/* Copyright (c) 2012-2016, The Linux Foundation. All rights reserved. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License version 2 and * only version 2 as published by the Free Software Foundation. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "hfi_packetization.h" #include "msm_vidc_debug.h" #include "venus_hfi.h" #include "vidc_hfi_io.h" #define FIRMWARE_SIZE 0X00A00000 #define REG_ADDR_OFFSET_BITMASK 0x000FFFFF #define QDSS_IOVA_START 0x80001000 static struct hal_device_data hal_ctxt; #define TZBSP_MEM_PROTECT_VIDEO_VAR 0x8 struct tzbsp_memprot { u32 cp_start; u32 cp_size; u32 cp_nonpixel_start; u32 cp_nonpixel_size; }; struct tzbsp_resp { int ret; }; #define TZBSP_VIDEO_SET_STATE 0xa /* Poll interval in uS */ #define POLL_INTERVAL_US 50 enum tzbsp_video_state { TZBSP_VIDEO_STATE_SUSPEND = 0, TZBSP_VIDEO_STATE_RESUME = 1, TZBSP_VIDEO_STATE_RESTORE_THRESHOLD = 2, }; struct tzbsp_video_set_state_req { u32 state; /* should be tzbsp_video_state enum value */ u32 spare; /* reserved for future, should be zero */ }; const struct msm_vidc_gov_data DEFAULT_BUS_VOTE = { .data = NULL, .data_count = 0, .imem_size = 0, }; const int max_packets = 250; static void venus_hfi_pm_handler(struct work_struct *work); static DECLARE_DELAYED_WORK(venus_hfi_pm_work, venus_hfi_pm_handler); static inline int __resume(struct venus_hfi_device *device); static inline int __suspend(struct venus_hfi_device *device); static int __disable_regulators(struct venus_hfi_device *device); static int __enable_regulators(struct venus_hfi_device *device); static inline int __prepare_enable_clks(struct venus_hfi_device *device); static inline void __disable_unprepare_clks(struct venus_hfi_device *device); static int __scale_clocks_load(struct venus_hfi_device *device, int load, struct vidc_clk_scale_data *data, unsigned long instant_bitrate); static void __flush_debug_queue(struct venus_hfi_device *device, u8 *packet); static int __initialize_packetization(struct venus_hfi_device *device); static struct hal_session *__get_session(struct venus_hfi_device *device, u32 session_id); static int __iface_cmdq_write(struct venus_hfi_device *device, void *pkt); static int __load_fw(struct venus_hfi_device *device); static void __unload_fw(struct venus_hfi_device *device); static int __tzbsp_set_video_state(enum tzbsp_video_state state); /** * Utility function to enforce some of our assumptions. Spam calls to this * in hotspots in code to double check some of the assumptions that we hold. */ static inline void __strict_check(struct venus_hfi_device *device) { WARN_ON(!mutex_is_locked(&device->lock)); } static inline void __set_state(struct venus_hfi_device *device, enum venus_hfi_state state) { device->state = state; } static inline bool __core_in_valid_state(struct venus_hfi_device *device) { return device->state != VENUS_STATE_DEINIT; } static void __dump_packet(u8 *packet) { u32 c = 0, packet_size = *(u32 *)packet; const int row_size = 32; /* row must contain enough for 0xdeadbaad * 8 to be converted into * "de ad ba ab " * 8 + '\0' */ char row[3 * row_size]; for (c = 0; c * row_size < packet_size; ++c) { int bytes_to_read = ((c + 1) * row_size > packet_size) ? packet_size % row_size : row_size; hex_dump_to_buffer(packet + c * row_size, bytes_to_read, row_size, 4, row, sizeof(row), false); dprintk(VIDC_PKT, "%s\n", row); } } static void __sim_modify_cmd_packet(u8 *packet, struct venus_hfi_device *device) { struct hfi_cmd_sys_session_init_packet *sys_init; struct hal_session *session = NULL; u8 i; phys_addr_t fw_bias = 0; if (!device || !packet) { dprintk(VIDC_ERR, "Invalid Param\n"); return; } else if (!device->hal_data->firmware_base || is_iommu_present(device->res)) { return; } fw_bias = device->hal_data->firmware_base; sys_init = (struct hfi_cmd_sys_session_init_packet *)packet; session = __get_session(device, sys_init->session_id); if (!session) { dprintk(VIDC_DBG, "%s :Invalid session id: %x\n", __func__, sys_init->session_id); return; } switch (sys_init->packet_type) { case HFI_CMD_SESSION_EMPTY_BUFFER: if (session->is_decoder) { struct hfi_cmd_session_empty_buffer_compressed_packet *pkt = (struct hfi_cmd_session_empty_buffer_compressed_packet *) packet; pkt->packet_buffer -= fw_bias; } else { struct hfi_cmd_session_empty_buffer_uncompressed_plane0_packet *pkt = (struct hfi_cmd_session_empty_buffer_uncompressed_plane0_packet *) packet; pkt->packet_buffer -= fw_bias; } break; case HFI_CMD_SESSION_FILL_BUFFER: { struct hfi_cmd_session_fill_buffer_packet *pkt = (struct hfi_cmd_session_fill_buffer_packet *)packet; pkt->packet_buffer -= fw_bias; break; } case HFI_CMD_SESSION_SET_BUFFERS: { struct hfi_cmd_session_set_buffers_packet *pkt = (struct hfi_cmd_session_set_buffers_packet *)packet; if (pkt->buffer_type == HFI_BUFFER_OUTPUT || pkt->buffer_type == HFI_BUFFER_OUTPUT2) { struct hfi_buffer_info *buff; buff = (struct hfi_buffer_info *) pkt->rg_buffer_info; buff->buffer_addr -= fw_bias; if (buff->extra_data_addr >= fw_bias) buff->extra_data_addr -= fw_bias; } else { for (i = 0; i < pkt->num_buffers; i++) pkt->rg_buffer_info[i] -= fw_bias; } break; } case HFI_CMD_SESSION_RELEASE_BUFFERS: { struct hfi_cmd_session_release_buffer_packet *pkt = (struct hfi_cmd_session_release_buffer_packet *)packet; if (pkt->buffer_type == HFI_BUFFER_OUTPUT || pkt->buffer_type == HFI_BUFFER_OUTPUT2) { struct hfi_buffer_info *buff; buff = (struct hfi_buffer_info *) pkt->rg_buffer_info; buff->buffer_addr -= fw_bias; buff->extra_data_addr -= fw_bias; } else { for (i = 0; i < pkt->num_buffers; i++) pkt->rg_buffer_info[i] -= fw_bias; } break; } case HFI_CMD_SESSION_PARSE_SEQUENCE_HEADER: { struct hfi_cmd_session_parse_sequence_header_packet *pkt = (struct hfi_cmd_session_parse_sequence_header_packet *) packet; pkt->packet_buffer -= fw_bias; break; } case HFI_CMD_SESSION_GET_SEQUENCE_HEADER: { struct hfi_cmd_session_get_sequence_header_packet *pkt = (struct hfi_cmd_session_get_sequence_header_packet *) packet; pkt->packet_buffer -= fw_bias; break; } default: break; } } static int __acquire_regulator(struct regulator_info *rinfo) { int rc = 0; if (rinfo->has_hw_power_collapse) { rc = regulator_set_mode(rinfo->regulator, REGULATOR_MODE_NORMAL); if (rc) { /* * This is somewhat fatal, but nothing we can do * about it. We can't disable the regulator w/o * getting it back under s/w control */ dprintk(VIDC_WARN, "Failed to acquire regulator control: %s\n", rinfo->name); } else { dprintk(VIDC_DBG, "Acquire regulator control from HW: %s\n", rinfo->name); } } if (!regulator_is_enabled(rinfo->regulator)) { dprintk(VIDC_WARN, "Regulator is not enabled %s\n", rinfo->name); WARN_ON(1); } return rc; } static int __hand_off_regulator(struct regulator_info *rinfo) { int rc = 0; if (rinfo->has_hw_power_collapse) { rc = regulator_set_mode(rinfo->regulator, REGULATOR_MODE_FAST); if (rc) { dprintk(VIDC_WARN, "Failed to hand off regulator control: %s\n", rinfo->name); } else { dprintk(VIDC_DBG, "Hand off regulator control to HW: %s\n", rinfo->name); } } return rc; } static int __hand_off_regulators(struct venus_hfi_device *device) { struct regulator_info *rinfo; int rc = 0, c = 0; venus_hfi_for_each_regulator(device, rinfo) { rc = __hand_off_regulator(rinfo); /* * If one regulator hand off failed, driver should take * the control for other regulators back. */ if (rc) goto err_reg_handoff_failed; c++; } return rc; err_reg_handoff_failed: venus_hfi_for_each_regulator_reverse_continue(device, rinfo, c) __acquire_regulator(rinfo); return rc; } static int __write_queue(struct vidc_iface_q_info *qinfo, u8 *packet, bool *rx_req_is_set) { struct hfi_queue_header *queue; u32 packet_size_in_words, new_write_idx; u32 empty_space, read_idx; u32 *write_ptr; if (!qinfo || !packet) { dprintk(VIDC_ERR, "Invalid Params\n"); return -EINVAL; } else if (!qinfo->q_array.align_virtual_addr) { dprintk(VIDC_WARN, "Queues have already been freed\n"); return -EINVAL; } queue = (struct hfi_queue_header *) qinfo->q_hdr; if (!queue) { dprintk(VIDC_ERR, "queue not present\n"); return -ENOENT; } if (msm_vidc_debug & VIDC_PKT) { dprintk(VIDC_PKT, "%s: %p\n", __func__, qinfo); __dump_packet(packet); } packet_size_in_words = (*(u32 *)packet) >> 2; if (!packet_size_in_words) { dprintk(VIDC_ERR, "Zero packet size\n"); return -ENODATA; } read_idx = queue->qhdr_read_idx; empty_space = (queue->qhdr_write_idx >= read_idx) ? (queue->qhdr_q_size - (queue->qhdr_write_idx - read_idx)) : (read_idx - queue->qhdr_write_idx); if (empty_space <= packet_size_in_words) { queue->qhdr_tx_req = 1; dprintk(VIDC_ERR, "Insufficient size (%d) to write (%d)\n", empty_space, packet_size_in_words); return -ENOTEMPTY; } queue->qhdr_tx_req = 0; new_write_idx = (queue->qhdr_write_idx + packet_size_in_words); write_ptr = (u32 *)((qinfo->q_array.align_virtual_addr) + (queue->qhdr_write_idx << 2)); if (new_write_idx < queue->qhdr_q_size) { memcpy(write_ptr, packet, packet_size_in_words << 2); } else { new_write_idx -= queue->qhdr_q_size; memcpy(write_ptr, packet, (packet_size_in_words - new_write_idx) << 2); memcpy((void *)qinfo->q_array.align_virtual_addr, packet + ((packet_size_in_words - new_write_idx) << 2), new_write_idx << 2); } /* Memory barrier to make sure packet is written before updating the * write index */ mb(); queue->qhdr_write_idx = new_write_idx; if (rx_req_is_set) *rx_req_is_set = queue->qhdr_rx_req == 1; /* Memory barrier to make sure write index is updated before an * interrupt is raised on venus. */ mb(); return 0; } static void __hal_sim_modify_msg_packet(u8 *packet, struct venus_hfi_device *device) { struct hfi_msg_sys_session_init_done_packet *sys_idle; struct hal_session *session = NULL; phys_addr_t fw_bias = 0; if (!device || !packet) { dprintk(VIDC_ERR, "Invalid Param\n"); return; } else if (!device->hal_data->firmware_base || is_iommu_present(device->res)) { return; } fw_bias = device->hal_data->firmware_base; sys_idle = (struct hfi_msg_sys_session_init_done_packet *)packet; session = __get_session(device, sys_idle->session_id); if (!session) { dprintk(VIDC_DBG, "%s: Invalid session id: %x\n", __func__, sys_idle->session_id); return; } switch (sys_idle->packet_type) { case HFI_MSG_SESSION_FILL_BUFFER_DONE: if (session->is_decoder) { struct hfi_msg_session_fbd_uncompressed_plane0_packet *pkt_uc = (struct hfi_msg_session_fbd_uncompressed_plane0_packet *) packet; pkt_uc->packet_buffer += fw_bias; } else { struct hfi_msg_session_fill_buffer_done_compressed_packet *pkt = (struct hfi_msg_session_fill_buffer_done_compressed_packet *) packet; pkt->packet_buffer += fw_bias; } break; case HFI_MSG_SESSION_EMPTY_BUFFER_DONE: { struct hfi_msg_session_empty_buffer_done_packet *pkt = (struct hfi_msg_session_empty_buffer_done_packet *)packet; pkt->packet_buffer += fw_bias; break; } case HFI_MSG_SESSION_GET_SEQUENCE_HEADER_DONE: { struct hfi_msg_session_get_sequence_header_done_packet *pkt = (struct hfi_msg_session_get_sequence_header_done_packet *) packet; pkt->sequence_header += fw_bias; break; } default: break; } } static int __read_queue(struct vidc_iface_q_info *qinfo, u8 *packet, u32 *pb_tx_req_is_set) { struct hfi_queue_header *queue; u32 packet_size_in_words, new_read_idx; u32 *read_ptr; u32 receive_request = 0; int rc = 0; if (!qinfo || !packet || !pb_tx_req_is_set) { dprintk(VIDC_ERR, "Invalid Params\n"); return -EINVAL; } else if (!qinfo->q_array.align_virtual_addr) { dprintk(VIDC_WARN, "Queues have already been freed\n"); return -EINVAL; } /*Memory barrier to make sure data is valid before *reading it*/ mb(); queue = (struct hfi_queue_header *) qinfo->q_hdr; if (!queue) { dprintk(VIDC_ERR, "Queue memory is not allocated\n"); return -ENOMEM; } /* * Do not set receive request for debug queue, if set, * Venus generates interrupt for debug messages even * when there is no response message available. * In general debug queue will not become full as it * is being emptied out for every interrupt from Venus. * Venus will anyway generates interrupt if it is full. */ if (queue->qhdr_type & HFI_Q_ID_CTRL_TO_HOST_MSG_Q) receive_request = 1; if (queue->qhdr_read_idx == queue->qhdr_write_idx) { queue->qhdr_rx_req = receive_request; *pb_tx_req_is_set = 0; dprintk(VIDC_DBG, "%s queue is empty, rx_req = %u, tx_req = %u, read_idx = %u\n", receive_request ? "message" : "debug", queue->qhdr_rx_req, queue->qhdr_tx_req, queue->qhdr_read_idx); return -ENODATA; } read_ptr = (u32 *)((qinfo->q_array.align_virtual_addr) + (queue->qhdr_read_idx << 2)); packet_size_in_words = (*read_ptr) >> 2; if (!packet_size_in_words) { dprintk(VIDC_ERR, "Zero packet size\n"); return -ENODATA; } new_read_idx = queue->qhdr_read_idx + packet_size_in_words; if (((packet_size_in_words << 2) <= VIDC_IFACEQ_VAR_HUGE_PKT_SIZE) && queue->qhdr_read_idx <= queue->qhdr_q_size) { if (new_read_idx < queue->qhdr_q_size) { memcpy(packet, read_ptr, packet_size_in_words << 2); } else { new_read_idx -= queue->qhdr_q_size; memcpy(packet, read_ptr, (packet_size_in_words - new_read_idx) << 2); memcpy(packet + ((packet_size_in_words - new_read_idx) << 2), (u8 *)qinfo->q_array.align_virtual_addr, new_read_idx << 2); } } else { dprintk(VIDC_WARN, "BAD packet received, read_idx: %#x, pkt_size: %d\n", queue->qhdr_read_idx, packet_size_in_words << 2); dprintk(VIDC_WARN, "Dropping this packet\n"); new_read_idx = queue->qhdr_write_idx; rc = -ENODATA; } queue->qhdr_read_idx = new_read_idx; if (queue->qhdr_read_idx != queue->qhdr_write_idx) queue->qhdr_rx_req = 0; else queue->qhdr_rx_req = receive_request; *pb_tx_req_is_set = (1 == queue->qhdr_tx_req) ? 