#include "common.h"
#include "log.h"
using namespace std;
typedef unsigned long long u64_t; //this works on most platform,avoid using the PRId64
typedef long long i64_t;
typedef unsigned int u32_t;
typedef int i32_t;
typedef u64_t anti_replay_seq_t;
int disable_replay_filter=0;
int dup_num=1;
int dup_delay_min=20; //0.1ms
int dup_delay_max=20;
//int dup_first_delay=9000; //0.1ms
int jitter_min=0;
int jitter_max=0;
int iv_min=2;
int iv_max=16;//< 256;
int random_number_fd=-1;
int remote_fd=-1;
int local_fd=-1;
int is_client = 0, is_server = 0;
int local_listen_fd=-1;
int disable_conv_clear=0;
int mtu_warn=1350;
u32_t remote_address_uint32=0;
char local_address[100], remote_address[100];
int local_port = -1, remote_port = -1;
int multi_process_mode=0;
const u32_t anti_replay_buff_size=10000;
char key_string[1000]= "secret key";
int random_drop=0;
u64_t last_report_time=0;
int report_interval=0;
u64_t packet_send_count=0;
u64_t dup_packet_send_count=0;
u64_t packet_recv_count=0;
u64_t dup_packet_recv_count=0;
int random_between(u32_t a,u32_t b)
{
if(a>b)
{
mylog(log_fatal,"min >max?? %d %d\n",a ,b);
myexit(1);
}
if(a==b)return a;
else return a+get_true_random_number()%(b+1-a);
}
int max_pending_packet=0;
int VVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVVV;
struct anti_replay_t
{
u64_t max_packet_received;
u64_t replay_buffer[anti_replay_buff_size];
unordered_set<u64_t> st;
u32_t const_id;
u32_t anti_replay_seq;
int index;
anti_replay_seq_t get_new_seq_for_send()
{
anti_replay_seq_t res=const_id;
res<<=32u;
anti_replay_seq++;
res|=anti_replay_seq;
return res;
}
void prepare()
{
anti_replay_seq=get_true_random_number();//random first seq
const_id=get_true_random_number_nz();
}
anti_replay_t()
{
memset(replay_buffer,0,sizeof(replay_buffer));
st.rehash(anti_replay_buff_size*10);
max_packet_received=0;
index=0;
}
int is_vaild(u64_t seq)
{
//if(disable_replay_filter) return 1;
if(seq==0)
{
mylog(log_debug,"seq=0\n");
return 0;
}
if(st.find(seq)!=st.end() )
{
mylog(log_trace,"seq %llx exist\n",seq);
return 0;
}
if(replay_buffer[index]!=0)
{
assert(st.find(replay_buffer[index])!=st.end());
st.erase(replay_buffer[index]);
}
replay_buffer[index]=seq;
st.insert(seq);
index++;
if(index==int(anti_replay_buff_size)) index=0;
return 1; //for complier check
}
}anti_replay;
struct conn_manager_t //TODO change map to unordered map
{
//typedef hash_map map;
unordered_map<u64_t,u32_t> u64_to_fd; //conv and u64 are both supposed to be uniq
unordered_map<u32_t,u64_t> fd_to_u64;
unordered_map<u32_t,u64_t> fd_last_active_time;
unordered_map<u32_t,u64_t>::iterator clear_it;
unordered_map<u32_t,u64_t>::iterator it;
unordered_map<u32_t,u64_t>::iterator old_it;
//void (*clear_function)(uint64_t u64) ;
long long last_clear_time;
list<int> clear_list;
conn_manager_t()
{
clear_it=fd_last_active_time.begin();
long long last_clear_time=0;
rehash();
//clear_function=0;
}
~conn_manager_t()
{
clear();
}
int get_size()
{
return fd_to_u64.size();
}
void rehash()
{
u64_to_fd.rehash(10007);
fd_to_u64.rehash(10007);
fd_last_active_time.rehash(10007);
}
void clear()
{
if(disable_conv_clear) return ;
for(it=fd_to_u64.begin();it!=fd_to_u64.end();it++)
{
//int fd=int((it->second<<32u)>>32u);
