// SPDX-License-Identifier: GPL-2.0-only /* * Copyright (c) 2011-2020,2021 The Linux Foundation. All rights reserved. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #define USB_THRESHOLD 512 #define USB_BAM_MAX_STR_LEN 50 #define USB_BAM_TIMEOUT (10*HZ) #define DBG_MAX_MSG 512UL #define DBG_MSG_LEN 160UL #define TIME_BUF_LEN 17 #define DBG_EVENT_LEN 143 #define ENABLE_EVENT_LOG 1 #define USB_BAM_NR_PORTS 4 #define ARRAY_INDEX_FROM_ADDR(base, addr) ((addr) - (base)) static unsigned int enable_event_log = ENABLE_EVENT_LOG; module_param(enable_event_log, uint, 0644); MODULE_PARM_DESC(enable_event_log, "enable event logging in debug buffer"); #define LOGLEVEL_NONE 8 #define LOGLEVEL_DEBUG 7 #define LOGLEVEL_ERR 3 #define log_event(log_level, x...) \ do { \ unsigned long flags; \ char *buf; \ if (log_level == LOGLEVEL_DEBUG) \ pr_debug(x); \ else if (log_level == LOGLEVEL_ERR) \ pr_err(x); \ if (enable_event_log) { \ write_lock_irqsave(&usb_bam_dbg.lck, flags); \ buf = usb_bam_dbg.buf[usb_bam_dbg.idx]; \ put_timestamp(buf); \ snprintf(&buf[TIME_BUF_LEN - 1], DBG_EVENT_LEN, x); \ usb_bam_dbg.idx = (usb_bam_dbg.idx + 1) % DBG_MAX_MSG; \ write_unlock_irqrestore(&usb_bam_dbg.lck, flags); \ } \ } while (0) #define log_event_none(x, ...) log_event(LOGLEVEL_NONE, x, ##__VA_ARGS__) #define log_event_dbg(x, ...) log_event(LOGLEVEL_DEBUG, x, ##__VA_ARGS__) #define log_event_err(x, ...) log_event(LOGLEVEL_ERR, x, ##__VA_ARGS__) /* Reset BAM with pipes connected */ #define SPS_BAM_FORCE_RESET (1UL << 11) enum usb_bam_event_type { USB_BAM_EVENT_WAKEUP_PIPE = 0, /* Wake a pipe */ USB_BAM_EVENT_WAKEUP, /* Wake a bam (first pipe waked) */ USB_BAM_EVENT_INACTIVITY, /* Inactivity on all pipes */ }; struct usb_bam_sps_type { struct sps_pipe **sps_pipes; struct sps_connect *sps_connections; }; /* * struct usb_bam_event_info: suspend/resume event information. * @type: usb bam event type. * @event: holds event data. * @callback: suspend/resume callback. * @param: port num (for suspend) or NULL (for resume). * @event_w: holds work queue parameters. */ struct usb_bam_event_info { enum usb_bam_event_type type; struct sps_register_event event; int (*callback)(void *ptr); void *param; struct work_struct event_w; }; /* * struct usb_bam_pipe_connect: pipe connection information * between USB/HSIC BAM and another BAM. USB/HSIC BAM can be * either src BAM or dst BAM * @name: pipe description. * @mem_type: type of memory used for BAM FIFOs * @src_phy_addr: src bam physical address. * @src_pipe_index: src bam pipe index. * @dst_phy_addr: dst bam physical address. * @dst_pipe_index: dst bam pipe index. * @data_fifo_base_offset: data fifo offset. * @data_fifo_size: data fifo size. * @desc_fifo_base_offset: descriptor fifo offset. * @desc_fifo_size: descriptor fifo size. * @data_mem_buf: data fifo buffer. * @desc_mem_buf: descriptor fifo buffer. * @event: event for wakeup. * @enabled: true if pipe is enabled. * @suspended: true if pipe is suspended. * @cons_stopped: true is pipe has consumer requests stopped. * @prod_stopped: true if pipe has producer requests stopped. * @priv: private data to return upon activity_notify * or inactivity_notify callbacks. * @activity_notify: callback to invoke on activity on one of the in pipes. * @inactivity_notify: callback to invoke on inactivity on all pipes. * @start: callback to invoke to enqueue transfers on a pipe. * @stop: callback to invoke on dequeue transfers on a pipe. * @start_stop_param: param for the start/stop callbacks. */ struct usb_bam_pipe_connect { const char *name; u32 pipe_num; enum usb_pipe_mem_type mem_type; enum usb_bam_pipe_dir dir; enum usb_ctrl bam_type; enum usb_bam_mode bam_mode; enum peer_bam peer_bam; enum usb_bam_pipe_type pipe_type; u32 src_phy_addr; u32 src_pipe_index; u32 dst_phy_addr; u32 dst_pipe_index; u32 data_fifo_base_offset; u32 data_fifo_size; u32 desc_fifo_base_offset; u32 desc_fifo_size; struct sps_mem_buffer data_mem_buf; struct sps_mem_buffer desc_mem_buf; struct usb_bam_event_info event; int enabled; int suspended; int cons_stopped; int prod_stopped; int ipa_clnt_hdl; void *priv; int (*activity_notify)(void *priv); int (*inactivity_notify)(void *priv); void (*start)(void *ptr, enum usb_bam_pipe_dir); void (*stop)(void *ptr, enum usb_bam_pipe_dir); void *start_stop_param; bool reset_pipe_after_lpm; }; /** * struct msm_usb_bam_data: pipe connection information * between USB/HSIC BAM and another BAM. USB/HSIC BAM can be * either src BAM or dst BAM * @usb_bam_num_pipes: max number of pipes to use. * @active_conn_num: number of active pipe connections. * @usb_bam_fifo_baseaddr: base address for bam pipe's data and descriptor * fifos. This can be on chip memory (ocimem) or usb * private memory. * @reset_on_connect: BAM must be reset before its first pipe connect * @reset_on_disconnect: BAM must be reset after its last pipe disconnect * @disable_clk_gating: Disable clock gating * @override_threshold: Override the default threshold value for Read/Write * event generation by the BAM towards another BAM. * @max_mbps_highspeed: Maximum Mbits per seconds that the USB core * can work at in bam2bam mode when connected to HS host. * @max_mbps_superspeed: Maximum Mbits per seconds that the USB core * can work at in bam2bam mode when connected to SS host. */ struct msm_usb_bam_data { u8 max_connections; int usb_bam_num_pipes; phys_addr_t usb_bam_fifo_baseaddr; bool reset_on_connect; bool reset_on_disconnect; bool disable_clk_gating; bool ignore_core_reset_ack; u32 override_threshold; u32 max_mbps_highspeed; u32 max_mbps_superspeed; enum usb_ctrl bam_type; }; /* * struct usb_bam_ctx_type - represents the usb bam driver entity * @usb_bam_sps: holds the sps pipes the usb bam driver holds * against the sps driver. * @usb_bam_pdev: the platform device that represents the usb bam. * @usb_bam_wq: Worqueue used for managing states of reset against * a peer bam. * @max_connections: The maximum number of pipes that are configured * in the platform data. * @h_bam: the handle/device of the sps driver. * @pipes_enabled_per_bam: the number of pipes currently enabled. * @inactivity_timer_ms: The timeout configuration per each bam for inactivity * timer feature. * @is_bam_inactivity: Is there no activity on all pipes belongs to a * specific bam. (no activity = no data is pulled or pushed * from/into ones of the pipes). * @usb_bam_connections: array (allocated on probe) having all BAM connections * @usb_bam_lock: to protect fields of ctx or usb_bam_connections */ struct usb_bam_ctx_type { struct usb_bam_sps_type usb_bam_sps; struct resource *io_res; int irq; struct platform_device *usb_bam_pdev; struct workqueue_struct *usb_bam_wq; u8 max_connections; unsigned long h_bam; u8 pipes_enabled_per_bam; u32 inactivity_timer_ms; bool is_bam_inactivity; struct usb_bam_pipe_connect *usb_bam_connections; struct msm_usb_bam_data *usb_bam_data; spinlock_t usb_bam_lock; }; static char *bam_enable_strings[MAX_BAMS] = { [DWC3_CTRL] = "ssusb", [CI_CTRL] = "hsusb", [HSIC_CTRL] = "hsic", }; struct usb_bam_host_info { struct device *dev; bool in_lpm; }; static struct usb_bam_host_info host_info[MAX_BAMS]; /* * CI_CTRL & DWC3_CTRL shouldn't be used simultaneously * since both share the same prod & cons rm resourses */ static enum ipa_rm_resource_name ipa_rm_resource_prod[MAX_BAMS] = { [CI_CTRL] = IPA_RM_RESOURCE_USB_PROD, [DWC3_CTRL] = IPA_RM_RESOURCE_USB_PROD, }; static enum ipa_rm_resource_name ipa_rm_resource_cons[MAX_BAMS] = { [CI_CTRL] = IPA_RM_RESOURCE_USB_CONS, [DWC3_CTRL] = IPA_RM_RESOURCE_USB_CONS, }; static int usb_cons_request_resource(void); static int usb_cons_release_resource(void); static int ss_usb_cons_request_resource(void); static int ss_usb_cons_release_resource(void); static int (*request_resource_cb[MAX_BAMS])(void) = { [CI_CTRL] = usb_cons_request_resource, [DWC3_CTRL] = ss_usb_cons_request_resource, }; static int (*release_resource_cb[MAX_BAMS])(void) = { [CI_CTRL] = usb_cons_release_resource, [DWC3_CTRL] = ss_usb_cons_release_resource, }; struct usb_bam_ipa_handshake_info { enum ipa_rm_event cur_prod_state; enum ipa_rm_event cur_cons_state; enum usb_bam_mode cur_bam_mode; enum usb_ctrl bam_type; int connect_complete; int bus_suspend; int disconnected; bool in_lpm; u8 prod_pipes_enabled_per_bam; int (*wake_cb)(void *wcb); void *wake_param; u32 suspend_src_idx[USB_BAM_NR_PORTS]; u32 suspend_dst_idx[USB_BAM_NR_PORTS]; u32 resume_src_idx[USB_BAM_NR_PORTS]; u32 resume_dst_idx[USB_BAM_NR_PORTS]; u32 pipes_to_suspend; u32 pipes_suspended; u32 pipes_resumed; struct completion prod_avail; struct completion prod_released; struct mutex suspend_resume_mutex; struct work_struct resume_work; struct work_struct finish_suspend_work; }; static spinlock_t usb_bam_ipa_handshake_info_lock; static struct usb_bam_ipa_handshake_info info[MAX_BAMS]; static struct usb_bam_ctx_type msm_usb_bam[MAX_BAMS]; /* USB bam type used as a peer of the qdss in bam2bam mode */ static enum usb_ctrl qdss_usb_bam_type; static int __usb_bam_register_wake_cb(enum usb_ctrl bam_type, int idx, int (*callback)(void *user), void *param, bool trigger_cb_per_pipe); static void wait_for_prod_release(enum usb_ctrl cur_bam); static void usb_bam_start_suspend(struct usb_bam_ipa_handshake_info *info_ptr); static struct { char buf[DBG_MAX_MSG][DBG_MSG_LEN]; /* buffer */ unsigned int idx; /* index */ rwlock_t lck; /* lock */ } __maybe_unused usb_bam_dbg = { .idx = 0, .lck = __RW_LOCK_UNLOCKED(lck) }; /*put_timestamp - writes time stamp to buffer */ static void __maybe_unused put_timestamp(char *tbuf) { unsigned long long t; unsigned long nanosec_rem; t = cpu_clock(smp_processor_id()); nanosec_rem = do_div(t, 1000000000)/1000; snprintf(tbuf, TIME_BUF_LEN, "[%5lu.%06lu]: ", (unsigned long)t, nanosec_rem); } void msm_bam_set_hsic_host_dev(struct device *dev) { if (dev) { /* Hold the device until allowing lpm */ log_event_dbg("%s: Getting hsic device %pK\n", __func__, dev); pm_runtime_get(dev); } else if (host_info[HSIC_CTRL].dev) { log_event_dbg("%s: Try Putting hsic device %pK, lpm:%d\n", __func__, host_info[HSIC_CTRL].dev, host_info[HSIC_CTRL].in_lpm); /* Just release previous device if not already done */ if (!host_info[HSIC_CTRL].in_lpm) { host_info[HSIC_CTRL].in_lpm = true; pm_runtime_put(host_info[HSIC_CTRL].dev); } } host_info[HSIC_CTRL].dev = dev; host_info[HSIC_CTRL].in_lpm = false; } static void usb_bam_set_inactivity_timer(enum usb_ctrl bam) { struct sps_timer_ctrl timer_ctrl; struct usb_bam_pipe_connect *pipe_connect; struct sps_pipe *pipe = NULL; struct usb_bam_ctx_type *ctx = &msm_usb_bam[bam]; int i; log_event_dbg("%s: enter\n", __func__); /* * Since we configure global incativity timer for all pipes * and not per each pipe, it is enough to use some pipe * handle associated with this bam, so just find the first one. * This pipe handle is required due to SPS driver API we use below. */ for (i = 0; i < ctx->max_connections; i++) { pipe_connect = &ctx->usb_bam_connections[i]; if (pipe_connect->bam_type == bam && pipe_connect->enabled) { pipe = ctx->usb_bam_sps.sps_pipes[i]; break; } } if (!pipe) { pr_warn("%s: Bam has no connected pipes\n", __func__); return; } timer_ctrl.op = SPS_TIMER_OP_CONFIG; timer_ctrl.mode = SPS_TIMER_MODE_ONESHOT; timer_ctrl.timeout_msec = ctx->inactivity_timer_ms; sps_timer_ctrl(pipe, &timer_ctrl, NULL); timer_ctrl.op = SPS_TIMER_OP_RESET; sps_timer_ctrl(pipe, &timer_ctrl, NULL); } void msm_bam_set_usb_host_dev(struct device *dev) { host_info[CI_CTRL].dev = dev; host_info[CI_CTRL].in_lpm = false; } static void _msm_bam_host_notify_on_resume(enum usb_ctrl bam_type) { struct usb_bam_ctx_type *ctx = &msm_usb_bam[bam_type]; spin_lock(&ctx->usb_bam_lock); log_event_dbg("%s: enter bam=%s\n", __func__, bam_enable_strings[bam_type]); host_info[bam_type].in_lpm = false; /* * This function is called to notify the usb bam driver * that the hsic core and hsic bam hw are fully resumed * and clocked on. Therefore we can now set the inactivity * timer to the hsic bam hw. */ if (ctx->inactivity_timer_ms) usb_bam_set_inactivity_timer(bam_type); spin_unlock(&ctx->usb_bam_lock); } /** * msm_bam_hsic_host_pipe_empty - Check all HSIC host BAM pipe state * * return true if all BAM pipe used for HSIC Host mode is empty. */ bool msm_bam_hsic_host_pipe_empty(void) { struct usb_bam_pipe_connect *pipe_connect; struct sps_pipe *pipe = NULL; enum usb_ctrl bam = HSIC_CTRL; struct usb_bam_ctx_type *ctx = &msm_usb_bam[bam]; int i, ret; u32 status; log_event_dbg("%s: enter\n", __func__); for (i = 0; i < ctx->max_connections; i++) { pipe_connect = &ctx->usb_bam_connections[i]; if (pipe_connect->enabled) { pipe = ctx->usb_bam_sps.sps_pipes[i]; ret = sps_is_pipe_empty(pipe, &status); if (ret) { log_event_err("%s(): sps_is_pipe_empty() failed\n", __func__); log_event_err("%s(): SRC index(%d), DEST index(%d):\n", __func__, pipe_connect->src_pipe_index, pipe_connect->dst_pipe_index); WARN_ON(1); } if (!status) { log_event_err("%s(): pipe is not empty.