1 : 0; if (msm_vidc_debug & VIDC_PKT) { dprintk(VIDC_PKT, "%s: %p\n", __func__, qinfo); __dump_packet(packet); } return rc; } static int __smem_alloc(struct venus_hfi_device *dev, struct vidc_mem_addr *mem, u32 size, u32 align, u32 flags, u32 usage) { struct msm_smem *alloc = NULL; int rc = 0; if (!dev || !dev->hal_client || !mem || !size) { dprintk(VIDC_ERR, "Invalid Params\n"); return -EINVAL; } dprintk(VIDC_INFO, "start to alloc size: %d, flags: %d\n", size, flags); alloc = msm_smem_alloc(dev->hal_client, size, align, flags, usage, 1); if (!alloc) { dprintk(VIDC_ERR, "Alloc failed\n"); rc = -ENOMEM; goto fail_smem_alloc; } dprintk(VIDC_DBG, "__smem_alloc: ptr = %p, size = %d\n", alloc->kvaddr, size); rc = msm_smem_cache_operations(dev->hal_client, alloc, SMEM_CACHE_CLEAN); if (rc) { dprintk(VIDC_WARN, "Failed to clean cache\n"); dprintk(VIDC_WARN, "This may result in undefined behavior\n"); } mem->mem_size = alloc->size; mem->mem_data = alloc; mem->align_virtual_addr = alloc->kvaddr; mem->align_device_addr = alloc->device_addr; return rc; fail_smem_alloc: return rc; } static void __smem_free(struct venus_hfi_device *dev, struct msm_smem *mem) { if (!dev || !mem) { dprintk(VIDC_ERR, "invalid param %p %p\n", dev, mem); return; } msm_smem_free(dev->hal_client, mem); } static void __write_register(struct venus_hfi_device *device, u32 reg, u32 value) { u32 hwiosymaddr = reg; u8 *base_addr; if (!device) { dprintk(VIDC_ERR, "Invalid params: %p\n", device); return; } __strict_check(device); if (!device->power_enabled) { dprintk(VIDC_WARN, "HFI Write register failed : Power is OFF\n"); WARN_ON(1); return; } base_addr = device->hal_data->register_base; dprintk(VIDC_DBG, "Base addr: %p, written to: %#x, Value: %#x...\n", base_addr, hwiosymaddr, value); base_addr += hwiosymaddr; writel_relaxed(value, base_addr); wmb(); } static int __read_register(struct venus_hfi_device *device, u32 reg) { int rc = 0; u8 *base_addr; if (!device) { dprintk(VIDC_ERR, "Invalid params: %p\n", device); return -EINVAL; } __strict_check(device); if (!device->power_enabled) { dprintk(VIDC_WARN, "HFI Read register failed : Power is OFF\n"); WARN_ON(1); return -EINVAL; } base_addr = device->hal_data->register_base; rc = readl_relaxed(base_addr + reg); rmb(); dprintk(VIDC_DBG, "Base addr: %p, read from: %#x, value: %#x...\n", base_addr, reg, rc); return rc; } static void __set_registers(struct venus_hfi_device *device) { struct reg_set *reg_set; int i; if (!device->res) { dprintk(VIDC_ERR, "device resources null, cannot set registers\n"); return; } reg_set = &device->res->reg_set; for (i = 0; i < reg_set->count; i++) { __write_register(device, reg_set->reg_tbl[i].reg, reg_set->reg_tbl[i].value); } } /* * The existence of this function is a hack for 8996 (or certain Venus versions) * to overcome a hardware bug. Whenever the GDSCs momentarily power collapse * (after calling __hand_off_regulators()), the values of the threshold * registers (typically programmed by TZ) are incorrectly reset. As a result * reprogram these registers at certain agreed upon points. */ static void __set_threshold_registers(struct venus_hfi_device *device) { u32 version = __read_register(device, VIDC_WRAPPER_HW_VERSION); version &= ~GENMASK(15, 0); if (version != (0x3 << 28 | 0x43 << 16)) return; if (__tzbsp_set_video_state(TZBSP_VIDEO_STATE_RESTORE_THRESHOLD)) dprintk(VIDC_ERR, "Failed to restore threshold values\n"); } static void __iommu_detach(struct venus_hfi_device *device) { struct context_bank_info *cb; if (!device || !device->res) { dprintk(VIDC_ERR, "Invalid paramter: %p\n", device); return; } list_for_each_entry(cb, &device->res->context_banks, list) { if (cb->dev) arm_iommu_detach_device(cb->dev); if (cb->mapping) arm_iommu_release_mapping(cb->mapping); } } static bool __is_session_supported(unsigned long sessions_supported, enum vidc_vote_data_session session_type) { bool same_codec, same_session_type; int codec_bit, session_type_bit; unsigned long session = session_type; if (!sessions_supported || !session) return false; /* ffs returns a 1 indexed, test_bit takes a 0 indexed...index */ codec_bit = ffs(session) - 1; session_type_bit = codec_bit + 1; same_codec = test_bit(codec_bit, &sessions_supported) == test_bit(codec_bit, &session); same_session_type = test_bit(session_type_bit, &sessions_supported) == test_bit(session_type_bit, &session); return same_codec && same_session_type; } bool venus_hfi_is_session_supported(unsigned long sessions_supported, enum vidc_vote_data_session session_type) { return __is_session_supported(sessions_supported, session_type); } static int __devfreq_target(struct device *devfreq_dev, unsigned long *freq, u32 flags) { int rc = 0; uint64_t ab = 0; struct bus_info *bus = NULL, *temp = NULL; struct venus_hfi_device *device = dev_get_drvdata(devfreq_dev); venus_hfi_for_each_bus(device, temp) { if (temp->dev == devfreq_dev) { bus = temp; break; } } if (!bus) { rc = -EBADHANDLE; goto err_unknown_device; } /* * Clamp for all non zero frequencies. This clamp is necessary to stop * devfreq driver from spamming - Couldn't update frequency - logs, if * the scaled ab value is not part of the frequency table. */ if (*freq) *freq = clamp_t(typeof(*freq), *freq, bus->range[0], bus->range[1]); /* we expect governors to provide values in kBps form, convert to Bps */ ab = *freq * 1000; rc = msm_bus_scale_update_bw(bus->client, ab, 0); if (rc) { dprintk(VIDC_ERR, "Failed voting bus %s to ab %llu\n: %d", bus->name, ab, rc); goto err_unknown_device; } dprintk(VIDC_PROF, "Voting bus %s to ab %llu\n", bus->name, ab); return 0; err_unknown_device: return rc; } static int __devfreq_get_status(struct device *devfreq_dev, struct devfreq_dev_status *stat) { int rc = 0; struct bus_info *bus = NULL, *temp = NULL; struct venus_hfi_device *device = dev_get_drvdata(devfreq_dev); venus_hfi_for_each_bus(device, temp) { if (temp->dev == devfreq_dev) { bus = temp; break; } } if (!bus) { rc = -EBADHANDLE; goto err_unknown_device; } *stat = (struct devfreq_dev_status) { .private_data = &device->bus_vote, /* * Put in dummy place holder values for upstream govs, our * custom gov only needs .private_data. We should fill this in * properly if we can actually measure busy_time accurately * (which we can't at the moment) */ .total_time = 1, .busy_time = 1, .current_frequency = 0, }; err_unknown_device: return rc; } static int __unvote_buses(struct venus_hfi_device *device) { int rc = 0; struct bus_info *bus = NULL; venus_hfi_for_each_bus(device, bus) { int local_rc = 0; unsigned long zero = 0; rc = devfreq_suspend_device(bus->devfreq); if (rc) goto err_unknown_device; local_rc = __devfreq_target(bus->dev, &zero, 0); rc = rc ?: local_rc; } if (rc) dprintk(VIDC_WARN, "Failed to unvote some buses\n"); err_unknown_device: return rc; } static int __vote_buses(struct venus_hfi_device *device, struct vidc_bus_vote_data *data, int num_data) { int rc = 0; struct bus_info *bus = NULL; struct vidc_bus_vote_data *new_data = NULL; if (!num_data) { dprintk(VIDC_DBG, "No vote data available\n"); goto no_data_count; } else if (!data) { dprintk(VIDC_ERR, "Invalid voting data\n"); return -EINVAL; } new_data = kmemdup(data, num_data * sizeof(*new_data), GFP_KERNEL); if (!new_data) { dprintk(VIDC_ERR, "Can't alloc memory to cache bus votes\n"); rc = -ENOMEM; goto err_no_mem; } no_data_count: kfree(device->bus_vote.data); device->bus_vote.data = new_data; device->bus_vote.data_count = num_data; device->bus_vote.imem_size = device->res->imem_size; venus_hfi_for_each_bus(device, bus) { if (bus && bus->devfreq) { /* NOP if already resume */ rc = devfreq_resume_device(bus->devfreq); if (rc) goto err_no_mem; /* Kick devfreq awake incase _resume() didn't do it */ bus->devfreq->nb.notifier_call( &bus->devfreq->nb, 0, NULL); } } err_no_mem: return rc; } static int venus_hfi_vote_buses(void *dev, struct vidc_bus_vote_data *d, int n) { int rc = 0; struct venus_hfi_device *device = dev; if (!device) return -EINVAL; mutex_lock(&device->lock); rc = __vote_buses(device, d, n); mutex_unlock(&device->lock); return rc; } static int __core_set_resource(struct venus_hfi_device *device, struct vidc_resource_hdr *resource_hdr, void *resource_value) { struct hfi_cmd_sys_set_resource_packet *pkt; u8 packet[VIDC_IFACEQ_VAR_SMALL_PKT_SIZE]; int rc = 0; if (!device || !resource_hdr || !resource_value) { dprintk(VIDC_ERR, "set_res: Invalid Params\n"); return -EINVAL; } pkt = (struct hfi_cmd_sys_set_resource_packet *) packet; rc = call_hfi_pkt_op(device, sys_set_resource, pkt, resource_hdr, resource_value); if (rc) { dprintk(VIDC_ERR, "set_res: failed to create packet\n"); goto err_create_pkt; } rc = __iface_cmdq_write(device, pkt); if (rc) rc = -ENOTEMPTY; err_create_pkt: return rc; } static DECLARE_COMPLETION(release_resources_done); static int __alloc_imem(struct venus_hfi_device *device, unsigned long size) { struct imem *imem = NULL; int rc = 0; if (!device) return -EINVAL; imem = &device->resources.imem; if (imem->type) { dprintk(VIDC_ERR, "IMEM of type %d already allocated\n", imem->type); return -ENOMEM; } switch (device->res->imem_type) { case IMEM_VMEM: { phys_addr_t vmem_buffer = 0; rc = vmem_allocate(size, &vmem_buffer); if (rc) { if (rc == -ENOTSUPP) { dprintk(VIDC_DBG, "Target does not support vmem\n"); rc = 0; } goto imem_alloc_failed; } else if (!vmem_buffer) { rc = -ENOMEM; goto imem_alloc_failed; } imem->vmem = vmem_buffer; break; } case IMEM_NONE: rc = 0; break; default: rc = -ENOTSUPP; goto imem_alloc_failed; } imem->type = device->res->imem_type; dprintk(VIDC_DBG, "Allocated %ld bytes of IMEM of type %d\n", size, imem->type); return 0; imem_alloc_failed: imem->type = IMEM_NONE; return rc; } static int __free_imem(struct venus_hfi_device *device) { struct imem *imem = NULL; int rc = 0; if (!device) return -EINVAL; imem = &device->resources.imem; switch (imem->type) { case IMEM_NONE: /* Follow the semantics of free(NULL), which is a no-op. */ break; case IMEM_VMEM: vmem_free(imem->vmem); break; default: rc = -ENOTSUPP; goto imem_free_failed; } imem->type = IMEM_NONE; return 0; imem_free_failed: return rc; } static int __set_imem(struct venus_hfi_device *device, struct imem *imem) { struct vidc_resource_hdr rhdr; phys_addr_t addr = 0; int rc = 0; if (!device || !device->res || !imem) { dprintk(VIDC_ERR, "Invalid params, core: %p, imem: %p\n", device, imem); return -EINVAL; } rhdr.resource_handle = imem; /* cookie */ rhdr.size = device->res->imem_size; rhdr.resource_id = VIDC_RESOURCE_NONE; switch (imem->type) { case IMEM_VMEM: rhdr.resource_id = VIDC_RESOURCE_VMEM; addr = imem->vmem; break; case IMEM_NONE: dprintk(VIDC_DBG, "%s Target does not support IMEM", __func__); rc = 0; goto imem_set_failed; default: dprintk(VIDC_ERR, "IMEM of type %d unsupported\n", imem->type); rc = -ENOTSUPP; goto imem_set_failed; } BUG_ON(!addr); rc = __core_set_resource(device, &rhdr, (void *)addr); if (rc) { dprintk(VIDC_ERR, "Failed to set IMEM on driver\n"); goto imem_set_failed; } dprintk(VIDC_DBG, "Managed to set IMEM buffer of type %d sized %d bytes at %pa\n", rhdr.resource_id, rhdr.size, &addr); rc = __vote_buses(device, device->bus_vote.data, device->bus_vote.data_count); if (rc) { dprintk(VIDC_ERR, "Failed to vote for buses after setting imem: %d\n", rc); } imem_set_failed: return rc; } static int __tzbsp_set_video_state(enum tzbsp_video_state state) { struct tzbsp_video_set_state_req cmd = {0}; int tzbsp_rsp = 0; int rc = 0; struct scm_desc desc = {0}; desc.args[0] = cmd.state = state; desc.args[1] = cmd.spare = 0; desc.arginfo = SCM_ARGS(2); if (!is_scm_armv8()) { rc = scm_call(SCM_SVC_BOOT, TZBSP_VIDEO_SET_STATE, &cmd, sizeof(cmd), &tzbsp_rsp, sizeof(tzbsp_rsp)); } else { rc = scm_call2(SCM_SIP_FNID(SCM_SVC_BOOT, TZBSP_VIDEO_SET_STATE), &desc); tzbsp_rsp = desc.ret[0]; } if (rc) { dprintk(VIDC_ERR, "Failed scm_call %d\n", rc); return rc; } dprintk(VIDC_DBG, "Set state %d, resp %d\n", state, tzbsp_rsp); if (tzbsp_rsp) { dprintk(VIDC_ERR, "Failed to set video core state to suspend: %d\n", tzbsp_rsp); return -EINVAL; } return 0; } static inline int __boot_firmware(struct venus_hfi_device *device) { int rc = 0; u32 ctrl_status = 0, count = 0, max_tries = 100; __write_register(device, VIDC_CTRL_INIT, 0x1); while (!ctrl_status && count < max_tries) { ctrl_status = __read_register(device, VIDC_CPU_CS_SCIACMDARG0); if ((ctrl_status & 0xFE) == 0x4) { dprintk(VIDC_ERR, "invalid setting for UC_REGION\n"); break; } usleep_range(500, 1000); count++; } if (count >= max_tries) { dprintk(VIDC_ERR, "Error booting up vidc firmware\n"); rc = -ETIME; } return rc; } static struct clock_info *__get_clock(struct venus_hfi_device *device, char *name) { struct clock_info *vc; venus_hfi_for_each_clock(device, vc) { if (!strcmp(vc->name, name)) return vc; } dprintk(VIDC_WARN, "%s Clock %s not found\n", __func__, name); return NULL; } static struct regulator_info *__get_regulator(struct venus_hfi_device *device, char *name) { struct regulator_info *r; venus_hfi_for_each_regulator(device, r) { if (!strcmp(r->name, name)) return r; } dprintk(VIDC_WARN, "%s Regulator %s not found\n", __func__, name); return NULL; } static unsigned long __get_clock_rate(struct clock_info *clock, int num_mbs_per_sec, struct vidc_clk_scale_data *data) { int num_rows = clock->count; struct load_freq_table *table = clock->load_freq_tbl; unsigned long freq = table[0].freq, max_freq = 0; int i = 0, j = 0; unsigned long instance_freq[VIDC_MAX_SESSIONS] = {0}; if (!data && !num_rows) { freq = 0; goto print_clk; } if ((!num_mbs_per_sec || !data) && num_rows) { freq = table[num_rows - 1].freq; goto print_clk; } for (i = 0; i < num_rows; i++) { if (num_mbs_per_sec > table[i].load) break; for (j = 0; j < data->num_sessions; j++) { bool matches = __is_session_supported( table[i].supported_codecs, data->session[j]); if (!matches) continue; instance_freq[j] = table[i].freq; } } for (i = 0; i < data->num_sessions; i++) max_freq = max(instance_freq[i], max_freq); freq = max_freq ? : freq; print_clk: