#include "socket_server.h" #include "xcam_obj_debug.h" #include #include #include #ifdef __ANDROID__ #include #endif #ifdef LOG_TAG #undef LOG_TAG #endif #define LOG_TAG "socket_server.cpp" #ifdef __ANDROID__ #define UNIX_DOMAIN "/dev/socket/camera_tool" #else #define UNIX_DOMAIN "/tmp/UNIX.domain" #endif #define RKAIQ_SOCKET_DATA_OFFSET 24 #define RKAIQ_SOCKET_OLD_HEADER_LEN 2 #define RKAIQ_SOCKET_DATA_HEADER_LEN 4 std::mutex SocketServer::send_mutex; typedef struct aiq_tunning_ctx_s { int socketfd; rk_aiq_sys_ctx_t *aiq_ctx; RkAiqSocketPacket_t *aiq_data; } aiq_tunning_ctx; int onPacketHandle(void *pri, void *packet, MessageType type); SocketServer::SocketServer() : tool_mode_on(false), sockfd(-1), client_socket(-1), quit_(0), serverAddress({0}), clientAddress({0}), aiq_ctx(nullptr), accept_threads_(nullptr), tunning_thread(nullptr), callback_(nullptr), _stop_fds{-1, -1} { msg_parser = std::unique_ptr(new RkMSG::MessageParser(this)); msg_parser->setMsgCallBack(onPacketHandle); msg_parser->start(); }; SocketServer::~SocketServer() { } void SocketServer::SaveEixt() { LOGD("socket in aiq uit"); quit_ = 1; if (_stop_fds[1] != -1) { char buf = 0xf; // random value to write to flush fd. unsigned int size = write(_stop_fds[1], &buf, sizeof(char)); if (size != sizeof(char)) LOGW("Flush write not completed"); } } void hexdump2(char *buf, const int num) { int i; for (i = 0; i < num; i++) { LOGE("%02X ", buf[i]); if ((i + 1) % 32 == 0) { } } return; } int ProcessText(int client_socket, rk_aiq_sys_ctx_t *ctx, RkAiqSocketPacket *receivedData) { int ret = -1; RkAiqSocketPacket dataReply; ret = ProcessCommand(ctx, receivedData, &dataReply); if (ret != -1) { const std::lock_guard lock(SocketServer::send_mutex); unsigned int packetSize = sizeof(RkAiqSocketPacket) + dataReply.dataSize - sizeof(char *); memcpy(dataReply.packetSize, &packetSize, 4); char *dataToSend = (char *)malloc(packetSize); int offset = 0; char magic[2] = {'R', 'K'}; memset(dataToSend, 0, packetSize); memcpy(dataToSend, magic, 2); offset += 2; memcpy(dataToSend + offset, dataReply.packetSize, 4); offset += 4; memcpy(dataToSend + offset, (void *)&dataReply.commandID, sizeof(dataReply.commandID)); offset += sizeof(dataReply.commandID); memcpy(dataToSend + offset, (void *)&dataReply.commandResult, sizeof(dataReply.commandResult)); offset += sizeof(dataReply.commandResult); memcpy(dataToSend + offset, (void *)&dataReply.dataSize, sizeof(dataReply.dataSize)); offset += sizeof(dataReply.dataSize); memcpy(dataToSend + offset, dataReply.data, dataReply.dataSize); offset += dataReply.dataSize; // LOGE("offset is %d,packetsize is %d",offset,packetSize); memcpy(dataToSend + offset, (void *)&dataReply.dataHash, sizeof(dataReply.dataHash)); send(client_socket, dataToSend, packetSize, 0); if (dataReply.data != NULL) { free(dataReply.data); dataReply.data = NULL; } free(dataToSend); dataToSend = NULL; } else { return -1; } return 0; } int SocketServer::Send(int cilent_socket, char *buff, int size) { return send(cilent_socket, buff, size, 0); } int SocketServer::Recvieve() { return 0; } uint8_t *bit_stream_find(uint8_t *data, int size, const uint8_t *dst, int len) { int start_pos = -1; if (!data || !size || !dst || !len) { return