close( it->first);
}
u64_to_fd.clear();
fd_to_u64.clear();
fd_last_active_time.clear();
clear_it=fd_last_active_time.begin();
}
int exist_fd(u32_t fd)
{
return fd_to_u64.find(fd)!=fd_to_u64.end();
}
int exist_u64(u64_t u64)
{
return u64_to_fd.find(u64)!=u64_to_fd.end();
}
u32_t find_fd_by_u64(u64_t u64)
{
return u64_to_fd[u64];
}
u64_t find_u64_by_fd(u32_t fd)
{
return fd_to_u64[fd];
}
int update_active_time(u32_t fd)
{
return fd_last_active_time[fd]=get_current_time();
}
int insert_fd(u32_t fd,u64_t u64)
{
u64_to_fd[u64]=fd;
fd_to_u64[fd]=u64;
fd_last_active_time[fd]=get_current_time();
return 0;
}
int erase_fd(u32_t fd)
{
if(disable_conv_clear) return 0;
u64_t u64=fd_to_u64[fd];
u32_t ip= (u64 >> 32u);
int port= uint16_t((u64 << 32u) >> 32u);
mylog(log_info,"fd %d cleared,assocated adress %s,%d\n",fd,my_ntoa(ip),port);
close(fd);
fd_to_u64.erase(fd);
u64_to_fd.erase(u64);
fd_last_active_time.erase(fd);
return 0;
}
void check_clear_list()
{
while(!clear_list.empty())
{
int fd=*clear_list.begin();
clear_list.pop_front();
erase_fd(fd);
}
}
int clear_inactive()
{
if(get_current_time()-last_clear_time>conv_clear_interval)
{
last_clear_time=get_current_time();
return clear_inactive0();
}
return 0;
}
int clear_inactive0()
{
if(disable_conv_clear) return 0;
//map<uint32_t,uint64_t>::iterator it;
int cnt=0;
it=clear_it;
int size=fd_last_active_time.size();
int num_to_clean=size/conv_clear_ratio+conv_clear_min; //clear 1/10 each time,to avoid latency glitch
u64_t current_time=get_current_time();
for(;;)
{
if(cnt>=num_to_clean) break;
if(fd_last_active_time.begin()==fd_last_active_time.end()) break;
if(it==fd_last_active_time.end())
{
it=fd_last_active_time.begin();
}
if( current_time -it->second >conv_timeout )
{
//mylog(log_info,"inactive conv %u cleared \n",it->first);
old_it=it;
it++;
u32_t fd= old_it->first;
erase_fd(old_it->first);
}
else
{
it++;
}
cnt++;
}
return 0;
}
}conn_manager;
typedef u64_t my_time_t;
struct delay_data
{
int fd;
int times_left;
char * data;
int len;
u64_t u64;
};
int delay_timer_fd;
int sendto_u64 (int fd,char * buf, int len,int flags, u64_t u64)
{
if(is_server)
{
dup_packet_send_count++;
}
if(is_server&&random_drop!=0)
{
if(get_true_random_number()%10000<(u32_t)random_drop)
{
return 0;
}
}
sockaddr_in tmp_sockaddr;
memset(&tmp_sockaddr,0,sizeof(tmp_sockaddr));
tmp_sockaddr.sin_family = AF_INET;
tmp_sockaddr.sin_addr.s_addr = (u64 >> 32u);
tmp_sockaddr.sin_port = htons(uint16_t((u64 << 32u) >> 32u));
return sendto(fd, buf,
len , 0,
(struct sockaddr *) &tmp_sockaddr,
sizeof(tmp_sockaddr));
}
int send_fd (int fd,char * buf, int len,int flags)
{
if(is_client)
{
dup_packet_send_count++;
}
if(is_client&&random_drop!=0)
{
if(get_true_random_number()%10000<(u32_t)random_drop)
{
return 0;
}
}
return send(fd,buf,len,flags);
}
multimap<my_time_t,delay_data> delay_mp;
int add_to_delay_mp(int fd,int times_left,u32_t delay,char * buf,int len,u64_t u64)
{
if(max_pending_packet!=0&&int(delay_mp.size()) >=max_pending_packet)
{
mylog(log_warn,"max pending packet reached,ignored\n");
return 0;
}
delay_data tmp;
tmp.data = buf;
tmp.fd = fd;
tmp.times_left = times_left;
tmp.len = len;
tmp.u64=u64;
my_time_t tmp_time=get_current_time_us();
tmp_time+=delay*100;
