transSrv.c

/*
 * Copyright (c) 2019 TAOS Data, Inc. <jhtao@taosdata.com>
 *
 * This program is free software: you can use, redistribute, and/or modify
 * it under the terms of the GNU Affero General Public License, version 3
 * or later ("AGPL"), 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.
 *
 * You should have received a copy of the GNU Affero General Public License
 * along with this program. If not, see <http://www.gnu.org/licenses/>.
 */

#ifdef USE_UV
#include "transComm.h"

typedef struct SConnBuffer {
  char* buf;
  int   len;
  int   cap;
  int   left;
} SConnBuffer;

typedef struct SConn {
  uv_tcp_t*   pTcp;
  uv_write_t* pWriter;
  uv_timer_t* pTimer;

  uv_async_t* pWorkerAsync;
  queue       queue;
  int         ref;
  int         persist;   // persist connection or not
  SConnBuffer connBuf;   // read buf,
  SConnBuffer writeBuf;  // write buf
  int         count;
  void*       shandle;  // rpc init
  void*       ahandle;  //
  void*       hostThrd;
  // del later
  char secured;
  int  spi;
  char info[64];
  char user[TSDB_UNI_LEN];  // user ID for the link
  char secret[TSDB_PASSWORD_LEN];
  char ckey[TSDB_PASSWORD_LEN];  // ciphering key
} SConn;

typedef struct SWorkThrdObj {
  pthread_t       thread;
  uv_pipe_t*      pipe;
  int             fd;
  uv_loop_t*      loop;
  uv_async_t*     workerAsync;  //
  queue           conn;
  pthread_mutex_t connMtx;
  void*           shandle;
} SWorkThrdObj;

typedef struct SServerObj {
  pthread_t      thread;
  uv_tcp_t       server;
  uv_loop_t*     loop;
  int            workerIdx;
  int            numOfThreads;
  SWorkThrdObj** pThreadObj;
  uv_pipe_t**    pipe;
  uint32_t       ip;
  uint32_t       port;
} SServerObj;

static const char* notify = "a";

// refactor later
static int rpcAddAuthPart(SConn* pConn, char* msg, int msgLen);

static int uvAuthMsg(SConn* pConn, char* msg, int msgLen);

static void uvAllocConnBufferCb(uv_handle_t* handle, size_t suggested_size, uv_buf_t* buf);
static void uvAllocReadBufferCb(uv_handle_t* handle, size_t suggested_size, uv_buf_t* buf);
static void uvOnReadCb(uv_stream_t* cli, ssize_t nread, const uv_buf_t* buf);
static void uvOnTimeoutCb(uv_timer_t* handle);
static void uvOnWriteCb(uv_write_t* req, int status);
static void uvOnAcceptCb(uv_stream_t* stream, int status);
static void uvOnConnectionCb(uv_stream_t* q, ssize_t nread, const uv_buf_t* buf);
static void uvWorkerAsyncCb(uv_async_t* handle);

// already read complete packet
static bool readComplete(SConnBuffer* buf);

static SConn* connCreate();
static void   connDestroy(SConn* conn);
static void   uvConnDestroy(uv_handle_t* handle);

// server worke thread
static void* workerThread(void* arg);
static void* acceptThread(void* arg);

void uvAllocReadBufferCb(uv_handle_t* handle, size_t suggested_size, uv_buf_t* buf) {
  /*
   * formate of data buffer:
   * |<-------SRpcReqContext------->|<------------data read from socket----------->|
   */
  static const int CAPACITY = 1024;

  SConn*       conn = handle->data;
  SConnBuffer* pBuf = &conn->connBuf;
  if (pBuf->cap == 0) {
    pBuf->buf = (char*)calloc(CAPACITY + RPC_RESERVE_SIZE, sizeof(char));
    pBuf->len = 0;
    pBuf->cap = CAPACITY;
    pBuf->left = -1;

    buf->base = pBuf->buf + RPC_RESERVE_SIZE;
    buf->len = CAPACITY;
  } else {
    if (pBuf->len >= pBuf->cap) {
      if (pBuf->left == -1) {
        pBuf->cap *= 2;
        pBuf->buf = realloc(pBuf->buf, pBuf->cap + RPC_RESERVE_SIZE);
      } else if (pBuf->len + pBuf->left > pBuf->cap) {
        pBuf->cap = pBuf->len + pBuf->left;
        pBuf->buf = realloc(pBuf->buf, pBuf->len + pBuf->left + RPC_RESERVE_SIZE);
      }
    }
    buf->base = pBuf->buf + pBuf->len + RPC_RESERVE_SIZE;
    buf->len = pBuf->cap - pBuf->len;
  }
}

