tor_multipath_voip/src/algo_naive.c

#include "algo_skel.h"
#define NAIVE_BUFFER 128

struct naive_ctx {
  struct ring_buffer rb;
};

void free_nothing(void* app_ctx) {}

void free_naive(void* app_ctx) {
  if (app_ctx != NULL) free(app_ctx);
}

void on_tcp_co(struct evt_core_ctx* ctx, struct evt_core_cat* cat, int fd) {
  int conn_sock1, conn_sock2;
  struct sockaddr addr;
  socklen_t in_len;
  struct epoll_event current_event;

  in_len = sizeof(addr);

  conn_sock1 = accept(fd, &addr, &in_len);
  if (conn_sock1 == -1) goto co_error;
  conn_sock2 = dup(conn_sock1);
  if (conn_sock2 == -1) goto co_error;
  //printf("fd=%d accepts, creating fds=%d,%d\n", fd, conn_sock1, conn_sock2);
  evt_core_add_fd (ctx, "tcp-read", conn_sock1);
  evt_core_add_fd (ctx, "tcp-write", conn_sock2);

  return;

co_error:
  perror("Failed to handle new connection");
  exit(EXIT_FAILURE);
}

void tcp_to_udp(struct evt_core_ctx* ctx, struct evt_core_cat* cat, int fd) {
  // Get target file descriptor
  struct evt_core_cat* udp = g_hash_table_lookup (ctx->catlist, "udp-write");
  if (udp == NULL || udp->socklist->len < 1) goto co_error;
  int udp_fd = g_array_index(udp->socklist, int, 0);

  // Init data structures for the transfer
  struct naive_ctx* app_ctx = cat->app_ctx;
  struct ring_buffer* rb = &(app_ctx->rb);
  char buffer[RING_BUFFER_SIZE];
  int nread, nwrite, rb_free_space;

  while (1) {
    rb_free_space = ring_buffer_free_space (rb); // We can't afford to read more
    nread = read(fd, buffer, rb_free_space);     // Effective read
    if (nread == 0) return;                      // End of file
    if (nread == -1 && errno == EAGAIN) return;  // No more data to read
    if (nread == -1) goto co_error;              // A bad error
    ring_buffer_write(rb, buffer, nread);        // Persist read data in our buffer

    nread = ring_buffer_read(rb, buffer, RING_BUFFER_SIZE);
    nwrite = write(udp_fd, buffer, nread);
    if (nwrite == -1 && errno == EAGAIN) return;
    if (nwrite == -1) goto co_error;
    ring_buffer_ack_read (rb, nwrite);
  }
  return;

co_error:
  perror("Failed to handle read write for tcp_to_udp");
  exit(EXIT_FAILURE);
}

void udp_to_tcp(struct evt_core_ctx* ctx, struct evt_core_cat* cat, int fd) {
  // Get target file descriptor
  struct evt_core_cat* tcp = g_hash_table_lookup (ctx->catlist, "tcp-write");
  if (tcp == NULL || tcp->socklist->len < 1) goto co_error;
  int tcp_fd = g_array_index(tcp->socklist, int, 0);

  // Init data structures for the transfer
  struct naive_ctx* app_ctx = cat->app_ctx;
  struct ring_buffer* rb = &(app_ctx->rb);
  char buffer[RING_BUFFER_SIZE];
  int nread, nwrite, rb_free_space;

  while (1) {
    rb_free_space = ring_buffer_free_space (rb); // We can't afford to read more
    nread = read(fd, buffer, rb_free_space);     // Effective read
    if (nread == 0) return;                      // End of file
    if (nread == -1 && errno == EAGAIN) return;  // No more data to read
    if (nread == -1) goto co_error;              // A bad error
    ring_buffer_write(rb, buffer, nread);        // Persist read data in our buffer

    nread = ring_buffer_read(rb, buffer, RING_BUFFER_SIZE);
    nwrite = write(tcp_fd, buffer, nread);
    if (nwrite == -1 && errno == EAGAIN) return;
    if (nwrite == -1) goto co_error;
    printf("written to tcp_fd=%d\n", nwrite);
    ring_buffer_ack_read (rb, nwrite);
  }

  return;

co_error:
  perror("Failed to handle read write for udp_to_tcp");
  exit(EXIT_FAILURE);
}

void algo_naive(struct algo_skel* as) {
  as->on_tcp_co.name = "tcp-listen";
  as->on_tcp_co.flags = EPOLLIN;
  as->on_tcp_co.app_ctx = NULL;
  as->on_tcp_co.free_app_ctx = free_naive;
  as->on_tcp_co.cb = on_tcp_co;
  as->on_tcp_co.socklist = NULL;

  as->on_tcp_read.name = "tcp-read";
  as->on_tcp_read.flags = EPOLLIN | EPOLLET | EPOLLRDHUP;
  as->on_tcp_read.app_ctx = malloc(sizeof(struct naive_ctx));
  as->on_tcp_read.free_app_ctx = free_naive;
  as->on_tcp_read.cb = tcp_to_udp;
  as->on_tcp_read.socklist = NULL;
  if (as->on_tcp_read.app_ctx == NULL) goto init_err;
  memset(as->on_tcp_read.app_ctx, 0, sizeof(struct naive_ctx));

  as->on_udp_read.name = "udp-read";
  as->on_udp_read.flags = EPOLLIN | EPOLLET;
  as->on_udp_read.app_ctx = malloc(sizeof(struct naive_ctx));
  as->on_udp_read.free_app_ctx = free_naive;
  as->on_udp_read.cb = udp_to_tcp;
  as->on_udp_read.socklist = NULL;
  if (as->on_udp_read.app_ctx == NULL) goto init_err;
  memset(as->on_udp_read.app_ctx, 0, sizeof(struct naive_ctx));

  as->on_tcp_write.name = "tcp-write";
  as->on_tcp_write.flags = EPOLLOUT | EPOLLET | EPOLLRDHUP;
  as->on_tcp_write.app_ctx = as->on_udp_read.app_ctx;
  as->on_tcp_write.free_app_ctx = free_nothing;
  as->on_tcp_write.cb = udp_to_tcp;
  as->on_tcp_write.socklist = NULL;

  as->on_udp_write.name = "udp-write";
  as->on_udp_write.flags = EPOLLOUT | EPOLLET;
  as->on_udp_write.app_ctx = as->on_tcp_read.app_ctx;
  as->on_udp_write.free_app_ctx = free_nothing;
  as->on_udp_write.cb = tcp_to_udp;
  as->on_udp_write.socklist = NULL;

  return;
init_err:
  fprintf(stderr, "Failed to init algo naive\n");
  exit(EXIT_FAILURE);
}