delay_mp.insert(make_pair(tmp_time,tmp));
return 0;
}
int add_and_new(int fd,int times_left,u32_t delay,char * buf,int len,u64_t u64)
{
if(times_left<=0) return -1;
char * str= (char *)malloc(len);
memcpy(str,buf,len);
add_to_delay_mp(fd,times_left,delay,str,len,u64);
return 0;
}
multimap<u64_t,delay_data> new_delay_mp;
void handler(int num) {
int status;
int pid;
while ((pid = waitpid(-1, &status, WNOHANG)) > 0) {
if (WIFEXITED(status)) {
//printf("The child exit with code %d",WEXITSTATUS(status));
}
}
}
void encrypt_0(char * input,int &len,char *key)
{
int i,j;
if(key[0]==0) return;
for(i=0,j=0;i<len;i++,j++)
{
if(key[j]==0)j=0;
input[i]^=key[j];
}
}
void decrypt_0(char * input,int &len,char *key)
{
int i,j;
if(key[0]==0) return;
for(i=0,j=0;i<len;i++,j++)
{
if(key[j]==0)j=0;
input[i]^=key[j];
}
}
int add_seq(char * data,int &data_len )
{
if(data_len<0) return -1;
anti_replay_seq_t seq=anti_replay.get_new_seq_for_send();
seq=hton64(seq);
memcpy(data+data_len,&seq,sizeof(seq));
data_len+=sizeof(seq);
return 0;
}
int remove_seq(char * data,int &data_len)
{
anti_replay_seq_t seq;
if(data_len<int(sizeof(seq))) return -1;
data_len-=sizeof(seq);
memcpy(&seq,data+data_len,sizeof(seq));
seq=ntoh64(seq);
if(anti_replay.is_vaild(seq)==0)
{
if(disable_replay_filter==1)
return 0;
mylog(log_trace,"seq %llx dropped bc of replay-filter\n ",seq);
return -1;
}
packet_recv_count++;
return 0;
}
int do_obscure(const char * input, int in_len,char *output,int &out_len)
{
//memcpy(output,input,in_len);
// out_len=in_len;
//return 0;
int i, j, k;
if (in_len > 65535||in_len<0)
return -1;
int iv_len=iv_min+rand()%(iv_max-iv_min);
get_true_random_chars(output,iv_len);
memcpy(output+iv_len,input,in_len);
output[iv_len+in_len]=(uint8_t)iv_len;
output[iv_len+in_len]^=output[0];
output[iv_len+in_len]^=key_string[0];
for(i=0,j=0,k=1;i<in_len;i++,j++,k++)
{
if(j==iv_len) j=0;
if(key_string[k]==0)k=0;
output[iv_len+i]^=output[j];
output[iv_len+i]^=key_string[k];
}
out_len=iv_len+in_len+1;
return 0;
}
int de_obscure(const char * input, int in_len,char *output,int &out_len)
{
//memcpy(output,input,in_len);
//out_len=in_len;
//return 0;
int i, j, k;
if (in_len > 65535||in_len<0)
{
mylog(log_debug,"in_len > 65535||in_len<0 , %d",in_len);
return -1;
}
int iv_len= int ((uint8_t)(input[in_len-1]^input[0]^key_string[0]) );
out_len=in_len-1-iv_len;
if(out_len<0)
{
mylog(log_debug,"%d %d\n",in_len,out_len);
return -1;
}
for(i=0,j=0,k=1;i<in_len;i++,j++,k++)
{
if(j==iv_len) j=0;
if(key_string[k]==0)k=0;
output[i]=input[iv_len+i]^input[j]^key_string[k];
}
dup_packet_recv_count++;
return 0;
}
void check_delay_map()
{
if(!delay_mp.empty())
{
my_time_t current_time;
multimap<my_time_t,delay_data>::iterator it;
while(1)
{
int ret=0;
it=delay_mp.begin();
if(it==delay_mp.end()) break;
current_time=get_current_time_us();
if(it->first < current_time||it->first ==current_time)
{
if (is_client) {
if (conn_manager.exist_fd(it->second.fd)) {
u64_t u64 = conn_manager.find_u64_by_fd(it->second.fd);
if (u64 != it->second.u64) {
it->second.times_left = 0; //fd has been deleted and recreated
// 偷懒的做法
} else {
char new_data[buf_len];
int new_len = 0;
do_obscure(it->second.data, it->second.len,
new_data, new_len);