dprintk(VIDC_PROF, "Required clock rate = %lu num_mbs_per_sec %d\n", freq, num_mbs_per_sec); return freq; } static unsigned long __get_clock_rate_with_bitrate(struct clock_info *clock, int num_mbs_per_sec, struct vidc_clk_scale_data *data, unsigned long instant_bitrate) { int num_rows = clock->count; struct load_freq_table *table = clock->load_freq_tbl; unsigned long freq = table[0].freq, max_freq = 0; unsigned long base_freq, supported_clk[VIDC_MAX_SESSIONS] = {0}; int i, j; if (!data && !num_rows) { freq = 0; goto print_clk; } if ((!num_mbs_per_sec || !data) && num_rows) { freq = table[num_rows - 1].freq; goto print_clk; } /* Get clock rate based on current load only */ base_freq = __get_clock_rate(clock, num_mbs_per_sec, data); /* * Supported bitrate = 40% of clock frequency * Check if the instant bitrate is supported by the base frequency. * If not, move on to the next frequency which supports the bitrate. */ for (j = 0; j < data->num_sessions; j++) { unsigned long supported_bitrate = 0; for (i = num_rows - 1; i >= 0; i--) { bool matches = __is_session_supported( table[i].supported_codecs, data->session[j]); if (!matches) continue; freq = table[i].freq; supported_bitrate = freq * 40/100; /* * Store this frequency for each instance, we need * to select the maximum freq among all the instances. */ if (freq >= base_freq && supported_bitrate >= instant_bitrate) { supported_clk[j] = freq; break; } } } for (i = 0; i < data->num_sessions; i++) max_freq = max(supported_clk[i], max_freq); freq = max_freq ? : base_freq; if (base_freq == freq) dprintk(VIDC_DBG, "Stay at base freq: %lu bitrate = %lu\n", freq, instant_bitrate); else dprintk(VIDC_DBG, "Move up clock freq: %lu bitrate = %lu\n", freq, instant_bitrate); print_clk: dprintk(VIDC_PROF, "Required clock rate = %lu num_mbs_per_sec %d\n", freq, num_mbs_per_sec); return freq; } static unsigned long venus_hfi_get_core_clock_rate(void *dev, bool actual_rate) { struct venus_hfi_device *device = (struct venus_hfi_device *) dev; struct clock_info *vc; if (!device) { dprintk(VIDC_ERR, "%s Invalid args: %p\n", __func__, device); return -EINVAL; } if (actual_rate) { vc = __get_clock(device, "core_clk"); if (vc) return clk_get_rate(vc->clk); else return 0; } else { return device->scaled_rate; } } static int venus_hfi_suspend(void *dev) { int rc = 0; struct venus_hfi_device *device = (struct venus_hfi_device *) dev; if (!device) { dprintk(VIDC_ERR, "%s invalid device\n", __func__); return -EINVAL; } else if (!device->res->sw_power_collapsible) { return -ENOTSUPP; } mutex_lock(&device->lock); if (device->power_enabled) { dprintk(VIDC_DBG, "Venus is busy\n"); rc = -EBUSY; } else { dprintk(VIDC_DBG, "Venus is power suspended\n"); rc = 0; } mutex_unlock(&device->lock); return rc; } static enum hal_default_properties venus_hfi_get_default_properties(void *dev) { enum hal_default_properties prop = 0; struct venus_hfi_device *device = (struct venus_hfi_device *) dev; if (!device) { dprintk(VIDC_ERR, "%s invalid device\n", __func__); return -EINVAL; } mutex_lock(&device->lock); if (device->packetization_type == HFI_PACKETIZATION_3XX) prop = HAL_VIDEO_DYNAMIC_BUF_MODE; mutex_unlock(&device->lock); return prop; } static int __halt_axi(struct venus_hfi_device *device) { u32 reg; int rc = 0; if (!device) { dprintk(VIDC_ERR, "Invalid input: %p\n", device); return -EINVAL; } /* * Driver needs to make sure that clocks are enabled to read Venus AXI * registers. If not skip AXI HALT. */ if (!device->power_enabled) { dprintk(VIDC_WARN, "Clocks are OFF, skipping AXI HALT\n"); WARN_ON(1); return -EINVAL; } /* Halt AXI and AXI IMEM VBIF Access */ reg = __read_register(device, VENUS_VBIF_AXI_HALT_CTRL0); reg |= VENUS_VBIF_AXI_HALT_CTRL0_HALT_REQ; __write_register(device, VENUS_VBIF_AXI_HALT_CTRL0, reg); /* Request for AXI bus port halt */ rc = readl_poll_timeout(device->hal_data->register_base + VENUS_VBIF_AXI_HALT_CTRL1, reg, reg & VENUS_VBIF_AXI_HALT_CTRL1_HALT_ACK, POLL_INTERVAL_US, VENUS_VBIF_AXI_HALT_ACK_TIMEOUT_US); if (rc) dprintk(VIDC_WARN, "AXI bus port halt timeout\n"); return rc; } static int __scale_clocks_cycles_per_mb(struct venus_hfi_device *device, struct vidc_clk_scale_data *data, unsigned long instant_bitrate) { int rc = 0, i = 0, j = 0; struct clock_info *cl; struct clock_freq_table *clk_freq_tbl = NULL; struct allowed_clock_rates_table *allowed_clks_tbl = NULL; struct clock_profile_entry *entry = NULL; u64 total_freq = 0, rate = 0; clk_freq_tbl = &device->res->clock_freq_tbl; allowed_clks_tbl = device->res->allowed_clks_tbl; if (!data) { dprintk(VIDC_DBG, "%s: NULL scale data\n", __func__); total_freq = device->clk_freq; goto get_clock_freq; } device->clk_bitrate = instant_bitrate; for (i = 0; i < data->num_sessions; i++) { /* * for each active session iterate through all possible * sessions and get matching session's cycles per mb * from dtsi and multiply with the session's load to * get the frequency required for the session. * accumulate all session's frequencies to get the * total clock frequency. */ for (j = 0; j < clk_freq_tbl->count; j++) { bool matched = false; u64 freq = 0; entry = &clk_freq_tbl->clk_prof_entries[j]; matched = __is_session_supported(entry->codec_mask, data->session[i]); if (!matched) continue; freq = entry->cycles * data->load[i]; if (data->power_mode[i] == VIDC_POWER_LOW && entry->low_power_factor) { /* low_power_factor is in Q16 format */ freq = (freq * entry->low_power_factor) >> 16; } total_freq += freq; dprintk(VIDC_DBG, "session[%d] %#x: cycles (%d), load (%d), freq (%llu), factor (%d)\n", i, data->session[i], entry->cycles, data->load[i], freq, entry->low_power_factor); } } get_clock_freq: /* * get required clock rate from allowed clock rates table */ for (i = device->res->allowed_clks_tbl_size - 1; i >= 0; i--) { rate = allowed_clks_tbl[i].clock_rate; if (rate >= total_freq) break; } venus_hfi_for_each_clock(device, cl) { if (!cl->has_scaling) continue; device->clk_freq = rate; rc = clk_set_rate(cl->clk, rate); if (rc) { dprintk(VIDC_ERR, "%s: Failed to set clock rate %llu %s: %d\n", __func__, rate, cl->name, rc); return rc; } if (!strcmp(cl->name, "core_clk")) device->scaled_rate = rate; dprintk(VIDC_DBG, "scaling clock %s to %llu (required freq %llu)\n", cl->name, rate, total_freq); } return rc; } static int __scale_clocks_load(struct venus_hfi_device *device, int load, struct vidc_clk_scale_data *data, unsigned long instant_bitrate) { struct clock_info *cl; device->clk_bitrate = instant_bitrate; venus_hfi_for_each_clock(device, cl) { if (cl->has_scaling) { unsigned long rate = 0; int rc; /* * load_fw and power_on needs to be addressed. * differently. Below check enforces the same. */ if (!device->clk_bitrate && !data && !load && device->clk_freq) rate = device->clk_freq; if (!rate) { if (!device->clk_bitrate) rate = __get_clock_rate(cl, load, data); else rate = __get_clock_rate_with_bitrate(cl, load, data, instant_bitrate); } device->clk_freq = rate; rc = clk_set_rate(cl->clk, rate); if (rc) { dprintk(VIDC_ERR, "Failed to set clock rate %lu %s: %d\n", rate, cl->name, rc); return rc; } if (!strcmp(cl->name, "core_clk")) device->scaled_rate = rate; dprintk(VIDC_PROF, "Scaling clock %s to %lu\n", cl->name, rate); } } return 0; } static int __scale_clocks(struct venus_hfi_device *device, int load, struct vidc_clk_scale_data *data, unsigned long instant_bitrate) { int rc = 0; if (device->res->clock_freq_tbl.clk_prof_entries && device->res->allowed_clks_tbl) rc = __scale_clocks_cycles_per_mb(device, data, instant_bitrate); else if (device->res->load_freq_tbl) rc = __scale_clocks_load(device, load, data, instant_bitrate); else dprintk(VIDC_DBG, "Clock scaling is not supported\n"); return rc; } static int venus_hfi_scale_clocks(void *dev, int load, struct vidc_clk_scale_data *data, unsigned long instant_bitrate) { int rc = 0; struct venus_hfi_device *device = dev; if (!device) { dprintk(VIDC_ERR, "Invalid args: %p\n", device); return -EINVAL; } mutex_lock(&device->lock); rc = __scale_clocks(device, load, data, instant_bitrate); mutex_unlock(&device->lock); return rc; } /* Writes into cmdq without raising an interrupt */ static int __iface_cmdq_write_relaxed(struct venus_hfi_device *device, void *pkt, bool *requires_interrupt) { struct vidc_iface_q_info *q_info; struct vidc_hal_cmd_pkt_hdr *cmd_packet; int result = -E2BIG; if (!device || !pkt) { dprintk(VIDC_ERR, "Invalid Params\n"); return -EINVAL; } __strict_check(device); if (!__core_in_valid_state(device)) { dprintk(VIDC_DBG, "%s - fw not in init state\n", __func__); result = -EINVAL; goto err_q_null; } cmd_packet = (struct vidc_hal_cmd_pkt_hdr *)pkt; device->last_packet_type = cmd_packet->packet_type; q_info = &device->iface_queues[VIDC_IFACEQ_CMDQ_IDX]; if (!q_info) { dprintk(VIDC_ERR, "cannot write to shared Q's\n"); goto err_q_null; } if (!q_info->q_array.align_virtual_addr) { dprintk(VIDC_ERR, "cannot write to shared CMD Q's\n"); result = -ENODATA; goto err_q_null; } __sim_modify_cmd_packet((u8 *)pkt, device); if (!__write_queue(q_info, (u8 *)pkt, requires_interrupt)) { if (__resume(device)) { dprintk(VIDC_ERR, "%s: Power on failed\n", __func__); goto err_q_write; } if (device->res->sw_power_collapsible) { cancel_delayed_work(&venus_hfi_pm_work); if (!queue_delayed_work(device->venus_pm_workq, &venus_hfi_pm_work, msecs_to_jiffies( msm_vidc_pwr_collapse_delay))) { dprintk(VIDC_DBG, "PM work already scheduled\n"); } } result = 0; } else { dprintk(VIDC_ERR, "__iface_cmdq_write: queue full\n"); } err_q_write: err_q_null: return result; } static int __iface_cmdq_write(struct venus_hfi_device *device, void *pkt) { bool needs_interrupt = false; int rc = __iface_cmdq_write_relaxed(device, pkt, &needs_interrupt); if (!rc && needs_interrupt) { /* Consumer of cmdq prefers that we raise an interrupt */ rc = 0; __write_register(device, VIDC_CPU_IC_SOFTINT, 1 << VIDC_CPU_IC_SOFTINT_H2A_SHFT); } return rc; } static int __iface_msgq_read(struct venus_hfi_device *device, void *pkt) { u32 tx_req_is_set = 0; int rc = 0; struct vidc_iface_q_info *q_info; if (!pkt) { dprintk(VIDC_ERR, "Invalid Params\n"); return -EINVAL; } __strict_check(device); if (!__core_in_valid_state(device)) { dprintk(VIDC_DBG, "%s - fw not in init state\n", __func__); rc = -EINVAL; goto read_error_null; } if (device->iface_queues[VIDC_IFACEQ_MSGQ_IDX]. q_array.align_virtual_addr == 0) { dprintk(VIDC_ERR, "cannot read from shared MSG Q's\n"); rc = -ENODATA; goto read_error_null; } q_info = &device->iface_queues[VIDC_IFACEQ_MSGQ_IDX]; if (!__read_queue(q_info, (u8 *)pkt, &tx_req_is_set)) { __hal_sim_modify_msg_packet((u8 *)pkt, device); if (tx_req_is_set) __write_register(device, VIDC_CPU_IC_SOFTINT, 1 << VIDC_CPU_IC_SOFTINT_H2A_SHFT); rc = 0; } else rc = -ENODATA; read_error_null: return rc; } static int __iface_dbgq_read(struct venus_hfi_device *device, void *pkt) { u32 tx_req_is_set = 0; int rc = 0; struct vidc_iface_q_info *q_info; if (!pkt) { dprintk(VIDC_ERR, "Invalid Params\n"); return -EINVAL; } __strict_check(device); if (!__core_in_valid_state(device)) { dprintk(VIDC_DBG, "%s - fw not in init state\n", __func__); rc = -EINVAL; goto dbg_error_null; } if (device->iface_queues[VIDC_IFACEQ_DBGQ_IDX]. q_array.align_virtual_addr == 0) { dprintk(VIDC_ERR, "cannot read from shared DBG Q's\n"); rc = -ENODATA; goto dbg_error_null; } q_info = &device->iface_queues[VIDC_IFACEQ_DBGQ_IDX]; if (!__read_queue(q_info, (u8 *)pkt, &tx_req_is_set)) { if (tx_req_is_set) __write_register(device, VIDC_CPU_IC_SOFTINT, 1 << VIDC_CPU_IC_SOFTINT_H2A_SHFT); rc = 0; } else rc = -ENODATA; dbg_error_null: return rc; } static void __set_queue_hdr_defaults(struct hfi_queue_header *q_hdr) { q_hdr->qhdr_status = 0x1; q_hdr->qhdr_type = VIDC_IFACEQ_DFLT_QHDR; q_hdr->qhdr_q_size = VIDC_IFACEQ_QUEUE_SIZE / 4; q_hdr->qhdr_pkt_size = 0; q_hdr->qhdr_rx_wm = 0x1; q_hdr->qhdr_tx_wm = 0x1; q_hdr->qhdr_rx_req = 0x1; q_hdr->qhdr_tx_req = 0x0; q_hdr->qhdr_rx_irq_status = 0x0; q_hdr->qhdr_tx_irq_status = 0x0; q_hdr->qhdr_read_idx = 0x0; q_hdr->qhdr_write_idx = 0x0; } static void __interface_queues_release(struct venus_hfi_device *device) { int i; struct hfi_mem_map_table *qdss; struct hfi_mem_map *mem_map; int num_entries = device->res->qdss_addr_set.count; unsigned long mem_map_table_base_addr; struct context_bank_info *cb; if (device->qdss.mem_data) { qdss = (struct hfi_mem_map_table *) device->qdss.align_virtual_addr; qdss->mem_map_num_entries = num_entries; mem_map_table_base_addr = device->qdss.align_device_addr + sizeof(struct hfi_mem_map_table); qdss->mem_map_table_base_addr = (u32)mem_map_table_base_addr; if ((unsigned long)qdss->mem_map_table_base_addr != mem_map_table_base_addr) { dprintk(VIDC_ERR, "Invalid mem_map_table_base_addr %#lx", mem_map_table_base_addr); } mem_map = (struct hfi_mem_map *)(qdss + 1); cb = msm_smem_get_context_bank(device->hal_client, false, HAL_BUFFER_INTERNAL_CMD_QUEUE); for (i = 0; cb && i < num_entries; i++) { iommu_unmap(cb->mapping->domain, mem_map[i].virtual_addr, mem_map[i].size); } __smem_free(device, device->qdss.mem_data); } __smem_free(device, device->iface_q_table.mem_data); __smem_free(device, device->sfr.mem_data); for (i = 0; i < VIDC_IFACEQ_NUMQ; i++) { device->iface_queues[i].q_hdr = NULL; device->iface_queues[i].q_array.mem_data = NULL; device->iface_queues[i].q_array.align_virtual_addr = NULL; device->iface_queues[i].q_array.align_device_addr = 0; } device->iface_q_table.mem_data = NULL; device->iface_q_table.align_virtual_addr = NULL; device->iface_q_table.align_device_addr = 0; device->qdss.mem_data = NULL; device->qdss.align_virtual_addr = NULL; device->qdss.align_device_addr = 0; device->sfr.mem_data = NULL; device->sfr.align_virtual_addr = NULL; device->sfr.align_device_addr = 0; device->mem_addr.mem_data = NULL; device->mem_addr.align_virtual_addr = NULL; device->mem_addr.align_device_addr = 0; msm_smem_delete_client(device->hal_client); device->hal_client = NULL; } static int __get_qdss_iommu_virtual_addr(struct venus_hfi_device *dev, struct hfi_mem_map *mem_map, struct dma_iommu_mapping *mapping) { int i; int rc = 0; dma_addr_t iova = QDSS_IOVA_START; int num_entries = dev->res->qdss_addr_set.count; struct addr_range *qdss_addr_tbl = dev->res->qdss_addr_set.addr_tbl; if (!num_entries) return -ENODATA; for (i = 0; i < num_entries; i++) { if (mapping) { rc = iommu_map(mapping->domain, iova, qdss_addr_tbl[i].start, qdss_addr_tbl[i].size, IOMMU_READ | IOMMU_WRITE); if (rc) { dprintk(VIDC_ERR, "IOMMU QDSS mapping failed for addr %#x\n", qdss_addr_tbl[i].start); rc = -ENOMEM; break; } } else { iova = qdss_addr_tbl[i].start; } mem_map[i].virtual_addr = (u32)iova; mem_map[i].physical_addr = qdss_addr_tbl[i].start; mem_map[i].size = qdss_addr_tbl[i].size; mem_map[i].attr = 0x0; iova += mem_map[i].size; } if (i < num_entries) { dprintk(VIDC_ERR, "QDSS mapping failed, Freeing other entries %d\n", i); for (--i; mapping && i >= 0; i--) { iommu_unmap(mapping->domain, mem_map[i].virtual_addr, mem_map[i].size); } } return rc; } static void __setup_ucregion_memory_map(struct venus_hfi_device *device) { __write_register(device, VIDC_UC_REGION_ADDR, (u32)device->iface_q_table.align_device_addr); __write_register(device, VIDC_UC_REGION_SIZE, SHARED_QSIZE); __write_register(device, VIDC_CPU_CS_SCIACMDARG2, (u32)device->iface_q_table.align_device_addr); __write_register(device, VIDC_CPU_CS_SCIACMDARG1, 0x01); if (device->sfr.align_device_addr) __write_register(device, VIDC_SFR_ADDR, (u32)device->sfr.align_device_addr); if (device->qdss.align_device_addr) __write_register(device, VIDC_MMAP_ADDR, (u32)device->qdss.align_device_addr); } static int __interface_queues_init(struct venus_hfi_device *dev) { struct hfi_queue_table_header *q_tbl_hdr; struct hfi_queue_header *q_hdr; u32 i; int rc = 0; struct hfi_mem_map_table *qdss; struct hfi_mem_map *mem_map; struct vidc_iface_q_info *iface_q; struct hfi_sfr_struct *vsfr; struct vidc_mem_addr *mem_addr; int offset = 0; int num_entries = dev->res->qdss_addr_set.count; u32 value = 0; phys_addr_t fw_bias = 0; size_t q_size; unsigned long mem_map_table_base_addr; struct context_bank_info *cb; q_size = SHARED_QSIZE - ALIGNED_SFR_SIZE - ALIGNED_QDSS_SIZE; mem_addr = &dev->mem_addr; if (!is_iommu_present(dev->res)) fw_bias = dev->hal_data->firmware_base; rc = __smem_alloc(dev, mem_addr, q_size, 1, 0, HAL_BUFFER_INTERNAL_CMD_QUEUE); if (rc) { dprintk(VIDC_ERR, "iface_q_table_alloc_fail\n"); goto fail_alloc_queue; } dev->iface_q_table.align_virtual_addr = mem_addr->align_virtual_addr; dev->iface_q_table.align_device_addr = mem_addr->align_device_addr - fw_bias; dev->iface_q_table.mem_size = VIDC_IFACEQ_TABLE_SIZE; dev->iface_q_table.mem_data = mem_addr->mem_data; offset += dev->iface_q_table.mem_size; for (i = 0; i < VIDC_IFACEQ_NUMQ; i++) { iface_q = &dev->iface_queues[i]; iface_q->q_array.align_device_addr = mem_addr->align_device_addr + offset - fw_bias; iface_q->q_array.align_virtual_addr = mem_addr->align_virtual_addr + offset; iface_q->q_array.mem_size = VIDC_IFACEQ_QUEUE_SIZE; iface_q->q_array.mem_data = NULL; offset += iface_q->q_array.mem_size; iface_q->q_hdr = VIDC_IFACEQ_GET_QHDR_START_ADDR( dev->iface_q_table.align_virtual_addr, i); __set_queue_hdr_defaults(iface_q->q_hdr); } if ((msm_vidc_fw_debug_mode & HFI_DEBUG_MODE_QDSS) && num_entries) { rc = __smem_alloc(dev, mem_addr, ALIGNED_QDSS_SIZE, 1, 0, HAL_BUFFER_INTERNAL_CMD_QUEUE); if (rc) { dprintk(VIDC_WARN, "qdss_alloc_fail: QDSS messages logging will not work\n"); dev->qdss.align_device_addr = 0; } else { dev->qdss.align_device_addr = mem_addr->align_device_addr - fw_bias; dev->qdss.align_virtual_addr = mem_addr->align_virtual_addr; dev->qdss.mem_size = ALIGNED_QDSS_SIZE; dev->qdss.mem_data = mem_addr->mem_data; } } rc = __smem_alloc(dev, mem_addr, ALIGNED_SFR_SIZE, 1, 0, HAL_BUFFER_INTERNAL_CMD_QUEUE); if (rc) { dprintk(VIDC_WARN, "sfr_alloc_fail: SFR not will work\n"); dev->sfr.align_device_addr = 0; } else { dev->sfr.align_device_addr = mem_addr->align_device_addr - fw_bias; dev->sfr.align_virtual_addr = mem_addr->align_virtual_addr; dev->sfr.mem_size = ALIGNED_SFR_SIZE; dev->sfr.mem_data = mem_addr->mem_data; } q_tbl_hdr = (struct hfi_queue_table_header *) dev->iface_q_table.align_virtual_addr; q_tbl_hdr->qtbl_version = 0; q_tbl_hdr->qtbl_size = VIDC_IFACEQ_TABLE_SIZE; q_tbl_hdr->qtbl_qhdr0_offset = sizeof(struct hfi_queue_table_header); q_tbl_hdr->qtbl_qhdr_size = sizeof(struct hfi_queue_header); q_tbl_hdr->qtbl_num_q = VIDC_IFACEQ_NUMQ; q_tbl_hdr->qtbl_num_active_q = VIDC_IFACEQ_NUMQ; iface_q = &dev->iface_queues[VIDC_IFACEQ_CMDQ_IDX]; q_hdr = iface_q->q_hdr; q_hdr->qhdr_start_addr = (u32)iface_q->q_array.align_device_addr; q_hdr->qhdr_type |= HFI_Q_ID_HOST_TO_CTRL_CMD_Q; if ((ion_phys_addr_t)q_hdr->qhdr_start_addr != iface_q->q_array.align_device_addr) { dprintk(VIDC_ERR, "Invalid CMDQ device address (%pa)", &iface_q->q_array.align_device_addr); } iface_q = &dev->iface_queues[VIDC_IFACEQ_MSGQ_IDX]; q_hdr = iface_q->q_hdr; q_hdr->qhdr_start_addr = (u32)iface_q->q_array.align_device_addr; q_hdr->qhdr_type |= HFI_Q_ID_CTRL_TO_HOST_MSG_Q; if ((ion_phys_addr_t)q_hdr->qhdr_start_addr != iface_q->q_array.align_device_addr) { dprintk(VIDC_ERR, "Invalid MSGQ device address (%pa)", &iface_q->q_array.align_device_addr); } iface_q = &dev->iface_queues[VIDC_IFACEQ_DBGQ_IDX]; q_hdr = iface_q->q_hdr; q_hdr->qhdr_start_addr = (u32)iface_q->q_array.align_device_addr; q_hdr->qhdr_type |= HFI_Q_ID_CTRL_TO_HOST_DEBUG_Q; /* * Set receive request to zero on debug queue as there is no * need of interrupt from video hardware for debug messages */ q_hdr->qhdr_rx_req = 0; if ((ion_phys_addr_t)q_hdr->qhdr_start_addr != iface_q->q_array.align_device_addr) { dprintk(VIDC_ERR, "Invalid DBGQ device address (%pa)", &iface_q->q_array.align_device_addr); } value = (u32)dev->iface_q_table.align_device_addr; if ((ion_phys_addr_t)value != dev->iface_q_table.align_device_addr) { dprintk(VIDC_ERR, "Invalid iface_q_table device address (%pa)", &dev->iface_q_table.align_device_addr); } if (dev->qdss.mem_data) { qdss = (struct hfi_mem_map_table *)dev->qdss.align_virtual_addr; qdss->mem_map_num_entries = num_entries; mem_map_table_base_addr = dev->qdss.align_device_addr + sizeof(struct hfi_mem_map_table); qdss->mem_map_table_base_addr = (u32)mem_map_table_base_addr; if ((ion_phys_addr_t)qdss->mem_map_table_base_addr != mem_map_table_base_addr) { dprintk(VIDC_ERR, "Invalid mem_map_table_base_addr (%#lx)", mem_map_table_base_addr); } mem_map = (struct hfi_mem_map *)(qdss + 1); cb = msm_smem_get_context_bank(dev->hal_client, false, HAL_BUFFER_INTERNAL_CMD_QUEUE); if (!cb) { dprintk(VIDC_ERR, "%s: failed to get context bank\n", __func__); return -EINVAL; } rc = __get_qdss_iommu_virtual_addr(dev, mem_map, cb->mapping); if (rc) { dprintk(VIDC_ERR, "IOMMU mapping failed, Freeing qdss memdata\n"); __smem_free(dev, dev->qdss.mem_data); dev->qdss.mem_data = NULL; dev->qdss.align_virtual_addr = NULL; dev->qdss.align_device_addr = 0; } value = (u32)dev->qdss.align_device_addr; if ((ion_phys_addr_t)value != dev->qdss.align_device_addr) { dprintk(VIDC_ERR, "Invalid qdss device address (%pa)", &dev->qdss.align_device_addr); } } vsfr = (struct hfi_sfr_struct *) dev->sfr.align_virtual_addr; vsfr->bufSize = ALIGNED_SFR_SIZE; value = (u32)dev->sfr.align_device_addr; if ((ion_phys_addr_t)value != dev->sfr.align_device_addr) { dprintk(VIDC_ERR, "Invalid sfr device address (%pa)", &dev->sfr.align_device_addr); } __setup_ucregion_memory_map(dev); return 0; fail_alloc_queue: return -ENOMEM; } static int __sys_set_debug(struct venus_hfi_device *device, u32 debug) { u8 packet[VIDC_IFACEQ_VAR_SMALL_PKT_SIZE]; int rc = 0; struct hfi_cmd_sys_set_property_packet *pkt = (struct hfi_cmd_sys_set_property_packet *) &packet; rc = call_hfi_pkt_op(device, sys_debug_config, pkt, debug); if (rc) { dprintk(VIDC_WARN, "Debug mode setting to FW failed\n"); return -ENOTEMPTY; } if (__iface_cmdq_write(device, pkt)) return -ENOTEMPTY; return 0; } static int __sys_set_coverage(struct venus_hfi_device *device, u32 mode) { u8 packet[VIDC_IFACEQ_VAR_SMALL_PKT_SIZE]; int rc = 0; struct hfi_cmd_sys_set_property_packet *pkt = (struct hfi_cmd_sys_set_property_packet *) &packet; rc = call_hfi_pkt_op(device, sys_coverage_config, pkt, mode); if (rc) { dprintk(VIDC_WARN, "Coverage mode setting to FW failed\n"); return -ENOTEMPTY; } if (__iface_cmdq_write(device, pkt)) { dprintk(VIDC_WARN, "Failed to send coverage pkt to f/w\n"); return -ENOTEMPTY; } return 0; } static int __sys_set_idle_message(struct venus_hfi_device *device, bool enable) { u8 packet[VIDC_IFACEQ_VAR_SMALL_PKT_SIZE]; struct hfi_cmd_sys_set_property_packet *pkt = (struct hfi_cmd_sys_set_property_packet *) &packet; if (!enable) { dprintk(VIDC_DBG, "sys_idle_indicator is not enabled\n"); return 0; } call_hfi_pkt_op(device, sys_idle_indicator, pkt, enable); if (__iface_cmdq_write(device, pkt)) return -ENOTEMPTY; return 0; } static int __sys_set_power_control(struct venus_hfi_device *device, bool enable) { struct regulator_info *rinfo; bool supported = false; u8 packet[VIDC_IFACEQ_VAR_SMALL_PKT_SIZE]; struct hfi_cmd_sys_set_property_packet *pkt = (struct hfi_cmd_sys_set_property_packet *) &packet; venus_hfi_for_each_regulator(device, rinfo) { if (rinfo->has_hw_power_collapse) { supported = true; break; } } if (!supported) return 0; call_hfi_pkt_op(device, sys_power_control, pkt, enable); if (__iface_cmdq_write(device, pkt)) return -ENOTEMPTY; return 0; } static int venus_hfi_core_init(void *device) { struct hfi_cmd_sys_init_packet pkt; struct hfi_cmd_sys_get_property_packet version_pkt; int rc = 0; struct list_head *ptr, *next; struct hal_session *session = NULL; struct venus_hfi_device *dev; if (!device) { dprintk(VIDC_ERR, "Invalid device\n"); return -ENODEV; } dev = device; mutex_lock(&dev->lock); init_completion(&release_resources_done); rc = __load_fw(dev); if (rc) { dprintk(VIDC_ERR, "Failed to load Venus FW\n"); goto err_load_fw; } __set_state(dev, VENUS_STATE_INIT); list_for_each_safe(ptr, next, &dev->sess_head) { /* This means that session list is not empty. Kick stale * sessions out of our valid instance list, but keep the * list_head inited so that list_del (in the future, called * by session_clean()) will be valid. When client doesn't close * them, then it is a genuine leak which driver can't fix. */ session = list_entry(ptr, struct hal_session, list); list_del_init(&session->list); } INIT_LIST_HEAD(&dev->sess_head); __set_registers(dev); if (!dev->hal_client) { dev->hal_client = msm_smem_new_client( SMEM_ION, dev->res, MSM_VIDC_UNKNOWN); if (dev->hal_client == NULL) { dprintk(VIDC_ERR, "Failed to alloc ION_Client\n"); rc = -ENODEV; goto err_core_init; } dprintk(VIDC_DBG, "Dev_Virt: %pa, Reg_Virt: %p\n", &dev->hal_data->firmware_base, dev->hal_data->register_base); rc = __interface_queues_init(dev); if (rc) { dprintk(VIDC_ERR, "failed to init queues\n"); rc = -ENOMEM; goto err_core_init; } } else { dprintk(VIDC_ERR, "hal_client exists\n"); rc = -EEXIST; goto err_core_init; } rc = __boot_firmware(dev); if (rc) { dprintk(VIDC_ERR, "Failed to start core\n"); rc = -ENODEV; goto err_core_init; } rc = call_hfi_pkt_op(dev, sys_init, &pkt, HFI_VIDEO_ARCH_OX); if (rc) { dprintk(VIDC_ERR, "Failed to create sys init pkt\n"); goto err_core_init; } if (__iface_cmdq_write(dev, &pkt)) { rc = -ENOTEMPTY; goto err_core_init; } rc = call_hfi_pkt_op(dev, sys_image_version, &version_pkt); if (rc || __iface_cmdq_write(dev, &version_pkt)) dprintk(VIDC_WARN, "Failed to send image version pkt to f/w\n"); if (dev->res->pm_qos_latency_us) pm_qos_add_request(&dev->qos, PM_QOS_CPU_DMA_LATENCY, dev->res->pm_qos_latency_us); mutex_unlock(&dev->lock); return rc; err_core_init: __set_state(dev, VENUS_STATE_DEINIT); __unload_fw(dev); err_load_fw: mutex_unlock(&dev->lock); return rc; } static int venus_hfi_core_release(void *dev) { struct venus_hfi_device *device = dev; int rc = 0; if (!device) { dprintk(VIDC_ERR, "invalid device\n"); return -ENODEV; } mutex_lock(&device->lock); if (device->res->pm_qos_latency_us) pm_qos_remove_request(&device->qos); __set_state(device, VENUS_STATE_DEINIT); __unload_fw(device); mutex_unlock(&device->lock); return rc; } static int __get_q_size(struct venus_hfi_device *dev, unsigned int q_index) { struct hfi_queue_header *queue; struct vidc_iface_q_info *q_info; u32 write_ptr, read_ptr; if (q_index >= VIDC_IFACEQ_NUMQ) { dprintk(VIDC_ERR, "Invalid q index: %d\n", q_index); return -ENOENT; } q_info = &dev->iface_queues[q_index]; if (!q_info) { dprintk(VIDC_ERR, "cannot read shared Q's\n"); return -ENOENT; } queue = (struct hfi_queue_header *)q_info->q_hdr; if (!queue) { dprintk(VIDC_ERR, "queue not present\n"); return -ENOENT; } write_ptr = (u32)queue->qhdr_write_idx; read_ptr = (u32)queue->qhdr_read_idx; return read_ptr - write_ptr; } static void __core_clear_interrupt(struct venus_hfi_device *device) { u32 intr_status = 0; if (!device) { dprintk(VIDC_ERR, "%s: NULL device\n", __func__); return; } intr_status = __read_register(device, VIDC_WRAPPER_INTR_STATUS); if (intr_status & VIDC_WRAPPER_INTR_STATUS_A2H_BMSK || intr_status & VIDC_WRAPPER_INTR_STATUS_A2HWD_BMSK || intr_status & VIDC_CPU_CS_SCIACMDARG0_HFI_CTRL_INIT_IDLE_MSG_BMSK) { device->intr_status |= intr_status; device->reg_count++; dprintk(VIDC_DBG, "INTERRUPT for device: %p: times: %d interrupt_status: %d\n", device, device->reg_count, intr_status); } else { device->spur_count++; dprintk(VIDC_INFO, "SPURIOUS_INTR for device: %p: times: %d interrupt_status: %d\n", device, device->spur_count, intr_status); } __write_register(device, VIDC_CPU_CS_A2HSOFTINTCLR, 1); __write_register(device, VIDC_WRAPPER_INTR_CLEAR, intr_status); dprintk(VIDC_DBG, "Cleared WRAPPER/A2H interrupt\n"); } static int venus_hfi_core_ping(void *device) { struct hfi_cmd_sys_ping_packet pkt; int rc = 0; struct venus_hfi_device *dev; if (!device) { dprintk(VIDC_ERR, "invalid device\n"); return -ENODEV; } dev = device; mutex_lock(&dev->lock); rc = call_hfi_pkt_op(dev, sys_ping, &pkt); if (rc) { dprintk(VIDC_ERR, "core_ping: failed to create packet\n"); goto err_create_pkt; } if (__iface_cmdq_write(dev, &pkt)) rc = -ENOTEMPTY; err_create_pkt: mutex_unlock(&dev->lock); return rc; } static int venus_hfi_core_trigger_ssr(void *device, enum hal_ssr_trigger_type type) { struct hfi_cmd_sys_test_ssr_packet pkt; int rc = 0; struct venus_hfi_device *dev; if (!device) { dprintk(VIDC_ERR, "invalid device\n"); return -ENODEV; } dev = device; mutex_lock(&dev->lock); rc = call_hfi_pkt_op(dev, ssr_cmd, type, &pkt); if (rc) { dprintk(VIDC_ERR, "core_ping: failed to create packet\n"); goto err_create_pkt; } if (__iface_cmdq_write(dev, &pkt)) rc = -ENOTEMPTY; err_create_pkt: mutex_unlock(&dev->lock); return rc; } static int venus_hfi_session_set_property(void *sess, enum hal_property ptype, void *pdata) { u8 packet[VIDC_IFACEQ_VAR_LARGE_PKT_SIZE]; struct hfi_cmd_session_set_property_packet *pkt = (struct hfi_cmd_session_set_property_packet *) &packet; struct hal_session *session = sess; struct venus_hfi_device *device; int rc = 0; if (!session || !session->device || !pdata) { dprintk(VIDC_ERR, "Invalid Params\n"); return -EINVAL; } device = session->device; mutex_lock(&device->lock); dprintk(VIDC_INFO, "in set_prop,with prop id: %#x\n", ptype); rc = call_hfi_pkt_op(device, session_set_property, pkt, session, ptype, pdata); if (rc == -ENOTSUPP) { dprintk(VIDC_DBG, "set property: unsupported prop id: %#x\n", ptype); rc = 0; goto err_set_prop; } else if (rc) { dprintk(VIDC_ERR, "set property: failed to create packet\n"); rc = -EINVAL; goto err_set_prop; } if (__iface_cmdq_write(session->device, pkt)) { rc = -ENOTEMPTY; goto err_set_prop; } err_set_prop: mutex_unlock(&device->lock); return rc; } static int venus_hfi_session_get_property(void *sess, enum hal_property ptype) { struct hfi_cmd_session_get_property_packet pkt = {0}; struct hal_session *session = sess; int rc = 0; struct venus_hfi_device *device; if (!session || !session->device) { dprintk(VIDC_ERR, "Invalid Params\n"); return -EINVAL; } device = session->device; mutex_lock(&device->lock); dprintk(VIDC_INFO, "%s: property id: %d\n", __func__, ptype); rc = call_hfi_pkt_op(device, session_get_property, &pkt, session, ptype); if (rc) { dprintk(VIDC_ERR, "get property profile: pkt failed\n"); goto err_create_pkt; } if (__iface_cmdq_write(session->device, &pkt)) { rc = -ENOTEMPTY; dprintk(VIDC_ERR, "%s cmdq_write error\n", __func__); } err_create_pkt: mutex_unlock(&device->lock); return rc; } static void __set_default_sys_properties(struct venus_hfi_device *device) { if (__sys_set_debug(device, msm_vidc_fw_debug)) dprintk(VIDC_WARN, "Setting fw_debug msg ON failed\n"); if (__sys_set_idle_message(device, device->res->sys_idle_indicator || msm_vidc_sys_idle_indicator)) dprintk(VIDC_WARN, "Setting idle response ON failed\n"); if (__sys_set_power_control(device, msm_vidc_fw_low_power_mode)) dprintk(VIDC_WARN, "Setting h/w power collapse ON failed\n"); } static void __session_clean(struct hal_session *session) { dprintk(VIDC_DBG, "deleted the session: %p\n", session); list_del(&session->list); /* Poison the session handle with zeros */ *session = (struct hal_session){ {0} }; kfree(session); } static int venus_hfi_session_clean(void *session) { struct hal_session *sess_close; struct venus_hfi_device *device; if (!session) { dprintk(VIDC_ERR, "Invalid Params %s\n", __func__); return -EINVAL; } sess_close = session; device = sess_close->device; if (!device) { dprintk(VIDC_ERR, "Invalid device handle %s\n", __func__); return -EINVAL; } mutex_lock(&device->lock); __session_clean(sess_close); __flush_debug_queue(device, NULL); mutex_unlock(&device->lock); return 0; } static int venus_hfi_session_init(void *device, void *session_id, enum hal_domain session_type, enum hal_video_codec codec_type, void **new_session) { struct hfi_cmd_sys_session_init_packet pkt; struct venus_hfi_device *dev; struct hal_session *s; if (!device || !new_session) { dprintk(VIDC_ERR, "%s - invalid input\n", __func__); return -EINVAL; } dev = device; mutex_lock(&dev->lock); s = kzalloc(sizeof(struct hal_session), GFP_KERNEL); if (!s) { dprintk(VIDC_ERR, "new session fail: Out of memory\n"); goto err_session_init_fail; } s->session_id = session_id; s->is_decoder = (session_type == HAL_VIDEO_DOMAIN_DECODER); s->device = dev; s->codec = codec_type; s->domain = session_type; dprintk(VIDC_DBG, "%s: inst %pK, session %pK, codec 0x%x, domain 0x%x\n", __func__, session_id, s, s->codec, s->domain); list_add_tail(&s->list, &dev->sess_head); __set_default_sys_properties(device); if (call_hfi_pkt_op(dev, session_init, &pkt, s, session_type, codec_type)) { dprintk(VIDC_ERR, "session_init: failed to create packet\n"); goto err_session_init_fail; } *new_session = s; if (__iface_cmdq_write(dev, &pkt)) goto err_session_init_fail; mutex_unlock(&dev->lock); return 0; err_session_init_fail: if (s) __session_clean(s); *new_session = NULL; mutex_unlock(&dev->lock); return -EINVAL; } static int __send_session_cmd(struct hal_session *session, int pkt_type) { struct vidc_hal_session_cmd_pkt pkt; int rc = 0; struct venus_hfi_device *device = session->device; rc = call_hfi_pkt_op(device, session_cmd, &pkt, pkt_type, session); if (rc == -EPERM) return 0; if (rc) { dprintk(VIDC_ERR, "send session cmd: create pkt failed\n"); goto err_create_pkt; } if (__iface_cmdq_write(session->device, &pkt)) rc = -ENOTEMPTY; err_create_pkt: return rc; } static int venus_hfi_session_end(void *session) { struct hal_session *sess; struct venus_hfi_device *device; int rc = 0; if (!session) { dprintk(VIDC_ERR, "Invalid Params %s\n", __func__); return -EINVAL; } sess = session; device = sess->device; mutex_lock(&device->lock); if (msm_vidc_fw_coverage) { if (__sys_set_coverage(sess->device, msm_vidc_fw_coverage)) dprintk(VIDC_WARN, "Fw_coverage msg ON failed\n"); } rc = __send_session_cmd(session, HFI_CMD_SYS_SESSION_END); mutex_unlock(&device->lock); return rc; } static int venus_hfi_session_abort(void *sess) { struct hal_session *session; struct venus_hfi_device *device; int rc = 0; session = sess; if (!session || !session->device) { dprintk(VIDC_ERR, "Invalid Params %s\n", __func__); return -EINVAL; } device = session->device; mutex_lock(&device->lock); __flush_debug_queue(device, NULL); rc = __send_session_cmd(session, HFI_CMD_SYS_SESSION_ABORT); mutex_unlock(&device->lock); return rc; } static int venus_hfi_session_set_buffers(void *sess, struct vidc_buffer_addr_info *buffer_info) { struct hfi_cmd_session_set_buffers_packet *pkt; u8 packet[VIDC_IFACEQ_VAR_LARGE_PKT_SIZE]; int rc = 0; struct hal_session *session = sess; struct venus_hfi_device *device; if (!session || !session->device || !buffer_info) { dprintk(VIDC_ERR, "Invalid Params\n"); return -EINVAL; } device = session->device; mutex_lock(&device->lock); if (buffer_info->buffer_type == HAL_BUFFER_INPUT) { /* * Hardware doesn't care about input buffers being * published beforehand */ rc = 0; goto err_create_pkt; } pkt = (struct hfi_cmd_session_set_buffers_packet *)packet; rc = call_hfi_pkt_op(device, session_set_buffers, pkt, session, buffer_info); if (rc) { dprintk(VIDC_ERR, "set buffers: failed to create packet\n"); goto err_create_pkt; } dprintk(VIDC_INFO, "set buffers: %#x\n", buffer_info->buffer_type); if (__iface_cmdq_write(session->device, pkt)) rc = -ENOTEMPTY; err_create_pkt: mutex_unlock(&device->lock); return rc; } static int venus_hfi_session_release_buffers(void *sess, struct vidc_buffer_addr_info *buffer_info) { struct hfi_cmd_session_release_buffer_packet *pkt; u8 packet[VIDC_IFACEQ_VAR_LARGE_PKT_SIZE]; int rc = 0; struct hal_session *session = sess; struct venus_hfi_device *device; if (!session || !session->device || !buffer_info) { dprintk(VIDC_ERR, "Invalid Params\n"); return -EINVAL; } device = session->device; mutex_lock(&device->lock); if (buffer_info->buffer_type == HAL_BUFFER_INPUT) { rc = 0; goto err_create_pkt; } pkt = (struct hfi_cmd_session_release_buffer_packet *) packet; rc = call_hfi_pkt_op(device, session_release_buffers, pkt, session, buffer_info); if (rc) { dprintk(VIDC_ERR, "release buffers: failed to create packet\n"); goto err_create_pkt; } dprintk(VIDC_INFO, "Release buffers: %#x\n", buffer_info->buffer_type); if (__iface_cmdq_write(session->device, pkt)) rc = -ENOTEMPTY; err_create_pkt: mutex_unlock(&device->lock); return rc; } static int venus_hfi_session_load_res(void *session) { struct hal_session *sess; struct venus_hfi_device *device; int rc = 0; if (!session) { dprintk(VIDC_ERR, "Invalid Params %s\n", __func__); return -EINVAL; } sess = session; device = sess->device; mutex_lock(&device->lock); rc = __send_session_cmd(sess, HFI_CMD_SESSION_LOAD_RESOURCES); mutex_unlock(&device->lock); return rc; } static int venus_hfi_session_release_res(void *session) { struct hal_session *sess; struct venus_hfi_device *device; int rc = 0; if (!session) { dprintk(VIDC_ERR, "Invalid Params %s\n", __func__); return -EINVAL; } sess = session; device = sess->device; mutex_lock(&device->lock); rc = __send_session_cmd(sess, HFI_CMD_SESSION_RELEASE_RESOURCES); mutex_unlock(&device->lock); return rc; } static int venus_hfi_session_start(void *session) { struct hal_session *sess; struct venus_hfi_device *device; int rc = 0; if (!session) { dprintk(VIDC_ERR, "Invalid Params %s\n", __func__); return -EINVAL; } sess = session; device = sess->device; mutex_lock(&device->lock); rc = __send_session_cmd(sess, HFI_CMD_SESSION_START); mutex_unlock(&device->lock); return rc; } static int venus_hfi_session_continue(void *session) { struct hal_session *sess; struct venus_hfi_device *device; int rc = 0; if (!session) { dprintk(VIDC_ERR, "Invalid Params %s\n", __func__); return -EINVAL; } sess = session; device = sess->device; mutex_lock(&device->lock); rc = __send_session_cmd(sess, HFI_CMD_SESSION_CONTINUE); mutex_unlock(&device->lock); return rc; } static int venus_hfi_session_stop(void *session) { struct hal_session *sess; struct venus_hfi_device *device; int rc = 0; if (!session) { dprintk(VIDC_ERR, "Invalid Params %s\n", __func__); return -EINVAL; } sess = session; device = sess->device; mutex_lock(&device->lock); rc = __send_session_cmd(sess, HFI_CMD_SESSION_STOP); mutex_unlock(&device->lock); return rc; } static int __session_etb(struct hal_session *session, struct vidc_frame_data *input_frame, bool relaxed) { int rc = 0; struct venus_hfi_device *device = session->device; if (session->is_decoder) { struct hfi_cmd_session_empty_buffer_compressed_packet pkt; rc = call_hfi_pkt_op(device, session_etb_decoder, &pkt, session, input_frame); if (rc) { dprintk(VIDC_ERR, "Session etb decoder: failed to create pkt\n"); goto err_create_pkt; } if (!relaxed) rc = __iface_cmdq_write(session->device, &pkt); else rc = __iface_cmdq_write_relaxed(session->device, &pkt, NULL); if (rc) goto err_create_pkt; } else { struct hfi_cmd_session_empty_buffer_uncompressed_plane0_packet pkt; rc = call_hfi_pkt_op(device, session_etb_encoder, &pkt, session, input_frame); if (rc) { dprintk(VIDC_ERR, "Session etb encoder: failed to create pkt\n"); goto err_create_pkt; } if (!relaxed) rc = __iface_cmdq_write(session->device, &pkt); else rc = __iface_cmdq_write_relaxed(session->device, &pkt, NULL); if (rc) goto err_create_pkt; } err_create_pkt: return rc; } static int venus_hfi_session_etb(void *sess, struct vidc_frame_data *input_frame) { int rc = 0; struct hal_session *session = sess; struct venus_hfi_device *device; if (!session || !session->device || !input_frame) { dprintk(VIDC_ERR, "Invalid Params\n"); return -EINVAL; } device = session->device; mutex_lock(&device->lock); rc = __session_etb(session, input_frame, false); mutex_unlock(&device->lock); return rc; } static int __session_ftb(struct hal_session *session, struct vidc_frame_data *output_frame, bool relaxed) { int rc = 0; struct venus_hfi_device *device = session->device; struct hfi_cmd_session_fill_buffer_packet pkt; rc = call_hfi_pkt_op(device, session_ftb, &pkt, session, output_frame); if (rc) { dprintk(VIDC_ERR, "Session ftb: failed to create pkt\n"); goto err_create_pkt; } if (!relaxed) rc = __iface_cmdq_write(session->device, &pkt); else rc = __iface_cmdq_write_relaxed(session->device, &pkt, NULL); err_create_pkt: return rc; } static int venus_hfi_session_ftb(void *sess, struct vidc_frame_data *output_frame) { int rc = 0; struct hal_session *session = sess; struct venus_hfi_device *device; if (!session || !session->device || !output_frame) { dprintk(VIDC_ERR, "Invalid Params\n"); return -EINVAL; } device = session->device; mutex_lock(&device->lock); rc = __session_ftb(session, output_frame, false); mutex_unlock(&device->lock); return rc; } static int venus_hfi_session_process_batch(void *sess, int num_etbs, struct vidc_frame_data etbs[], int num_ftbs, struct vidc_frame_data ftbs[]) { int rc = 0, c = 0; struct hal_session *session = sess; struct venus_hfi_device *device; struct hfi_cmd_session_sync_process_packet pkt; if (!session || !session->device) { dprintk(VIDC_ERR, "%s: Invalid Params\n", __func__); return -EINVAL; } device = session->device; mutex_lock(&device->lock); for (c = 0; c < num_ftbs; ++c) { rc = __session_ftb(session, &ftbs[c], true); if (rc) { dprintk(VIDC_ERR, "Failed to queue batched ftb: %d\n", rc); goto err_etbs_and_ftbs; } } for (c = 0; c < num_etbs; ++c) { rc = __session_etb(session, &etbs[c], true); if (rc) { dprintk(VIDC_ERR, "Failed to queue batched etb: %d\n", rc); goto err_etbs_and_ftbs; } } rc = call_hfi_pkt_op(device, session_sync_process, &pkt, session); if (rc) { dprintk(VIDC_ERR, "Failed to create sync packet\n"); goto err_etbs_and_ftbs; } if (__iface_cmdq_write(session->device, &pkt)) rc = -ENOTEMPTY; err_etbs_and_ftbs: mutex_unlock(&device->lock); return rc; } static int venus_hfi_session_parse_seq_hdr(void *sess, struct vidc_seq_hdr *seq_hdr) { struct hfi_cmd_session_parse_sequence_header_packet *pkt; int rc = 0; u8 packet[VIDC_IFACEQ_VAR_SMALL_PKT_SIZE]; struct hal_session *session = sess; struct venus_hfi_device *device; if (!session || !session->device || !seq_hdr) { dprintk(VIDC_ERR, "Invalid Params\n"); return -EINVAL; } device = session->device; mutex_lock(&device->lock); pkt = (struct hfi_cmd_session_parse_sequence_header_packet *)packet; rc = call_hfi_pkt_op(device, session_parse_seq_header, pkt, session, seq_hdr); if (rc) { dprintk(VIDC_ERR, "Session parse seq hdr: failed to create pkt\n"); goto err_create_pkt; } if (__iface_cmdq_write(session->device, pkt)) rc = -ENOTEMPTY; err_create_pkt: mutex_unlock(&device->lock); return rc; } static int venus_hfi_session_get_seq_hdr(void *sess, struct vidc_seq_hdr *seq_hdr) { struct hfi_cmd_session_get_sequence_header_packet *pkt; int rc = 0; u8 packet[VIDC_IFACEQ_VAR_SMALL_PKT_SIZE]; struct hal_session *session = sess; struct venus_hfi_device *device; if (!session || !session->device || !seq_hdr) { dprintk(VIDC_ERR, "Invalid Params\n"); return -EINVAL; } device = session->device; mutex_lock(&device->lock); pkt = (struct hfi_cmd_session_get_sequence_header_packet *)packet; rc = call_hfi_pkt_op(device, session_get_seq_hdr, pkt, session, seq_hdr); if (rc) { dprintk(VIDC_ERR, "Session get seq hdr: failed to create pkt\n"); goto err_create_pkt; } if (__iface_cmdq_write(session->device, pkt)) rc = -ENOTEMPTY; err_create_pkt: mutex_unlock(&device->lock); return rc; } static int venus_hfi_session_get_buf_req(void *sess) { struct hfi_cmd_session_get_property_packet pkt; int rc = 0; struct hal_session *session = sess; struct venus_hfi_device *device; if (!session || !session->device) { dprintk(VIDC_ERR, "invalid session"); return -ENODEV; } device = session->device; mutex_lock(&device->lock); rc = call_hfi_pkt_op(device, session_get_buf_req, &pkt, session); if (rc) { dprintk(VIDC_ERR, "Session get buf req: failed to create pkt\n"); goto err_create_pkt; } if (__iface_cmdq_write(session->device, &pkt)) rc = -ENOTEMPTY; err_create_pkt: mutex_unlock(&device->lock); return rc; } static int venus_hfi_session_flush(void *sess, enum hal_flush flush_mode) { struct hfi_cmd_session_flush_packet pkt; int rc = 0; struct hal_session *session = sess; struct venus_hfi_device *device; if (!session || !session->device) { dprintk(VIDC_ERR, "invalid session"); return -ENODEV; } device = session->device; mutex_lock(&device->lock); rc = call_hfi_pkt_op(device, session_flush, &pkt, session, flush_mode); if (rc) { dprintk(VIDC_ERR, "Session flush: failed to create pkt\n"); goto err_create_pkt; } if (__iface_cmdq_write(session->device, &pkt)) rc = -ENOTEMPTY; err_create_pkt: mutex_unlock(&device->lock); return rc; } static int __check_core_registered(struct hal_device_data core, phys_addr_t fw_addr, u8 *reg_addr, u32 reg_size, phys_addr_t irq) { struct venus_hfi_device *device; struct list_head *curr, *next; if (core.dev_count) { list_for_each_safe(curr, next, &core.dev_head) { device = list_entry(curr, struct venus_hfi_device, list); if (device && device->hal_data->irq == irq && (CONTAINS(device->hal_data-> firmware_base, FIRMWARE_SIZE, fw_addr) || CONTAINS(fw_addr, FIRMWARE_SIZE, device->hal_data-> firmware_base) || CONTAINS(device->hal_data-> register_base, reg_size, reg_addr) || CONTAINS(reg_addr, reg_size, device->hal_data-> register_base) || OVERLAPS(device->hal_data-> register_base, reg_size, reg_addr, reg_size) || OVERLAPS(reg_addr, reg_size, device->hal_data-> register_base, reg_size) || OVERLAPS(device->hal_data-> firmware_base, FIRMWARE_SIZE, fw_addr, FIRMWARE_SIZE) || OVERLAPS(fw_addr, FIRMWARE_SIZE, device->hal_data-> firmware_base, FIRMWARE_SIZE))) { return 0; } else { dprintk(VIDC_INFO, "Device not registered\n"); return -EINVAL; } } } else { dprintk(VIDC_INFO, "no device Registered\n"); } return -EINVAL; } static void __process_fatal_error( struct venus_hfi_device *device) { struct msm_vidc_cb_cmd_done cmd_done = {0}; cmd_done.device_id = device->device_id; device->callback(HAL_SYS_ERROR, &cmd_done); } static int __prepare_pc(struct venus_hfi_device *device) { int rc = 0; struct hfi_cmd_sys_pc_prep_packet pkt; rc = call_hfi_pkt_op(device, sys_pc_prep, &pkt); if (rc) { dprintk(VIDC_ERR, "Failed to create sys pc prep pkt\n"); goto err_pc_prep; } if (__iface_cmdq_write(device, &pkt)) rc = -ENOTEMPTY; if (rc) dprintk(VIDC_ERR, "Failed to prepare venus for power off"); err_pc_prep: return rc; } static void venus_hfi_pm_handler(struct work_struct *work) { int rc = 0; u32 wfi_status = 0, idle_status = 0, pc_ready = 0; int count = 0; const int max_tries = 5; struct venus_hfi_device *device = list_first_entry( &hal_ctxt.dev_head, struct venus_hfi_device, list); if (!device) { dprintk(VIDC_ERR, "%s: NULL device\n", __func__); return; } /* * It is ok to check this variable outside the lock since * it is being updated in this context only */ if (device->skip_pc_count >= VIDC_MAX_PC_SKIP_COUNT) { dprintk(VIDC_WARN, "Failed to PC for %d times\n", device->skip_pc_count); device->skip_pc_count = 0; __process_fatal_error(device); return; } mutex_lock(&device->lock); if (!device->power_enabled) { dprintk(VIDC_DBG, "%s: Power already disabled\n", __func__); goto exit; } rc = __core_in_valid_state(device); if (!rc) { dprintk(VIDC_WARN, "Core is in bad state, Skipping power collapse\n"); goto skip_power_off; } pc_ready = __read_register(device, VIDC_CPU_CS_SCIACMDARG0) & VIDC_CPU_CS_SCIACMDARG0_HFI_CTRL_PC_READY; if (!pc_ready) { wfi_status = __read_register(device, VIDC_WRAPPER_CPU_STATUS); idle_status = __read_register(device, VIDC_CPU_CS_SCIACMDARG0); if (!(wfi_status & BIT(0)) || !(idle_status & BIT(30))) { dprintk(VIDC_WARN, "Skipping PC\n"); goto skip_power_off; } rc = __prepare_pc(device); if (rc) { dprintk(VIDC_WARN, "Failed PC %d\n", rc); goto skip_power_off; } while (count < max_tries) { wfi_status = __read_register(device, VIDC_WRAPPER_CPU_STATUS); pc_ready = __read_register(device, VIDC_CPU_CS_SCIACMDARG0); if ((wfi_status & BIT(0)) && (pc_ready & VIDC_CPU_CS_SCIACMDARG0_HFI_CTRL_PC_READY)) break; usleep_range(1000, 1500); count++; } if (count == max_tries) { dprintk(VIDC_ERR, "Skip PC. Core is not in right state (%#x, %#x)\n", wfi_status, pc_ready); goto skip_power_off; } } rc = __suspend(device); if (rc) dprintk(VIDC_ERR, "Failed venus power off\n"); /* Cancel pending delayed works if any */ cancel_delayed_work(&venus_hfi_pm_work); device->skip_pc_count = 0; mutex_unlock(&device->lock); return; skip_power_off: device->skip_pc_count++; dprintk(VIDC_WARN, "Skip PC(%d, %#x, %#x, %#x)\n", device->skip_pc_count, wfi_status, idle_status, pc_ready); queue_delayed_work(device->venus_pm_workq, &venus_hfi_pm_work, msecs_to_jiffies(msm_vidc_pwr_collapse_delay)); exit: mutex_unlock(&device->lock); return; } static void __process_sys_error(struct venus_hfi_device *device) { struct hfi_sfr_struct *vsfr = NULL; __set_state(device, VENUS_STATE_DEINIT); /* Once SYS_ERROR received from HW, it is safe to halt the AXI. * With SYS_ERROR, Venus FW may have crashed and HW might be * active and causing unnecessary transactions. Hence it is * safe to stop all AXI transactions from venus sub-system. */ if (__halt_axi(device)) dprintk(VIDC_WARN, "Failed to halt AXI after SYS_ERROR\n"); vsfr = (struct hfi_sfr_struct *)device->sfr.align_virtual_addr; if (vsfr) { void *p = memchr(vsfr->rg_data, '\0', vsfr->bufSize); /* SFR isn't guaranteed to be NULL terminated since SYS_ERROR indicates that Venus is in the process of crashing.*/ if (p == NULL) vsfr->rg_data[vsfr->bufSize - 1] = '\0'; dprintk(VIDC_ERR, "SFR Message from FW: %s\n", vsfr->rg_data); } } static void __flush_debug_queue(struct venus_hfi_device *device, u8 *packet) { bool local_packet = false; if (!device) { dprintk(VIDC_ERR, "%s: Invalid params\n", __func__); return; } if (!packet) { packet = kzalloc(VIDC_IFACEQ_VAR_HUGE_PKT_SIZE, GFP_TEMPORARY); if (!packet) { dprintk(VIDC_ERR, "In %s() Fail to allocate mem\n", __func__); return; } local_packet = true; } while (!__iface_dbgq_read(device, packet)) { struct hfi_msg_sys_coverage_packet *pkt = (struct hfi_msg_sys_coverage_packet *) packet; if (pkt->packet_type == HFI_MSG_SYS_COV) { int stm_size = 0; stm_size = stm_log_inv_ts(0, 0, pkt->rg_msg_data, pkt->msg_size); if (stm_size == 0) dprintk(VIDC_ERR, "In %s, stm_log returned size of 0\n", __func__); } else { struct hfi_msg_sys_debug_packet *pkt = (struct hfi_msg_sys_debug_packet *) packet; dprintk(VIDC_FW, "%s", pkt->rg_msg_data); } } if (local_packet) kfree(packet); } static struct hal_session *__get_session(struct venus_hfi_device *device, u32 session_id) { struct hal_session *temp = NULL; list_for_each_entry(temp, &device->sess_head, list) { if (session_id == hash32_ptr(temp)) return temp; } return NULL; } static int __response_handler(struct venus_hfi_device *device) { struct msm_vidc_cb_info *packets; int packet_count = 0; u8 *raw_packet = NULL; bool requeue_pm_work = true; if (!device || device->state != VENUS_STATE_INIT) return 0; packets = device->response_pkt; raw_packet = kzalloc(VIDC_IFACEQ_VAR_HUGE_PKT_SIZE, GFP_TEMPORARY); if (!raw_packet || !packets) { dprintk(VIDC_ERR, "%s: Failed to allocate memory\n", __func__); kfree(raw_packet); return 0; } if (device->intr_status & VIDC_WRAPPER_INTR_CLEAR_A2HWD_BMSK) { struct hfi_sfr_struct *vsfr = (struct hfi_sfr_struct *) device->sfr.align_virtual_addr; struct msm_vidc_cb_info info = { .response_type = HAL_SYS_WATCHDOG_TIMEOUT, .response.cmd = { .device_id = device->device_id, } }; if (vsfr) dprintk(VIDC_ERR, "SFR Message from FW: %s\n", vsfr->rg_data); dprintk(VIDC_ERR, "Received watchdog timeout\n"); packets[packet_count++] = info; goto exit; } /* Bleed the msg queue dry of packets */ while (!__iface_msgq_read(device, raw_packet)) { void **session_id = NULL; struct msm_vidc_cb_info *info = &packets[packet_count++]; struct vidc_hal_sys_init_done sys_init_done = {0}; int rc = 0; rc = hfi_process_msg_packet(device->device_id, (struct vidc_hal_msg_pkt_hdr *)raw_packet, info); if (rc) { dprintk(VIDC_WARN, "Corrupt/unknown packet found, discarding\n"); --packet_count; continue; } /* Process the packet types that we're interested in */ switch (info->response_type) { case HAL_SYS_ERROR: __process_sys_error(device); break; case HAL_SYS_RELEASE_RESOURCE_DONE: dprintk(VIDC_DBG, "Received SYS_RELEASE_RESOURCE\n"); complete(&release_resources_done); break; case HAL_SYS_INIT_DONE: dprintk(VIDC_DBG, "Received SYS_INIT_DONE\n"); /* Video driver intentionally does not unset * IMEM on venus to simplify power collapse. */ if (__set_imem(device, &device->resources.imem)) dprintk(VIDC_WARN, "Failed to set IMEM. Performance will be impacted\n"); sys_init_done.capabilities = device->sys_init_capabilities; hfi_process_sys_init_done_prop_read( (struct hfi_msg_sys_init_done_packet *) raw_packet, &sys_init_done); info->response.cmd.data.sys_init_done = sys_init_done; break; case HAL_SESSION_LOAD_RESOURCE_DONE: /* * Work around for H/W bug, need to re-program these * registers as part of a handshake agreement with the * firmware. This strictly only needs to be done for * decoder secure sessions, but there's no harm in doing * so for all sessions as it's at worst a NO-OP. */ __set_threshold_registers(device); break; default: break; } /* For session-related packets, validate session */ switch (info->response_type) { case HAL_SESSION_LOAD_RESOURCE_DONE: case HAL_SESSION_INIT_DONE: case HAL_SESSION_END_DONE: case HAL_SESSION_ABORT_DONE: case HAL_SESSION_START_DONE: case HAL_SESSION_STOP_DONE: case HAL_SESSION_FLUSH_DONE: case HAL_SESSION_SUSPEND_DONE: case HAL_SESSION_RESUME_DONE: case HAL_SESSION_SET_PROP_DONE: case HAL_SESSION_GET_PROP_DONE: case HAL_SESSION_PARSE_SEQ_HDR_DONE: case HAL_SESSION_RELEASE_BUFFER_DONE: case HAL_SESSION_RELEASE_RESOURCE_DONE: case HAL_SESSION_PROPERTY_INFO: session_id = &info->response.cmd.session_id; break; case HAL_SESSION_ERROR: case HAL_SESSION_GET_SEQ_HDR_DONE: case HAL_SESSION_ETB_DONE: case HAL_SESSION_FTB_DONE: session_id = &info->response.data.session_id; break; case HAL_SESSION_EVENT_CHANGE: session_id = &info->response.event.session_id; break; case HAL_RESPONSE_UNUSED: default: session_id = NULL; break; } /* * hfi_process_msg_packet provides a session_id that's a hashed * value of struct hal_session, we need to coerce the hashed * value back to pointer that we can use. Ideally, hfi_process\ * _msg_packet should take care of this, but it doesn't have * required information for it */ if (session_id) { struct hal_session *session = NULL; WARN_ON(upper_32_bits((uintptr_t)*session_id) != 0); session = __get_session(device, (u32)(uintptr_t)*session_id); if (!session) { dprintk(VIDC_ERR, "Received a packet (%#x) for an unrecognized session (%p), discarding\n", info->response_type, *session_id); --packet_count; continue; } *session_id = session->session_id; } if (packet_count >= max_packets && __get_q_size(device, VIDC_IFACEQ_MSGQ_IDX)) { dprintk(VIDC_WARN, "Too many packets in message queue to handle at once, deferring read\n"); break; } } if (requeue_pm_work && device->res->sw_power_collapsible) { cancel_delayed_work(&venus_hfi_pm_work); if (!queue_delayed_work(device->venus_pm_workq, &venus_hfi_pm_work, msecs_to_jiffies(msm_vidc_pwr_collapse_delay))) { dprintk(VIDC_ERR, "PM work already scheduled\n"); } } exit: __flush_debug_queue(device, raw_packet); kfree(raw_packet); return packet_count; } static void venus_hfi_core_work_handler(struct work_struct *work) { struct venus_hfi_device *device = list_first_entry( &hal_ctxt.dev_head, struct venus_hfi_device, list); int num_responses = 0, i = 0; mutex_lock(&device->lock); dprintk(VIDC_INFO, "Handling interrupt\n"); if (!