/* Copyright (c) 2015-2019, 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 "diagchar.h" #include "diagfwd.h" #include "diagfwd_peripheral.h" #include "diagfwd_socket.h" #include "diag_ipc_logging.h" #include #include #define DIAG_SVC_ID 0x1001 #define MODEM_INST_BASE 0 #define LPASS_INST_BASE 64 #define WCNSS_INST_BASE 128 #define SENSORS_INST_BASE 192 #define CDSP_INST_BASE 256 #define WDSP_INST_BASE 320 #define NPU_INST_BASE 384 #define INST_ID_CNTL 0 #define INST_ID_CMD 1 #define INST_ID_DATA 2 #define INST_ID_DCI_CMD 3 #define INST_ID_DCI 4 #define MAX_BUF_SIZE 0x4400 #define MAX_NO_PACKETS 10 #define DIAG_SO_RCVBUF_SIZE (MAX_BUF_SIZE * MAX_NO_PACKETS) struct qmi_handle *cntl_qmi; static uint64_t bootup_req[NUM_SOCKET_SUBSYSTEMS]; struct diag_socket_info socket_data[NUM_PERIPHERALS] = { { .peripheral = PERIPHERAL_MODEM, .type = TYPE_DATA, .name = "MODEM_DATA" }, { .peripheral = PERIPHERAL_LPASS, .type = TYPE_DATA, .name = "LPASS_DATA" }, { .peripheral = PERIPHERAL_WCNSS, .type = TYPE_DATA, .name = "WCNSS_DATA" }, { .peripheral = PERIPHERAL_SENSORS, .type = TYPE_DATA, .name = "SENSORS_DATA" }, { .peripheral = PERIPHERAL_WDSP, .type = TYPE_DATA, .name = "DIAG_DATA" }, { .peripheral = PERIPHERAL_CDSP, .type = TYPE_DATA, .name = "CDSP_DATA" }, { .peripheral = PERIPHERAL_NPU, .type = TYPE_DATA, .name = "NPU_DATA" } }; struct diag_socket_info socket_cntl[NUM_PERIPHERALS] = { { .peripheral = PERIPHERAL_MODEM, .type = TYPE_CNTL, .name = "MODEM_CNTL" }, { .peripheral = PERIPHERAL_LPASS, .type = TYPE_CNTL, .name = "LPASS_CNTL" }, { .peripheral = PERIPHERAL_WCNSS, .type = TYPE_CNTL, .name = "WCNSS_CNTL" }, { .peripheral = PERIPHERAL_SENSORS, .type = TYPE_CNTL, .name = "SENSORS_CNTL" }, { .peripheral = PERIPHERAL_WDSP, .type = TYPE_CNTL, .name = "DIAG_CTRL" }, { .peripheral = PERIPHERAL_CDSP, .type = TYPE_CNTL, .name = "CDSP_CNTL" }, { .peripheral = PERIPHERAL_NPU, .type = TYPE_CNTL, .name = "NPU_CNTL" } }; struct diag_socket_info socket_dci[NUM_PERIPHERALS] = { { .peripheral = PERIPHERAL_MODEM, .type = TYPE_DCI, .name = "MODEM_DCI" }, { .peripheral = PERIPHERAL_LPASS, .type = TYPE_DCI, .name = "LPASS_DCI" }, { .peripheral = PERIPHERAL_WCNSS, .type = TYPE_DCI, .name = "WCNSS_DCI" }, { .peripheral = PERIPHERAL_SENSORS, .type = TYPE_DCI, .name = "SENSORS_DCI" }, { .peripheral = PERIPHERAL_WDSP, .type = TYPE_DCI, .name = "DIAG_DCI_DATA" }, { .peripheral = PERIPHERAL_CDSP, .type = TYPE_DCI, .name = "CDSP_DCI" }, { .peripheral = PERIPHERAL_NPU, .type = TYPE_DCI, .name = "NPU_DCI" } }; struct diag_socket_info socket_cmd[NUM_PERIPHERALS] = { { .peripheral = PERIPHERAL_MODEM, .type = TYPE_CMD, .name = "MODEM_CMD" }, { .peripheral = PERIPHERAL_LPASS, .type = TYPE_CMD, .name = "LPASS_CMD" }, { .peripheral = PERIPHERAL_WCNSS, .type = TYPE_CMD, .name = "WCNSS_CMD" }, { .peripheral = PERIPHERAL_SENSORS, .type = TYPE_CMD, .name = "SENSORS_CMD" }, { .peripheral = PERIPHERAL_WDSP, .type = TYPE_CMD, .name = "DIAG_CMD" }, { .peripheral = PERIPHERAL_CDSP, .type = TYPE_CMD, .name = "CDSP_CMD" }, { .peripheral = PERIPHERAL_NPU, .type = TYPE_CMD, .name = "NPU_CMD" } }; struct diag_socket_info socket_dci_cmd[NUM_PERIPHERALS] = { { .peripheral = PERIPHERAL_MODEM, .type = TYPE_DCI_CMD, .name = "MODEM_DCI_CMD" }, { .peripheral = PERIPHERAL_LPASS, .type = TYPE_DCI_CMD, .name = "LPASS_DCI_CMD" }, { .peripheral = PERIPHERAL_WCNSS, .type = TYPE_DCI_CMD, .name = "WCNSS_DCI_CMD" }, { .peripheral = PERIPHERAL_SENSORS, .type = TYPE_DCI_CMD, .name = "SENSORS_DCI_CMD" }, { .peripheral = PERIPHERAL_WDSP, .type = TYPE_DCI_CMD, .name = "DIAG_DCI_CMD" }, { .peripheral = PERIPHERAL_CDSP, .type = TYPE_DCI_CMD, .name = "CDSP_DCI_CMD" }, { .peripheral = PERIPHERAL_NPU, .type = TYPE_DCI_CMD, .name = "NPU_DCI_CMD" } }; struct restart_notifier_block { unsigned int processor; char *name; struct notifier_block nb; }; static int restart_notifier_cb(struct notifier_block *this, unsigned long code, void *_cmd) { struct restart_notifier_block *notifier; notifier = container_of(this, struct restart_notifier_block, nb); if (!notifier) { DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "diag: %s: invalid notifier block\n", __func__); return NOTIFY_DONE; } DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "%s: ssr for processor %d ('%s')\n", __func__, notifier->processor, notifier->name); switch (code) { case SUBSYS_BEFORE_SHUTDOWN: DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "diag: %s: SUBSYS_BEFORE_SHUTDOWN\n", __func__); mutex_lock(&driver->diag_notifier_mutex); bootup_req[notifier->processor] = PERIPHERAL_SSR_DOWN; DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "diag: bootup_req[%s] = %d\n", notifier->name, (int)bootup_req[notifier->processor]); mutex_unlock(&driver->diag_notifier_mutex); break; case SUBSYS_AFTER_SHUTDOWN: DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "diag: %s: SUBSYS_AFTER_SHUTDOWN\n", __func__); break; case SUBSYS_BEFORE_POWERUP: DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "diag: %s: SUBSYS_BEFORE_POWERUP\n", __func__); break; case SUBSYS_AFTER_POWERUP: DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "diag: %s: SUBSYS_AFTER_POWERUP\n", __func__); mutex_lock(&driver->diag_notifier_mutex); if (!bootup_req[notifier->processor]) { bootup_req[notifier->processor] = PERIPHERAL_SSR_DOWN; DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "diag: bootup_req[%s] = %d\n", notifier->name, (int)bootup_req[notifier->processor]); mutex_unlock(&driver->diag_notifier_mutex); break; } bootup_req[notifier->processor] = PERIPHERAL_SSR_UP; DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "diag: bootup_req[%s] = %d\n", notifier->name, (int)bootup_req[notifier->processor]); mutex_unlock(&driver->diag_notifier_mutex); break; default: DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "diag: code: %lu\n", code); break; } return NOTIFY_DONE; } static struct restart_notifier_block restart_notifiers[] = { {SOCKET_MODEM, "modem", .nb.notifier_call = restart_notifier_cb}, {SOCKET_ADSP, "adsp", .nb.notifier_call = restart_notifier_cb}, {SOCKET_WCNSS, "wcnss", .nb.notifier_call = restart_notifier_cb}, {SOCKET_SLPI, "slpi", .nb.notifier_call = restart_notifier_cb}, {SOCKET_CDSP, "cdsp", .nb.notifier_call = restart_notifier_cb}, {SOCKET_NPU, "npu", .nb.notifier_call = restart_notifier_cb}, }; void diag_socket_invalidate(void *ctxt, struct diagfwd_info *fwd_ctxt) { struct diag_socket_info *info = NULL; if (!ctxt || !fwd_ctxt) return; info = (struct diag_socket_info *)ctxt; info->fwd_ctxt = fwd_ctxt; } int diag_socket_check_state(void *ctxt) { struct diag_socket_info *info = NULL; if (!ctxt) return 0; info = (struct diag_socket_info *)ctxt; return (int)(atomic_read(&info->diag_state)); } static void diag_state_open_socket(void *ctxt); static void diag_state_close_socket(void *ctxt); static int diag_socket_write(void *ctxt, unsigned char *buf, int len); static int diag_socket_read(void *ctxt, unsigned char *buf, int buf_len); static void diag_socket_drop_data(struct diag_socket_info *info); static