ret = send_fd(it->second.fd, new_data, new_len, 0);
}
} else {
it->second.times_left = 0;
}
} else {
if (conn_manager.exist_fd(it->second.fd)) {
u64_t u64 = conn_manager.find_u64_by_fd(it->second.fd);
if (u64 != it->second.u64) {
it->second.times_left = 0;//fd has been deleted and recreated
// 偷懒的做法
} else {
char new_data[buf_len];
int new_len = 0;
do_obscure(it->second.data, it->second.len,
new_data, new_len);
sendto_u64(local_listen_fd, new_data, new_len, 0,
u64);
}
} else {
it->second.times_left = 0;
}
}
if (ret < 0) {
mylog(log_debug, "send return %d at @300", ret);
}
if(it->second.times_left>1)
{
//delay_mp.insert(pair<my_time,delay_data>(current_time));
add_to_delay_mp(it->second.fd,it->second.times_left-1,random_between(dup_delay_min,dup_delay_max),it->second.data,it->second.len,it->second.u64);
}
else
{
free(it->second.data);
}
delay_mp.erase(it);
}
else
{
break;
}
}
if(!delay_mp.empty())
{
itimerspec its;
memset(&its.it_interval,0,sizeof(its.it_interval));
its.it_value.tv_sec=delay_mp.begin()->first/1000000llu;
its.it_value.tv_nsec=(delay_mp.begin()->first%1000000llu)*1000llu;
timerfd_settime(delay_timer_fd,TFD_TIMER_ABSTIME,&its,0);
}
}
}
int create_new_udp(int &new_udp_fd)
{
struct sockaddr_in remote_addr_in;
socklen_t slen = sizeof(sockaddr_in);
memset(&remote_addr_in, 0, sizeof(remote_addr_in));
remote_addr_in.sin_family = AF_INET;
remote_addr_in.sin_port = htons(remote_port);
remote_addr_in.sin_addr.s_addr = remote_address_uint32;
new_udp_fd = socket(AF_INET, SOCK_DGRAM, IPPROTO_UDP);
if (new_udp_fd < 0) {
mylog(log_warn, "create udp_fd error\n");
return -1;
}
setnonblocking(new_udp_fd);
set_buf_size(new_udp_fd);
mylog(log_debug, "created new udp_fd %d\n", new_udp_fd);
int ret = connect(new_udp_fd, (struct sockaddr *) &remote_addr_in, slen);
if (ret != 0) {
mylog(log_warn, "udp fd connect fail\n");
close(new_udp_fd);
return -1;
}
return 0;
}
int set_timer(int epollfd,int &timer_fd)
{
int ret;
epoll_event ev;
itimerspec its;
memset(&its,0,sizeof(its));
if((timer_fd=timerfd_create(CLOCK_MONOTONIC,TFD_NONBLOCK)) < 0)
{
mylog(log_fatal,"timer_fd create error\n");
myexit(1);
}
its.it_interval.tv_sec=(timer_interval/1000);
its.it_interval.tv_nsec=(timer_interval%1000)*1000ll*1000ll;
its.it_value.tv_nsec=1; //imidiately
timerfd_settime(timer_fd,0,&its,0);
ev.events = EPOLLIN;
ev.data.fd = timer_fd;
ret=epoll_ctl(epollfd, EPOLL_CTL_ADD, timer_fd, &ev);
if (ret < 0) {
mylog(log_fatal,"epoll_ctl return %d\n", ret);
myexit(-1);
}
return 0;
}
int event_loop()
{
struct sockaddr_in local_me, local_other;
local_listen_fd = socket(AF_INET, SOCK_DGRAM, IPPROTO_UDP);
int yes = 1;
//setsockopt(local_listen_fd, SOL_SOCKET, SO_REUSEADDR, &yes, sizeof(yes));
set_buf_size(local_listen_fd,4*1024*1024);
setnonblocking(local_listen_fd);
//char data[buf_len];
//char *data=data0;
socklen_t slen = sizeof(sockaddr_in);
memset(&local_me, 0, sizeof(local_me));
local_me.sin_family = AF_INET;
local_me.sin_port = htons(local_port);
local_me.sin_addr.s_addr = inet_addr(local_address);
if (bind(local_listen_fd, (struct sockaddr*) &local_me, slen) == -1)
{
mylog(log_fatal,"socket bind error");
myexit(1);
}
int epollfd = epoll_create1(0);
const int max_events = 4096;
