ptr. */ if (event_ring_deq != pdev->event_ring->dequeue) { deq = cdnsp_trb_virt_to_dma(pdev->event_ring->deq_seg, pdev->event_ring->dequeue); temp_64 &= ERST_PTR_MASK; temp_64 |= ((u64)deq & (u64)~ERST_PTR_MASK); } /* Clear the event handler busy flag (RW1C). */ if (clear_ehb) temp_64 |= ERST_EHB; else temp_64 &= ~ERST_EHB; cdnsp_write_64(temp_64, &pdev->ir_set->erst_dequeue); } static void cdnsp_clear_cmd_ring(struct cdnsp_device *pdev) { struct cdnsp_segment *seg; u64 val_64; int i; cdnsp_initialize_ring_info(pdev->cmd_ring); seg = pdev->cmd_ring->first_seg; for (i = 0; i < pdev->cmd_ring->num_segs; i++) { memset(seg->trbs, 0, sizeof(union cdnsp_trb) * (TRBS_PER_SEGMENT - 1)); seg = seg->next; } /* Set the address in the Command Ring Control register. */ val_64 = cdnsp_read_64(&pdev->op_regs->cmd_ring); val_64 = (val_64 & (u64)CMD_RING_RSVD_BITS) | (pdev->cmd_ring->first_seg->dma & (u64)~CMD_RING_RSVD_BITS) | pdev->cmd_ring->cycle_state; cdnsp_write_64(val_64, &pdev->op_regs->cmd_ring); } static void cdnsp_consume_all_events(struct cdnsp_device *pdev) { struct cdnsp_segment *event_deq_seg; union cdnsp_trb *event_ring_deq; union cdnsp_trb *event; u32 cycle_bit; event_ring_deq = pdev->event_ring->dequeue; event_deq_seg = pdev->event_ring->deq_seg; event = pdev->event_ring->dequeue; /* Update ring dequeue pointer. */ while (1) { cycle_bit = (le32_to_cpu(event->event_cmd.flags) & TRB_CYCLE); /* Does the controller or driver own the TRB? */ if (cycle_bit != pdev->event_ring->cycle_state) break; cdnsp_inc_deq(pdev, pdev->event_ring); if (!cdnsp_last_trb_on_seg(event_deq_seg, event)) { event++; continue; } if (cdnsp_last_trb_on_ring(pdev->event_ring, event_deq_seg, event)) cycle_bit ^= 1; event_deq_seg = event_deq_seg->next; event = event_deq_seg->trbs; } cdnsp_update_erst_dequeue(pdev, event_ring_deq, 1); } static void cdnsp_stop(struct cdnsp_device *pdev) { u32 temp; cdnsp_cmd_flush_ep(pdev, &pdev->eps[0]); /* Remove internally queued request for ep0. */ if (!list_empty(&pdev->eps[0].pending_list)) { struct cdnsp_request *req; req = next_request(&pdev->eps[0].pending_list); if (req == &pdev->ep0_preq) cdnsp_ep_dequeue(&pdev->eps[0], req); } cdnsp_disable_port(pdev, &pdev->usb2_port.regs->portsc); cdnsp_disable_port(pdev, &pdev->usb3_port.regs->portsc); cdnsp_disable_slot(pdev); cdnsp_halt(pdev); temp = readl(&pdev->op_regs->status); writel((temp & ~0x1fff) | STS_EINT, &pdev->op_regs->status); temp = readl(&pdev->ir_set->irq_pending); writel(IMAN_IE_CLEAR(temp), &pdev->ir_set->irq_pending); cdnsp_clear_port_change_bit(pdev, &pdev->usb2_port.regs->portsc); cdnsp_clear_port_change_bit(pdev, &pdev->usb3_port.regs->portsc); /* Clear interrupt line */ temp = readl(&pdev->ir_set->irq_pending); temp |= IMAN_IP; writel(temp, &pdev->ir_set->irq_pending); cdnsp_consume_all_events(pdev); cdnsp_clear_cmd_ring(pdev); trace_cdnsp_exit("Controller stopped."); } /* * Stop controller. * This function is called by the gadget core when the driver is removed. * Disable slot, disable IRQs, and quiesce the controller. */ static int cdnsp_gadget_udc_stop(struct usb_gadget *g) { struct cdnsp_device *pdev = gadget_to_cdnsp(g); unsigned long flags; spin_lock_irqsave(&pdev->lock, flags); cdnsp_stop(pdev); pdev->gadget_driver = NULL; spin_unlock_irqrestore(&pdev->lock, flags); return 0; } static int cdnsp_gadget_get_frame(struct usb_gadget *g) { struct cdnsp_device *pdev = gadget_to_cdnsp(g); return cdnsp_get_frame(pdev); } static void __cdnsp_gadget_wakeup(struct cdnsp_device *pdev) { struct cdnsp_port_regs __iomem *port_regs; u32 portpm, portsc; port_regs = pdev->active_port->regs; portsc = readl(&port_regs->portsc) & PORT_PLS_MASK; /* Remote wakeup feature is not enabled by host. */ if (pdev->gadget.speed < USB_SPEED_SUPER && portsc == XDEV_U2) { portpm = readl(&port_regs->portpmsc); if (!(portpm & PORT_RWE)) return; } if (portsc == XDEV_U3 && !pdev->may_wakeup) return; cdnsp_set_link_state(pdev, &port_regs->portsc, XDEV_U0); pdev->cdnsp_state |= CDNSP_WAKEUP_PENDING; } static int cdnsp_gadget_wakeup(struct usb_gadget *g) { struct cdnsp_device *pdev = gadget_to_cdnsp(g); unsigned long flags; spin_lock_irqsave(&pdev->lock, flags); __cdnsp_gadget_wakeup(pdev); spin_unlock_irqrestore(&pdev->lock, flags); return 0; } static int cdnsp_gadget_set_selfpowered(struct usb_gadget *g, int is_selfpowered) { struct cdnsp_device *pdev = gadget_to_cdnsp(g); unsigned long flags; spin_lock_irqsave(&pdev->lock, flags); g->is_selfpowered = !!is_selfpowered; spin_unlock_irqrestore(&pdev->lock, flags); return 0; } static int cdnsp_gadget_pullup(struct usb_gadget *gadget, int is_on) { struct cdnsp_device *pdev = gadget_to_cdnsp(gadget); struct cdns *cdns = dev_get_drvdata(pdev->dev); unsigned long flags; trace_cdnsp_pullup(is_on); /* * Disable events handling while controller is being * enabled/disabled. */ disable_irq(cdns->dev_irq); spin_lock_irqsave(&pdev->lock, flags); if (!is_on) { cdnsp_reset_device(pdev); cdns_clear_vbus(cdns); } else { cdns_set_vbus(cdns); } spin_unlock_irqrestore(&pdev->lock, flags); enable_irq(cdns->dev_irq); return 0; } static const struct usb_gadget_ops cdnsp_gadget_ops = { .get_frame = cdnsp_gadget_get_frame, .wakeup = cdnsp_gadget_wakeup, .set_selfpowered = cdnsp_gadget_set_selfpowered, .pullup = cdnsp_gadget_pullup, .udc_start = cdnsp_gadget_udc_start, .udc_stop = cdnsp_gadget_udc_stop, }; static void cdnsp_get_ep_buffering(struct cdnsp_device *pdev, struct cdnsp_ep *pep) { void __iomem *reg = &pdev->cap_regs->hc_capbase; int endpoints; reg += cdnsp_find_next_ext_cap(reg, 0, XBUF_CAP_ID); if (!pep->direction) { pep->buffering = readl(reg + XBUF_RX_TAG_MASK_0_OFFSET); pep->buffering_period = readl(reg + XBUF_RX_TAG_MASK_1_OFFSET); pep->buffering = (pep->buffering + 1) / 2; pep->buffering_period = (pep->buffering_period + 1) / 2; return; } endpoints = HCS_ENDPOINTS(pdev->hcs_params1) / 2; /* Set to XBUF_TX_TAG_MASK_0 register. */ reg += XBUF_TX_CMD_OFFSET + (endpoints * 2 + 2) * sizeof(u32); /* Set reg to XBUF_TX_TAG_MASK_N related with this endpoint. */ reg += pep->number * sizeof(u32) * 2; pep->buffering = (readl(reg) + 1) / 2; pep->buffering_period = pep->buffering; } static int cdnsp_gadget_init_endpoints(struct cdnsp_device *pdev) { int max_streams = HCC_MAX_PSA(pdev->hcc_params); struct cdnsp_ep *pep; int i; INIT_LIST_HEAD(&pdev->gadget.ep_list); if (max_streams < STREAM_LOG_STREAMS) { dev_err(pdev->dev, "Stream size %d not supported\n", max_streams); return -EINVAL; } max_streams = STREAM_LOG_STREAMS; for (i = 0; i < CDNSP_ENDPOINTS_NUM; i++) { bool direction = !