NULL; } if (size < len) { return NULL; } for (start_pos = 0; start_pos < size - len; start_pos++) { if (0 == memcmp(data + start_pos, dst, len)) { return data + start_pos; } } return NULL; } int rkaiq_ipc_send(int sockfd, int id, int ack, int seqn, void *data, uint32_t data_len) { uint32_t out_len = sizeof(RkAiqSocketPacket_t) - sizeof(char *) + data_len; char *out_data = (char *)malloc(out_len); RkAiqSocketPacket_t *out_res = (RkAiqSocketPacket_t *)out_data; const std::lock_guard lock(SocketServer::send_mutex); int ret = 0; out_res->magic[0] = 'R'; out_res->magic[1] = 0xAA; out_res->magic[2] = 0xFF; out_res->magic[3] = 'K'; out_res->cmd_id = id; out_res->cmd_ret = ack; out_res->payload_size = data_len; out_res->sequence = seqn; out_res->packet_size = data_len; memcpy(&out_res->data, data, data_len); ret = send(sockfd, out_data, out_len, 0); free(out_data); return 0; } // return 0 if a sigle packet or payload size int rkaiq_packet_parse_old(RkAiqSocketPacket *aiq_data, uint8_t *buffer, int len) { uint8_t *start_pos = NULL; uint32_t packet_size = 0; uint32_t valid_size = 0; RkAiqSocketPacket *aiq_pkt = NULL; if (buffer[0] == 'R' && buffer[1] == 'K') { start_pos = buffer; } if (start_pos) { if ((len - (start_pos - buffer)) < (int)sizeof(RkAiqSocketPacket)) { LOGE("Not a complete packet [%d], discard!\n", len); return -1; } aiq_pkt = (RkAiqSocketPacket *)start_pos; memcpy(aiq_data, aiq_pkt, sizeof(RkAiqSocketPacket)); packet_size = (start_pos[2] & 0xff) | ((start_pos[3] & 0xff) << 8) | ((start_pos[4] & 0xff) << 16) | ((start_pos[5] & 0xff) << 24); // refer to the real offset of data aiq_data->data = (char *)(&start_pos); aiq_data->dataSize = packet_size; valid_size = (buffer + len) - start_pos; // sigle packet : HEAD:24byte + PAYLOAD + CRC:1byte if (valid_size == packet_size) { return 0; } return packet_size; } else { // may be fragment packet, head already parsed just return full size return -1; } } // return 0 if a sigle packet or payload size int rkaiq_packet_parse(RkAiqSocketPacket_t *aiq_data, uint8_t *buffer, int len) { uint8_t *start_pos = NULL; uint32_t packet_size = 0; RkAiqSocketPacket_t *aiq_pkt = NULL; start_pos = bit_stream_find(buffer, len, RKAIQ_SOCKET_DATA_HEADER, RKAIQ_SOCKET_DATA_HEADER_LEN); if (start_pos) { if ((len - (start_pos - buffer)) < (int)sizeof(RkAiqSocketPacket_t)) { LOGE("Not a complete packet [%d], discard!\n", len); return -1; } aiq_pkt = (RkAiqSocketPacket_t *)start_pos; packet_size = &buffer[len - 1] - start_pos; memcpy(aiq_data, aiq_pkt, sizeof(RkAiqSocketPacket_t)); // refer to the real offset of data aiq_data->data = (uint8_t *)(&aiq_pkt->data); // sigle packet : HEAD:24byte + PAYLOAD + CRC:1byte if (aiq_pkt->payload_size <= (packet_size - 1)) { return 0; } return packet_size; } else { // may be fragment packet, head already parsed just return full size return -1; } } int rkaiq_is_uapi(const char *cmd_str) { if (strstr(cmd_str, "uapi/0/")) { return 1; } else { return 0; } } void rkaiq_params_tuning(aiq_tunning_ctx *tunning_ctx) { int sockfd = -1; rk_aiq_sys_ctx_t *aiq_ctx = NULL; RkAiqSocketPacket_t *aiq_data = NULL; if (!tunning_ctx) { return; } sockfd = tunning_ctx->socketfd; aiq_ctx = tunning_ctx->aiq_ctx; aiq_data = tunning_ctx->aiq_data; #if 