struct epoll_event ev, events[max_events];
if (epollfd < 0)
{
mylog(log_fatal,"epoll created return %d\n", epollfd);
myexit(-1);
}
ev.events = EPOLLIN;
ev.data.fd = local_listen_fd;
int ret = epoll_ctl(epollfd, EPOLL_CTL_ADD, local_listen_fd, &ev);
if(ret!=0)
{
mylog(log_fatal,"epoll created return %d\n", epollfd);
myexit(-1);
}
int clear_timer_fd=-1;
set_timer(epollfd,clear_timer_fd);
if ((delay_timer_fd = timerfd_create(CLOCK_MONOTONIC, TFD_NONBLOCK)) < 0)
{
mylog(log_fatal,"timer_fd create error");
myexit(1);
}
ev.events = EPOLLIN;
ev.data.fd = delay_timer_fd;
itimerspec zero_its;
memset(&zero_its, 0, sizeof(zero_its));
timerfd_settime(delay_timer_fd, TFD_TIMER_ABSTIME, &zero_its, 0);
epoll_ctl(epollfd, EPOLL_CTL_ADD, delay_timer_fd, &ev);
if (ret < 0)
{
mylog(log_fatal,"epoll_ctl return %d\n", ret);
myexit(-1);
}
for (;;)
{
int nfds = epoll_wait(epollfd, events, max_events, 180 * 1000); //3mins
if (nfds < 0)
{
mylog(log_fatal,"epoll_wait return %d\n", nfds);
myexit(-1);
}
int n;
int clear_triggered=0;
for (n = 0; n < nfds; ++n)
{
if (events[n].data.fd == local_listen_fd) //data income from local end
{
char data[buf_len];
int data_len;
if ((data_len = recvfrom(local_listen_fd, data, max_data_len, 0,
(struct sockaddr *) &local_other, &slen)) == -1) //<--first packet from a new ip:port turple
{
mylog(log_error,"recv_from error,errno %s,this shouldnt happen,but lets try to pretend it didnt happen",strerror(errno));
//myexit(1);
continue;
}
mylog(log_trace, "received data from listen fd,%s:%d, len=%d\n", my_ntoa(local_other.sin_addr.s_addr),ntohs(local_other.sin_port),data_len);
if(data_len>mtu_warn)
{
mylog(log_warn,"huge packet,data len=%d (>%d).strongly suggested to set a smaller mtu at upper level,to get rid of this warn\n ",data_len,mtu_warn);
}
data[data_len] = 0; //for easier debug
u64_t u64=pack_u64(local_other.sin_addr.s_addr,ntohs(local_other.sin_port));
if(!conn_manager.exist_u64(u64))
{
if(int(conn_manager.fd_to_u64.size())>=max_conv_num)
{
mylog(log_info,"new connection from %s:%d ,but ignored,bc of max_conv_num reached\n",my_ntoa(local_other.sin_addr.s_addr),ntohs(local_other.sin_port));
continue;
}
int new_udp_fd;
if(create_new_udp(new_udp_fd)!=0)
{
mylog(log_info,"new connection from %s:%d ,but create udp fd failed\n",my_ntoa(local_other.sin_addr.s_addr),ntohs(local_other.sin_port));
continue;
}
struct epoll_event ev;
mylog(log_trace, "u64: %lld\n", u64);
ev.events = EPOLLIN;
ev.data.fd = new_udp_fd;
ret = epoll_ctl(epollfd, EPOLL_CTL_ADD, new_udp_fd, &ev);
if (ret != 0) {
mylog(log_info,"new connection from %s:%d ,but add to epoll failed\n",my_ntoa(local_other.sin_addr.s_addr),ntohs(local_other.sin_port));
close(new_udp_fd);
continue;
}
mylog(log_info,"new connection from %s:%d ,created new udp fd %d\n",my_ntoa(local_other.sin_addr.s_addr),ntohs(local_other.sin_port),new_udp_fd);
conn_manager.insert_fd(new_udp_fd,u64);
}
int new_udp_fd=conn_manager.find_fd_by_u64(u64);
conn_manager.update_active_time(new_udp_fd);
int ret;
if(is_client)
{
add_seq(data,data_len);
if(jitter_max==0)
{
char new_data[buf_len];
int new_len=0;
do_obscure(data, data_len, new_data, new_len);
ret = send_fd(new_udp_fd, new_data,new_len, 0);
if (ret < 0) {