// check data read from socket completely or not
//
static bool readComplete(SConnBuffer* data) {
  // TODO(yihao): handle pipeline later
  SRpcHead rpcHead;
  int32_t  headLen = sizeof(rpcHead);
  if (data->len >= headLen) {
    memcpy((char*)&rpcHead, data->buf + RPC_RESERVE_SIZE, headLen);
    int32_t msgLen = (int32_t)htonl((uint32_t)rpcHead.msgLen);
    if (msgLen > data->len) {
      data->left = msgLen - data->len;
      return false;
    } else {
      return true;
    }
  } else {
    return false;
  }
}

static void uvDoProcess(SRecvInfo* pRecv) {
  SRpcHead* pHead = (SRpcHead*)pRecv->msg;
  SRpcInfo* pRpc = (SRpcInfo*)pRecv->shandle;
  SConn*    pConn = pRecv->thandle;

  tDump(pRecv->msg, pRecv->msgLen);

  terrno = 0;
  SRpcReqContext* pContest;

  // do auth and check
}

static int uvAuthMsg(SConn* pConn, char* msg, int len) {
  SRpcHead* pHead = (SRpcHead*)msg;
  int       code = 0;

  if ((pConn->secured && pHead->spi == 0) || (pHead->spi == 0 && pConn->spi == 0)) {
    // secured link, or no authentication
    pHead->msgLen = (int32_t)htonl((uint32_t)pHead->msgLen);
    // tTrace("%s, secured link, no auth is required", pConn->info);
    return 0;
  }

  if (!rpcIsReq(pHead->msgType)) {
    // for response, if code is auth failure, it shall bypass the auth process
    code = htonl(pHead->code);
    if (code == TSDB_CODE_RPC_INVALID_TIME_STAMP || code == TSDB_CODE_RPC_AUTH_FAILURE ||
        code == TSDB_CODE_RPC_INVALID_VERSION || code == TSDB_CODE_RPC_AUTH_REQUIRED ||
        code == TSDB_CODE_MND_USER_NOT_EXIST || code == TSDB_CODE_RPC_NOT_READY) {
      pHead->msgLen = (int32_t)htonl((uint32_t)pHead->msgLen);
      // tTrace("%s, dont check authentication since code is:0x%x", pConn->info, code);
      return 0;
    }
  }

  code = 0;
  if (pHead->spi == pConn->spi) {
    // authentication
    SRpcDigest* pDigest = (SRpcDigest*)((char*)pHead + len - sizeof(SRpcDigest));

    int32_t delta;
    delta = (int32_t)htonl(pDigest->timeStamp);
    delta -= (int32_t)taosGetTimestampSec();
    if (abs(delta) > 900) {
      tWarn("%s, time diff:%d is too big, msg discarded", pConn->info, delta);
      code = TSDB_CODE_RPC_INVALID_TIME_STAMP;
    } else {
      if (rpcAuthenticateMsg(pHead, len - TSDB_AUTH_LEN, pDigest->auth, pConn->secret) < 0) {
        // tDebug("%s, authentication failed, msg discarded", pConn->info);
        code = TSDB_CODE_RPC_AUTH_FAILURE;
      } else {
        pHead->msgLen = (int32_t)htonl((uint32_t)pHead->msgLen) - sizeof(SRpcDigest);
        if (!rpcIsReq(pHead->msgType)) pConn->secured = 1;  // link is secured for client
        // tTrace("%s, message is authenticated", pConn->info);
      }
    }
  } else {
    tDebug("%s, auth spi:%d not matched with received:%d", pConn->info, pConn->spi, pHead->spi);
    code = pHead->spi ? TSDB_CODE_RPC_AUTH_FAILURE : TSDB_CODE_RPC_AUTH_REQUIRED;
  }

  return code;
}

// refers specifically to query or insert timeout
static void uvHandleActivityTimeout(uv_timer_t* handle) {
  // impl later
  SConn* conn = handle->data;
}

static void uvProcessData(SConn* pConn) {
  SRecvInfo    info;
  SRecvInfo*   p = &info;
  SConnBuffer* pBuf = &pConn->connBuf;
  p->msg = pBuf->buf + RPC_RESERVE_SIZE;
  p->msgLen = pBuf->len;
  p->ip = 0;
  p->port = 0;
  p->shandle = pConn->shandle;  //
  p->thandle = pConn;
  p->chandle = NULL;