__core_in_valid_state(device)) { dprintk(VIDC_DBG, "%s - Core not in init state\n", __func__); goto err_no_work; } if (!device->callback) { dprintk(VIDC_ERR, "No interrupt callback function: %p\n", device); goto err_no_work; } if (__resume(device)) { dprintk(VIDC_ERR, "%s: Power enable failed\n", __func__); goto err_no_work; } __core_clear_interrupt(device); num_responses = __response_handler(device); err_no_work: /* We need re-enable the irq which was disabled in ISR handler */ if (!(device->intr_status & VIDC_WRAPPER_INTR_STATUS_A2HWD_BMSK)) enable_irq(device->hal_data->irq); mutex_unlock(&device->lock); /* * Issue the callbacks outside of the locked contex to preserve * re-entrancy. */ for (i = 0; !IS_ERR_OR_NULL(device->response_pkt) && i < num_responses; ++i) { struct msm_vidc_cb_info *r = &device->response_pkt[i]; device->callback(r->response_type, &r->response); } /* * XXX: Don't add any code beyond here. Reacquiring locks after release * it above doesn't guarantee the atomicity that we're aiming for. */ } static DECLARE_WORK(venus_hfi_work, venus_hfi_core_work_handler); static irqreturn_t venus_hfi_isr(int irq, void *dev) { struct venus_hfi_device *device = dev; dprintk(VIDC_INFO, "Received an interrupt %d\n", irq); disable_irq_nosync(irq); queue_work(device->vidc_workq, &venus_hfi_work); return IRQ_HANDLED; } static int __init_regs_and_interrupts(struct venus_hfi_device *device, struct msm_vidc_platform_resources *res) { struct hal_data *hal = NULL; int rc = 0; rc = __check_core_registered(hal_ctxt, res->firmware_base, (u8 *)(uintptr_t)res->register_base, res->register_size, res->irq); if (!rc) { dprintk(VIDC_ERR, "Core present/Already added\n"); rc = -EEXIST; goto err_core_init; } dprintk(VIDC_DBG, "HAL_DATA will be assigned now\n"); hal = (struct hal_data *) kzalloc(sizeof(struct hal_data), GFP_KERNEL); if (!hal) { dprintk(VIDC_ERR, "Failed to alloc\n"); rc = -ENOMEM; goto err_core_init; } hal->irq = res->irq; hal->firmware_base = res->firmware_base; hal->register_base = devm_ioremap_nocache(&res->pdev->dev, res->register_base, res->register_size); hal->register_size = res->register_size; if (!hal->register_base) { dprintk(VIDC_ERR, "could not map reg addr %pa of size %d\n", &res->register_base, res->register_size); goto error_irq_fail; } device->hal_data = hal; rc = request_irq(res->irq, venus_hfi_isr, IRQF_TRIGGER_HIGH, "msm_vidc", device); if (unlikely(rc)) { dprintk(VIDC_ERR, "() :request_irq failed\n"); goto error_irq_fail; } disable_irq_nosync(res->irq); dprintk(VIDC_INFO, "firmware_base = %pa, register_base = %pa, register_size = %d\n", &res->firmware_base, &res->register_base, res->register_size); return rc; error_irq_fail: kfree(hal); err_core_init: return rc; } static inline void __deinit_clocks(struct venus_hfi_device *device) { struct clock_info *cl; device->clk_freq = 0; venus_hfi_for_each_clock_reverse(device, cl) { if (cl->clk) { clk_put(cl->clk); cl->clk = NULL; } } } static inline int __init_clocks(struct venus_hfi_device *device) { int rc = 0; struct clock_info *cl = NULL; if (!device) { dprintk(VIDC_ERR, "Invalid params: %p\n", device); return -EINVAL; } venus_hfi_for_each_clock(device, cl) { int i = 0; dprintk(VIDC_DBG, "%s: scalable? %d, count %d\n", cl->name, cl->has_scaling, cl->count); for (i = 0; i < cl->count; ++i) { dprintk(VIDC_DBG, "\tload = %d, freq = %d codecs supported %#x\n", cl->load_freq_tbl[i].load, cl->load_freq_tbl[i].freq, cl->load_freq_tbl[i].supported_codecs); } } venus_hfi_for_each_clock(device, cl) { if (!cl->clk) { cl->clk = clk_get(&device->res->pdev->dev, cl->name); if (IS_ERR_OR_NULL(cl->clk)) { dprintk(VIDC_ERR, "Failed to get clock: %s\n", cl->name); rc = PTR_ERR(cl->clk) ?: -EINVAL; cl->clk = NULL; goto err_clk_get; } } } device->clk_freq = 0; return 0; err_clk_get: __deinit_clocks(device); return rc; } static inline void __disable_unprepare_clks(struct venus_hfi_device *device) { struct clock_info *cl; if (!device) { dprintk(VIDC_ERR, "Invalid params: %p\n", device); return; } venus_hfi_for_each_clock(device, cl) { usleep_range(100, 500); dprintk(VIDC_DBG, "Clock: %s disable and unprepare\n", cl->name); clk_disable_unprepare(cl->clk); } } static inline int __prepare_enable_clks(struct venus_hfi_device *device) { struct clock_info *cl = NULL, *cl_fail = NULL; int rc = 0; if (!device) { dprintk(VIDC_ERR, "Invalid params: %p\n", device); return -EINVAL; } venus_hfi_for_each_clock(device, cl) { /* * For the clocks we control, set the rate prior to preparing * them. Since we don't really have a load at this point, scale * it to the lowest frequency possible */ if (cl->has_scaling) clk_set_rate(cl->clk, clk_round_rate(cl->clk, 0)); rc = clk_prepare_enable(cl->clk); if (rc) { dprintk(VIDC_ERR, "Failed to enable clocks\n"); cl_fail = cl; goto fail_clk_enable; } dprintk(VIDC_DBG, "Clock: %s prepared and enabled\n", cl->name); } __write_register(device, VIDC_WRAPPER_CLOCK_CONFIG, 0); __write_register(device, VIDC_WRAPPER_CPU_CLOCK_CONFIG, 0); return rc; fail_clk_enable: venus_hfi_for_each_clock(device, cl) { if (cl_fail == cl) break; usleep_range(100, 500); dprintk(VIDC_ERR, "Clock: %s disable and unprepare\n", cl->name); clk_disable_unprepare(cl->clk); } return rc; } static void __deinit_bus(struct venus_hfi_device *device) { struct bus_info *bus = NULL; if (!device) return; kfree(device->bus_vote.data); device->bus_vote = DEFAULT_BUS_VOTE; venus_hfi_for_each_bus_reverse(device, bus) { devfreq_remove_device(bus->devfreq); bus->devfreq = NULL; dev_set_drvdata(bus->dev, NULL); msm_bus_scale_unregister(bus->client); bus->client = NULL; } } static int __init_bus(struct venus_hfi_device *device) { struct bus_info *bus = NULL; int rc = 0; if (!device) return -EINVAL; venus_hfi_for_each_bus(device, bus) { struct devfreq_dev_profile profile = { .initial_freq = 0, .polling_ms = INT_MAX, .freq_table = NULL, .max_state = 0, .target = __devfreq_target, .get_dev_status = __devfreq_get_status, .exit = NULL, }; /* * This is stupid, but there's no other easy way to ahold * of struct bus_info in venus_hfi_devfreq_*() */ WARN(dev_get_drvdata(bus->dev), "%s's drvdata already set\n", dev_name(bus->dev)); dev_set_drvdata(bus->dev, device); bus->client = msm_bus_scale_register(bus->master, bus->slave, bus->name, false); if (IS_ERR_OR_NULL(bus->client)) { rc = PTR_ERR(bus->client) ?: -EBADHANDLE; dprintk(VIDC_ERR, "Failed to register bus %s: %d\n", bus->name, rc); bus->client = NULL; goto err_add_dev; } bus->devfreq_prof = profile; bus->devfreq = devfreq_add_device(bus->dev, &bus->devfreq_prof, bus->governor, NULL); if (IS_ERR_OR_NULL(bus->devfreq)) { rc = PTR_ERR(bus->devfreq) ?: -EBADHANDLE; dprintk(VIDC_ERR, "Failed to add devfreq device for bus %s and governor %s: %d\n", bus->name, bus->governor, rc); bus->devfreq = NULL; goto err_add_dev; } /* * Devfreq starts monitoring immediately, since we are just * initializing stuff at this point, force it to suspend */ devfreq_suspend_device(bus->devfreq); } device->bus_vote = DEFAULT_BUS_VOTE; return 0; err_add_dev: __deinit_bus(device); return rc; } static void __deinit_regulators(struct venus_hfi_device *device) { struct regulator_info *rinfo = NULL; venus_hfi_for_each_regulator_reverse(device, rinfo) { if (rinfo->regulator) { regulator_put(rinfo->regulator); rinfo->regulator = NULL; } } } static int __init_regulators(struct venus_hfi_device *device) { int rc = 0; struct regulator_info *rinfo = NULL; venus_hfi_for_each_regulator(device, rinfo) { rinfo->regulator = regulator_get(&device->res->pdev->dev, rinfo->name); if (IS_ERR_OR_NULL(rinfo->regulator)) { rc = PTR_ERR(rinfo->regulator) ?: -EBADHANDLE; dprintk(VIDC_ERR, "Failed to get regulator: %s\n", rinfo->name); rinfo->regulator = NULL; goto err_reg_get; } } return 0; err_reg_get: __deinit_regulators(device); return rc; } static int __init_resources(struct venus_hfi_device *device, struct msm_vidc_platform_resources *res) { int rc = 0; rc = __init_regulators(device); if (rc) { dprintk(VIDC_ERR, "Failed to get all regulators\n"); return -ENODEV; } rc = __init_clocks(device); if (rc) { dprintk(VIDC_ERR, "Failed to init clocks\n"); rc = -ENODEV; goto err_init_clocks; } rc = __init_bus(device); if (rc) { dprintk(VIDC_ERR, "Failed to init bus: %d\n", rc); goto err_init_bus; } device->sys_init_capabilities = kzalloc(sizeof(struct msm_vidc_capability) * VIDC_MAX_SESSIONS, GFP_TEMPORARY); return rc; err_init_bus: __deinit_clocks(device); err_init_clocks: __deinit_regulators(device); return rc; } static void __deinit_resources(struct venus_hfi_device *device) { __deinit_bus(device); __deinit_clocks(device); __deinit_regulators(device); kfree(device->sys_init_capabilities); device->sys_init_capabilities = NULL; } static int __protect_cp_mem(struct venus_hfi_device *device) { struct tzbsp_memprot memprot; unsigned int resp = 0; int rc = 0; struct context_bank_info *cb; struct scm_desc desc = {0}; if (!device) return -EINVAL; memprot.cp_start = 0x0; memprot.cp_size = 0x0; memprot.cp_nonpixel_start = 0x0; memprot.cp_nonpixel_size = 0x0; list_for_each_entry(cb, &device->res->context_banks, list) { if (!strcmp(cb->name, "venus_ns")) { desc.args[1] = memprot.cp_size = cb->addr_range.start; dprintk(VIDC_DBG, "%s memprot.cp_size: %#x\n", __func__, memprot.cp_size); } if (!strcmp(cb->name, "venus_sec_non_pixel")) { desc.args[2] = memprot.cp_nonpixel_start = cb->addr_range.start; desc.args[3] = memprot.cp_nonpixel_size = cb->addr_range.size; dprintk(VIDC_DBG, "%s memprot.cp_nonpixel_start: %#x size: %#x\n", __func__, memprot.cp_nonpixel_start, memprot.cp_nonpixel_size); } } if (!is_scm_armv8()) { rc = scm_call(SCM_SVC_MP, TZBSP_MEM_PROTECT_VIDEO_VAR, &memprot, sizeof(memprot), &resp, sizeof(resp)); } else { desc.arginfo = SCM_ARGS(4); rc = scm_call2(SCM_SIP_FNID(SCM_SVC_MP, TZBSP_MEM_PROTECT_VIDEO_VAR), &desc); resp = desc.ret[0]; } if (rc) { dprintk(VIDC_ERR, "Failed to protect memory(%d) response: %d\n", rc, resp); } trace_venus_hfi_var_done( memprot.cp_start, memprot.cp_size, memprot.cp_nonpixel_start, memprot.cp_nonpixel_size); return rc; } static int __disable_regulator(struct regulator_info *rinfo) { int rc = 0; dprintk(VIDC_DBG, "Disabling regulator %s\n", rinfo->name); /* * This call is needed. Driver needs to acquire the control back * from HW in order to disable the regualtor. Else the behavior * is unknown. */ rc = __acquire_regulator(rinfo); if (rc) { /* This is somewhat fatal, but nothing we can do * about it. We can't disable the regulator w/o * getting it back under s/w control */ dprintk(VIDC_WARN, "Failed to acquire control on %s\n", rinfo->name); goto disable_regulator_failed; } rc = regulator_disable(rinfo->regulator); if (rc) { dprintk(VIDC_WARN, "Failed to disable %s: %d\n", rinfo->name, rc); goto disable_regulator_failed; } return 0; disable_regulator_failed: /* Bring attention to this issue */ WARN_ON(1); return rc; } static int __enable_hw_power_collapse(struct venus_hfi_device *device) { int rc = 0; if (!msm_vidc_fw_low_power_mode) { dprintk(VIDC_DBG, "Not enabling hardware power collapse\n"); return 0; } rc = __hand_off_regulators(device); if (rc) dprintk(VIDC_WARN, "%s : Failed to enable HW power collapse %d\n", __func__, rc); return rc; } static int __core_clk_reset(struct venus_hfi_device *device, enum clk_reset_action action) { int rc = 0; struct regulator_info *rinfo; struct clock_info *vc; rinfo = __get_regulator(device, "venus"); if (!rinfo) return -EINVAL; /* * This is a workaround for msm8996 V2, because MDP enables * Venus GDSC. Due to MDP's vote on Venus GDSC, some of Venus * registers are not cleared after firmware is unloaded. This * causes subsequent video sessions to fail. By resetting * core_clk we are forcing a hard reset and ensure each * firmware load starts on a clean slate. * For targets which do not need to reset the core_clk, clock * driver returns -EPERM. Do not consider such cases as erroneous. */ dprintk(VIDC_DBG, "%s core-clk\n", action == CLK_RESET_DEASSERT ? "de-assert" : "assert"); vc = __get_clock(device, "core_clk"); if (vc) { rc = clk_reset(vc->clk, action); if (rc == -EPERM) { rc = 0; dprintk(VIDC_DBG, "%s No need to reset\n", __func__); } else if (rc) { dprintk(VIDC_ERR, "clk_reset action - %d failed: %d\n", action, rc); return rc; } } else { return -EINVAL; } udelay(1); return rc; } static int __enable_regulators(struct venus_hfi_device *device) { int rc = 0, c = 0; struct regulator_info *rinfo; rc = __core_clk_reset(device, CLK_RESET_DEASSERT); if (rc) return rc; dprintk(VIDC_DBG, "Enabling regulators\n"); venus_hfi_for_each_regulator(device, rinfo) { rc = regulator_enable(rinfo->regulator); if (rc) { dprintk(VIDC_ERR, "Failed to enable %s: %d\n", rinfo->name, rc); goto err_reg_enable_failed; } dprintk(VIDC_DBG, "Enabled regulator %s\n", rinfo->name); c++; } return 0; err_reg_enable_failed: venus_hfi_for_each_regulator_reverse_continue(device, rinfo, c) __disable_regulator(rinfo); return rc; } static int __disable_regulators(struct venus_hfi_device *device) { struct regulator_info *rinfo; int rc = 0; dprintk(VIDC_DBG, "Disabling regulators\n"); venus_hfi_for_each_regulator_reverse(device, rinfo) __disable_regulator(rinfo); rc = __core_clk_reset(device, CLK_RESET_ASSERT); return rc; } static int __venus_power_on(struct venus_hfi_device *device) { int rc = 0; if (device->power_enabled) return 0; device->power_enabled = true; /* Vote for all hardware resources */ rc = __vote_buses(device, device->bus_vote.data, device->bus_vote.data_count); if (rc) { dprintk(VIDC_ERR, "Failed to vote buses, err: %d\n", rc); goto fail_vote_buses; } rc = __alloc_imem(device, device->res->imem_size); if (rc) { dprintk(VIDC_ERR, "Failed to allocate IMEM\n"); goto fail_alloc_imem; } rc = __enable_regulators(device); if (rc) { dprintk(VIDC_ERR, "Failed to enable GDSC, err = %d\n", rc); goto fail_enable_gdsc; } rc = __prepare_enable_clks(device); if (rc) { dprintk(VIDC_ERR, "Failed to enable clocks: %d\n", rc); goto fail_enable_clks; } rc = __scale_clocks(device, 0, NULL, 0); if (rc) { dprintk(VIDC_WARN, "Failed to scale clocks, performance might be affected\n"); rc = 0; } __write_register(device, VIDC_WRAPPER_INTR_MASK, VIDC_WRAPPER_INTR_MASK_A2HVCODEC_BMSK); device->intr_status = 0; enable_irq(device->hal_data->irq); /* * Hand off control of regulators to h/w _after_ enabling clocks. * Note that the GDSC will turn off when switching from normal * (s/w triggered) to fast (HW triggered) unless the h/w vote is * present. Since Venus isn't up yet, the GDSC will be off briefly. */ if (__enable_hw_power_collapse(device)) dprintk(VIDC_ERR, "Failed to enabled inter-frame PC\n"); return rc; fail_enable_clks: __disable_regulators(device); fail_enable_gdsc: __free_imem(device); fail_alloc_imem: __unvote_buses(device); fail_vote_buses: device->power_enabled = false; return rc; } static void __venus_power_off(struct venus_hfi_device *device, bool halt_axi) { if (!device->power_enabled) return; if (!