\n", __func__); log_event_err("%s(): SRC index(%d), DEST index(%d):\n", __func__, pipe_connect->src_pipe_index, pipe_connect->dst_pipe_index); return false; } log_event_dbg("%s(): SRC index(%d), DEST index(%d):\n", __func__, pipe_connect->src_pipe_index, pipe_connect->dst_pipe_index); } } if (!pipe) log_event_err("%s: Bam %s has no connected pipes\n", __func__, bam_enable_strings[bam]); return true; } EXPORT_SYMBOL(msm_bam_hsic_host_pipe_empty); static bool msm_bam_host_lpm_ok(enum usb_ctrl bam_type) { struct usb_bam_ctx_type *ctx = &msm_usb_bam[bam_type]; struct usb_bam_pipe_connect *pipe_iter; int i; log_event_dbg("%s: enter bam=%s\n", __func__, bam_enable_strings[bam_type]); if (!host_info[bam_type].dev) return true; log_event_dbg("%s: Starting hsic full suspend sequence\n", __func__); log_event_dbg("%s(): checking HSIC Host pipe state\n", __func__); if (!msm_bam_hsic_host_pipe_empty()) { log_event_err("%s(): HSIC HOST Pipe is not empty\n", __func__); return false; } /* HSIC host will go now to lpm */ log_event_dbg("%s: vote for suspend hsic %pK\n", __func__, host_info[bam_type].dev); for (i = 0; i < ctx->max_connections; i++) { pipe_iter = &ctx->usb_bam_connections[i]; if (pipe_iter->bam_type == bam_type && pipe_iter->enabled && !pipe_iter->suspended) pipe_iter->suspended = true; } host_info[bam_type].in_lpm = true; return true; } bool msm_bam_hsic_lpm_ok(void) { log_event_dbg("%s: enter\n", __func__); return msm_bam_host_lpm_ok(HSIC_CTRL); } EXPORT_SYMBOL(msm_bam_hsic_lpm_ok); void msm_bam_hsic_host_notify_on_resume(void) { _msm_bam_host_notify_on_resume(HSIC_CTRL); } static inline enum usb_ctrl get_bam_type_from_core_name(const char *name) { if (strnstr(name, bam_enable_strings[DWC3_CTRL], USB_BAM_MAX_STR_LEN) || strnstr(name, "dwc3", USB_BAM_MAX_STR_LEN)) return DWC3_CTRL; else if (strnstr(name, bam_enable_strings[HSIC_CTRL], USB_BAM_MAX_STR_LEN) || strnstr(name, "ci13xxx_msm_hsic", USB_BAM_MAX_STR_LEN)) return HSIC_CTRL; else if (strnstr(name, bam_enable_strings[CI_CTRL], USB_BAM_MAX_STR_LEN) || strnstr(name, "ci", USB_BAM_MAX_STR_LEN)) return CI_CTRL; log_event_err("%s: invalid BAM name(%s)\n", __func__, name); return -EINVAL; } static int usb_bam_alloc_buffer(struct usb_bam_pipe_connect *pipe_connect) { int ret = 0; struct usb_bam_ctx_type *ctx = &msm_usb_bam[pipe_connect->bam_type]; struct sps_mem_buffer *data_buf = &(pipe_connect->data_mem_buf); struct sps_mem_buffer *desc_buf = &(pipe_connect->desc_mem_buf); struct device *dev = &ctx->usb_bam_pdev->dev; struct sg_table data_sgt, desc_sgt; dma_addr_t data_iova, desc_iova; log_event_dbg("%s: data_fifo size:%x desc_fifo_size:%x\n", __func__, pipe_connect->data_fifo_size, pipe_connect->desc_fifo_size); if (dev->parent) dev = dev->parent; switch (pipe_connect->mem_type) { case SPS_PIPE_MEM: log_event_dbg("%s: USB BAM using SPS pipe memory\n", __func__); ret = sps_setup_bam2bam_fifo(data_buf, pipe_connect->data_fifo_base_offset, pipe_connect->data_fifo_size, 1); if (ret) { log_event_err("%s: data fifo setup failure %d\n", __func__, ret); goto err_exit; } ret = sps_setup_bam2bam_fifo(desc_buf, pipe_connect->desc_fifo_base_offset, pipe_connect->desc_fifo_size, 1); if (ret) { log_event_err("%s: desc. fifo setup failure %d\n", __func__, ret); goto err_exit; } break; case OCI_MEM: if (pipe_connect->mem_type == OCI_MEM) log_event_dbg("%s: USB BAM using ocimem\n", __func__); if (data_buf->base) { log_event_err("%s: Already allocated OCI Memory\n", __func__); break; } data_buf->phys_base = pipe_connect->data_fifo_base_offset + ctx->usb_bam_data->usb_bam_fifo_baseaddr; data_buf->size = pipe_connect->data_fifo_size; data_buf->base = ioremap(data_buf->phys_base, data_buf->size); if (!data_buf->base) { log_event_err("%s: ioremap failed for data fifo\n", __func__); ret = -ENOMEM; goto err_exit; } memset_io(data_buf->base, 0, data_buf->size); data_buf->iova = dma_map_resource(dev, data_buf->phys_base, data_buf->size, DMA_BIDIRECTIONAL, 0); if (dma_mapping_error(dev, data_buf->iova)) log_event_err("%s(): oci_mem: err mapping data_buf\n", __func__); log_event_dbg("%s: data_buf:%s virt:%pK, phys:%lx, iova:%lx\n", __func__, dev_name(dev), data_buf->base, (unsigned long)data_buf->phys_base, data_buf->iova); desc_buf->phys_base = pipe_connect->desc_fifo_base_offset + ctx->usb_bam_data->usb_bam_fifo_baseaddr; desc_buf->size = pipe_connect->desc_fifo_size; desc_buf->base = ioremap(desc_buf->phys_base, desc_buf->size); if (!desc_buf->base) { log_event_err("%s: ioremap failed for desc fifo\n", __func__); iounmap(data_buf->base); ret = -ENOMEM; goto err_exit; } memset_io(desc_buf->base, 0, desc_buf->size); desc_buf->iova = dma_map_resource(dev, desc_buf->phys_base, desc_buf->size, DMA_BIDIRECTIONAL, 0); if (dma_mapping_error(dev, desc_buf->iova)) log_event_err("%s(): oci_mem: err mapping desc_buf\n", __func__); log_event_dbg("%s: desc_buf:%s virt:%pK, phys:%lx, iova:%lx\n", __func__, dev_name(dev), desc_buf->base, (unsigned long)desc_buf->phys_base, desc_buf->iova); break; case SYSTEM_MEM: log_event_dbg("%s: USB BAM using system memory\n", __func__); if (data_buf->base) { log_event_err("%s: Already allocated memory\n", __func__); break; } /* BAM would use system memory, allocate FIFOs */ data_buf->size = pipe_connect->data_fifo_size; data_buf->base = dma_alloc_attrs(dev, pipe_connect->data_fifo_size, &data_iova, GFP_KERNEL, DMA_ATTR_FORCE_CONTIGUOUS); if (!data_buf->base) { log_event_err("%s: data_fifo: dma_alloc_attr failed\n", __func__); ret = -ENOMEM; goto err_exit; } memset(data_buf->base, 0, pipe_connect->data_fifo_size); data_buf->iova = data_iova; dma_get_sgtable(dev, &data_sgt, data_buf->base, data_buf->iova, pipe_connect->data_fifo_size); data_buf->phys_base = page_to_phys(sg_page(data_sgt.sgl)); sg_free_table(&data_sgt); log_event_dbg("%s: data_buf:%s virt:%pK, phys:%lx, iova:%lx\n", __func__, dev_name(dev), data_buf->base, (unsigned long)data_buf->phys_base, data_buf->iova); desc_buf->size = pipe_connect->desc_fifo_size; desc_buf->base = dma_alloc_attrs(dev, pipe_connect->desc_fifo_size, &desc_iova, GFP_KERNEL, DMA_ATTR_FORCE_CONTIGUOUS); if (!desc_buf->base) { log_event_err("%s: desc_fifo: dma_alloc_attr failed\n", __func__); dma_free_attrs(dev, pipe_connect->data_fifo_size, data_buf->base, data_buf->iova, DMA_ATTR_FORCE_CONTIGUOUS); ret = -ENOMEM; goto err_exit; } memset(desc_buf->base, 0, pipe_connect->desc_fifo_size); desc_buf->iova = desc_iova; dma_get_sgtable(dev, &desc_sgt, desc_buf->base, desc_buf->iova, desc_buf->size); desc_buf->phys_base = page_to_phys(sg_page(desc_sgt.sgl)); sg_free_table(&desc_sgt); log_event_dbg("%s: desc_buf:%s virt:%pK, phys:%lx, iova:%lx\n", __func__, dev_name(dev), desc_buf->base, (unsigned long)desc_buf->phys_base, desc_buf->iova); break; default: log_event_err("%s: invalid mem type\n", __func__); ret = -EINVAL; } return ret; err_exit: return ret; } int usb_bam_alloc_fifos(enum usb_ctrl cur_bam, u8 idx) { int ret; struct usb_bam_ctx_type *ctx = &msm_usb_bam[cur_bam]; struct usb_bam_pipe_connect *pipe_connect = &ctx->usb_bam_connections[idx]; ret = usb_bam_alloc_buffer(pipe_connect); if (ret) { log_event_err("%s(): Error(%d) allocating buffer\n", __func__, ret); return ret; } return 0; } EXPORT_SYMBOL_GPL(usb_bam_alloc_fifos); int usb_bam_free_fifos(enum usb_ctrl cur_bam, u8 idx) { struct usb_bam_ctx_type *ctx = &msm_usb_bam[cur_bam]; struct usb_bam_pipe_connect *pipe_connect = &ctx->usb_bam_connections[idx]; struct sps_connect *sps_connection = &ctx->usb_bam_sps.sps_connections[idx]; struct device *dev = &ctx->usb_bam_pdev->dev; u32 data_fifo_size; log_event_dbg("%s(): data size:%x desc size:%x\n", __func__, sps_connection->data.size, sps_connection->desc.size); if (dev->parent) dev = dev->parent; switch (pipe_connect->mem_type) { case SYSTEM_MEM: log_event_dbg("%s: Freeing system memory used by PIPE\n", __func__); if (sps_connection->data.iova) { data_fifo_size = sps_connection->data.size; dma_free_attrs(dev, data_fifo_size, sps_connection->data.base, sps_connection->data.iova, DMA_ATTR_FORCE_CONTIGUOUS); sps_connection->data.iova = 0; sps_connection->data.phys_base = 0; pipe_connect->data_mem_buf.base = NULL; } if (sps_connection->desc.iova) { dma_free_attrs(dev, sps_connection->desc.size, sps_connection->desc.base, sps_connection->desc.iova, DMA_ATTR_FORCE_CONTIGUOUS); sps_connection->desc.iova = 0; sps_connection->desc.phys_base = 0; pipe_connect->desc_mem_buf.base = NULL; } break; case OCI_MEM: log_event_dbg("Freeing oci memory used by BAM PIPE\n"); if (sps_connection->data.base) { if (sps_connection->data.iova) { dma_unmap_resource(dev, sps_connection->data.iova, sps_connection->data.size, DMA_BIDIRECTIONAL, 0); sps_connection->data.iova = 0; } iounmap(sps_connection->data.base); sps_connection->data.base = NULL; pipe_connect->data_mem_buf.base = NULL; } if (sps_connection->desc.base) { if (sps_connection->desc.iova) { dma_unmap_resource(dev, sps_connection->desc.iova, sps_connection->desc.size, DMA_BIDIRECTIONAL, 0); sps_connection->desc.iova = 0; } iounmap(sps_connection->desc.base); sps_connection->desc.base = NULL; pipe_connect->desc_mem_buf.base = NULL; } break; case SPS_PIPE_MEM: log_event_dbg("%s: nothing to be be\n", __func__); break; } return 0; } static int connect_pipe(enum usb_ctrl cur_bam, u8 idx, u32 *usb_pipe_idx, unsigned long iova) { int ret; struct usb_bam_ctx_type *ctx = &msm_usb_bam[cur_bam]; struct usb_bam_sps_type usb_bam_sps = ctx->usb_bam_sps; struct sps_pipe **pipe = &(usb_bam_sps.sps_pipes[idx]); struct sps_connect *sps_connection = &usb_bam_sps.sps_connections[idx]; struct usb_bam_pipe_connect *pipe_connect = &ctx->usb_bam_connections[idx]; enum usb_bam_pipe_dir dir = pipe_connect->dir; struct sps_mem_buffer *data_buf = &(pipe_connect->data_mem_buf); struct sps_mem_buffer *desc_buf = &(pipe_connect->desc_mem_buf); *pipe = sps_alloc_endpoint(); if (*pipe == NULL) { log_event_err("%s: sps_alloc_endpoint failed\n", __func__); return -ENOMEM; } ret = sps_get_config(*pipe, sps_connection); if (ret) { log_event_err("%s: tx get config failed %d\n", __func__, ret); goto free_sps_endpoint; } ret = sps_phy2h(pipe_connect->src_phy_addr, &(sps_connection->source)); if (ret) { log_event_err("%s: sps_phy2h failed (src BAM) %d\n", __func__, ret); goto free_sps_endpoint; } sps_connection->src_pipe_index = pipe_connect->src_pipe_index; ret = sps_phy2h(pipe_connect->dst_phy_addr, &(sps_connection->destination)); if (ret) { log_event_err("%s: sps_phy2h failed (dst BAM) %d\n", __func__, ret); goto free_sps_endpoint; } sps_connection->dest_pipe_index = pipe_connect->dst_pipe_index; if (dir == USB_TO_PEER_PERIPHERAL) { sps_connection->mode = SPS_MODE_SRC; *usb_pipe_idx = pipe_connect->src_pipe_index; sps_connection->dest_iova = iova; } else { sps_connection->mode = SPS_MODE_DEST; *usb_pipe_idx = pipe_connect->dst_pipe_index; sps_connection->source_iova = iova; } sps_connection->data = *data_buf; sps_connection->desc = *desc_buf; sps_connection->event_thresh = 16; sps_connection->options = SPS_O_AUTO_ENABLE; ret = sps_connect(*pipe, sps_connection); if (ret < 0) { log_event_err("%s: sps_connect failed %d\n", __func__, ret); goto error; } return 0; error: sps_disconnect(*pipe); free_sps_endpoint: sps_free_endpoint(*pipe); *pipe = NULL; return ret; } static int