  //
  SRpcHead* pHead = (SRpcHead*)p->msg;
  assert(rpcIsReq(pHead->msgType));

  SRpcInfo* pRpc = (SRpcInfo*)p->shandle;
  pConn->ahandle = (void*)pHead->ahandle;
  // auth here

  int8_t code = uvAuthMsg(pConn, (char*)pHead, p->msgLen);
  if (code != 0) {
    terrno = code;
    return;
  }
  pHead->code = htonl(pHead->code);

  SRpcMsg rpcMsg;

  pHead = rpcDecompressRpcMsg(pHead);
  rpcMsg.contLen = rpcContLenFromMsg(pHead->msgLen);
  rpcMsg.pCont = pHead->content;
  rpcMsg.msgType = pHead->msgType;
  rpcMsg.code = pHead->code;
  rpcMsg.ahandle = pConn->ahandle;
  rpcMsg.handle = pConn;

  (*(pRpc->cfp))(pRpc->parent, &rpcMsg, NULL);
  uv_timer_start(pConn->pTimer, uvHandleActivityTimeout, pRpc->idleTime, 0);
  // auth
  // validate msg type
}

void uvOnReadCb(uv_stream_t* cli, ssize_t nread, const uv_buf_t* buf) {
  // opt
  SConn*       ctx = cli->data;
  SConnBuffer* pBuf = &ctx->connBuf;
  if (nread > 0) {
    pBuf->len += nread;
    if (readComplete(pBuf)) {
      tDebug("alread read complete packet");
      uvProcessData(ctx);
    } else {
      tDebug("read half packet, continue to read");
    }
    return;
  }
  if (terrno != 0) {
    // handle err code
  }

  if (nread != UV_EOF) {
    tDebug("Read error %s\n", uv_err_name(nread));
  }
  uv_close((uv_handle_t*)cli, uvConnDestroy);
}
void uvAllocConnBufferCb(uv_handle_t* handle, size_t suggested_size, uv_buf_t* buf) {
  buf->base = malloc(sizeof(char));
  buf->len = 2;
}

void uvOnTimeoutCb(uv_timer_t* handle) {
  // opt
  tDebug("time out");
}

void uvOnWriteCb(uv_write_t* req, int status) {
  SConn* conn = req->data;
  if (status == 0) {
    tDebug("data already was written on stream");
  } else {
    connDestroy(conn);
  }
  // opt
}

void uvWorkerAsyncCb(uv_async_t* handle) {
  SWorkThrdObj* pThrd = container_of(handle, SWorkThrdObj, workerAsync);
  SConn*        conn = NULL;

  // opt later
  pthread_mutex_lock(&pThrd->connMtx);
  if (!QUEUE_IS_EMPTY(&pThrd->conn)) {
    queue* head = QUEUE_HEAD(&pThrd->conn);
    conn = QUEUE_DATA(head, SConn, queue);
    QUEUE_REMOVE(head);
  }
  pthread_mutex_unlock(&pThrd->connMtx);
  if (conn == NULL) {
    tError("except occurred, do nothing");
    return;
  }
  uv_buf_t wb = uv_buf_init(conn->writeBuf.buf, conn->writeBuf.len);
  uv_write(conn->pWriter, (uv_stream_t*)conn->pTcp, &wb, 1, uvOnWriteCb);
}

void uvOnAcceptCb(uv_stream_t* stream, int status) {
  if (status == -1) {
    return;
  }
  SServerObj* pObj = container_of(stream, SServerObj, server);

  uv_tcp_t* cli = (uv_tcp_t*)malloc(sizeof(uv_tcp_t));
  uv_tcp_init(pObj->loop, cli);