void diag_socket_queue_read(void *ctxt); static struct diag_peripheral_ops socket_ops = { .open = diag_state_open_socket, .close = diag_state_close_socket, .write = diag_socket_write, .read = diag_socket_read, .queue_read = diag_socket_queue_read }; static void diag_state_open_socket(void *ctxt) { struct diag_socket_info *info = NULL; if (!ctxt) return; info = (struct diag_socket_info *)(ctxt); atomic_set(&info->diag_state, 1); DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "%s setting diag state to 1", info->name); } static void diag_state_close_socket(void *ctxt) { struct diag_socket_info *info = NULL; if (!ctxt) return; info = (struct diag_socket_info *)(ctxt); atomic_set(&info->diag_state, 0); DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "%s setting diag state to 0", info->name); wake_up_interruptible(&info->read_wait_q); flush_workqueue(info->wq); } static void __socket_open_channel(struct diag_socket_info *info) { if (!info) return; if (!info->inited) { pr_debug("diag: In %s, socket %s is not initialized\n", __func__, info->name); return; } if (atomic_read(&info->opened)) { pr_debug("diag: In %s, socket %s already opened\n", __func__, info->name); return; } atomic_set(&info->opened, 1); diagfwd_channel_open(info->fwd_ctxt); } static void socket_data_ready(struct sock *sk_ptr) { struct diag_socket_info *info; unsigned long flags; if (!sk_ptr) { pr_err_ratelimited("diag: In %s, invalid sk_ptr", __func__); return; } info = (struct diag_socket_info *)(sk_ptr->sk_user_data); if (!info) { pr_err_ratelimited("diag: In %s, invalid info\n", __func__); return; } spin_lock_irqsave(&info->lock, flags); info->data_ready++; spin_unlock_irqrestore(&info->lock, flags); diag_ws_on_notify(); queue_work(info->wq, &(info->read_work)); wake_up_interruptible(&info->read_wait_q); } static void socket_open_client(struct diag_socket_info *info) { int ret; if (!info || info->port_type != PORT_TYPE_CLIENT) return; ret = sock_create(AF_QIPCRTR, SOCK_DGRAM, PF_QIPCRTR, &info->hdl); if (ret < 0 || !info->hdl) { pr_err("diag: In %s, socket not initialized for %s\n", __func__, info->name); return; } write_lock_bh(&info->hdl->sk->sk_callback_lock); info->hdl->sk->sk_user_data = (void *)(info); info->hdl->sk->sk_data_ready = socket_data_ready; info->hdl->sk->sk_error_report = socket_data_ready; write_unlock_bh(&info->hdl->sk->sk_callback_lock); if (!info->remote_addr.sq_node && !info->remote_addr.sq_port) { pr_err("diag: In %s, failed to get remote_addr\n", __func__); return; } __socket_open_channel(info); DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "%s opened client\n", info->name); } static void socket_open_server(struct diag_socket_info *info) { struct qrtr_ctrl_pkt pkt; struct sockaddr_qrtr sq; struct msghdr msg = {0}; struct kvec iv = { &pkt, sizeof(pkt) }; int ret; int sl = sizeof(sq); unsigned int size = DIAG_SO_RCVBUF_SIZE; if (!info || info->port_type != PORT_TYPE_SERVER) return; ret = sock_create(AF_QIPCRTR, SOCK_DGRAM, PF_QIPCRTR, &info->hdl); if (ret < 0 || !info->hdl) { pr_err("diag: In %s, socket not initialized for %s\n", __func__, info->name); return; } ret = kernel_getsockname(info->hdl, (struct sockaddr *)&sq, &sl); if (ret < 0) { pr_err("diag: In %s, getsockname failed %d\n", __func__, ret); sock_release(info->hdl); return; } kernel_setsockopt(info->hdl, SOL_SOCKET, SO_RCVBUF, (char *)&size, sizeof(size)); write_lock_bh(&info->hdl->sk->sk_callback_lock); info->hdl->sk->sk_user_data = (void *)(info); info->hdl->sk->sk_data_ready = socket_data_ready; info->hdl->sk->sk_error_report = socket_data_ready; write_unlock_bh(&info->hdl->sk->sk_callback_lock); memset(&pkt, 0, sizeof(pkt)); pkt.cmd = cpu_to_le32(QRTR_TYPE_NEW_SERVER); pkt.server.service = cpu_to_le32(info->svc_id); pkt.server.instance = cpu_to_le32(info->ins_id); pkt.server.node = sq.sq_node; pkt.server.port = sq.sq_port; sq.sq_port = QRTR_PORT_CTRL; msg.msg_name = &sq; msg.msg_namelen = sizeof(sq); ret = kernel_sendmsg(info->hdl, &msg, &iv, 1, sizeof(pkt)); if (ret < 0) { pr_err("%s: failed to send new_server: %d\n", __func__, ret); return; } DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "%s opened server svc: %d ins: %d\n", info->name, info->svc_id, info->ins_id); } static void __socket_close_channel(struct diag_socket_info *info) { unsigned long flags; if (!info) return; memset(&info->remote_addr, 0, sizeof(info->remote_addr)); diagfwd_channel_close(info->fwd_ctxt); atomic_set(&info->opened, 0); /* Don't close the server. Server should always remain open */ if (info->port_type == PORT_TYPE_SERVER) return; mutex_lock(&info->socket_info_mutex); if (!info->hdl) { mutex_unlock(&info->socket_info_mutex); return; } sock_release(info->hdl); info->hdl = NULL; mutex_unlock(&info->socket_info_mutex); cancel_work(&info->read_work); wake_up_interruptible(&info->read_wait_q); spin_lock_irqsave(&info->lock, flags); info->data_ready = 0; spin_unlock_irqrestore(&info->lock, flags); DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "%s exiting\n", info->name); } static void socket_close_channel(struct diag_socket_info *info) { if (!info) return; __socket_close_channel(info); } static void socket_init_work_fn(struct work_struct *work) { struct diag_socket_info *info = container_of(work, struct diag_socket_info, init_work); if (!info) return; if (!info->inited) { pr_err("diag: In %s, socket %s is not initialized\n", __func__, info->name); return; } switch (info->port_type) { case PORT_TYPE_SERVER: socket_open_server(info); break; case PORT_TYPE_CLIENT: socket_open_client(info); break; default: pr_err("diag: In %s, unknown type %d\n", __func__, info->port_type); break; } } static void socket_read_work_fn(struct work_struct *work) { int err; struct diag_socket_info *info = container_of(work, struct diag_socket_info, read_work); struct diagfwd_info *fwd_info; if (!info) { diag_ws_release(); return; } mutex_lock(&info->socket_info_mutex); if (!info->hdl || !info->hdl->sk) { mutex_unlock(&info->socket_info_mutex); diag_ws_release(); return; } err = sock_error(info->hdl->sk); mutex_unlock(&info->socket_info_mutex); if (unlikely(err == -ENETRESET)) { socket_close_channel(info); if (info->port_type == PORT_TYPE_SERVER) socket_init_work_fn(&info->init_work); diag_ws_release(); return; } fwd_info = info->fwd_ctxt; if (info->port_type == PORT_TYPE_SERVER && (!fwd_info || !atomic_read(&fwd_info->opened))) diag_socket_drop_data(info); if (!atomic_read(&info->opened) && info->port_type == PORT_TYPE_SERVER) diagfwd_buffers_init(info->fwd_ctxt); diagfwd_channel_read(info->fwd_ctxt); } static void diag_socket_queue_read(void *ctxt) { struct diag_socket_info *info; if (!ctxt) return; info = (struct diag_socket_info *)ctxt; if (info->hdl && info->wq) queue_work(info->wq, &(info->read_work)); } static void handle_ctrl_pkt(struct diag_socket_info *info, void *buf, int len) { const struct qrtr_ctrl_pkt *pkt = buf; u32 node; u32 port; if (len < sizeof(struct qrtr_ctrl_pkt)) return; switch (le32_to_cpu(pkt->cmd)) { case QRTR_TYPE_BYE: node = le32_to_cpu(pkt->client.node); if (info->remote_addr.sq_node == node) { DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "%s rcvd bye\n", info->name); mutex_lock(&driver->diag_notifier_mutex); if (bootup_req[info->peripheral] == PERIPHERAL_SSR_UP) DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "diag: %s is up, bootup_req = %d\n", info->name, (int)bootup_req[info->peripheral]); mutex_unlock(&driver->diag_notifier_mutex); socket_close_channel(info); } break; case QRTR_TYPE_DEL_CLIENT: node = le32_to_cpu(pkt->client.node); port = le32_to_cpu(pkt->client.port); if (info->remote_addr.sq_node == node && info->remote_addr.sq_port == port) { DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "%s rcvd del client\n", info->name); mutex_lock(&driver->diag_notifier_mutex); if (bootup_req[info->peripheral] == PERIPHERAL_SSR_UP) { DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "diag: %s is up, stopping cleanup: bootup_req = %d\n", info->name, (int)bootup_req[info->peripheral]); mutex_unlock(&driver->diag_notifier_mutex); break; } mutex_unlock(&driver->diag_notifier_mutex); socket_close_channel(info); } break; } } static void diag_socket_drop_data(struct diag_socket_info *info) { int err = 0; int pkt_len = 0; int read_len = 0; unsigned char *temp = NULL; struct kvec iov; struct msghdr read_msg = {NULL, 0}; struct sockaddr_qrtr src_addr = {0}; unsigned long flags; temp = vzalloc(PERIPHERAL_BUF_SZ); if (!temp) return; while (info->data_ready > 0) { iov.iov_base = temp; iov.iov_len = PERIPHERAL_BUF_SZ; read_msg.msg_name = &src_addr; read_msg.msg_namelen = sizeof(src_addr); err = kernel_sock_ioctl(info->hdl, TIOCINQ, (unsigned long)&pkt_len); if (err || pkt_len < 0) break; spin_lock_irqsave(&info->lock, flags); if (info->data_ready > 0) { info->data_ready--; } else { spin_unlock_irqrestore(&info->lock, flags); break; } spin_unlock_irqrestore(&info->lock, flags); read_len = kernel_recvmsg(info->hdl, &read_msg, &iov, 1, pkt_len, MSG_DONTWAIT); pr_debug("%s : %s drop total bytes: %d\n", __func__, info->name, read_len); } vfree(temp); } static int diag_socket_read(void *ctxt, unsigned char *buf, int buf_len) { int err = 0; int pkt_len = 0; int read_len = 0; int bytes_remaining = 0; int total_recd = 0; int qrtr_ctrl_recd = 0; uint8_t buf_full = 0; unsigned char *temp = NULL; struct kvec iov; struct msghdr read_msg = {NULL, 0}; struct sockaddr_qrtr src_addr = {0}; struct diag_socket_info *info; struct mutex *channel_mutex; unsigned long flags; info = (struct diag_socket_info *)(ctxt); if (!info) return -ENODEV; if (!buf || !ctxt || buf_len <= 0) return -EINVAL; temp = buf; bytes_remaining = buf_len; channel_mutex = &driver->diagfwd_channel_mutex[info->peripheral]; err = wait_event_interruptible(info->read_wait_q, (info->data_ready > 0) || (!info->hdl) || (atomic_read(&info->diag_state) == 0)); if (err) { mutex_lock(channel_mutex); diagfwd_channel_read_done(info->fwd_ctxt, buf, 0); mutex_unlock(channel_mutex); return -ERESTARTSYS; } /* * There is no need to continue reading over peripheral in this case. * Release the wake source hold earlier. */ if (atomic_read(&info->diag_state) == 0) { DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "%s closing read thread. diag state is closed\n", info->name); mutex_lock(channel_mutex); diagfwd_channel_read_done(info->fwd_ctxt, buf, 0); mutex_unlock(channel_mutex); return 0; } if (!info->hdl) { DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "%s closing read thread\n", info->name); goto fail; } do { iov.iov_base = temp; iov.iov_len = bytes_remaining; read_msg.msg_name = &src_addr; read_msg.msg_namelen = sizeof(src_addr); mutex_lock(&info->socket_info_mutex); if (!info->hdl) { DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "%s closing read thread\n", info->name); mutex_unlock(&info->socket_info_mutex); goto fail; } err = kernel_sock_ioctl(info->hdl, TIOCINQ, (unsigned long)&pkt_len); if (err || pkt_len < 0) { mutex_unlock(&info->socket_info_mutex); break; } if (pkt_len > bytes_remaining) { buf_full = 1; mutex_unlock(&info->socket_info_mutex); break; } spin_lock_irqsave(&info->lock, flags); if (info->data_ready > 0) { info->data_ready--; } else { spin_unlock_irqrestore(&info->lock, flags); mutex_unlock(&info->socket_info_mutex); break; } spin_unlock_irqrestore(&info->lock, flags); read_len = kernel_recvmsg(info->hdl, &read_msg, &iov, 1, pkt_len, MSG_DONTWAIT); mutex_unlock(&info->socket_info_mutex); if (unlikely(read_len == -ENETRESET)) { mutex_lock(channel_mutex); diagfwd_channel_read_done(info->fwd_ctxt, buf, 0); mutex_unlock(channel_mutex); socket_close_channel(info); if (info->port_type == PORT_TYPE_SERVER) socket_init_work_fn(&info->init_work); return read_len; } else if (read_len <= 0) { DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "Invalid read_len: %d\n", read_len); continue; } if (src_addr.sq_port == QRTR_PORT_CTRL) { handle_ctrl_pkt(info, temp, read_len); qrtr_ctrl_recd += read_len; continue; } if (info->type == TYPE_CNTL) { memcpy(&info->remote_addr, &src_addr, sizeof(src_addr)); DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "%s client node:port::[0x%x]:[0x%x]\n", info->name, src_addr.sq_node, src_addr.sq_port); if (!atomic_read(&info->opened)) __socket_open_channel(info); } else { if (!atomic_read(&info->opened) && info->port_type == PORT_TYPE_SERVER) { /* * This is the first packet from the client. * Copy its address to the connection object. * Consider this channel open for communication. */ memcpy(&info->remote_addr, &src_addr, sizeof(src_addr)); DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "%s client node:port::[0x%x]:[0x%x]\n", info->name, src_addr.sq_node, src_addr.sq_port); if (info->ins_id == INST_ID_DCI) atomic_set(&info->opened, 1); else __socket_open_channel(info); } } temp += read_len; total_recd += read_len; bytes_remaining -= read_len; } while (info->data_ready > 0); if (buf_full || (info->type == TYPE_DATA && pkt_len)) err = queue_work(info->wq, &(info->read_work)); if (total_recd > 0) { DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "%s read total bytes: %d\n", info->name, total_recd); mutex_lock(channel_mutex); err = diagfwd_channel_read_done(info->fwd_ctxt, buf, total_recd); mutex_unlock(channel_mutex); if (err) goto fail; } else { if (qrtr_ctrl_recd > 0) DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "%s read qrtr ctrl bytes: %d\n", info->name, qrtr_ctrl_recd); else DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "%s error in read, err: %d\n", info->name, total_recd); goto fail; } diag_socket_queue_read(info); return 0; fail: mutex_lock(channel_mutex); diagfwd_channel_read_done(info->fwd_ctxt, buf, 0); mutex_unlock(channel_mutex); return -EIO; } static int diag_socket_write(void *ctxt, unsigned char *buf, int len) { int err = 0; int write_len = 0; struct kvec iov = {0}; struct msghdr write_msg = {0}; struct diag_socket_info *info = NULL; if (!ctxt || !buf || len <= 0) return -EIO; info = (struct diag_socket_info *)(ctxt); if (!atomic_read(&info->opened) || !info->hdl) return -ENODEV; iov.iov_base = buf; iov.iov_len = len; write_msg.msg_name = &info->remote_addr; write_msg.msg_namelen = sizeof(info->remote_addr); write_msg.msg_flags |= MSG_DONTWAIT; mutex_lock(&info->socket_info_mutex); if (!info->hdl) { mutex_unlock(&info->socket_info_mutex); return -ENODEV; } write_len = kernel_sendmsg(info->hdl, &write_msg, &iov, 1, len); mutex_unlock(&info->socket_info_mutex); if (write_len < 0) { err = write_len; /* * -EAGAIN means that the number of packets in flight is at * max capactity and the peripheral hasn't read the data. */ if (err != -EAGAIN && err != -ECONNRESET) { pr_err_ratelimited("diag: In %s, error sending data, err: %d, ch: %s\n", __func__, err, info->name); } } else if (write_len != len) { err = write_len; pr_err_ratelimited("diag: In %s, wrote partial packet to %s, len: %d, wrote: %d\n", __func__, info->name, len, write_len); } DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "%s wrote to socket, len: %d\n", info->name, write_len); return err; } static void __diag_socket_init(struct diag_socket_info *info) { uint16_t ins_base = 0; uint16_t ins_offset = 0; char wq_name[DIAG_SOCKET_NAME_SZ + 10]; if (!info) return; info->inited = 0; atomic_set(&info->opened, 0); atomic_set(&info->diag_state, 0); info->pkt_len = 0; info->pkt_read = 0; info->hdl = NULL; info->fwd_ctxt = NULL; info->data_ready = 0; atomic_set(&info->flow_cnt, 0); spin_lock_init(&info->lock); strlcpy(wq_name, info->name, sizeof(wq_name)); init_waitqueue_head(&info->read_wait_q); info->wq = create_singlethread_workqueue(wq_name); if (!info->wq) { pr_err("diag: In %s, unable to create workqueue for socket channel %s\n", __func__, info->name); return; } INIT_WORK(&(info->init_work), socket_init_work_fn); INIT_WORK(&(info->read_work), socket_read_work_fn); memset(&info->remote_addr, 0, sizeof(info->remote_addr)); switch (info->peripheral) { case PERIPHERAL_MODEM: ins_base = MODEM_INST_BASE; break; case PERIPHERAL_LPASS: ins_base = LPASS_INST_BASE; break; case PERIPHERAL_WCNSS: ins_base = WCNSS_INST_BASE; break; case PERIPHERAL_SENSORS: ins_base = SENSORS_INST_BASE; break; case PERIPHERAL_WDSP: ins_base = WDSP_INST_BASE; break; case PERIPHERAL_CDSP: ins_base = CDSP_INST_BASE; break; case PERIPHERAL_NPU: ins_base = NPU_INST_BASE; break; } switch (info->type) { case TYPE_DATA: ins_offset = INST_ID_DATA; info->port_type = PORT_TYPE_SERVER; break; case TYPE_CNTL: ins_offset = INST_ID_CNTL; info->port_type = PORT_TYPE_SERVER; break; case TYPE_DCI: ins_offset = INST_ID_DCI; info->port_type = PORT_TYPE_SERVER; break; case TYPE_CMD: ins_offset = INST_ID_CMD; info->port_type = PORT_TYPE_CLIENT; break; case TYPE_DCI_CMD: ins_offset = INST_ID_DCI_CMD; info->port_type = PORT_TYPE_CLIENT; break; } mutex_init(&info->socket_info_mutex); info->svc_id = DIAG_SVC_ID; info->ins_id = ins_base + ins_offset; info->inited = 1; } static struct diag_socket_info *diag_get_svc_sock_info(struct qmi_service *svc) { struct diag_socket_info *info = NULL; u32 inst; int i; inst = svc->version | (svc->instance << 8); for (i = 0; i < NUM_PERIPHERALS; i++) { if ((svc->service == socket_cmd[i].svc_id) && (inst == socket_cmd[i].ins_id)) { info = &socket_cmd[i]; break; } if ((svc->service == socket_dci_cmd[i].svc_id) && (inst == socket_dci_cmd[i].ins_id)) { info = &socket_dci_cmd[i]; break; } } return info; } static int diag_new_server(struct qmi_handle *qmi, struct qmi_service *svc) { struct diag_socket_info *info; int ret; info = diag_get_svc_sock_info(svc); if (!info) return -EINVAL; DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "%s rcvd new server\n", info->name); ret = diagfwd_register(TRANSPORT_SOCKET, info->peripheral, info->type, (void *)info, &socket_ops, &info->fwd_ctxt); info->remote_addr.sq_family = AF_QIPCRTR; info->remote_addr.sq_node = svc->node; info->remote_addr.sq_port = svc->port; socket_init_work_fn(&info->init_work); return 0; } static void diag_del_server(struct qmi_handle *qmi, struct qmi_service *svc) { struct diag_socket_info *info; info = diag_get_svc_sock_info(svc); if (!info) return; DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "%s rcvd del server\n", info->name); socket_close_channel(info); } static struct qmi_ops diag_qmi_cntl_ops = { .new_server = diag_new_server, .del_server = diag_del_server, }; int diag_socket_init(void) { struct diag_socket_info *info = NULL; struct restart_notifier_block *nb; int peripheral; void *handle; int rc; int i; for (peripheral = 0; peripheral < NUM_PERIPHERALS; peripheral++) { info = &socket_cntl[peripheral]; __diag_socket_init(&socket_cntl[peripheral]); diagfwd_cntl_register(TRANSPORT_SOCKET, peripheral, (void *)info, &socket_ops, &(info->fwd_ctxt)); __diag_socket_init(&socket_data[peripheral]); __diag_socket_init(&socket_cmd[peripheral]); __diag_socket_init(&socket_dci[peripheral]); __diag_socket_init(&socket_dci_cmd[peripheral]); } for (i = 0; i < ARRAY_SIZE(restart_notifiers); i++) { nb = &restart_notifiers[i]; handle = subsys_notif_register_notifier(nb->name, &nb->nb); DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "%s: registering notifier for '%s', handle=%p\n", __func__, nb->name, handle); } cntl_qmi = kzalloc(sizeof(*cntl_qmi), GFP_KERNEL); if (!cntl_qmi) { rc = -ENOMEM; goto fail; } rc = qmi_handle_init(cntl_qmi, 0, &diag_qmi_cntl_ops, NULL); if (rc < 0) goto fail; for (peripheral = 0; peripheral < NUM_PERIPHERALS; peripheral++) { info = &socket_cmd[peripheral]; qmi_add_lookup(cntl_qmi, info->svc_id, info->ins_id & 0xFF, info->ins_id >> 8); info = &socket_dci_cmd[peripheral]; qmi_add_lookup(cntl_qmi, info->svc_id, info->ins_id & 0xFF, info->ins_id >> 8); info = &socket_cntl[peripheral]; socket_init_work_fn(&info->init_work); info = &socket_data[peripheral]; socket_init_work_fn(&info->init_work); info = &socket_dci[peripheral]; socket_init_work_fn(&info->init_work); } DIAG_LOG(DIAG_DEBUG_PERIPHERALS, "%s: init done\n", __func__); fail: return rc; } int diag_socket_init_peripheral(uint8_t peripheral) { struct diag_socket_info *info = NULL; if (peripheral >= NUM_PERIPHERALS) return -EINVAL; info = &socket_data[peripheral]; diagfwd_register(TRANSPORT_SOCKET, info->peripheral, info->type, (void *)info, &socket_ops, &info->fwd_ctxt); info = &socket_dci[peripheral]; diagfwd_register(TRANSPORT_SOCKET, info->peripheral, info->type, (void *)info, &socket_ops, &info->fwd_ctxt); return 0; } static void __diag_socket_exit(struct diag_socket_info *info) { if (!info) return; diagfwd_deregister(info->peripheral, info->type, (void *)info); info->fwd_ctxt = NULL; if (info->hdl) sock_release(info->hdl); info->hdl = NULL; mutex_destroy(&info->socket_info_mutex); if (info->wq) destroy_workqueue(info->wq); } void diag_socket_exit(void) { int i; if (cntl_qmi) { qmi_handle_release(cntl_qmi); kfree(cntl_qmi); } for (i = 0; i < NUM_PERIPHERALS; i++) { __diag_socket_exit(&socket_cntl[i]); __diag_socket_exit(&socket_data[i]); __diag_socket_exit(&socket_cmd[i]); __diag_socket_exit(&socket_dci[i]); __diag_socket_exit(&socket_dci_cmd[i]); } }