connect_pipe_sys2bam_ipa(enum usb_ctrl cur_bam, u8 idx, struct usb_bam_connect_ipa_params *ipa_params) { int ret; enum usb_bam_pipe_dir dir = ipa_params->dir; struct usb_bam_ctx_type *ctx = &msm_usb_bam[cur_bam]; struct usb_bam_pipe_connect *pipe_connect = &ctx->usb_bam_connections[idx]; struct ipa_sys_connect_params sys_in_params; unsigned long usb_handle; phys_addr_t usb_phy_addr; u32 clnt_hdl = 0; memset(&sys_in_params, 0, sizeof(sys_in_params)); if (dir == USB_TO_PEER_PERIPHERAL) { usb_phy_addr = pipe_connect->src_phy_addr; sys_in_params.client = ipa_params->src_client; ipa_params->ipa_cons_ep_idx = ipa_get_ep_mapping(sys_in_params.client); } else { usb_phy_addr = pipe_connect->dst_phy_addr; sys_in_params.client = ipa_params->dst_client; ipa_params->ipa_prod_ep_idx = ipa_get_ep_mapping(sys_in_params.client); } log_event_dbg("%s(): ipa_prod_ep_idx:%d ipa_cons_ep_idx:%d\n", __func__, ipa_params->ipa_prod_ep_idx, ipa_params->ipa_cons_ep_idx); /* Get HSUSB / HSIC bam handle */ ret = sps_phy2h(usb_phy_addr, &usb_handle); if (ret) { log_event_err("%s: sps_phy2h failed (HSUSB/HSIC BAM) %d\n", __func__, ret); return ret; } pipe_connect->activity_notify = ipa_params->activity_notify; pipe_connect->inactivity_notify = ipa_params->inactivity_notify; pipe_connect->priv = ipa_params->priv; /* IPA sys connection params */ sys_in_params.desc_fifo_sz = pipe_connect->desc_fifo_size; sys_in_params.priv = ipa_params->priv; sys_in_params.notify = ipa_params->notify; sys_in_params.skip_ep_cfg = ipa_params->skip_ep_cfg; sys_in_params.keep_ipa_awake = ipa_params->keep_ipa_awake; memcpy(&sys_in_params.ipa_ep_cfg, &ipa_params->ipa_ep_cfg, sizeof(struct ipa_ep_cfg)); ret = ipa_setup_sys_pipe(&sys_in_params, &clnt_hdl); if (ret) { log_event_err("%s: ipa_connect failed\n", __func__); return ret; } pipe_connect->ipa_clnt_hdl = clnt_hdl; if (dir == USB_TO_PEER_PERIPHERAL) ipa_params->cons_clnt_hdl = clnt_hdl; else ipa_params->prod_clnt_hdl = clnt_hdl; return 0; } static int connect_pipe_bam2bam_ipa(enum usb_ctrl cur_bam, u8 idx, struct usb_bam_connect_ipa_params *ipa_params) { int ret; struct usb_bam_ctx_type *ctx = &msm_usb_bam[cur_bam]; struct usb_bam_sps_type usb_bam_sps = ctx->usb_bam_sps; enum usb_bam_pipe_dir dir = ipa_params->dir; struct sps_pipe **pipe = &(usb_bam_sps.sps_pipes[idx]); struct sps_connect *sps_connection = &usb_bam_sps.sps_connections[idx]; struct usb_bam_pipe_connect *pipe_connect = &ctx->usb_bam_connections[idx]; struct sps_mem_buffer *data_buf = &(pipe_connect->data_mem_buf); struct sps_mem_buffer *desc_buf = &(pipe_connect->desc_mem_buf); struct ipa_connect_params ipa_in_params; struct ipa_sps_params sps_out_params; u32 usb_phy_addr; unsigned long usb_handle; u32 clnt_hdl = 0; memset(&ipa_in_params, 0, sizeof(ipa_in_params)); memset(&sps_out_params, 0, sizeof(sps_out_params)); if (dir == USB_TO_PEER_PERIPHERAL) { usb_phy_addr = pipe_connect->src_phy_addr; ipa_in_params.client_ep_idx = pipe_connect->src_pipe_index; ipa_in_params.client = ipa_params->src_client; } else { usb_phy_addr = pipe_connect->dst_phy_addr; ipa_in_params.client_ep_idx = pipe_connect->dst_pipe_index; ipa_in_params.client = ipa_params->dst_client; } /* Get HSUSB / HSIC bam handle */ ret = sps_phy2h(usb_phy_addr, &usb_handle); if (ret) { log_event_err("%s: sps_phy2h failed (HSUSB/HSIC BAM) %d\n", __func__, ret); return ret; } pipe_connect->activity_notify = ipa_params->activity_notify; pipe_connect->inactivity_notify = ipa_params->inactivity_notify; pipe_connect->priv = ipa_params->priv; pipe_connect->reset_pipe_after_lpm = ipa_params->reset_pipe_after_lpm; /* IPA input parameters */ ipa_in_params.client_bam_hdl = usb_handle; ipa_in_params.desc_fifo_sz = pipe_connect->desc_fifo_size; ipa_in_params.data_fifo_sz = pipe_connect->data_fifo_size; ipa_in_params.notify = ipa_params->notify; ipa_in_params.priv = ipa_params->priv; ipa_in_params.skip_ep_cfg = ipa_params->skip_ep_cfg; ipa_in_params.keep_ipa_awake = ipa_params->keep_ipa_awake; ipa_in_params.desc = pipe_connect->desc_mem_buf; ipa_in_params.data = pipe_connect->data_mem_buf; memcpy(&ipa_in_params.ipa_ep_cfg, &ipa_params->ipa_ep_cfg, sizeof(struct ipa_ep_cfg)); ret = ipa_connect(&ipa_in_params, &sps_out_params, &clnt_hdl); if (ret) { log_event_err("%s: ipa_connect failed\n", __func__); return ret; } pipe_connect->ipa_clnt_hdl = clnt_hdl; *pipe = sps_alloc_endpoint(); if (*pipe == NULL) { log_event_err("%s: sps_alloc_endpoint failed\n", __func__); ret = -ENOMEM; goto disconnect_ipa; } ret = sps_get_config(*pipe, sps_connection); if (ret) { log_event_err("%s: tx get config failed %d\n", __func__, ret); goto free_sps_endpoints; } if (dir == USB_TO_PEER_PERIPHERAL) { /* USB src IPA dest */ sps_connection->mode = SPS_MODE_SRC; ipa_params->cons_clnt_hdl = clnt_hdl; sps_connection->source = usb_handle; sps_connection->destination = sps_out_params.ipa_bam_hdl; sps_connection->src_pipe_index = pipe_connect->src_pipe_index; sps_connection->dest_pipe_index = sps_out_params.ipa_ep_idx; ipa_params->ipa_cons_ep_idx = sps_out_params.ipa_ep_idx; *(ipa_params->src_pipe) = sps_connection->src_pipe_index; pipe_connect->dst_pipe_index = sps_out_params.ipa_ep_idx; log_event_dbg("%s: BAM pipe usb[%x]->ipa[%x] connection\n", __func__, pipe_connect->src_pipe_index, pipe_connect->dst_pipe_index); sps_connection->options = SPS_O_NO_DISABLE; } else { /* IPA src, USB dest */ sps_connection->mode = SPS_MODE_DEST; ipa_params->prod_clnt_hdl = clnt_hdl; sps_connection->source = sps_out_params.ipa_bam_hdl; sps_connection->destination = usb_handle; sps_connection->src_pipe_index = sps_out_params.ipa_ep_idx; ipa_params->ipa_prod_ep_idx = sps_out_params.ipa_ep_idx; sps_connection->dest_pipe_index = pipe_connect->dst_pipe_index; *(ipa_params->dst_pipe) = sps_connection->dest_pipe_index; pipe_connect->src_pipe_index = sps_out_params.ipa_ep_idx; log_event_dbg("%s: BAM pipe ipa[%x]->usb[%x] connection\n", __func__, pipe_connect->src_pipe_index, pipe_connect->dst_pipe_index); sps_connection->options = 0; } sps_connection->data = *data_buf; sps_connection->desc = *desc_buf; sps_connection->event_thresh = 16; sps_connection->options |= SPS_O_AUTO_ENABLE; ret = sps_connect(*pipe, sps_connection); if (ret < 0) { log_event_err("%s: sps_connect failed %d\n", __func__, ret); goto error; } return 0; error: sps_disconnect(*pipe); free_sps_endpoints: sps_free_endpoint(*pipe); disconnect_ipa: ipa_disconnect(clnt_hdl); return ret; } static int disconnect_pipe(enum usb_ctrl cur_bam, u8 idx) { struct usb_bam_ctx_type *ctx = &msm_usb_bam[cur_bam]; struct sps_pipe *pipe = ctx->usb_bam_sps.sps_pipes[idx]; struct sps_connect *sps_connection = &ctx->usb_bam_sps.sps_connections[idx]; sps_disconnect(pipe); sps_free_endpoint(pipe); ctx->usb_bam_sps.sps_pipes[idx] = NULL; sps_connection->options &= ~SPS_O_AUTO_ENABLE; return 0; } static void usb_bam_suspend_core(enum usb_ctrl bam_type, enum usb_bam_mode bam_mode, bool disconnect) { log_event_dbg("%s: enter bam=%s\n", __func__, bam_enable_strings[bam_type]); if ((bam_mode == USB_BAM_DEVICE) || (bam_type != HSIC_CTRL)) { log_event_err("%s: Invalid BAM type %d\n", __func__, bam_type); return; } } /** * usb_bam_disconnect_ipa_prod() - disconnects USB consumer(i.e. IPA producer) * @ipa_params: USB IPA related parameters * @cur_bam: USB controller used for BAM functionality * * It performs disconnect with IPA driver for IPA producer pipe and * with SPS driver for USB BAM consumer pipe. This API also takes care * of SYS2BAM and BAM2BAM IPA disconnect functionality. * * Return: 0 in case of success, errno otherwise. */ static int usb_bam_disconnect_ipa_prod( struct usb_bam_connect_ipa_params *ipa_params, enum usb_ctrl cur_bam) { int ret; u8 idx = 0; struct usb_bam_pipe_connect *pipe_connect; struct usb_bam_ctx_type *ctx = &msm_usb_bam[cur_bam]; idx = ipa_params->dst_idx; pipe_connect = &ctx->usb_bam_connections[idx]; pipe_connect->activity_notify = NULL; pipe_connect->inactivity_notify = NULL; pipe_connect->priv = NULL; /* close IPA -> USB pipe */ if (pipe_connect->pipe_type == USB_BAM_PIPE_BAM2BAM) { ret = ipa_disconnect(ipa_params->prod_clnt_hdl); if (ret) { log_event_err("%s: dst pipe disconnection failure\n", __func__); return ret; } ret = usb_bam_disconnect_pipe(cur_bam, idx); if (ret) { log_event_err("%s: failure to disconnect pipe %d\n", __func__, idx); return ret; } } else { ret = ipa_teardown_sys_pipe(ipa_params->prod_clnt_hdl); if (ret) { log_event_err("%s: dst pipe disconnection failure\n", __func__); return ret; } pipe_connect->enabled = false; spin_lock(&ctx->usb_bam_lock); if (ctx->pipes_enabled_per_bam == 0) log_event_err("%s: wrong pipes enabled counter for bam=%d\n", __func__, pipe_connect->bam_type); else ctx->pipes_enabled_per_bam -= 1; spin_unlock(&ctx->usb_bam_lock); } return 0; } /** * usb_bam_disconnect_ipa_cons() - disconnects USB producer(i.e. IPA consumer) * @ipa_params: USB IPA related parameters * @cur_bam: USB controller used for BAM functionality * * It performs disconnect with IPA driver for IPA consumer pipe and * with SPS driver for USB BAM producer pipe. This API also takes care * of SYS2BAM and BAM2BAM IPA disconnect functionality. * * Return: 0 in case of success, errno otherwise. */ static int usb_bam_disconnect_ipa_cons( struct usb_bam_connect_ipa_params *ipa_params, enum usb_ctrl cur_bam) { int ret; u8 idx = 0; struct usb_bam_ctx_type *ctx = &msm_usb_bam[cur_bam]; struct usb_bam_pipe_connect *pipe_connect; struct sps_pipe *pipe; u32 timeout = 10, pipe_empty; struct usb_bam_sps_type usb_bam_sps = ctx->usb_bam_sps; struct sps_connect *sps_connection; bool inject_zlt = true; idx = ipa_params->src_idx; pipe = ctx->usb_bam_sps.sps_pipes[idx]; pipe_connect = &ctx->usb_bam_connections[idx]; sps_connection = &usb_bam_sps.sps_connections[idx]; pipe_connect->activity_notify = NULL; pipe_connect->inactivity_notify = NULL; pipe_connect->priv = NULL; /* * On some platforms, there is a chance that flow control * is disabled from IPA side, due to this IPA core may not * consume data from USB. Hence notify IPA to enable flow * control and then check sps pipe is empty or not before * processing USB->IPA pipes disconnect. */ ipa_clear_endpoint_delay(ipa_params->cons_clnt_hdl); retry: /* Make sure pipe is empty before disconnecting it */ while (1) { ret = sps_is_pipe_empty(pipe, &pipe_empty); if (ret) { log_event_err("%s: sps_is_pipe_empty failed with %d\n", __func__, ret); return ret; } if (pipe_empty || !--timeout) break; /* Check again */ usleep_range(1000, 2000); } if (!pipe_empty) { if (inject_zlt) { log_event_dbg("%s: Inject ZLT\n", __func__); inject_zlt = false; sps_pipe_inject_zlt(sps_connection->destination, sps_connection->dest_pipe_index); timeout = 10; goto retry; } log_event_err("%s: src pipe(USB) not empty, wait timed out!