(device->intr_status & VIDC_WRAPPER_INTR_STATUS_A2HWD_BMSK)) disable_irq_nosync(device->hal_data->irq); device->intr_status = 0; /* Halt the AXI to make sure there are no pending transactions. * Clocks should be unprepared after making sure axi is halted. */ if (halt_axi && __halt_axi(device)) dprintk(VIDC_WARN, "Failed to halt AXI\n"); __disable_unprepare_clks(device); if (__disable_regulators(device)) dprintk(VIDC_WARN, "Failed to disable regulators\n"); __free_imem(device); if (__unvote_buses(device)) dprintk(VIDC_WARN, "Failed to unvote for buses\n"); device->power_enabled = false; } static inline int __suspend(struct venus_hfi_device *device) { int rc = 0; if (!device) { dprintk(VIDC_ERR, "Invalid params: %p\n", device); return -EINVAL; } else if (!device->power_enabled) { dprintk(VIDC_DBG, "Power already disabled\n"); return 0; } dprintk(VIDC_DBG, "Entering power collapse\n"); if (device->res->pm_qos_latency_us) pm_qos_remove_request(&device->qos); rc = __tzbsp_set_video_state(TZBSP_VIDEO_STATE_SUSPEND); if (rc) { dprintk(VIDC_WARN, "Failed to suspend video core %d\n", rc); goto err_tzbsp_suspend; } __venus_power_off(device, true); dprintk(VIDC_INFO, "Venus power collapsed\n"); return rc; err_tzbsp_suspend: return rc; } static inline int __resume(struct venus_hfi_device *device) { int rc = 0; if (!device) { dprintk(VIDC_ERR, "Invalid params: %p\n", device); return -EINVAL; } else if (device->power_enabled) { dprintk(VIDC_DBG, "Power is already enabled\n"); goto exit; } dprintk(VIDC_DBG, "Resuming from power collapse\n"); rc = __venus_power_on(device); if (rc) { dprintk(VIDC_ERR, "Failed to power on venus\n"); goto err_venus_power_on; } /* Reboot the firmware */ rc = __tzbsp_set_video_state(TZBSP_VIDEO_STATE_RESUME); if (rc) { dprintk(VIDC_ERR, "Failed to resume video core %d\n", rc); goto err_set_video_state; } /* * Re-program all of the registers that get reset as a result of * regulator_disable() and _enable() */ __set_registers(device); __setup_ucregion_memory_map(device); /* Wait for boot completion */ rc = __boot_firmware(device); if (rc) { dprintk(VIDC_ERR, "Failed to reset venus core\n"); goto err_reset_core; } /* * Work around for H/W bug, need to reprogram these registers once * firmware is out reset */ __set_threshold_registers(device); if (device->res->pm_qos_latency_us) pm_qos_add_request(&device->qos, PM_QOS_CPU_DMA_LATENCY, device->res->pm_qos_latency_us); dprintk(VIDC_INFO, "Resumed from power collapse\n"); exit: device->skip_pc_count = 0; return rc; err_reset_core: __tzbsp_set_video_state(TZBSP_VIDEO_STATE_SUSPEND); err_set_video_state: __venus_power_off(device, true); err_venus_power_on: dprintk(VIDC_ERR, "Failed to resume from power collapse\n"); return rc; } static int __load_fw(struct venus_hfi_device *device) { int rc = 0; /* Initialize resources */ rc = __init_resources(device, device->res); if (rc) { dprintk(VIDC_ERR, "Failed to init resources: %d\n", rc); goto fail_init_res; } rc = __initialize_packetization(device); if (rc) { dprintk(VIDC_ERR, "Failed to initialize packetization\n"); goto fail_init_pkt; } trace_msm_v4l2_vidc_fw_load_start("msm_v4l2_vidc venus_fw load start"); rc = __venus_power_on(device); if (rc) { dprintk(VIDC_ERR, "Failed to power on venus in in load_fw\n"); goto fail_venus_power_on; } if ((!device->res->use_non_secure_pil && !device->res->firmware_base) || device->res->use_non_secure_pil) { if (!device->resources.fw.cookie) device->resources.fw.cookie = subsystem_get_with_fwname("venus", device->res->fw_name); if (IS_ERR_OR_NULL(device->resources.fw.cookie)) { dprintk(VIDC_ERR, "Failed to download firmware\n"); device->resources.fw.cookie = NULL; rc = -ENOMEM; goto fail_load_fw; } } if (!device->res->use_non_secure_pil && !device->res->firmware_base) { rc = __protect_cp_mem(device); if (rc) { dprintk(VIDC_ERR, "Failed to protect memory\n"); goto fail_protect_mem; } } trace_msm_v4l2_vidc_fw_load_end("msm_v4l2_vidc venus_fw load end"); return rc; fail_protect_mem: if (device->resources.fw.cookie) subsystem_put(device->resources.fw.cookie); device->resources.fw.cookie = NULL; fail_load_fw: __venus_power_off(device, true); fail_venus_power_on: fail_init_pkt: __deinit_resources(device); fail_init_res: trace_msm_v4l2_vidc_fw_load_end("msm_v4l2_vidc venus_fw load end"); return rc; } static void __unload_fw(struct venus_hfi_device *device) { if (!device->resources.fw.cookie) return; cancel_delayed_work(&venus_hfi_pm_work); if (device->state != VENUS_STATE_DEINIT) flush_workqueue(device->venus_pm_workq); /* * If the core_clk is asserted, then PIL cannot enable * any of the venus clocks. So deassert the clock before * calling subsystem_put. */ if (__core_clk_reset(device, CLK_RESET_DEASSERT)) dprintk(VIDC_ERR, "failed to deassert core_clk\n"); subsystem_put(device->resources.fw.cookie); __interface_queues_release(device); __venus_power_off(device, false); device->resources.fw.cookie = NULL; __deinit_resources(device); } static int venus_hfi_get_fw_info(void *dev, struct hal_fw_info *fw_info) { int i = 0, j = 0; struct venus_hfi_device *device = dev; u32 smem_block_size = 0; u8 *smem_table_ptr; char version[VENUS_VERSION_LENGTH]; const u32 smem_image_index_venus = 14 * 128; if (!device || !fw_info) { dprintk(VIDC_ERR, "%s Invalid parameter: device = %pK fw_info = %pK\n", __func__, device, fw_info); return -EINVAL; } mutex_lock(&device->lock); smem_table_ptr = smem_get_entry(SMEM_IMAGE_VERSION_TABLE, &smem_block_size, 0, SMEM_ANY_HOST_FLAG); if (smem_table_ptr && ((smem_image_index_venus + VENUS_VERSION_LENGTH) <= smem_block_size)) memcpy(version, smem_table_ptr + smem_image_index_venus, VENUS_VERSION_LENGTH); while (version[i++] != 'V' && i < VENUS_VERSION_LENGTH) ; if (i == VENUS_VERSION_LENGTH - 1) { dprintk(VIDC_WARN, "Venus version string is not proper\n"); fw_info->version[0] = '\0'; goto fail_version_string; } for (i--; i < VENUS_VERSION_LENGTH && j < VENUS_VERSION_LENGTH; i++) fw_info->version[j++] = version[i]; fw_info->version[j] = '\0'; fail_version_string: dprintk(VIDC_DBG, "F/W version retrieved : %s\n", fw_info->version); fw_info->base_addr = device->hal_data->firmware_base; fw_info->register_base = device->res->register_base; fw_info->register_size = device->hal_data->register_size; fw_info->irq = device->hal_data->irq; mutex_unlock(&device->lock); return 0; } static int venus_hfi_get_core_capabilities(void *dev) { struct venus_hfi_device *device = dev; int rc = 0; if (!device) return -EINVAL; mutex_lock(&device->lock); rc = HAL_VIDEO_ENCODER_ROTATION_CAPABILITY | HAL_VIDEO_ENCODER_SCALING_CAPABILITY | HAL_VIDEO_ENCODER_DEINTERLACE_CAPABILITY | HAL_VIDEO_DECODER_MULTI_STREAM_CAPABILITY; mutex_unlock(&device->lock); return rc; } static int __initialize_packetization(struct venus_hfi_device *device) { int rc = 0; const char *hfi_version; if (!device || !device->res) { dprintk(VIDC_ERR, "%s - invalid param\n", __func__); return -EINVAL; } hfi_version = device->res->hfi_version; if (!hfi_version) { device->packetization_type = HFI_PACKETIZATION_LEGACY; } else if (!strcmp(hfi_version, "3xx")) { device->packetization_type = HFI_PACKETIZATION_3XX; } else { dprintk(VIDC_ERR, "Unsupported hfi version\n"); return -EINVAL; } device->pkt_ops = hfi_get_pkt_ops_handle(device->packetization_type); if (!device->pkt_ops) { rc = -EINVAL; dprintk(VIDC_ERR, "Failed to get pkt_ops handle\n"); } return rc; } static struct venus_hfi_device *__add_device(u32 device_id, struct msm_vidc_platform_resources *res, hfi_cmd_response_callback callback) { struct venus_hfi_device *hdevice = NULL; int rc = 0; if (!res || !callback) { dprintk(VIDC_ERR, "Invalid Parameters\n"); return NULL; } dprintk(VIDC_INFO, "entered , device_id: %d\n", device_id); hdevice = (struct venus_hfi_device *) kzalloc(sizeof(struct venus_hfi_device), GFP_KERNEL); if (!hdevice) { dprintk(VIDC_ERR, "failed to allocate new device\n"); goto exit; } hdevice->response_pkt = kmalloc_array(max_packets, sizeof(*hdevice->response_pkt), GFP_TEMPORARY); if (!hdevice->response_pkt) { dprintk(VIDC_ERR, "failed to allocate response_pkt\n"); goto err_cleanup; } rc = __init_regs_and_interrupts(hdevice, res); if (rc) goto err_cleanup; hdevice->res = res; hdevice->device_id = device_id; hdevice->callback = callback; hdevice->vidc_workq = create_singlethread_workqueue( "msm_vidc_workerq_venus"); if (!hdevice->vidc_workq) { dprintk(VIDC_ERR, ": create vidc workq failed\n"); goto err_cleanup; } hdevice->venus_pm_workq = create_singlethread_workqueue( "pm_workerq_venus"); if (!hdevice->venus_pm_workq) { dprintk(VIDC_ERR, ": create pm workq failed\n"); goto err_cleanup; } if (!hal_ctxt.dev_count) INIT_LIST_HEAD(&hal_ctxt.dev_head); mutex_init(&hdevice->lock); INIT_LIST_HEAD(&hdevice->list); INIT_LIST_HEAD(&hdevice->sess_head); list_add_tail(&hdevice->list, &hal_ctxt.dev_head); hal_ctxt.dev_count++; return hdevice; err_cleanup: if (hdevice->vidc_workq) destroy_workqueue(hdevice->vidc_workq); kfree(hdevice->response_pkt); kfree(hdevice); exit: return NULL; } static struct venus_hfi_device *__get_device(u32 device_id, struct msm_vidc_platform_resources *res, hfi_cmd_response_callback callback) { if (!res || !callback) { dprintk(VIDC_ERR, "Invalid params: %p %p\n", res, callback); return NULL; } return __add_device(device_id, res, callback); } void venus_hfi_delete_device(void *device) { struct venus_hfi_device *close, *tmp, *dev; if (!device) return; dev = (struct venus_hfi_device *) device; mutex_lock(&dev->lock); __iommu_detach(dev); mutex_unlock(&dev->lock); list_for_each_entry_safe(close, tmp, &hal_ctxt.dev_head, list) { if (close->hal_data->irq == dev->hal_data->irq) { hal_ctxt.dev_count--; list_del(&close->list); destroy_workqueue(close->vidc_workq); destroy_workqueue(close->venus_pm_workq); free_irq(dev->hal_data->irq, close); iounmap(dev->hal_data->register_base); kfree(close->hal_data); kfree(close->response_pkt); kfree(close); break; } } } static void venus_init_hfi_callbacks(struct hfi_device *hdev) { hdev->core_init = venus_hfi_core_init; hdev->core_release = venus_hfi_core_release; hdev->core_ping = venus_hfi_core_ping; hdev->core_trigger_ssr = venus_hfi_core_trigger_ssr; hdev->session_init = venus_hfi_session_init; hdev->session_end = venus_hfi_session_end; hdev->session_abort = venus_hfi_session_abort; hdev->session_clean = venus_hfi_session_clean; hdev->session_set_buffers = venus_hfi_session_set_buffers; hdev->session_release_buffers = venus_hfi_session_release_buffers; hdev->session_load_res = venus_hfi_session_load_res; hdev->session_release_res = venus_hfi_session_release_res; hdev->session_start = venus_hfi_session_start; hdev->session_continue = venus_hfi_session_continue; hdev->session_stop = venus_hfi_session_stop; hdev->session_etb = venus_hfi_session_etb; hdev->session_ftb = venus_hfi_session_ftb; hdev->session_process_batch = venus_hfi_session_process_batch; hdev->session_parse_seq_hdr = venus_hfi_session_parse_seq_hdr; hdev->session_get_seq_hdr = venus_hfi_session_get_seq_hdr; hdev->session_get_buf_req = venus_hfi_session_get_buf_req; hdev->session_flush = venus_hfi_session_flush; hdev->session_set_property = venus_hfi_session_set_property; hdev->session_get_property = venus_hfi_session_get_property; hdev->scale_clocks = venus_hfi_scale_clocks; hdev->vote_bus = venus_hfi_vote_buses; hdev->get_fw_info = venus_hfi_get_fw_info; hdev->get_core_capabilities = venus_hfi_get_core_capabilities; hdev->suspend = venus_hfi_suspend; hdev->get_core_clock_rate = venus_hfi_get_core_clock_rate; hdev->get_default_properties = venus_hfi_get_default_properties; } int venus_hfi_initialize(struct hfi_device *hdev, u32 device_id, struct msm_vidc_platform_resources *res, hfi_cmd_response_callback callback) { int rc = 0; if (!hdev || !res || !callback) { dprintk(VIDC_ERR, "Invalid params: %p %p %p\n", hdev, res, callback); rc = -EINVAL; goto err_venus_hfi_init; } hdev->hfi_device_data = __get_device(device_id, res, callback); if (IS_ERR_OR_NULL(hdev->hfi_device_data)) { rc = PTR_ERR(hdev->hfi_device_data) ?: -EINVAL; goto err_venus_hfi_init; } venus_init_hfi_callbacks(hdev); err_venus_hfi_init: return rc; }