(i & 1); /* Start from OUT endpoint. */ u8 epnum = ((i + 1) >> 1); if (!CDNSP_IF_EP_EXIST(pdev, epnum, direction)) continue; pep = &pdev->eps[i]; pep->pdev = pdev; pep->number = epnum; pep->direction = direction; /* 0 for OUT, 1 for IN. */ /* * Ep0 is bidirectional, so ep0in and ep0out are represented by * pdev->eps[0] */ if (epnum == 0) { snprintf(pep->name, sizeof(pep->name), "ep%d%s", epnum, "BiDir"); pep->idx = 0; usb_ep_set_maxpacket_limit(&pep->endpoint, 512); pep->endpoint.maxburst = 1; pep->endpoint.ops = &cdnsp_gadget_ep0_ops; pep->endpoint.desc = &cdnsp_gadget_ep0_desc; pep->endpoint.comp_desc = NULL; pep->endpoint.caps.type_control = true; pep->endpoint.caps.dir_in = true; pep->endpoint.caps.dir_out = true; pdev->ep0_preq.epnum = pep->number; pdev->ep0_preq.pep = pep; pdev->gadget.ep0 = &pep->endpoint; } else { snprintf(pep->name, sizeof(pep->name), "ep%d%s", epnum, (pep->direction) ? "in" : "out"); pep->idx = (epnum * 2 + (direction ? 1 : 0)) - 1; usb_ep_set_maxpacket_limit(&pep->endpoint, 1024); pep->endpoint.max_streams = max_streams; pep->endpoint.ops = &cdnsp_gadget_ep_ops; list_add_tail(&pep->endpoint.ep_list, &pdev->gadget.ep_list); pep->endpoint.caps.type_iso = true; pep->endpoint.caps.type_bulk = true; pep->endpoint.caps.type_int = true; pep->endpoint.caps.dir_in = direction; pep->endpoint.caps.dir_out = !direction; } pep->endpoint.name = pep->name; pep->in_ctx = cdnsp_get_ep_ctx(&pdev->in_ctx, pep->idx); pep->out_ctx = cdnsp_get_ep_ctx(&pdev->out_ctx, pep->idx); cdnsp_get_ep_buffering(pdev, pep); dev_dbg(pdev->dev, "Init %s, MPS: %04x SupType: " "CTRL: %s, INT: %s, BULK: %s, ISOC %s, " "SupDir IN: %s, OUT: %s\n", pep->name, 1024, (pep->endpoint.caps.type_control) ? "yes" : "no", (pep->endpoint.caps.type_int) ? "yes" : "no", (pep->endpoint.caps.type_bulk) ? "yes" : "no", (pep->endpoint.caps.type_iso) ? "yes" : "no", (pep->endpoint.caps.dir_in) ? "yes" : "no", (pep->endpoint.caps.dir_out) ? "yes" : "no"); INIT_LIST_HEAD(&pep->pending_list); } return 0; } static void cdnsp_gadget_free_endpoints(struct cdnsp_device *pdev) { struct cdnsp_ep *pep; int i; for (i = 0; i < CDNSP_ENDPOINTS_NUM; i++) { pep = &pdev->eps[i]; if (pep->number != 0 && pep->out_ctx) list_del(&pep->endpoint.ep_list); } } void cdnsp_disconnect_gadget(struct cdnsp_device *pdev) { pdev->cdnsp_state |= CDNSP_STATE_DISCONNECT_PENDING; if (pdev->gadget_driver && pdev->gadget_driver->disconnect) { spin_unlock(&pdev->lock); pdev->gadget_driver->disconnect(&pdev->gadget); spin_lock(&pdev->lock); } pdev->gadget.speed = USB_SPEED_UNKNOWN; usb_gadget_set_state(&pdev->gadget, USB_STATE_NOTATTACHED); pdev->cdnsp_state &= ~CDNSP_STATE_DISCONNECT_PENDING; } void cdnsp_suspend_gadget(struct cdnsp_device *pdev) { if (pdev->gadget_driver && pdev->gadget_driver->suspend) { spin_unlock(&pdev->lock); pdev->gadget_driver->suspend(&pdev->gadget); spin_lock(&pdev->lock); } } void cdnsp_resume_gadget(struct cdnsp_device *pdev) { if (pdev->gadget_driver && pdev->gadget_driver->resume) { spin_unlock(&pdev->lock); pdev->gadget_driver->resume(&pdev->gadget); spin_lock(&pdev->lock); } } void cdnsp_irq_reset(struct cdnsp_device *pdev) { struct cdnsp_port_regs __iomem *port_regs; cdnsp_reset_device(pdev); port_regs = pdev->active_port->regs; pdev->gadget.speed = cdnsp_port_speed(readl(port_regs)); spin_unlock(&pdev->lock); usb_gadget_udc_reset(&pdev->gadget, pdev->gadget_driver); spin_lock(&pdev->lock); switch (pdev->gadget.speed) { case USB_SPEED_SUPER_PLUS: case USB_SPEED_SUPER: cdnsp_gadget_ep0_desc.wMaxPacketSize = cpu_to_le16(512); pdev->gadget.ep0->maxpacket = 512; break; case USB_SPEED_HIGH: case USB_SPEED_FULL: cdnsp_gadget_ep0_desc.wMaxPacketSize = cpu_to_le16(64); pdev->gadget.ep0->maxpacket = 64; break; default: /* Low speed is not supported. */ dev_err(pdev->dev, "Unknown device speed\n"); break; } cdnsp_clear_chicken_bits_2(pdev, CHICKEN_XDMA_2_TP_CACHE_DIS); cdnsp_setup_device(pdev, SETUP_CONTEXT_ONLY); usb_gadget_set_state(&pdev->gadget, USB_STATE_DEFAULT); } static void cdnsp_get_rev_cap(struct cdnsp_device *pdev) { void __iomem *reg = &pdev->cap_regs->hc_capbase; reg += cdnsp_find_next_ext_cap(reg, 0, RTL_REV_CAP); pdev->rev_cap = reg; dev_info(pdev->dev, "Rev: %08x/%08x, eps: %08x, buff: %08x/%08x\n", readl(&pdev->rev_cap->ctrl_revision), readl(&pdev->rev_cap->rtl_revision), readl(&pdev->rev_cap->ep_supported), readl(&pdev->rev_cap->rx_buff_size), readl(&pdev->rev_cap->tx_buff_size)); } static int cdnsp_gen_setup(struct cdnsp_device *pdev) { int ret; u32 reg; pdev->cap_regs = pdev->regs; pdev->op_regs = pdev->regs + HC_LENGTH(readl(&pdev->cap_regs->hc_capbase)); pdev->run_regs = pdev->regs + (readl(&pdev->cap_regs->run_regs_off) & RTSOFF_MASK); /* Cache read-only capability registers */ pdev->hcs_params1 = readl(&pdev->cap_regs->hcs_params1); pdev->hcc_params = readl(&pdev->cap_regs->hc_capbase); pdev->hci_version = HC_VERSION(pdev->hcc_params); pdev->hcc_params = readl(&pdev->cap_regs->hcc_params); cdnsp_get_rev_cap(pdev); /* Make sure the Device Controller is halted. */ ret = cdnsp_halt(pdev); if (ret) return ret; /* Reset the internal controller memory state and registers. */ ret = cdnsp_reset(pdev); if (ret) return ret; /* * Set dma_mask and coherent_dma_mask to 64-bits, * if controller supports 64-bit addressing. */ if (HCC_64BIT_ADDR(pdev->hcc_params) && !dma_set_mask(pdev->dev, DMA_BIT_MASK(64))) { dev_dbg(pdev->dev, "Enabling 64-bit DMA addresses.\n"); dma_set_coherent_mask(pdev->dev, DMA_BIT_MASK(64)); } else { /* * This is to avoid error in cases where a 32-bit USB * controller is used on a 64-bit capable system. */ ret = dma_set_mask(pdev->dev, DMA_BIT_MASK(32)); if (ret) return ret; dev_dbg(pdev->dev, "Enabling 32-bit DMA addresses.\n"); dma_set_coherent_mask(pdev->dev, DMA_BIT_MASK(32)); } spin_lock_init(&pdev->lock); ret = cdnsp_mem_init(pdev); if (ret) return ret; /* * Software workaround for U1: after transition * to U1 the controller starts gating clock, and in some cases, * it causes that controller stack. */ reg = readl(&pdev->port3x_regs->mode_2); reg &= ~CFG_3XPORT_U1_PIPE_CLK_GATE_EN; writel(reg, &pdev->port3x_regs->mode_2); return 0; } static int __cdnsp_gadget_init(struct cdns *cdns) { struct cdnsp_device *pdev; u32 max_speed; int ret = -ENOMEM; cdns_drd_gadget_on(cdns); pdev = kzalloc(sizeof(*pdev), GFP_KERNEL); if (!pdev) return -ENOMEM; pm_runtime_get_sync(cdns->dev); cdns->gadget_dev = pdev; pdev->dev = cdns->dev; pdev->regs = cdns->dev_regs; max_speed = usb_get_maximum_speed(cdns->dev); switch (max_speed) { case USB_SPEED_FULL: case USB_SPEED_HIGH: case USB_SPEED_SUPER: case USB_SPEED_SUPER_PLUS: break; default: dev_err(cdns->dev, "invalid speed parameter %d\n", max_speed); fallthrough; case USB_SPEED_UNKNOWN: /* Default to SSP */ max_speed = USB_SPEED_SUPER_PLUS; break; } pdev->gadget.ops = &cdnsp_gadget_ops; pdev->gadget.name = "cdnsp-gadget"; pdev->gadget.speed = USB_SPEED_UNKNOWN; pdev->gadget.sg_supported = 1; pdev->gadget.max_speed = max_speed; pdev->gadget.lpm_capable = 1; pdev->setup_buf = kzalloc(CDNSP_EP0_SETUP_SIZE, GFP_KERNEL); if (!pdev->setup_buf) goto free_pdev; /* * Controller supports not aligned buffer but it should improve * performance. */ pdev->gadget.quirk_ep_out_aligned_size = true; ret = cdnsp_gen_setup(pdev); if (ret) { dev_err(pdev->dev, "Generic initialization failed %d\n", ret); goto free_setup; } ret = cdnsp_gadget_init_endpoints(pdev); if (ret) { dev_err(pdev->dev, "failed to initialize endpoints\n"); goto halt_pdev; } ret = usb_add_gadget_udc(pdev->dev, &pdev->gadget); if (ret) { dev_err(pdev->dev, "failed to register udc\n"); goto free_endpoints; } ret = devm_request_threaded_irq(pdev->dev, cdns->dev_irq, cdnsp_irq_handler, cdnsp_thread_irq_handler, IRQF_SHARED, dev_name(pdev->dev), pdev); if (ret) goto del_gadget; return 0; del_gadget: usb_del_gadget_udc(&pdev->gadget); free_endpoints: cdnsp_gadget_free_endpoints(pdev); halt_pdev: cdnsp_halt(pdev); cdnsp_reset(pdev); cdnsp_mem_cleanup(pdev); free_setup: kfree(pdev->setup_buf); free_pdev: kfree(pdev); return ret; } static void cdnsp_gadget_exit(struct cdns *cdns) { struct cdnsp_device *pdev = cdns->gadget_dev; devm_free_irq(pdev->dev, cdns->dev_irq, pdev); pm_runtime_mark_last_busy(cdns->dev); pm_runtime_put_autosuspend(cdns->dev); usb_del_gadget_udc(&pdev->gadget); cdnsp_gadget_free_endpoints(pdev); cdnsp_mem_cleanup(pdev); kfree(pdev); cdns->gadget_dev = NULL; cdns_drd_gadget_off(cdns); } static int cdnsp_gadget_suspend(struct cdns *cdns, bool do_wakeup) { struct cdnsp_device *pdev = cdns->gadget_dev; unsigned long flags; if (pdev->link_state == XDEV_U3) return 0; spin_lock_irqsave(&pdev->lock, flags); cdnsp_disconnect_gadget(pdev); cdnsp_stop(pdev); spin_unlock_irqrestore(&pdev->lock, flags); return 0; } static int cdnsp_gadget_resume(struct cdns *cdns, bool hibernated) { struct cdnsp_device *pdev = cdns->gadget_dev; enum usb_device_speed max_speed; unsigned long flags; int ret; if (!pdev->gadget_driver) return 0; spin_lock_irqsave(&pdev->lock, flags); max_speed = pdev->gadget_driver->max_speed; /* Limit speed if necessary. */ max_speed = min(max_speed, pdev->gadget.max_speed); ret = cdnsp_run(pdev, max_speed); if (pdev->link_state == XDEV_U3) __cdnsp_gadget_wakeup(pdev); spin_unlock_irqrestore(&pdev->lock, flags); return ret; } /** * cdnsp_gadget_init - initialize device structure * @cdns: cdnsp instance * * This function initializes the gadget. */ int cdnsp_gadget_init(struct cdns *cdns) { struct cdns_role_driver *rdrv; rdrv = devm_kzalloc(cdns->dev, sizeof(*rdrv), GFP_KERNEL); if (!rdrv) return -ENOMEM; rdrv->start = __cdnsp_gadget_init; rdrv->stop = cdnsp_gadget_exit; rdrv->suspend = cdnsp_gadget_suspend; rdrv->resume = cdnsp_gadget_resume; rdrv->state = CDNS_ROLE_STATE_INACTIVE; rdrv->name = "gadget"; cdns->roles[USB_ROLE_DEVICE] = rdrv; return 0; }