\n", __func__); sps_get_bam_debug_info(ctx->h_bam, 93, (SPS_BAM_PIPE(0) | SPS_BAM_PIPE(1)), 0, 2); ipa_bam_reg_dump(); panic("%s:SPS pipe not empty for USB->IPA\n", __func__); } /* Do the release handshake with the IPA via RM */ spin_lock(&usb_bam_ipa_handshake_info_lock); info[cur_bam].connect_complete = 0; info[cur_bam].disconnected = 1; spin_unlock(&usb_bam_ipa_handshake_info_lock); /* Start release handshake on the last USB BAM producer pipe */ if (info[cur_bam].prod_pipes_enabled_per_bam == 1) wait_for_prod_release(cur_bam); /* close USB -> IPA pipe */ if (pipe_connect->pipe_type == USB_BAM_PIPE_BAM2BAM) { ret = ipa_disconnect(ipa_params->cons_clnt_hdl); if (ret) { log_event_err("%s: src pipe disconnection failure\n", __func__); return ret; } ret = usb_bam_disconnect_pipe(cur_bam, idx); if (ret) { log_event_err("%s: failure to disconnect pipe %d\n", __func__, idx); return ret; } } else { ret = ipa_teardown_sys_pipe(ipa_params->cons_clnt_hdl); if (ret) { log_event_err("%s: src pipe disconnection failure\n", __func__); return ret; } pipe_connect->enabled = false; spin_lock(&ctx->usb_bam_lock); if (ctx->pipes_enabled_per_bam == 0) log_event_err("%s: wrong pipes enabled counter for bam=%d\n", __func__, pipe_connect->bam_type); else ctx->pipes_enabled_per_bam -= 1; spin_unlock(&ctx->usb_bam_lock); } pipe_connect->ipa_clnt_hdl = -1; info[cur_bam].prod_pipes_enabled_per_bam -= 1; return 0; } int get_qdss_bam_info(enum usb_ctrl cur_bam, u8 idx, phys_addr_t *p_addr, u32 *bam_size) { int ret = 0; struct usb_bam_ctx_type *ctx = &msm_usb_bam[cur_bam]; struct usb_bam_pipe_connect *pipe_connect = &ctx->usb_bam_connections[idx]; unsigned long peer_bam_handle; ret = sps_phy2h(pipe_connect->src_phy_addr, &peer_bam_handle); if (ret) { log_event_err("%s: sps_phy2h failed (src BAM) %d\n", __func__, ret); return ret; } ret = sps_get_bam_addr(peer_bam_handle, p_addr, bam_size); if (ret) { log_event_err("%s: sps_get_bam_addr failed%d\n", __func__, ret); return ret; } return 0; } int usb_bam_connect(enum usb_ctrl cur_bam, int idx, u32 *bam_pipe_idx, unsigned long iova) { int ret; struct usb_bam_ctx_type *ctx = &msm_usb_bam[cur_bam]; struct usb_bam_pipe_connect *pipe_connect = &ctx->usb_bam_connections[idx]; struct device *bam_dev = &ctx->usb_bam_pdev->dev; if (pipe_connect->enabled) { pr_warn("%s: connection %d was already established\n", __func__, idx); return 0; } if (!bam_pipe_idx) { log_event_err("%s: invalid bam_pipe_idx\n", __func__); return -EINVAL; } if (idx < 0 || idx > ctx->max_connections) { log_event_err("idx is wrong %d\n", idx); return -EINVAL; } log_event_dbg("%s: PM Runtime GET %d, count: %d\n", __func__, idx, get_pm_runtime_counter(bam_dev)); pm_runtime_get_sync(bam_dev); spin_lock(&ctx->usb_bam_lock); /* Check if BAM requires RESET before connect and reset of first pipe */ if (ctx->usb_bam_data->reset_on_connect && (ctx->pipes_enabled_per_bam == 0)) { spin_unlock(&ctx->usb_bam_lock); sps_device_reset(ctx->h_bam); spin_lock(&ctx->usb_bam_lock); } spin_unlock(&ctx->usb_bam_lock); ret = connect_pipe(cur_bam, idx, bam_pipe_idx, iova); if (ret) { log_event_err("%s: pipe connection[%d] failure\n", __func__, idx); log_event_dbg("%s: err, PM RT PUT %d, count: %d\n", __func__, idx, get_pm_runtime_counter(bam_dev)); pm_runtime_put_sync(bam_dev); return ret; } log_event_dbg("%s: pipe connection[%d] success\n", __func__, idx); pipe_connect->enabled = 1; spin_lock(&ctx->usb_bam_lock); ctx->pipes_enabled_per_bam += 1; spin_unlock(&ctx->usb_bam_lock); return 0; } EXPORT_SYMBOL_GPL(usb_bam_connect); static int __sps_reset_pipe(enum usb_ctrl bam_type, struct sps_pipe *pipe, u32 idx) { int ret; struct usb_bam_ctx_type *ctx = &msm_usb_bam[bam_type]; struct sps_connect *sps_connection = &ctx->usb_bam_sps.sps_connections[idx]; ret = sps_disconnect(pipe); if (ret) { log_event_err("%s: sps_disconnect() failed %d\n", __func__, ret); return ret; } ret = sps_connect(pipe, sps_connection); if (ret < 0) { log_event_err("%s: sps_connect() failed %d\n", __func__, ret); return ret; } return 0; } static void reset_pipe_for_resume(struct usb_bam_pipe_connect *pipe_connect) { int ret; enum usb_ctrl bam_type = pipe_connect->bam_type; struct usb_bam_ctx_type *ctx = &msm_usb_bam[bam_type]; u32 idx = ARRAY_INDEX_FROM_ADDR(ctx->usb_bam_connections, pipe_connect); struct sps_pipe *pipe = ctx->usb_bam_sps.sps_pipes[idx]; if (!pipe_connect->reset_pipe_after_lpm || pipe_connect->pipe_type != USB_BAM_PIPE_BAM2BAM) { log_event_dbg("No need to reset pipe %d\n", idx); return; } ret = __sps_reset_pipe(bam_type, pipe, idx); if (ret) { log_event_err("%s failed to reset the USB sps pipe\n", __func__); return; } ret = ipa_reset_endpoint(pipe_connect->ipa_clnt_hdl); if (ret) { log_event_err("%s failed to reset the IPA pipe\n", __func__); return; } log_event_dbg("%s: USB/IPA pipes reset after resume\n", __func__); } /* Stop PROD transfers in case they were started */ static void stop_prod_transfers(struct usb_bam_pipe_connect *pipe_connect) { if (pipe_connect->stop && !pipe_connect->prod_stopped) { log_event_dbg("%s: Stop PROD transfers on\n", __func__); pipe_connect->stop(pipe_connect->start_stop_param, USB_TO_PEER_PERIPHERAL); pipe_connect->prod_stopped = true; } } static void start_prod_transfers(struct usb_bam_pipe_connect *pipe_connect) { log_event_err("%s: Starting PROD\n", __func__); if (pipe_connect->start && pipe_connect->prod_stopped) { log_event_dbg("%s: Enqueue PROD transfer\n", __func__); pipe_connect->start(pipe_connect->start_stop_param, USB_TO_PEER_PERIPHERAL); pipe_connect->prod_stopped = false; } } static void start_cons_transfers(struct usb_bam_pipe_connect *pipe_connect) { /* Start CONS transfer */ if (pipe_connect->start && pipe_connect->cons_stopped) { log_event_dbg("%s: Enqueue CONS transfer\n", __func__); pipe_connect->start(pipe_connect->start_stop_param, PEER_PERIPHERAL_TO_USB); pipe_connect->cons_stopped = 0; } } /* Stop CONS transfers in case they were started */ static void stop_cons_transfers(struct usb_bam_pipe_connect *pipe_connect) { if (pipe_connect->stop && !pipe_connect->cons_stopped) { log_event_dbg("%s: Stop CONS transfers\n", __func__); pipe_connect->stop(pipe_connect->start_stop_param, PEER_PERIPHERAL_TO_USB); pipe_connect->cons_stopped = 1; } } static void resume_suspended_pipes(enum usb_ctrl cur_bam) { u32 idx, dst_idx; struct usb_bam_ctx_type *ctx = &msm_usb_bam[cur_bam]; struct usb_bam_pipe_connect *pipe_connect; log_event_dbg("Resuming: suspend pipes =%d\n", info[cur_bam].pipes_suspended); while (info[cur_bam].pipes_suspended >= 1) { idx = info[cur_bam].pipes_suspended - 1; dst_idx = info[cur_bam].resume_dst_idx[idx]; pipe_connect = &ctx->usb_bam_connections[dst_idx]; if (pipe_connect->cons_stopped) { log_event_dbg("%s: Starting CONS on %d\n", __func__, dst_idx); start_cons_transfers(pipe_connect); } log_event_dbg("%s: Starting PROD on %d\n", __func__, dst_idx); start_prod_transfers(pipe_connect); info[cur_bam].pipes_suspended--; info[cur_bam].pipes_resumed++; /* Suspend was aborted, renew pm_runtime vote */ log_event_dbg("%s: PM Runtime GET %d, count: %d\n", __func__, idx, get_pm_runtime_counter(&ctx->usb_bam_pdev->dev)); pm_runtime_get(&ctx->usb_bam_pdev->dev); } } static inline int all_pipes_suspended(enum usb_ctrl cur_bam) { struct usb_bam_ctx_type *ctx = &msm_usb_bam[cur_bam]; log_event_dbg("%s: pipes_suspended=%d pipes_enabled_per_bam=%d\n", __func__, info[cur_bam].pipes_suspended, ctx->pipes_enabled_per_bam); return info[cur_bam].pipes_suspended == ctx->pipes_enabled_per_bam; } static void usb_bam_finish_suspend(enum usb_ctrl cur_bam) { int ret, bam2bam; u32 cons_empty, idx, dst_idx; struct sps_pipe *cons_pipe; struct usb_bam_pipe_connect *pipe_connect; struct usb_bam_ctx_type *ctx = &msm_usb_bam[cur_bam]; struct device *bam_dev = &ctx->usb_bam_pdev->dev; mutex_lock(&info[cur_bam].suspend_resume_mutex); spin_lock(&usb_bam_ipa_handshake_info_lock); /* If cable was disconnected, let disconnection seq do everything */ if (info[cur_bam].disconnected || all_pipes_suspended(cur_bam)) { spin_unlock(&usb_bam_ipa_handshake_info_lock); mutex_unlock(&info[cur_bam].suspend_resume_mutex); log_event_dbg("%s: Cable disconnected\n", __func__); return; } log_event_dbg("%s: bam:%s RT GET: %d\n", __func__, bam_enable_strings[cur_bam], get_pm_runtime_counter(bam_dev)); pm_runtime_get(bam_dev); /* If resume was called don't finish this work */ if (!info[cur_bam].bus_suspend) { spin_unlock(&usb_bam_ipa_handshake_info_lock); log_event_dbg("%s: Bus resume in progress\n", __func__); goto no_lpm; } /* Go over all pipes, stop and suspend them, and go to lpm */ while (!all_pipes_suspended(cur_bam)) { idx = info[cur_bam].pipes_suspended; dst_idx = info[cur_bam].suspend_dst_idx[idx]; cons_pipe = ctx->usb_bam_sps.sps_pipes[dst_idx]; pipe_connect = &ctx->usb_bam_connections[dst_idx]; log_event_dbg("pipes_suspended=%d pipes_to_suspend=%d\n", info[cur_bam].pipes_suspended, info[cur_bam].pipes_to_suspend); bam2bam = (pipe_connect->pipe_type == USB_BAM_PIPE_BAM2BAM); spin_unlock(&usb_bam_ipa_handshake_info_lock); if (bam2bam) { ret = sps_is_pipe_empty(cons_pipe, &cons_empty); if (ret) { log_event_err("%s: sps_is_pipe_empty failed with %d\n", __func__, ret); goto no_lpm; } } else { log_event_err("%s: pipe type is not B2B\n", __func__); cons_empty = true; } spin_lock(&usb_bam_ipa_handshake_info_lock); /* Stop CONS transfers and go to lpm if no more data in the */ /* pipes */ if (cons_empty) { log_event_dbg("%s: Stopping CONS transfers on dst_idx=%d\n" , __func__, dst_idx); stop_cons_transfers(pipe_connect); spin_unlock(&usb_bam_ipa_handshake_info_lock); log_event_dbg("%s: Suspending pipe\n", __func__); spin_lock(&usb_bam_ipa_handshake_info_lock); info[cur_bam].resume_src_idx[idx] = info[cur_bam].suspend_src_idx[idx]; info[cur_bam].resume_dst_idx[idx] = info[cur_bam].suspend_dst_idx[idx]; info[cur_bam].pipes_suspended++; log_event_dbg("%s: PM Runtime PUT %d, count: %d\n", __func__, idx, get_pm_runtime_counter(bam_dev)); pm_runtime_put(&ctx->usb_bam_pdev->dev); } else { log_event_dbg("%s: Pipe is not empty, not going to LPM\n", __func__); spin_unlock(&usb_bam_ipa_handshake_info_lock); goto no_lpm; } } info[cur_bam].pipes_to_suspend = 0; info[cur_bam].pipes_resumed = 0; spin_unlock(&usb_bam_ipa_handshake_info_lock); /* ACK on the last pipe */ if (info[cur_bam].pipes_suspended == ctx->pipes_enabled_per_bam && info[cur_bam].cur_cons_state == IPA_RM_RESOURCE_RELEASED) { ipa_rm_notify_completion( IPA_RM_RESOURCE_RELEASED, ipa_rm_resource_cons[cur_bam]); } log_event_dbg("%s: Starting LPM on Bus Suspend, RT PUT:%d\n", __func__, get_pm_runtime_counter(bam_dev)); /* Put to match _get at the beginning of this routine */ pm_runtime_put_sync(bam_dev); mutex_unlock(&info[cur_bam].suspend_resume_mutex); return; no_lpm: spin_lock(&usb_bam_ipa_handshake_info_lock); resume_suspended_pipes(cur_bam); info[cur_bam].pipes_resumed = 0; info[cur_bam].pipes_to_suspend = 0; info[cur_bam].pipes_suspended = 0; spin_unlock(&usb_bam_ipa_handshake_info_lock); /* * Finish the handshake. Resume Sequence will start automatically * by the data in the pipes. */ if (info[cur_bam].cur_cons_state == IPA_RM_RESOURCE_RELEASED) ipa_rm_notify_completion(IPA_RM_RESOURCE_RELEASED, ipa_rm_resource_cons[cur_bam]); /* Put to match _get at the beginning of this routine */ pm_runtime_put(bam_dev); mutex_unlock(&info[cur_bam].suspend_resume_mutex); } static void usb_bam_finish_suspend_(struct work_struct *w) { enum usb_ctrl cur_bam; struct usb_bam_ipa_handshake_info *info_ptr; info_ptr = container_of(w, struct usb_bam_ipa_handshake_info, finish_suspend_work); cur_bam = info_ptr->bam_type; log_event_dbg("%s: Finishing suspend sequence(BAM=%s)\n", __func__, bam_enable_strings[cur_bam]); usb_bam_finish_suspend(cur_bam); } static void usb_prod_notify_cb(void *user_data, enum ipa_rm_event event, unsigned long data) { enum usb_ctrl *cur_bam = (void *)user_data; switch (event) { case IPA_RM_RESOURCE_GRANTED: log_event_dbg("%s: %s_PROD resource granted\n", __func__, bam_enable_strings[*cur_bam]); info[*cur_bam].cur_prod_state = IPA_RM_RESOURCE_GRANTED; complete_all(&info[*cur_bam].prod_avail); break; case IPA_RM_RESOURCE_RELEASED: log_event_dbg("%s: %s_PROD resource released\n", __func__, bam_enable_strings[*cur_bam]); info[*cur_bam].cur_prod_state = IPA_RM_RESOURCE_RELEASED; complete_all(&info[*cur_bam].prod_released); break; default: break; } } static int cons_request_resource(enum usb_ctrl cur_bam) { struct usb_bam_ctx_type *ctx = &msm_usb_bam[cur_bam]; int ret = -EINPROGRESS; log_event_dbg("%s: Request %s_CONS resource\n", __func__, bam_enable_strings[cur_bam]); spin_lock(&ctx->usb_bam_lock); spin_lock(&usb_bam_ipa_handshake_info_lock); info[cur_bam].cur_cons_state = IPA_RM_RESOURCE_GRANTED; switch (info[cur_bam].cur_bam_mode) { case USB_BAM_DEVICE: if (ctx->pipes_enabled_per_bam && info[cur_bam].connect_complete) { if (!all_pipes_suspended(cur_bam) && !info[cur_bam].bus_suspend) { log_event_dbg("%s: ACK on cons_request\n", __func__); ret = 0; } else if (info[cur_bam].bus_suspend) { info[cur_bam].bus_suspend = 0; log_event_dbg("%s: Wake up host\n", __func__); if (info[cur_bam].wake_cb) info[cur_bam].wake_cb( info[cur_bam].wake_param); } } break; default: break; } spin_unlock(&usb_bam_ipa_handshake_info_lock); spin_unlock(&ctx->usb_bam_lock); if (ret == -EINPROGRESS) log_event_dbg("%s: EINPROGRESS on cons_request\n", __func__); return ret; } static int ss_usb_cons_request_resource(void) { return cons_request_resource(DWC3_CTRL); } static