mylog(log_warn, "send returned %d ,errno:%s\n", ret,strerror(errno));
}
add_and_new(new_udp_fd, dup_num - 1,random_between(dup_delay_min,dup_delay_max), data, data_len,u64);
}
else
{
add_and_new(new_udp_fd, dup_num,random_between(jitter_min,jitter_max), data, data_len,u64);
}
packet_send_count++;
}
else
{
char new_data[buf_len];
int new_len;
if (de_obscure(data, data_len, new_data, new_len) != 0) {
mylog(log_trace,"de_obscure failed \n");
continue;
}
//dup_packet_recv_count++;
if (remove_seq(new_data, new_len) != 0) {
mylog(log_trace,"remove_seq failed \n");
continue;
}
//packet_recv_count++;
ret = send_fd(new_udp_fd, new_data,new_len, 0);
if (ret < 0) {
mylog(log_warn, "send returned %d,%s\n", ret,strerror(errno));
//perror("what happened????");
}
}
}
else if(events[n].data.fd == clear_timer_fd)
{
clear_triggered=1;
if(report_interval!=0 &&get_current_time()-last_report_time>u64_t(report_interval)*1000)
{
last_report_time=get_current_time();
if(is_client)
mylog(log_info,"client-->server: %llu,%llu(include dup); server-->client %llu,%lld(include dup)\n",packet_send_count,
dup_packet_send_count,packet_recv_count,dup_packet_recv_count);
else
mylog(log_info,"client-->server: %llu,%llu(include dup); server-->client %llu,%lld(include dup)\n",packet_recv_count,dup_packet_recv_count,packet_send_count,
dup_packet_send_count);
}
}
else if (events[n].data.fd == delay_timer_fd)
{
uint64_t value;
read(delay_timer_fd, &value, 8);
//printf("<timerfd_triggered, %d>",delay_mp.size());
//fflush(stdout);
}
else
{
int udp_fd=events[n].data.fd;
if(!conn_manager.exist_fd(udp_fd)) continue;
char data[buf_len];
int data_len =recv(udp_fd,data,max_data_len,0);
mylog(log_trace, "received data from udp fd %d, len=%d\n", udp_fd,data_len);
if(data_len<0)
{
if(errno==ECONNREFUSED)
{
//conn_manager.clear_list.push_back(udp_fd);
mylog(log_debug, "recv failed %d ,udp_fd%d,errno:%s\n", data_len,udp_fd,strerror(errno));
}
mylog(log_warn, "recv failed %d ,udp_fd%d,errno:%s\n", data_len,udp_fd,strerror(errno));
continue;
}
if(data_len>mtu_warn)
{
mylog(log_warn,"huge packet,data len=%d (>%d).strongly suggested to set a smaller mtu at upper level,to get rid of this warn\n ",data_len,mtu_warn);
}
assert(conn_manager.exist_fd(udp_fd));
conn_manager.update_active_time(udp_fd);
u64_t u64=conn_manager.find_u64_by_fd(udp_fd);
if(is_client)
{
char new_data[buf_len];
int new_len;
if (de_obscure(data, data_len, new_data, new_len) != 0) {
mylog(log_debug,"data_len=%d \n",data_len);
continue;
}
//dup_packet_recv_count++;
if (remove_seq(new_data, new_len) != 0) {
mylog(log_debug,"remove_seq error \n");
continue;
}
//packet_recv_count++;
ret = sendto_u64(local_listen_fd, new_data,
new_len , 0,u64);
if (ret < 0) {
mylog(log_warn, "sento returned %d,%s\n", ret,strerror(errno));
//perror("ret<0");
}
}
else
{
add_seq(data,data_len);
if(jitter_max==0)
{
char new_data[buf_len];
int new_len=0;
do_obscure(data, data_len, new_data, new_len);
ret = sendto_u64(local_listen_fd, new_data,
new_len , 0,u64);
add_and_new(udp_fd, dup_num - 1,random_between(dup_delay_min,dup_delay_max), data, data_len,u64);
if (ret < 0) {
mylog(log_warn, "sento returned %d,%s\n", ret,strerror(errno));
//perror("ret<0");
}
}
else
{