  if (uv_accept(stream, (uv_stream_t*)cli) == 0) {
    uv_write_t* wr = (uv_write_t*)malloc(sizeof(uv_write_t));

    uv_buf_t buf = uv_buf_init((char*)notify, strlen(notify));

    pObj->workerIdx = (pObj->workerIdx + 1) % pObj->numOfThreads;
    tDebug("new conntion accepted by main server, dispatch to %dth worker-thread", pObj->workerIdx);
    uv_write2(wr, (uv_stream_t*)&(pObj->pipe[pObj->workerIdx][0]), &buf, 1, (uv_stream_t*)cli, uvOnWriteCb);
  } else {
    uv_close((uv_handle_t*)cli, NULL);
  }
}
void uvOnConnectionCb(uv_stream_t* q, ssize_t nread, const uv_buf_t* buf) {
  tDebug("connection coming");
  if (nread < 0) {
    if (nread != UV_EOF) {
      tError("read error %s", uv_err_name(nread));
    }
    // TODO(log other failure reason)
    uv_close((uv_handle_t*)q, NULL);
    return;
  }
  // free memory allocated by
  assert(nread == strlen(notify));
  assert(buf->base[0] == notify[0]);
  free(buf->base);

  SWorkThrdObj* pThrd = q->data;

  uv_pipe_t* pipe = (uv_pipe_t*)q;
  if (!uv_pipe_pending_count(pipe)) {
    tError("No pending count");
    return;
  }

  uv_handle_type pending = uv_pipe_pending_type(pipe);
  assert(pending == UV_TCP);

  SConn* pConn = connCreate();
  pConn->shandle = pThrd->shandle;
  /* init conn timer*/
  pConn->pTimer = malloc(sizeof(uv_timer_t));
  uv_timer_init(pThrd->loop, pConn->pTimer);
  pConn->pTimer->data = pConn;

  pConn->hostThrd = pThrd;
  pConn->pWorkerAsync = pThrd->workerAsync;  // thread safty

  // init client handle
  pConn->pTcp = (uv_tcp_t*)malloc(sizeof(uv_tcp_t));
  uv_tcp_init(pThrd->loop, pConn->pTcp);
  pConn->pTcp->data = pConn;

  // init write request, just
  pConn->pWriter = calloc(1, sizeof(uv_write_t));
  pConn->pWriter->data = pConn;

  if (uv_accept(q, (uv_stream_t*)(pConn->pTcp)) == 0) {
    uv_os_fd_t fd;
    uv_fileno((const uv_handle_t*)pConn->pTcp, &fd);
    tDebug("new connection created: %d", fd);
    uv_read_start((uv_stream_t*)(pConn->pTcp), uvAllocReadBufferCb, uvOnReadCb);
  } else {
    connDestroy(pConn);
  }
}

void* acceptThread(void* arg) {
  // opt
  SServerObj* srv = (SServerObj*)arg;
  uv_tcp_init(srv->loop, &srv->server);

  struct sockaddr_in bind_addr;

  uv_ip4_addr("0.0.0.0", srv->port, &bind_addr);
  uv_tcp_bind(&srv->server, (const struct sockaddr*)&bind_addr, 0);
  int err = 0;
  if ((err = uv_listen((uv_stream_t*)&srv->server, 128, uvOnAcceptCb)) != 0) {
    tError("Listen error %s\n", uv_err_name(err));
    return NULL;
  }
  uv_run(srv->loop, UV_RUN_DEFAULT);
}
void* workerThread(void* arg) {
  SWorkThrdObj* pThrd = (SWorkThrdObj*)arg;

  pThrd->loop = (uv_loop_t*)malloc(sizeof(uv_loop_t));
  uv_loop_init(pThrd->loop);

  // SRpcInfo* pRpc = pThrd->shandle;
  uv_pipe_init(pThrd->loop, pThrd->pipe, 1);
  uv_pipe_open(pThrd->pipe, pThrd->fd);

  pThrd->pipe->data = pThrd;