int usb_cons_request_resource(void) { return cons_request_resource(CI_CTRL); } static int cons_release_resource(enum usb_ctrl cur_bam) { struct usb_bam_ctx_type *ctx = &msm_usb_bam[cur_bam]; log_event_dbg("%s: Release %s_CONS resource\n", __func__, bam_enable_strings[cur_bam]); info[cur_bam].cur_cons_state = IPA_RM_RESOURCE_RELEASED; spin_lock(&ctx->usb_bam_lock); if (!ctx->pipes_enabled_per_bam) { spin_unlock(&ctx->usb_bam_lock); log_event_dbg("%s: ACK on cons_release\n", __func__); return 0; } spin_unlock(&ctx->usb_bam_lock); if (info[cur_bam].cur_bam_mode == USB_BAM_DEVICE) { spin_lock(&usb_bam_ipa_handshake_info_lock); if (info[cur_bam].bus_suspend) { queue_work(ctx->usb_bam_wq, &info[cur_bam].finish_suspend_work); } spin_unlock(&usb_bam_ipa_handshake_info_lock); log_event_dbg("%s: EINPROGRESS cons_release\n", __func__); return -EINPROGRESS; } return 0; } static int usb_cons_release_resource(void) { return cons_release_resource(CI_CTRL); } static int ss_usb_cons_release_resource(void) { return cons_release_resource(DWC3_CTRL); } static void usb_bam_ipa_create_resources(enum usb_ctrl cur_bam) { struct usb_bam_ctx_type *ctx = &msm_usb_bam[cur_bam]; struct ipa_rm_create_params usb_prod_create_params; struct ipa_rm_create_params usb_cons_create_params; int ret; /* Create USB/HSIC_PROD entity */ memset(&usb_prod_create_params, 0, sizeof(usb_prod_create_params)); usb_prod_create_params.name = ipa_rm_resource_prod[cur_bam]; usb_prod_create_params.reg_params.notify_cb = usb_prod_notify_cb; usb_prod_create_params.reg_params.user_data = &ctx->usb_bam_data->bam_type; usb_prod_create_params.floor_voltage = IPA_VOLTAGE_SVS; ret = ipa_rm_create_resource(&usb_prod_create_params); if (ret) { log_event_err("%s: Failed to create USB_PROD resource\n", __func__); return; } /* Create USB_CONS entity */ memset(&usb_cons_create_params, 0, sizeof(usb_cons_create_params)); usb_cons_create_params.name = ipa_rm_resource_cons[cur_bam]; usb_cons_create_params.request_resource = request_resource_cb[cur_bam]; usb_cons_create_params.release_resource = release_resource_cb[cur_bam]; usb_cons_create_params.floor_voltage = IPA_VOLTAGE_SVS; ret = ipa_rm_create_resource(&usb_cons_create_params); if (ret) { log_event_err("%s: Failed to create USB_CONS resource\n", __func__); return; } } static void usb_bam_ipa_delete_resources(enum usb_ctrl cur_bam) { int ret; ret = ipa_rm_delete_resource(ipa_rm_resource_prod[cur_bam]); if (ret) log_event_err("%s: Failed to delete USB_PROD resource\n", __func__); ret = ipa_rm_delete_resource(ipa_rm_resource_cons[cur_bam]); if (ret) log_event_err("%s: Failed to delete USB_CONS resource\n", __func__); } static void wait_for_prod_granted(enum usb_ctrl cur_bam) { int ret; log_event_dbg("%s Request %s_PROD_RES\n", __func__, bam_enable_strings[cur_bam]); if (info[cur_bam].cur_cons_state == IPA_RM_RESOURCE_GRANTED) log_event_dbg("%s: CONS already granted for some reason\n", __func__); if (info[cur_bam].cur_prod_state == IPA_RM_RESOURCE_GRANTED) log_event_dbg("%s: PROD already granted for some reason\n", __func__); init_completion(&info[cur_bam].prod_avail); ret = ipa_rm_request_resource(ipa_rm_resource_prod[cur_bam]); if (!ret) { info[cur_bam].cur_prod_state = IPA_RM_RESOURCE_GRANTED; complete_all(&info[cur_bam].prod_avail); log_event_dbg("%s: PROD_GRANTED without wait\n", __func__); } else if (ret == -EINPROGRESS) { log_event_dbg("%s: Waiting for PROD_GRANTED\n", __func__); if (!wait_for_completion_timeout(&info[cur_bam].prod_avail, USB_BAM_TIMEOUT)) log_event_err("%s: Timeout wainting for PROD_GRANTED\n", __func__); } else log_event_err("%s: ipa_rm_request_resource ret =%d\n", __func__, ret); } static void notify_usb_connected(enum usb_ctrl cur_bam) { log_event_dbg("%s: enter\n", __func__); spin_lock(&usb_bam_ipa_handshake_info_lock); if (info[cur_bam].cur_bam_mode == USB_BAM_DEVICE) info[cur_bam].connect_complete = 1; spin_unlock(&usb_bam_ipa_handshake_info_lock); if (info[cur_bam].cur_cons_state == IPA_RM_RESOURCE_GRANTED) { log_event_dbg("%s: Notify %s CONS_GRANTED\n", __func__, bam_enable_strings[cur_bam]); ipa_rm_notify_completion(IPA_RM_RESOURCE_GRANTED, ipa_rm_resource_cons[cur_bam]); } } static void wait_for_prod_release(enum usb_ctrl cur_bam) { int ret; if (info[cur_bam].cur_cons_state == IPA_RM_RESOURCE_RELEASED) log_event_dbg("%s consumer already released\n", __func__); if (info[cur_bam].cur_prod_state == IPA_RM_RESOURCE_RELEASED) log_event_dbg("%s producer already released\n", __func__); init_completion(&info[cur_bam].prod_released); log_event_dbg("%s: Releasing %s_PROD\n", __func__, bam_enable_strings[cur_bam]); ret = ipa_rm_release_resource(ipa_rm_resource_prod[cur_bam]); if (!ret) { log_event_dbg("%s: Released without waiting\n", __func__); info[cur_bam].cur_prod_state = IPA_RM_RESOURCE_RELEASED; complete_all(&info[cur_bam].prod_released); } else if (ret == -EINPROGRESS) { log_event_dbg("%s: Waiting for PROD_RELEASED\n", __func__); if (!wait_for_completion_timeout(&info[cur_bam].prod_released, USB_BAM_TIMEOUT)) log_event_err("%s: Timeout waiting for PROD_RELEASED\n", __func__); } else { log_event_err("%s: ipa_rm_request_resource ret =%d\n", __func__, ret); } } static bool check_pipes_empty(enum usb_ctrl bam_type, u8 src_idx, u8 dst_idx) { struct usb_bam_ctx_type *ctx = &msm_usb_bam[bam_type]; struct sps_pipe *prod_pipe, *cons_pipe; struct usb_bam_pipe_connect *prod_pipe_connect, *cons_pipe_connect; u32 prod_empty, cons_empty; prod_pipe_connect = &ctx->usb_bam_connections[src_idx]; cons_pipe_connect = &ctx->usb_bam_connections[dst_idx]; if (!prod_pipe_connect->enabled || !cons_pipe_connect->enabled) { log_event_err("%s: pipes are not enabled dst=%d src=%d\n", __func__, prod_pipe_connect->enabled, cons_pipe_connect->enabled); } /* If we have any remaints in the pipes we don't go to sleep */ prod_pipe = ctx->usb_bam_sps.sps_pipes[src_idx]; cons_pipe = ctx->usb_bam_sps.sps_pipes[dst_idx]; log_event_dbg("prod_pipe=%pK, cons_pipe=%pK\n", prod_pipe, cons_pipe); if (!cons_pipe || (!prod_pipe && prod_pipe_connect->pipe_type == USB_BAM_PIPE_BAM2BAM)) { log_event_err("Missing a pipe!\n"); return false; } if (prod_pipe && sps_is_pipe_empty(prod_pipe, &prod_empty)) { log_event_err("sps_is_pipe_empty(prod) failed\n"); return false; } prod_empty = true; if (sps_is_pipe_empty(cons_pipe, &cons_empty)) { log_event_err("sps_is_pipe_empty(cons) failed\n"); return false; } if (!prod_empty || !cons_empty) { log_event_err("pipes not empty prod=%d cond=%d\n", prod_empty, cons_empty); return false; } return true; } void usb_bam_suspend(enum usb_ctrl cur_bam, struct usb_bam_connect_ipa_params *ipa_params) { struct usb_bam_pipe_connect *pipe_connect; struct usb_bam_ctx_type *ctx = &msm_usb_bam[cur_bam]; enum usb_bam_mode bam_mode; u8 src_idx, dst_idx; log_event_dbg("%s: enter\n", __func__); if (!ipa_params) { log_event_err("%s: Invalid ipa params\n", __func__); return; } src_idx = ipa_params->src_idx; dst_idx = ipa_params->dst_idx; if (src_idx >= ctx->max_connections || dst_idx >= ctx->max_connections) { log_event_err("%s: Invalid connection index src=%d dst=%d\n", __func__, src_idx, dst_idx); } pipe_connect = &ctx->usb_bam_connections[src_idx]; bam_mode = pipe_connect->bam_mode; if (bam_mode != USB_BAM_DEVICE) return; log_event_dbg("%s: Starting suspend sequence(BAM=%s)\n", __func__, bam_enable_strings[cur_bam]); spin_lock(&usb_bam_ipa_handshake_info_lock); info[cur_bam].bus_suspend = 1; /* If cable was disconnected, let disconnection seq do everything */ if (info[cur_bam].disconnected) { spin_unlock(&usb_bam_ipa_handshake_info_lock); log_event_dbg("%s: Cable disconnected\n", __func__); return; } log_event_dbg("%s: Adding src=%d dst=%d in pipes_to_suspend=%d\n", __func__, src_idx, dst_idx, info[cur_bam].pipes_to_suspend); info[cur_bam].suspend_src_idx[info[cur_bam].pipes_to_suspend] = src_idx; info[cur_bam].suspend_dst_idx[info[cur_bam].pipes_to_suspend] = dst_idx; info[cur_bam].pipes_to_suspend++; spin_unlock(&usb_bam_ipa_handshake_info_lock); usb_bam_start_suspend(&info[cur_bam]); } EXPORT_SYMBOL_GPL(usb_bam_free_fifos); static void usb_bam_start_suspend(struct usb_bam_ipa_handshake_info *info_ptr) { struct usb_bam_pipe_connect *pipe_connect; enum usb_ctrl cur_bam = info_ptr->bam_type; struct usb_bam_ctx_type *ctx = &msm_usb_bam[cur_bam]; u8 src_idx, dst_idx; int pipes_to_suspend; cur_bam = info_ptr->bam_type; log_event_dbg("%s: Starting suspend sequence(BAM=%s)\n", __func__, bam_enable_strings[cur_bam]); mutex_lock(&info[cur_bam].suspend_resume_mutex); spin_lock(&usb_bam_ipa_handshake_info_lock); /* If cable was disconnected, let disconnection seq do everything */ if (info[cur_bam].disconnected) { spin_unlock(&usb_bam_ipa_handshake_info_lock); mutex_unlock(&info[cur_bam].suspend_resume_mutex); log_event_dbg("%s: Cable disconnected\n", __func__); return; } pipes_to_suspend = info[cur_bam].pipes_to_suspend; if (!info[cur_bam].bus_suspend || !pipes_to_suspend) { spin_unlock(&usb_bam_ipa_handshake_info_lock); log_event_dbg("%s: Resume started, not suspending\n", __func__); mutex_unlock(&info[cur_bam].suspend_resume_mutex); return; } src_idx = info[cur_bam].suspend_src_idx[pipes_to_suspend - 1]; dst_idx = info[cur_bam].suspend_dst_idx[pipes_to_suspend - 1]; pipe_connect = &ctx->usb_bam_connections[dst_idx]; stop_prod_transfers(pipe_connect); spin_unlock(&usb_bam_ipa_handshake_info_lock); /* Don't start LPM seq if data in the pipes */ if (!check_pipes_empty(cur_bam, src_idx, dst_idx)) { start_prod_transfers(pipe_connect); info[cur_bam].pipes_to_suspend = 0; info[cur_bam].bus_suspend = 0; mutex_unlock(&info[cur_bam].suspend_resume_mutex); return; } spin_lock(&usb_bam_ipa_handshake_info_lock); /* Start release handshake on the last pipe */ if (info[cur_bam].pipes_to_suspend * 2 == ctx->pipes_enabled_per_bam) { spin_unlock(&usb_bam_ipa_handshake_info_lock); wait_for_prod_release(cur_bam); } else { spin_unlock(&usb_bam_ipa_handshake_info_lock); } mutex_unlock(&info[cur_bam].suspend_resume_mutex); if (info[cur_bam].cur_cons_state == IPA_RM_RESOURCE_RELEASED) usb_bam_finish_suspend(cur_bam); else log_event_dbg("Consumer not released yet\n"); } static void usb_bam_finish_resume(struct work_struct *w) { /* TODO: Change this when HSIC device support is introduced */ enum usb_ctrl cur_bam; struct usb_bam_ipa_handshake_info *info_ptr; struct usb_bam_pipe_connect *pipe_connect; struct usb_bam_ctx_type *ctx; struct device *bam_dev; u32 idx, dst_idx, suspended; info_ptr = container_of(w, struct usb_bam_ipa_handshake_info, resume_work); cur_bam = info_ptr->bam_type; ctx = &msm_usb_bam[cur_bam]; bam_dev = &ctx->usb_bam_pdev->dev; log_event_dbg("%s: enter bam=%s, RT GET: %d\n", __func__, bam_enable_strings[cur_bam], get_pm_runtime_counter(bam_dev)); pm_runtime_get_sync(bam_dev); mutex_lock(&info[cur_bam].suspend_resume_mutex); /* Suspend or disconnect happened in the meantime */ spin_lock(&usb_bam_ipa_handshake_info_lock); if (info[cur_bam].bus_suspend || info[cur_bam].disconnected) { spin_unlock(&usb_bam_ipa_handshake_info_lock); log_event_dbg("%s: Bus suspended, not resuming, RT PUT: %d\n", __func__, get_pm_runtime_counter(bam_dev)); mutex_unlock(&info[cur_bam].suspend_resume_mutex); pm_runtime_put_sync(bam_dev); return; } info[cur_bam].pipes_to_suspend = 0; log_event_dbg("Resuming: pipes_suspended =%d\n", info[cur_bam].pipes_suspended); suspended = info[cur_bam].pipes_suspended; while (suspended >= 1) { idx = suspended - 1; dst_idx = info[cur_bam].resume_dst_idx[idx]; pipe_connect = &ctx->usb_bam_connections[dst_idx]; spin_unlock(&usb_bam_ipa_handshake_info_lock); reset_pipe_for_resume(pipe_connect); spin_lock(&usb_bam_ipa_handshake_info_lock); if (pipe_connect->cons_stopped) { log_event_dbg("%s: Starting CONS on %d\n", __func__, dst_idx); start_cons_transfers(pipe_connect); } suspended--; } if (info[cur_bam].cur_cons_state == IPA_RM_RESOURCE_GRANTED) { log_event_dbg("%s: Notify CONS_GRANTED\n", __func__); ipa_rm_notify_completion(IPA_RM_RESOURCE_GRANTED, ipa_rm_resource_cons[cur_bam]); } spin_unlock(&usb_bam_ipa_handshake_info_lock); /* Start handshake for the first pipe resumed */ if (info[cur_bam].pipes_resumed == 0) wait_for_prod_granted(cur_bam); spin_lock(&usb_bam_ipa_handshake_info_lock); while (info[cur_bam].pipes_suspended >= 1) { idx = info[cur_bam].pipes_suspended - 1; dst_idx = info[cur_bam].resume_dst_idx[idx]; pipe_connect = &ctx->usb_bam_connections[dst_idx]; log_event_dbg("%s: Starting PROD on %d\n", __func__, dst_idx); start_prod_transfers(pipe_connect); info[cur_bam].pipes_suspended--; info[cur_bam].pipes_resumed++; log_event_dbg("%s: PM Runtime GET %d, count: %d\n", __func__, idx, get_pm_runtime_counter(bam_dev)); pm_runtime_get(&ctx->usb_bam_pdev->dev); } if (info[cur_bam].pipes_resumed == ctx->pipes_enabled_per_bam) { info[cur_bam].pipes_resumed = 0; if (info[cur_bam].cur_cons_state == IPA_RM_RESOURCE_GRANTED) { log_event_dbg("%s: Notify CONS_GRANTED\n", __func__); ipa_rm_notify_completion(IPA_RM_RESOURCE_GRANTED, ipa_rm_resource_cons[cur_bam]); } } spin_unlock(&usb_bam_ipa_handshake_info_lock); mutex_unlock(&info[cur_bam].suspend_resume_mutex); log_event_dbg("%s: done..PM Runtime PUT :%d\n", __func__, get_pm_runtime_counter(bam_dev)); /* Put to match _get at the beginning of this routine */ pm_runtime_put(&ctx->usb_bam_pdev->dev); } void usb_bam_resume(enum usb_ctrl cur_bam, struct usb_bam_connect_ipa_params *ipa_params) { u8 src_idx, dst_idx; struct usb_bam_ctx_type *ctx = &msm_usb_bam[cur_bam]; struct usb_bam_pipe_connect *pipe_connect; log_event_dbg("%s: Resuming\n", __func__); if (!ipa_params) { log_event_err("%s: Invalid ipa params\n", __func__); return; } src_idx = ipa_params->src_idx; dst_idx = ipa_params->dst_idx; if (src_idx >= ctx->max_connections || dst_idx >= ctx->max_connections) { log_event_err("%s: Invalid connection index src=%d dst=%d\n", __func__, src_idx, dst_idx); return; } pipe_connect = &ctx->usb_bam_connections[src_idx]; log_event_dbg("%s: bam=%s mode =%d\n", __func__, bam_enable_strings[cur_bam], pipe_connect->bam_mode); if (pipe_connect->bam_mode != USB_BAM_DEVICE) return; info[cur_bam].in_lpm = false; spin_lock(&usb_bam_ipa_handshake_info_lock); info[cur_bam].bus_suspend = 0; spin_unlock(&usb_bam_ipa_handshake_info_lock); queue_work(ctx->usb_bam_wq, &info[cur_bam].resume_work); } static int usb_bam_set_ipa_perf(enum usb_ctrl cur_bam, enum usb_bam_pipe_dir dir, enum usb_device_speed usb_connection_speed) { int ret; struct usb_bam_ctx_type *ctx = &msm_usb_bam[cur_bam]; struct ipa_rm_perf_profile ipa_rm_perf_prof; if (usb_connection_speed == USB_SPEED_SUPER) ipa_rm_perf_prof.max_supported_bandwidth_mbps = ctx->usb_bam_data->max_mbps_superspeed; else /* Bam2Bam is supported only for SS and HS (HW limitation) */ ipa_rm_perf_prof.max_supported_bandwidth_mbps = ctx->usb_bam_data->max_mbps_highspeed; /* * Having a max mbps property in dtsi file is a must * for target with IPA capability. */ if (!ipa_rm_perf_prof.max_supported_bandwidth_mbps) { log_event_err("%s: Max mbps is required for speed %d\n", __func__, usb_connection_speed); return -EINVAL; } if (dir == USB_TO_PEER_PERIPHERAL) { log_event_dbg("%s: vote ipa_perf resource=%d perf=%d mbps\n", __func__, ipa_rm_resource_prod[cur_bam], ipa_rm_perf_prof.max_supported_bandwidth_mbps); ret = ipa_rm_set_perf_profile(ipa_rm_resource_prod[cur_bam], &ipa_rm_perf_prof); } else { log_event_dbg("%s: vote ipa_perf resource=%d perf=%d mbps\n", __func__, ipa_rm_resource_cons[cur_bam], ipa_rm_perf_prof.max_supported_bandwidth_mbps); ret = ipa_rm_set_perf_profile(ipa_rm_resource_cons[cur_bam], &ipa_rm_perf_prof); } return ret; } EXPORT_SYMBOL_GPL(get_qdss_bam_info); static bool _hsic_host_bam_resume_core(void) { log_event_dbg("%s: enter\n", __func__); /* Exit from "full suspend" in case of hsic host */ if (host_info[HSIC_CTRL].dev) { log_event_dbg("%s: Getting hsic device %pK\n", __func__, host_info[HSIC_CTRL].dev); pm_runtime_get(host_info[HSIC_CTRL].dev); return true; } return false; } static bool usb_bam_resume_core(enum usb_ctrl bam_type, enum usb_bam_mode bam_mode) { log_event_dbg("%s: enter bam=%s\n", __func__, bam_enable_strings[bam_type]); if ((bam_mode == USB_BAM_DEVICE) || (bam_type != HSIC_CTRL)) { log_event_err("%s: Invalid BAM type %d\n", __func__, bam_type); return false; } return _hsic_host_bam_resume_core(); } static void _msm_bam_wait_for_host_prod_granted(enum usb_ctrl bam_type) { struct usb_bam_ctx_type *ctx = &msm_usb_bam[bam_type]; spin_lock(&ctx->usb_bam_lock); log_event_dbg("%s: enter bam=%s\n", __func__, bam_enable_strings[bam_type]); ctx->is_bam_inactivity = false; /* Get back to resume state including wakeup ipa */ usb_bam_resume_core(bam_type, USB_BAM_HOST); spin_unlock(&ctx->usb_bam_lock); } void msm_bam_wait_for_hsic_host_prod_granted(void) { log_event_dbg("%s: start\n", __func__); _msm_bam_wait_for_host_prod_granted(HSIC_CTRL); } int usb_bam_connect_ipa(enum usb_ctrl cur_bam, struct usb_bam_connect_ipa_params *ipa_params) { u8 idx; enum usb_bam_mode cur_mode; struct usb_bam_ctx_type *ctx = &msm_usb_bam[cur_bam]; struct usb_bam_pipe_connect *pipe_connect; struct device *bam_dev = &ctx->usb_bam_pdev->dev; int ret; bool bam2bam, is_dpl; log_event_dbg("%s: start\n", __func__); if (!ipa_params) { log_event_err("%s: Invalid ipa params\n", __func__); return -EINVAL; } if (ipa_params->dir == USB_TO_PEER_PERIPHERAL) idx = ipa_params->src_idx; else idx = ipa_params->dst_idx; if (idx >= ctx->max_connections) { log_event_err("%s: Invalid connection index\n", __func__); return -EINVAL; } pipe_connect = &ctx->usb_bam_connections[idx]; if (pipe_connect->enabled) { log_event_err("%s: connection %d was already established\n", __func__, idx); return 0; } ret = usb_bam_set_ipa_perf(pipe_connect->bam_type, ipa_params->dir, ipa_params->usb_connection_speed); if (ret) { log_event_err("%s: call to usb_bam_set_ipa_perf failed %d\n", __func__, ret); return ret; } log_event_dbg("%s: enter\n", __func__); cur_mode = pipe_connect->bam_mode; bam2bam = (pipe_connect->pipe_type == USB_BAM_PIPE_BAM2BAM); if (ipa_params->dst_client == IPA_CLIENT_USB_DPL_CONS) is_dpl = true; else is_dpl = false; /* Set the BAM mode (host/device) according to connected pipe */ info[cur_bam].cur_bam_mode = pipe_connect->bam_mode; if (cur_mode == USB_BAM_DEVICE) { mutex_lock(&info[cur_bam].suspend_resume_mutex); spin_lock(&ctx->usb_bam_lock); if (ctx->pipes_enabled_per_bam == 0) { spin_unlock(&ctx->usb_bam_lock); spin_lock(&usb_bam_ipa_handshake_info_lock); info[cur_bam].connect_complete = 0; info[cur_bam].disconnected = 0; info[cur_bam].bus_suspend = 0; info[cur_bam].pipes_suspended = 0; info[cur_bam].pipes_to_suspend = 0; info[cur_bam].pipes_resumed = 0; spin_unlock(&usb_bam_ipa_handshake_info_lock); } else { spin_unlock(&ctx->usb_bam_lock); } pipe_connect->cons_stopped = 0; pipe_connect->prod_stopped = 0; } log_event_dbg("%s: PM Runtime GET %d, count: %d\n", __func__, idx, get_pm_runtime_counter(bam_dev)); pm_runtime_get_sync(bam_dev); /* Check if BAM requires RESET before connect and reset first pipe */ spin_lock(&ctx->usb_bam_lock); if (ctx->usb_bam_data->reset_on_connect && !ctx->pipes_enabled_per_bam) { spin_unlock(&ctx->usb_bam_lock); if (cur_bam == CI_CTRL) msm_hw_bam_disable(1); sps_device_reset(ctx->h_bam); if (cur_bam == CI_CTRL) msm_hw_bam_disable(0); /* On re-connect assume out from lpm for all BAMs */ info[cur_bam].in_lpm = false; } else { spin_unlock(&ctx->usb_bam_lock); if (!ctx->pipes_enabled_per_bam) log_event_dbg("No BAM reset on connect, just pipe reset\n"); } if (ipa_params->dir == USB_TO_PEER_PERIPHERAL) { if (info[cur_bam].prod_pipes_enabled_per_bam == 0) wait_for_prod_granted(cur_bam); info[cur_bam].prod_pipes_enabled_per_bam += 1; } if (bam2bam) ret = connect_pipe_bam2bam_ipa(cur_bam, idx, ipa_params); else ret = connect_pipe_sys2bam_ipa(cur_bam, idx, ipa_params); if (ret) { log_event_err("%s: pipe connection failure RT PUT: %d\n", __func__, get_pm_runtime_counter(bam_dev)); pm_runtime_put_sync(bam_dev); if (cur_mode == USB_BAM_DEVICE) mutex_unlock(&info[cur_bam].suspend_resume_mutex); return ret; } log_event_dbg("%s: pipe connection success\n", __func__); spin_lock(&ctx->usb_bam_lock); pipe_connect->enabled = 1; pipe_connect->suspended = 0; /* Set global inactivity timer upon first pipe connection */ if (!ctx->pipes_enabled_per_bam && ctx->inactivity_timer_ms && pipe_connect->inactivity_notify && bam2bam) usb_bam_set_inactivity_timer(cur_bam); ctx->pipes_enabled_per_bam += 1; /* * Notify USB connected on the first two pipes connected for * tethered function's producer and consumer only. Current * understanding is that there won't be more than 3 pipes used * in USB BAM2BAM IPA mode i.e. 2 consumers and 1 producer. * If more producer and consumer pipe are being used, this * logic is required to be revisited here. */ if (ctx->pipes_enabled_per_bam >= 2 && ipa_params->dir == PEER_PERIPHERAL_TO_USB && !is_dpl) notify_usb_connected(cur_bam); spin_unlock(&ctx->usb_bam_lock); if (cur_mode == USB_BAM_DEVICE) mutex_unlock(&info[cur_bam].suspend_resume_mutex); log_event_dbg("%s: done\n", __func__); return 0; } EXPORT_SYMBOL(usb_bam_connect_ipa); int usb_bam_get_pipe_type(enum usb_ctrl bam_type, u8 idx, enum usb_bam_pipe_type *type) { struct usb_bam_ctx_type *ctx = &msm_usb_bam[bam_type]; struct usb_bam_pipe_connect *pipe_connect = &ctx->usb_bam_connections[idx]; if (idx >= ctx->max_connections) { log_event_err("%s: Invalid connection index\n", __func__); return -EINVAL; } if (!type) { log_event_err("%s: null pointer provided for type\n", __func__); return -EINVAL; } *type = pipe_connect->pipe_type; return 0; } EXPORT_SYMBOL(usb_bam_get_pipe_type); static void usb_bam_work(struct work_struct *w) { int i; struct usb_bam_event_info *event_info = container_of(w, struct usb_bam_event_info, event_w); struct usb_bam_pipe_connect *pipe_connect = container_of(event_info, struct usb_bam_pipe_connect, event); struct usb_bam_ctx_type *ctx = &msm_usb_bam[pipe_connect->bam_type]; struct usb_bam_pipe_connect *pipe_iter; int (*callback)(void *priv); void *param = NULL; switch (event_info->type) { case USB_BAM_EVENT_WAKEUP: case USB_BAM_EVENT_WAKEUP_PIPE: log_event_dbg("%s received USB_BAM_EVENT_WAKEUP\n", __func__); /* Notify about wakeup / activity of the bam */ if (event_info->callback) event_info->callback(event_info->param); /* * Reset inactivity timer counter if this pipe's bam * has inactivity timeout. */ spin_lock(&ctx->usb_bam_lock); if (ctx->inactivity_timer_ms) usb_bam_set_inactivity_timer(pipe_connect->bam_type); spin_unlock(&ctx->usb_bam_lock); if (pipe_connect->bam_mode == USB_BAM_DEVICE) { /* A2 wakeup not from LPM (CONS was up) */ wait_for_prod_granted(pipe_connect->bam_type); if (pipe_connect->start) { log_event_dbg("%s: Enqueue PROD transfer\n", __func__); pipe_connect->start( pipe_connect->start_stop_param, USB_TO_PEER_PERIPHERAL); } } break; case USB_BAM_EVENT_INACTIVITY: log_event_dbg("%s received USB_BAM_EVENT_INACTIVITY\n", __func__); /* * Since event info is one structure per pipe, it might be * overridden when we will register the wakeup events below, * and still we want ot register the wakeup events before we * notify on the inactivity in order to identify the next * activity as soon as possible. */ callback = event_info->callback; param = event_info->param; /* * Upon inactivity, configure wakeup irq for all pipes * that are into the usb bam. */ spin_lock(&ctx->usb_bam_lock); for (i = 0; i < ctx->max_connections; i++) { pipe_iter = &ctx->usb_bam_connections[i]; if (pipe_iter->bam_type == pipe_connect->bam_type && pipe_iter->dir == PEER_PERIPHERAL_TO_USB && pipe_iter->enabled) { log_event_dbg("%s: Register wakeup on pipe %pK\n", __func__, pipe_iter); __usb_bam_register_wake_cb( pipe_connect->bam_type, i, pipe_iter->activity_notify, pipe_iter->priv, false); } } spin_unlock(&ctx->usb_bam_lock); /* Notify about the inactivity to the USB class driver */ if (callback) callback(param); wait_for_prod_release(pipe_connect->bam_type); log_event_dbg("%s: complete wait on hsic producer s=%d\n", __func__, info[pipe_connect->bam_type].cur_prod_state); /* * Allow to go to lpm for now if also consumer is down. * If consumer is up, we will wait to the release consumer * notification. */ if (host_info[pipe_connect->bam_type].dev && info[pipe_connect->bam_type].cur_cons_state == IPA_RM_RESOURCE_RELEASED && !info[pipe_connect->bam_type].in_lpm) { usb_bam_suspend_core(pipe_connect->bam_type, pipe_connect->bam_mode, 1); } break; default: log_event_err("%s: unknown usb bam event type %d\n", __func__, event_info->type); } } static void usb_bam_wake_cb(struct sps_event_notify *notify) { struct usb_bam_event_info *event_info = (struct usb_bam_event_info *)notify->user; struct usb_bam_pipe_connect *pipe_connect = container_of(event_info, struct usb_bam_pipe_connect, event); enum usb_ctrl bam = pipe_connect->bam_type; struct usb_bam_ctx_type *ctx = &msm_usb_bam[bam]; spin_lock(&ctx->usb_bam_lock); if (event_info->type == USB_BAM_EVENT_WAKEUP_PIPE) queue_work(ctx->usb_bam_wq, &event_info->event_w); else if (event_info->type == USB_BAM_EVENT_WAKEUP && ctx->is_bam_inactivity) { /* * Sps wake event is per pipe, so usb_bam_wake_cb is * called per pipe. However, we want to filter the wake * event to be wake event per all the pipes. * Therefore, the first pipe that awaked will be considered * as global bam wake event. */ ctx->is_bam_inactivity = false; queue_work(ctx->usb_bam_wq, &event_info->event_w); } spin_unlock(&ctx->usb_bam_lock); } static int __usb_bam_register_wake_cb(enum usb_ctrl bam_type, int idx, int (*callback)(void *user), void *param, bool trigger_cb_per_pipe) { struct sps_pipe *pipe; struct sps_connect *sps_connection; struct usb_bam_pipe_connect *pipe_connect; struct usb_bam_event_info *wake_event_info; struct usb_bam_ctx_type *ctx = &msm_usb_bam[bam_type]; int ret; if (idx < 0 || idx > ctx->max_connections) { log_event_err("%s:idx is wrong %d\n", __func__, idx); return -EINVAL; } pipe = ctx->usb_bam_sps.sps_pipes[idx]; sps_connection = &ctx->usb_bam_sps.sps_connections[idx]; pipe_connect = &ctx->usb_bam_connections[idx]; wake_event_info = &pipe_connect->event; wake_event_info->type = (trigger_cb_per_pipe ? USB_BAM_EVENT_WAKEUP_PIPE : USB_BAM_EVENT_WAKEUP); wake_event_info->param = param; wake_event_info->callback = callback; wake_event_info->event.mode = SPS_TRIGGER_CALLBACK; wake_event_info->event.xfer_done = NULL; wake_event_info->event.callback = callback ? usb_bam_wake_cb : NULL; wake_event_info->event.user = wake_event_info; wake_event_info->event.options = SPS_O_WAKEUP; ret = sps_register_event(pipe, &wake_event_info->event); if (ret) { log_event_err("%s: sps_register_event() failed %d\n", __func__, ret); return ret; } sps_connection->options = callback ? (SPS_O_AUTO_ENABLE | SPS_O_WAKEUP | SPS_O_WAKEUP_IS_ONESHOT) : SPS_O_AUTO_ENABLE; ret = sps_set_config(pipe, sps_connection); if (ret) { log_event_err("%s: sps_set_config() failed %d\n", __func__, ret); return ret; } log_event_dbg("%s: success\n", __func__); return 0; } int usb_bam_register_wake_cb(enum usb_ctrl bam_type, u8 idx, int (*callback)(void *user), void *param) { struct usb_bam_ctx_type *ctx = &msm_usb_bam[bam_type]; struct usb_bam_pipe_connect *pipe_connect = &ctx->usb_bam_connections[idx]; info[pipe_connect->bam_type].wake_cb = callback; info[pipe_connect->bam_type].wake_param = param; return __usb_bam_register_wake_cb(bam_type, idx, callback, param, true); } int usb_bam_register_start_stop_cbs(enum usb_ctrl bam_type, u8 dst_idx, void (*start)(void *, enum usb_bam_pipe_dir), void (*stop)(void *, enum usb_bam_pipe_dir), void *param) { struct usb_bam_ctx_type *ctx = &msm_usb_bam[bam_type]; struct usb_bam_pipe_connect *pipe_connect = &ctx->usb_bam_connections[dst_idx]; log_event_dbg("%s: Register for %d\n", __func__, dst_idx); pipe_connect->start = start; pipe_connect->stop = stop; pipe_connect->start_stop_param = param; return 0; } int usb_bam_disconnect_pipe(enum usb_ctrl bam_type, u8 idx) { struct usb_bam_ctx_type *ctx = &msm_usb_bam[bam_type]; struct usb_bam_pipe_connect *pipe_connect; struct device *bam_dev = &ctx->usb_bam_pdev->dev; int ret; pipe_connect = &ctx->usb_bam_connections[idx]; if (!pipe_connect->enabled) { log_event_err("%s: connection %d isn't enabled\n", __func__, idx); return 0; } ret = disconnect_pipe(bam_type, idx); if (ret) { log_event_err("%s: src pipe disconnection failure\n", __func__); return ret; } pipe_connect->enabled = 0; spin_lock(&ctx->usb_bam_lock); if (!ctx->pipes_enabled_per_bam) { log_event_err("%s: wrong pipes enabled counter for bam_type=%d\n", __func__, bam_type); } else { ctx->pipes_enabled_per_bam -= 1; } spin_unlock(&ctx->usb_bam_lock); log_event_dbg("%s: success disconnecting pipe %d\n", __func__, idx); if (ctx->usb_bam_data->reset_on_disconnect && !ctx->pipes_enabled_per_bam) sps_device_reset(ctx->h_bam); /* This function is directly called by USB Transport drivers * to disconnect pipes. Drop runtime usage count here. For * IPA, caller takes care of it */ if (pipe_connect->peer_bam != IPA_P_BAM) { log_event_dbg("%s: PM Runtime PUT %d, count: %d\n", __func__, idx, get_pm_runtime_counter(bam_dev)); pm_runtime_put_sync(bam_dev); } return 0; } EXPORT_SYMBOL_GPL(usb_bam_disconnect_pipe); /** * is_ipa_handle_valid: Check if ipa_handle is valid or not * @ipa_handle: IPA Handle for producer or consumer * * Returns true is ipa handle is valid. */ static bool is_ipa_handle_valid(u32 ipa_handle) { return (ipa_handle != -1); } int usb_bam_disconnect_ipa(enum usb_ctrl cur_bam, struct usb_bam_connect_ipa_params *ipa_params) { int ret = 0, pipes_disconncted = 0; u8 idx = 0; struct usb_bam_ctx_type *ctx = &msm_usb_bam[cur_bam]; struct usb_bam_pipe_connect *pipe_connect; struct device *bam_dev = &ctx->usb_bam_pdev->dev; enum usb_bam_mode bam_mode; if (!is_ipa_handle_valid(ipa_params->prod_clnt_hdl) && !is_ipa_handle_valid(ipa_params->cons_clnt_hdl)) { log_event_err("%s: Both IPA handles are invalid.\n", __func__); return -EINVAL; } log_event_dbg("%s: Starting disconnect sequence\n", __func__); log_event_dbg("%s(): prod_clnt_hdl:%d cons_clnt_hdl:%d\n", __func__, ipa_params->prod_clnt_hdl, ipa_params->cons_clnt_hdl); if (is_ipa_handle_valid(ipa_params->prod_clnt_hdl)) idx = ipa_params->dst_idx; if (is_ipa_handle_valid(ipa_params->cons_clnt_hdl)) idx = ipa_params->src_idx; pipe_connect = &ctx->usb_bam_connections[idx]; bam_mode = pipe_connect->bam_mode; if (bam_mode != USB_BAM_DEVICE) return -EINVAL; mutex_lock(&info[cur_bam].suspend_resume_mutex); /* Delay USB core to go into lpm before we finish our handshake */ if (is_ipa_handle_valid(ipa_params->prod_clnt_hdl)) { ret = usb_bam_disconnect_ipa_prod(ipa_params, cur_bam); if (ret) goto out; pipes_disconncted++; } if (is_ipa_handle_valid(ipa_params->cons_clnt_hdl)) { ret = usb_bam_disconnect_ipa_cons(ipa_params, cur_bam); if (ret) goto out; pipes_disconncted++; } /* Notify CONS release on the last cons pipe released */ if (!ctx->pipes_enabled_per_bam) { if (info[cur_bam].cur_cons_state == IPA_RM_RESOURCE_RELEASED) { log_event_dbg("%s: Notify CONS_RELEASED\n", __func__); ipa_rm_notify_completion( IPA_RM_RESOURCE_RELEASED, ipa_rm_resource_cons[cur_bam]); } } out: /* Pipes are connected one by one, but can get disconnected in pairs */ while (pipes_disconncted--) { if (!info[cur_bam].pipes_suspended) { log_event_dbg("%s: PM Runtime PUT %d, count: %d\n", __func__, pipes_disconncted, get_pm_runtime_counter(bam_dev)); pm_runtime_put_sync(&ctx->usb_bam_pdev->dev); } } mutex_unlock(&info[cur_bam].suspend_resume_mutex); return ret; } EXPORT_SYMBOL(usb_bam_disconnect_ipa); static void usb_bam_sps_events(enum sps_callback_case sps_cb_case, void *user) { int i; struct usb_bam_ctx_type *ctx = user; struct usb_bam_pipe_connect *pipe_connect; struct usb_bam_event_info *event_info; switch (sps_cb_case) { case SPS_CALLBACK_BAM_TIMER_IRQ: log_event_dbg("%s: received SPS_CALLBACK_BAM_TIMER_IRQ\n", __func__); spin_lock(&ctx->usb_bam_lock); ctx->is_bam_inactivity = true; for (i = 0; i < ctx->max_connections; i++) { pipe_connect = &ctx->usb_bam_connections[i]; /* * Notify inactivity once, Since it is global * for all pipes on bam. Notify only if we have * connected pipes. */ if (pipe_connect->enabled) { event_info = &pipe_connect->event; event_info->type = USB_BAM_EVENT_INACTIVITY; event_info->param = pipe_connect->priv; event_info->callback = pipe_connect->inactivity_notify; queue_work(ctx->usb_bam_wq, &event_info->event_w); break; } } spin_unlock(&ctx->usb_bam_lock); break; default: log_event_dbg("%s: received sps_cb_case=%d\n", __func__, (int)sps_cb_case); } } static struct msm_usb_bam_data *usb_bam_dt_to_data( struct platform_device *pdev, u32 usb_addr) { struct msm_usb_bam_data *usb_bam_data; struct device_node *node = pdev->dev.of_node; int rc = 0; u8 i = 0; u32 bam = DWC3_CTRL; u32 addr = 0; u32 threshold, max_connections = 0; static struct usb_bam_pipe_connect *usb_bam_connections; usb_bam_data = devm_kzalloc(&pdev->dev, sizeof(*usb_bam_data), GFP_KERNEL); if (!usb_bam_data) return NULL; /* override bam-type if specified, default is dwc3 */ of_property_read_u32(node, "qcom,bam-type", &bam); if (bam >= MAX_BAMS) { log_event_err("%s: Invalid bam type %d in device tree\n", __func__, bam); return NULL; } usb_bam_data->bam_type = bam; usb_bam_data->reset_on_connect = of_property_read_bool(node, "qcom,reset-bam-on-connect"); usb_bam_data->reset_on_disconnect = of_property_read_bool(node, "qcom,reset-bam-on-disconnect"); rc = of_property_read_u32(node, "qcom,usb-bam-num-pipes", &usb_bam_data->usb_bam_num_pipes); if (rc) { log_event_err("Invalid usb bam num pipes property\n"); return NULL; } rc = of_property_read_u32(node, "qcom,usb-bam-max-mbps-highspeed", &usb_bam_data->max_mbps_highspeed); if (rc) usb_bam_data->max_mbps_highspeed = 0; rc = of_property_read_u32(node, "qcom,usb-bam-max-mbps-superspeed", &usb_bam_data->max_mbps_superspeed); if (rc) usb_bam_data->max_mbps_superspeed = 0; rc = of_property_read_u32(node, "qcom,usb-bam-fifo-baseaddr", &addr); if (rc) log_event_dbg("%s: Invalid usb base address property\n", __func__); else usb_bam_data->usb_bam_fifo_baseaddr = addr; usb_bam_data->disable_clk_gating = of_property_read_bool(node, "qcom,disable-clk-gating"); rc = of_property_read_u32(node, "qcom,usb-bam-override-threshold", &threshold); if (rc) usb_bam_data->override_threshold = USB_THRESHOLD; else usb_bam_data->override_threshold = threshold; for_each_child_of_node(pdev->dev.of_node, node) max_connections++; if (!max_connections) { log_event_err("%s: error: max_connections is zero\n", __func__); goto err; } usb_bam_connections = devm_kzalloc(&pdev->dev, max_connections * sizeof(struct usb_bam_pipe_connect), GFP_KERNEL); if (!usb_bam_connections) { log_event_err("%s: devm_kzalloc failed(%d)\n", __func__, __LINE__); return NULL; } /* retrieve device tree parameters */ for_each_child_of_node(pdev->dev.of_node, node) { usb_bam_connections[i].bam_type = bam; rc = of_property_read_string(node, "label", &usb_bam_connections[i].name); if (rc) goto err; rc = of_property_read_u32(node, "qcom,usb-bam-mem-type", &usb_bam_connections[i].mem_type); if (rc) goto err; if (usb_bam_connections[i].mem_type == OCI_MEM) { if (!usb_bam_data->usb_bam_fifo_baseaddr) { log_event_err("%s: base address is missing\n", __func__); goto err; } } rc = of_property_read_u32(node, "qcom,peer-bam", &usb_bam_connections[i].peer_bam); if (rc) { log_event_err("%s: peer bam is missing in device tree\n", __func__); goto err; } /* * Store USB bam_type to be used with QDSS. As only one device * bam is currently supported, check the same in DT connections */ if (usb_bam_connections[i].peer_bam == QDSS_P_BAM) { if (qdss_usb_bam_type) { log_event_err("%s: overriding QDSS pipe!, update DT\n", __func__); } qdss_usb_bam_type = usb_bam_connections[i].bam_type; } rc = of_property_read_u32(node, "qcom,dir", &usb_bam_connections[i].dir); if (rc) { log_event_err("%s: direction is missing in device tree\n", __func__); goto err; } rc = of_property_read_u32(node, "qcom,pipe-num", &usb_bam_connections[i].pipe_num); if (rc) { log_event_err("%s: pipe num is missing in device tree\n", __func__); goto err; } rc = of_property_read_u32(node, "qcom,pipe-connection-type", &usb_bam_connections[i].pipe_type); if (rc) log_event_dbg("%s: pipe type is defaulting to bam2bam\n", __func__); of_property_read_u32(node, "qcom,peer-bam-physical-address", &addr); if (usb_bam_connections[i].dir == USB_TO_PEER_PERIPHERAL) { usb_bam_connections[i].src_phy_addr = usb_addr; usb_bam_connections[i].dst_phy_addr = addr; } else { usb_bam_connections[i].src_phy_addr = addr; usb_bam_connections[i].dst_phy_addr = usb_addr; } of_property_read_u32(node, "qcom,src-bam-pipe-index", &usb_bam_connections[i].src_pipe_index); of_property_read_u32(node, "qcom,dst-bam-pipe-index", &usb_bam_connections[i].dst_pipe_index); of_property_read_u32(node, "qcom,data-fifo-offset", &usb_bam_connections[i].data_fifo_base_offset); rc = of_property_read_u32(node, "qcom,data-fifo-size", &usb_bam_connections[i].data_fifo_size); if (rc) goto err; of_property_read_u32(node, "qcom,descriptor-fifo-offset", &usb_bam_connections[i].desc_fifo_base_offset); rc = of_property_read_u32(node, "qcom,descriptor-fifo-size", &usb_bam_connections[i].desc_fifo_size); if (rc) goto err; i++; } msm_usb_bam[bam].usb_bam_connections = usb_bam_connections; msm_usb_bam[bam].max_connections = max_connections; return usb_bam_data; err: log_event_err("%s: failed\n", __func__); return NULL; } static void msm_usb_bam_update_props(struct sps_bam_props *props, struct platform_device *pdev) { struct usb_bam_ctx_type *ctx = dev_get_drvdata(&pdev->dev); enum usb_ctrl bam_type = ctx->usb_bam_data->bam_type; struct device *dev; props->phys_addr = ctx->io_res->start; props->virt_addr = NULL; props->virt_size = resource_size(ctx->io_res); props->irq = ctx->irq; props->summing_threshold = ctx->usb_bam_data->override_threshold; props->event_threshold = ctx->usb_bam_data->override_threshold; props->num_pipes = ctx->usb_bam_data->usb_bam_num_pipes; props->callback = usb_bam_sps_events; props->user = bam_enable_strings[bam_type]; /* * HSUSB and HSIC Cores don't support RESET ACK signal to BAMs * Hence, let BAM to ignore acknowledge from USB while resetting PIPE */ if (ctx->usb_bam_data->ignore_core_reset_ack && bam_type != DWC3_CTRL) props->options = SPS_BAM_NO_EXT_P_RST; if (ctx->usb_bam_data->disable_clk_gating) props->options |= SPS_BAM_NO_LOCAL_CLK_GATING; /* * HSUSB BAM is not NDP BAM and it must be enabled before * starting peripheral controller to avoid switching USB core mode * from legacy to BAM with ongoing data transfers. */ if (bam_type == CI_CTRL) { log_event_dbg("Register and enable HSUSB BAM\n"); props->options |= SPS_BAM_OPT_ENABLE_AT_BOOT; props->options |= SPS_BAM_FORCE_RESET; } dev = &ctx->usb_bam_pdev->dev; if (dev && dev->parent && device_property_present(dev->parent, "iommus") && !device_property_present(dev->parent, "qcom,smmu-s1-bypass")) { pr_info("%s: setting SPS_BAM_SMMU_EN flag with (%s)\n", __func__, dev_name(dev)); props->options |= SPS_BAM_SMMU_EN; } } static int usb_bam_init(struct platform_device *pdev) { int ret; struct usb_bam_ctx_type *ctx = dev_get_drvdata(&pdev->dev); enum usb_ctrl bam_type = ctx->usb_bam_data->bam_type; struct sps_bam_props props; struct device *dev; memset(&props, 0, sizeof(props)); log_event_dbg("%s\n", __func__); props.phys_addr = ctx->io_res->start; props.virt_size = resource_size(ctx->io_res); props.irq = ctx->irq; props.summing_threshold = ctx->usb_bam_data->override_threshold; props.event_threshold = ctx->usb_bam_data->override_threshold; props.num_pipes = ctx->usb_bam_data->usb_bam_num_pipes; props.callback = usb_bam_sps_events; props.user = &msm_usb_bam[bam_type]; if (ctx->usb_bam_data->disable_clk_gating) props.options |= SPS_BAM_NO_LOCAL_CLK_GATING; dev = &ctx->usb_bam_pdev->dev; if (dev && dev->parent && device_property_present(dev->parent, "iommus") && !device_property_present(dev->parent, "qcom,smmu-s1-bypass")) { pr_info("%s: setting SPS_BAM_SMMU_EN flag with (%s)\n", __func__, dev_name(dev)); props.options |= SPS_BAM_SMMU_EN; } ret = sps_register_bam_device(&props, &ctx->h_bam); if (ret < 0) { log_event_err("%s: register bam error %d\n", __func__, ret); return -EFAULT; } return 0; } static int enable_usb_bam(struct platform_device *pdev) { int ret; struct usb_bam_ctx_type *ctx = dev_get_drvdata(&pdev->dev); ret = usb_bam_init(pdev); if (ret) return ret; ctx->usb_bam_sps.sps_pipes = devm_kzalloc(&pdev->dev, ctx->max_connections * sizeof(struct sps_pipe *), GFP_KERNEL); if (!ctx->usb_bam_sps.sps_pipes) { log_event_err("%s: failed to allocate sps_pipes\n", __func__); return -ENOMEM; } ctx->usb_bam_sps.sps_connections = devm_kzalloc(&pdev->dev, ctx->max_connections * sizeof(struct sps_connect), GFP_KERNEL); if (!ctx->usb_bam_sps.sps_connections) { log_event_err("%s: failed to allocate sps_connections\n", __func__); return -ENOMEM; } return 0; } static int usb_bam_panic_notifier(struct notifier_block *this, unsigned long event, void *ptr) { int i; struct usb_bam_ctx_type *ctx; for (i = 0; i < MAX_BAMS; i++) { ctx = &msm_usb_bam[i]; if (ctx->h_bam) break; } if (i == MAX_BAMS) goto fail; if (!ctx->pipes_enabled_per_bam || info[i].pipes_suspended) goto fail; pr_err("%s: dump usb bam registers here in call back!\n", __func__); sps_get_bam_debug_info(ctx->h_bam, 93, (SPS_BAM_PIPE(0) | SPS_BAM_PIPE(1)), 0, 2); fail: return NOTIFY_DONE; } static struct notifier_block usb_bam_panic_blk = { .notifier_call = usb_bam_panic_notifier, }; void usb_bam_register_panic_hdlr(void) { atomic_notifier_chain_register(&panic_notifier_list, &usb_bam_panic_blk); } static void usb_bam_unregister_panic_hdlr(void) { atomic_notifier_chain_unregister(&panic_notifier_list, &usb_bam_panic_blk); } static int usb_bam_probe(struct platform_device *pdev) { int ret, i, irq; struct resource *io_res; enum usb_ctrl bam_type; struct usb_bam_ctx_type *ctx; struct msm_usb_bam_data *usb_bam_data; dev_dbg(&pdev->dev, "%s\n", __func__); io_res = platform_get_resource(pdev, IORESOURCE_MEM, 0); if (!io_res) { dev_err(&pdev->dev, "missing BAM memory resource\n"); return -ENODEV; } irq = platform_get_irq(pdev, 0); if (irq < 0) { dev_err(&pdev->dev, "Unable to get IRQ resource\n"); return irq; } /* specify BAM physical address to be filled in BAM connections */ usb_bam_data = usb_bam_dt_to_data(pdev, io_res->start); if (!usb_bam_data) return -EINVAL; bam_type = usb_bam_data->bam_type; ctx = &msm_usb_bam[bam_type]; dev_set_drvdata(&pdev->dev, ctx); ctx->usb_bam_pdev = pdev; ctx->irq = irq; ctx->io_res = io_res; ctx->usb_bam_data = usb_bam_data; for (i = 0; i < ctx->max_connections; i++) { ctx->usb_bam_connections[i].enabled = 0; INIT_WORK(&ctx->usb_bam_connections[i].event.event_w, usb_bam_work); } init_completion(&info[bam_type].prod_avail); complete(&info[bam_type].prod_avail); init_completion(&info[bam_type].prod_released); complete(&info[bam_type].prod_released); info[bam_type].cur_prod_state = IPA_RM_RESOURCE_RELEASED; info[bam_type].cur_cons_state = IPA_RM_RESOURCE_RELEASED; info[bam_type].bam_type = bam_type; INIT_WORK(&info[bam_type].resume_work, usb_bam_finish_resume); INIT_WORK(&info[bam_type].finish_suspend_work, usb_bam_finish_suspend_); mutex_init(&info[bam_type].suspend_resume_mutex); ctx->usb_bam_wq = alloc_workqueue("usb_bam_wq", WQ_UNBOUND | WQ_MEM_RECLAIM, 1); if (!ctx->usb_bam_wq) { log_event_err("unable to create workqueue usb_bam_wq\n"); return -ENOMEM; } ret = enable_usb_bam(pdev); if (ret) { destroy_workqueue(ctx->usb_bam_wq); return ret; } pm_runtime_no_callbacks(&pdev->dev); pm_runtime_set_active(&pdev->dev); pm_runtime_enable(&pdev->dev); spin_lock_init(&usb_bam_ipa_handshake_info_lock); if (ipa_get_transport_type() == IPA_TRANSPORT_TYPE_SPS && ipa_is_ready()) usb_bam_ipa_create_resources(bam_type); spin_lock_init(&ctx->usb_bam_lock); usb_bam_register_panic_hdlr(); return ret; } bool usb_bam_get_prod_granted(enum usb_ctrl bam_type, u8 idx) { return (info[bam_type].cur_prod_state == IPA_RM_RESOURCE_GRANTED); } EXPORT_SYMBOL(usb_bam_get_prod_granted); int get_bam2bam_connection_info(enum usb_ctrl bam_type, u8 idx, u32 *usb_bam_pipe_idx, struct sps_mem_buffer *desc_fifo, struct sps_mem_buffer *data_fifo, enum usb_pipe_mem_type *mem_type) { struct usb_bam_ctx_type *ctx = &msm_usb_bam[bam_type]; struct usb_bam_pipe_connect *pipe_connect = &ctx->usb_bam_connections[idx]; enum usb_bam_pipe_dir dir = pipe_connect->dir; if (dir == USB_TO_PEER_PERIPHERAL) *usb_bam_pipe_idx = pipe_connect->src_pipe_index; else *usb_bam_pipe_idx = pipe_connect->dst_pipe_index; if (data_fifo) memcpy(data_fifo, &pipe_connect->data_mem_buf, sizeof(struct sps_mem_buffer)); if (desc_fifo) memcpy(desc_fifo, &pipe_connect->desc_mem_buf, sizeof(struct sps_mem_buffer)); if (mem_type) *mem_type = pipe_connect->mem_type; return 0; } EXPORT_SYMBOL(get_bam2bam_connection_info); int get_qdss_bam_connection_info(unsigned long *usb_bam_handle, u32 *usb_bam_pipe_idx, u32 *peer_pipe_idx, struct sps_mem_buffer *desc_fifo, struct sps_mem_buffer *data_fifo, enum usb_pipe_mem_type *mem_type) { u8 idx; struct usb_bam_ctx_type *ctx = &msm_usb_bam[qdss_usb_bam_type]; struct sps_connect *sps_connection; /* QDSS uses only one pipe */ idx = usb_bam_get_connection_idx(qdss_usb_bam_type, QDSS_P_BAM, PEER_PERIPHERAL_TO_USB, 0); get_bam2bam_connection_info(qdss_usb_bam_type, idx, usb_bam_pipe_idx, desc_fifo, data_fifo, mem_type); sps_connection = &ctx->usb_bam_sps.sps_connections[idx]; *usb_bam_handle = sps_connection->destination; *peer_pipe_idx = sps_connection->src_pipe_index; return 0; } EXPORT_SYMBOL(get_qdss_bam_connection_info); int usb_bam_get_connection_idx(enum usb_ctrl bam_type, enum peer_bam client, enum usb_bam_pipe_dir dir, u32 num) { struct usb_bam_ctx_type *ctx = &msm_usb_bam[bam_type]; u8 i; for (i = 0; i < ctx->max_connections; i++) { if (ctx->usb_bam_connections[i].peer_bam == client && ctx->usb_bam_connections[i].dir == dir && ctx->usb_bam_connections[i].pipe_num == num) { log_event_dbg("%s: index %d was found\n", __func__, i); return i; } } log_event_err("%s: failed for %d\n", __func__, bam_type); return -ENODEV; } EXPORT_SYMBOL(usb_bam_get_connection_idx); enum usb_ctrl usb_bam_get_bam_type(const char *core_name) { enum usb_ctrl bam_type = get_bam_type_from_core_name(core_name); if (bam_type < 0 || bam_type >= MAX_BAMS) { log_event_err("%s: Invalid bam, type=%d, name=%s\n", __func__, bam_type, core_name); return -EINVAL; } return bam_type; } EXPORT_SYMBOL(usb_bam_get_bam_type); bool msm_usb_bam_enable(enum usb_ctrl bam, bool bam_enable) { struct msm_usb_bam_data *usb_bam_data; struct usb_bam_ctx_type *ctx = &msm_usb_bam[bam]; static bool bam_enabled; int ret; if (!ctx->usb_bam_pdev) return false; usb_bam_data = ctx->usb_bam_data; if (bam != CI_CTRL) return false; if (bam_enabled == bam_enable) { log_event_dbg("%s: USB BAM is already %s\n", __func__, bam_enable ? "Registered" : "De-registered"); return false; } if (bam_enable) { struct sps_bam_props props; memset(&props, 0, sizeof(props)); msm_usb_bam_update_props(&props, ctx->usb_bam_pdev); msm_hw_bam_disable(1); ret = sps_register_bam_device(&props, &ctx->h_bam); bam_enabled = true; if (ret < 0) { log_event_err("%s: register bam error %d\n", __func__, ret); return false; } log_event_dbg("%s: USB BAM Registered\n", __func__); msm_hw_bam_disable(0); } else { msm_hw_soft_reset(); msm_hw_bam_disable(1); sps_device_reset(ctx->h_bam); sps_deregister_bam_device(ctx->h_bam); log_event_dbg("%s: USB BAM De-registered\n", __func__); bam_enabled = false; } return true; } EXPORT_SYMBOL(msm_usb_bam_enable); static int usb_bam_remove(struct platform_device *pdev) { struct usb_bam_ctx_type *ctx = dev_get_drvdata(&pdev->dev); usb_bam_ipa_delete_resources(ctx->usb_bam_data->bam_type); usb_bam_unregister_panic_hdlr(); sps_deregister_bam_device(ctx->h_bam); destroy_workqueue(ctx->usb_bam_wq); return 0; } static const struct of_device_id usb_bam_dt_match[] = { { .compatible = "qcom,usb-bam-msm", }, {} }; MODULE_DEVICE_TABLE(of, usb_bam_dt_match); static struct platform_driver usb_bam_driver = { .probe = usb_bam_probe, .remove = usb_bam_remove, .driver = { .name = "usb_bam", .of_match_table = usb_bam_dt_match, }, }; static int __init init(void) { return platform_driver_register(&usb_bam_driver); } module_init(init); static void __exit cleanup(void) { platform_driver_unregister(&usb_bam_driver); } module_exit(cleanup); MODULE_DESCRIPTION("MSM USB BAM DRIVER"); MODULE_LICENSE("GPL v2");