1 printf("[TCP]%d,%d,%d--->PC CMD STRING:\n%s\n", sockfd, aiq_data->cmd_id, aiq_data->payload_size, aiq_data->data); #endif switch (aiq_data->cmd_id) { case AIQ_IPC_CMD_WRITE: { if (rkaiq_is_uapi((char *)aiq_data->data)) { char *ret_str_js = NULL; rkaiq_uapi_unified_ctl(aiq_ctx, (char *)aiq_data->data, &ret_str_js, 0); } else { rk_aiq_uapi_sysctl_tuning(aiq_ctx, (char *)aiq_data->data); } } break; case AIQ_IPC_CMD_READ: { char *out_data = NULL; if (rkaiq_is_uapi((char *)aiq_data->data)) { rkaiq_uapi_unified_ctl(aiq_ctx, (char *)aiq_data->data, &out_data, 1); } else { out_data = rk_aiq_uapi_sysctl_readiq(aiq_ctx, (char *)aiq_data->data); } if (!out_data) { LOGE("[Tuning]: aiq return NULL!\n"); break; } #if 1 printf("---> read:\n%s\n", out_data); #endif rkaiq_ipc_send(sockfd, AIQ_IPC_CMD_READ, 0, 0, out_data, strlen(out_data)); } break; default: break; } if (aiq_data) { RkMSG::MessageParser::freePacket(aiq_data, RKAIQ_MESSAGE_NEW); } free(tunning_ctx); } int SocketServer::packetHandle(void *packet, MessageType type) { if (type == RKAIQ_MESSAGE_NEW) { RkAiqSocketPacket_t *aiq_data = (RkAiqSocketPacket_t *)packet; aiq_tunning_ctx *tunning_ctx = (aiq_tunning_ctx *)calloc(1, sizeof(aiq_tunning_ctx)); tunning_ctx->aiq_data = aiq_data; tunning_ctx->aiq_ctx = aiq_ctx; tunning_ctx->socketfd = client_socket; if (this->tunning_thread && this->tunning_thread->joinable()) { this->tunning_thread->join(); } this->tunning_thread = std::make_shared( std::thread(rkaiq_params_tuning, tunning_ctx)); this->tunning_thread->detach(); } else { RkAiqSocketPacket *aiq_data = (RkAiqSocketPacket *)packet; ProcessText(client_socket, aiq_ctx, aiq_data); RkMSG::MessageParser::freePacket(aiq_data, RKAIQ_MESSAGE_OLD); } return 0; } int onPacketHandle(void *pri, void *packet, MessageType type) { SocketServer *server = (SocketServer *)pri; if (server) { server->packetHandle(packet, type); } return 0; } int SocketServer::Recvieve(int sync) { uint8_t buffer[MAXPACKETSIZE]; struct timeval interval = {3, 0}; setsockopt(client_socket, SOL_SOCKET, SO_RCVTIMEO, (char *)&interval, sizeof(struct timeval)); while (!quit_) { int recv_len = -1; memset(&buffer, 0, MAXPACKETSIZE); // 1. recv MAX SIZE every timne. recv_len = recv(client_socket, buffer, MAXPACKETSIZE, 0); if (recv_len == 0) { break; } if (recv_len < 0) { continue; } msg_parser->pushRawData(buffer, recv_len); if (sync) { } } return 0; } #define POLL_STOP_RET (3) int SocketServer::poll_event(int timeout_msec, int fds[]) { int num_fds = fds[1] == -1 ? 1 : 2; struct pollfd poll_fds[num_fds]; int ret = 0; memset(poll_fds, 0, sizeof(poll_fds)); poll_fds[0].fd = fds[0]; poll_fds[0].events = (POLLIN | POLLOUT | POLLHUP); if (fds[1] != -1) { poll_fds[1].fd = fds[1]; poll_fds[1].events = POLLPRI | POLLIN | POLLOUT; poll_fds[1].revents = 0; } ret = poll(poll_fds, num_fds, timeout_msec); if (fds[1] != -1) { if ((poll_fds[1].revents & POLLIN) || (poll_fds[1].revents & POLLPRI)) { LOGD("%s: Poll returning from flush", __FUNCTION__); return POLL_STOP_RET; } } if (ret > 0 && (poll_fds[0].revents & (POLLERR | POLLNVAL | POLLHUP))) { LOGE("polled error"); return -1; } return ret; } void SocketServer::Accepted() { struct timeval interval = {3, 