  QUEUE_INIT(&pThrd->conn);
  pthread_mutex_init(&pThrd->connMtx, NULL);

  pThrd->workerAsync = malloc(sizeof(uv_async_t));
  uv_async_init(pThrd->loop, pThrd->workerAsync, uvWorkerAsyncCb);

  uv_read_start((uv_stream_t*)pThrd->pipe, uvAllocConnBufferCb, uvOnConnectionCb);
  uv_run(pThrd->loop, UV_RUN_DEFAULT);
}

static SConn* connCreate() {
  SConn* pConn = (SConn*)calloc(1, sizeof(SConn));
  return pConn;
}
static void connDestroy(SConn* conn) {
  if (conn == NULL) {
    return;
  }
  uv_timer_stop(conn->pTimer);
  free(conn->pTimer);
  uv_close((uv_handle_t*)conn->pTcp, NULL);
  free(conn->connBuf.buf);
  free(conn->pTcp);
  free(conn->pWriter);
  free(conn);
  // handle
}
static void uvConnDestroy(uv_handle_t* handle) {
  SConn* conn = handle->data;
  connDestroy(conn);
}
static int rpcAddAuthPart(SConn* pConn, char* msg, int msgLen) {
  SRpcHead* pHead = (SRpcHead*)msg;

  if (pConn->spi && pConn->secured == 0) {
    // add auth part
    pHead->spi = pConn->spi;
    SRpcDigest* pDigest = (SRpcDigest*)(msg + msgLen);
    pDigest->timeStamp = htonl(taosGetTimestampSec());
    msgLen += sizeof(SRpcDigest);
    pHead->msgLen = (int32_t)htonl((uint32_t)msgLen);
    rpcBuildAuthHead(pHead, msgLen - TSDB_AUTH_LEN, pDigest->auth, pConn->secret);
  } else {
    pHead->spi = 0;
    pHead->msgLen = (int32_t)htonl((uint32_t)msgLen);
  }

  return msgLen;
}

void* taosInitServer(uint32_t ip, uint32_t port, char* label, int numOfThreads, void* fp, void* shandle) {
  SServerObj* srv = calloc(1, sizeof(SServerObj));
  srv->loop = (uv_loop_t*)malloc(sizeof(uv_loop_t));
  srv->numOfThreads = numOfThreads;
  srv->workerIdx = 0;
  srv->pThreadObj = (SWorkThrdObj**)calloc(srv->numOfThreads, sizeof(SWorkThrdObj*));
  srv->pipe = (uv_pipe_t**)calloc(srv->numOfThreads, sizeof(uv_pipe_t*));
  srv->ip = ip;
  srv->port = port;
  uv_loop_init(srv->loop);

  for (int i = 0; i < srv->numOfThreads; i++) {
    SWorkThrdObj* thrd = (SWorkThrdObj*)calloc(1, sizeof(SWorkThrdObj));
    srv->pipe[i] = (uv_pipe_t*)calloc(2, sizeof(uv_pipe_t));
    int fds[2];
    if (uv_socketpair(AF_UNIX, SOCK_STREAM, fds, UV_NONBLOCK_PIPE, UV_NONBLOCK_PIPE) != 0) {
      return NULL;
    }
    uv_pipe_init(srv->loop, &(srv->pipe[i][0]), 1);
    uv_pipe_open(&(srv->pipe[i][0]), fds[1]);  // init write

    thrd->shandle = shandle;
    thrd->fd = fds[0];
    thrd->pipe = &(srv->pipe[i][1]);  // init read
    int err = pthread_create(&(thrd->thread), NULL, workerThread, (void*)(thrd));
    if (err == 0) {
      tDebug("sucess to create worker-thread %d", i);
      // printf("thread %d create\n", i);
    } else {
      // TODO: clear all other resource later
      tError("failed to create worker-thread %d", i);
    }
    srv->pThreadObj[i] = thrd;
  }

  int err = pthread_create(&srv->thread, NULL, acceptThread, (void*)srv);
  if (err == 0) {
    tDebug("success to create accept-thread");
  } else {
    // clear all resource later
  }

  return srv;
}

void rpcSendResponse(const SRpcMsg* pMsg) {
  SConn*        pConn = pMsg->handle;
  SWorkThrdObj* pThrd = pConn->hostThrd;

  // opt later
  pthread_mutex_lock(&pThrd->connMtx);
  QUEUE_PUSH(&pThrd->conn, &pConn->queue);
  pthread_mutex_unlock(&pThrd->connMtx);

  uv_async_send(pConn->pWorkerAsync);
}

#endif