0}; setsockopt(sockfd, SOL_SOCKET, SO_RCVTIMEO, (char *)&interval, sizeof(struct timeval)); while (!quit_) { // int client_socket; socklen_t sosize = sizeof(clientAddress); int fds[2] = {sockfd, _stop_fds[0]}; int poll_ret = poll_event(-1, fds); if (poll_ret == POLL_STOP_RET) { LOG1("poll socket stop success !"); break; } else if (poll_ret <= 0) { LOGW("poll socket got error(0x%x) but continue\n"); ::usleep(10000); // 10ms continue; } client_socket = accept(sockfd, (struct sockaddr *)&clientAddress, &sosize); if (client_socket < 0) { if (errno != EAGAIN) LOGE("Error socket accept failed %d %d\n", client_socket, errno); continue; } LOGD("socket accept ip %s\n", serverAddress); tool_mode_set(true); // std::shared_ptr recv_thread; // recv_thread = make_shared(&SocketServer::Recvieve, this, // client_socket); recv_thread->join(); recv_thread = nullptr; this->Recvieve(0); close(client_socket); LOGD("socket accept close\n"); tool_mode_set(false); } LOGD("socket accept exit\n"); } #ifdef __ANDROID__ int SocketServer::getAndroidLocalSocket() { static const char socketName[] = "camera_tool"; int sock = android_get_control_socket(socketName); if (sock < 0) { // TODO(Cody): will always failed with permission denied // Should let init to create socket sock = socket_local_server(socketName, ANDROID_SOCKET_NAMESPACE_RESERVED, SOCK_STREAM | SOCK_CLOEXEC | SOCK_NONBLOCK); } return sock; } #endif int SocketServer::Process(rk_aiq_sys_ctx_t *ctx) { LOGW("SocketServer::Process\n"); int opt = 1; aiq_ctx = ctx; #ifdef __ANDROID__ sockfd = getAndroidLocalSocket(); if (sockfd < 0) { LOGE("Error get socket %s\n", strerror(errno)); return -1; } fcntl(sockfd, F_SETFD, FD_CLOEXEC); #else sockfd = socket(AF_UNIX, SOCK_STREAM, 0); memset(&serverAddress, 0, sizeof(serverAddress)); serverAddress.sun_family = AF_LOCAL; strncpy(serverAddress.sun_path, UNIX_DOMAIN, sizeof(serverAddress.sun_path) - 1); unlink(UNIX_DOMAIN); if ((::bind(sockfd, (struct sockaddr *)&serverAddress, sizeof(serverAddress))) < 0) { LOGE("Error bind %s\n", strerror(errno)); return -1; } #endif if (listen(sockfd, 5) < 0) { LOGE("Error listen\n"); return -1; } if (pipe(_stop_fds) < 0) { LOGE("poll stop pipe error: %s", strerror(errno)); } else { if (fcntl(_stop_fds[0], F_SETFL, O_NONBLOCK)) { LOGE("Fail to set stop pipe flag: %s", strerror(errno)); } } this->accept_threads_ = std::unique_ptr( new std::thread(&SocketServer::Accepted, this)); return 0; } void SocketServer::Deinit() { struct linger so_linger; so_linger.l_onoff = 1; so_linger.l_linger = 0; this->SaveEixt(); // setsockopt(client_socket,SOL_SOCKET,SO_LINGER,&so_linger,sizeof(so_linger)); // struct timeval interval = {0, 0}; // setsockopt(client_socket, SOL_SOCKET, SO_RCVTIMEO, (char // *)&interval,sizeof(struct timeval)); if (this->accept_threads_) this->accept_threads_->join(); if (this->tunning_thread && this->tunning_thread->joinable()) this->tunning_thread->join(); // shutdown(client_socket, SHUT_RDWR); // close(client_socket); unlink(UNIX_DOMAIN); close(sockfd); this->accept_threads_ = nullptr; this->tunning_thread = nullptr; if (_stop_fds[0] != -1) close(_stop_fds[0]); if (_stop_fds[1] != -1) close(_stop_fds[1]); LOGD("socekt stop in aiq"); if (msg_parser) { msg_parser->stop(); } }