add_and_new(udp_fd, dup_num,random_between(jitter_min,jitter_max), data, data_len,u64);
}
packet_send_count++;
}
//mylog(log_trace, "%s :%d\n", inet_ntoa(tmp_sockaddr.sin_addr),
// ntohs(tmp_sockaddr.sin_port));
//mylog(log_trace, "%d byte sent\n", ret);
}
}
check_delay_map();
conn_manager.check_clear_list();
if(clear_triggered) // 删除操作在epoll event的最后进行,防止event cache中的fd失效。
{
u64_t value;
read(clear_timer_fd, &value, 8);
mylog(log_trace, "timer!\n");
conn_manager.clear_inactive();
}
}
myexit(0);
return 0;
}
void print_help()
{
printf("UDPspeeder\n");
printf("version: %s %s\n",__DATE__,__TIME__);
printf("repository: https://github.com/wangyu-/UDPspeeder\n");
printf("\n");
printf("usage:\n");
printf(" run as client : ./this_program -c -l local_listen_ip:local_port -r server_ip:server_port [options]\n");
printf(" run as server : ./this_program -s -l server_listen_ip:server_port -r remote_ip:remote_port [options]\n");
printf("\n");
printf("common option,must be same on both sides:\n");
printf(" -k,--key <string> key for simple xor encryption,default:\"secret key\"\n");
printf("main options:\n");
printf(" -d <number> duplicated packet number, -d 0 means no duplicate. default value:0\n");
printf(" -t <number> duplicated packet delay time, unit: 0.1ms,default value:20(2ms)\n");
printf(" -j <number> simulated jitter.randomly delay first packet for 0~jitter_value*0.1 ms,to\n");
printf(" create simulated jitter.default value:0.do not use if you dont\n");
printf(" know what it means\n");
printf(" --report <number> turn on udp send/recv report,and set a time interval for reporting,unit:s\n");
printf("advanced options:\n");
printf(" -t tmin:tmax simliar to -t above,but delay randomly between tmin and tmax\n");
printf(" -j jmin:jmax simliar to -j above,but create jitter randomly between jmin and jmax\n");
printf(" --random-drop <number> simulate packet loss ,unit 0.01%%\n");
printf(" -m <number> max pending packets,to prevent the program from eating up all your memory.\n");
printf("other options:\n");
printf(" --log-level <number> 0:never 1:fatal 2:error 3:warn \n");
printf(" 4:info (default) 5:debug 6:trace\n");
printf(" --log-position enable file name,function name,line number in log\n");
printf(" --disable-color disable log color\n");
printf(" --sock-buf <number> buf size for socket,>=10 and <=10240,unit:kbyte,default:512\n");
//printf(" -p use multi-process mode instead of epoll.very costly,only for test,do dont use\n");
printf(" -h,--help print this help message\n");
//printf("common options,these options must be same on both side\n");
}
void process_arg(int argc, char *argv[])
{
int i, j, k;
int opt;
static struct option long_options[] =
{
{"log-level", required_argument, 0, 1},
{"log-position", no_argument, 0, 1},
{"disable-color", no_argument, 0, 1},
{"disable-filter", no_argument, 0, 1},
{"sock-buf", required_argument, 0, 1},
{"random-drop", required_argument, 0, 1},
{"report", required_argument, 0, 1},
{NULL, 0, 0, 0}
};
int option_index = 0;
if (argc == 1)
{
print_help();
myexit( -1);
}
for (i = 0; i < argc; i++)
{
if(strcmp(argv[i],"-h")==0||strcmp(argv[i],"--help")==0)
{
print_help();
myexit(0);
}
}
for (i = 0; i < argc; i++)
{
if(strcmp(argv[i],"--log-level")==0)
{
if(i<argc -1)
{
sscanf(argv[i+1],"%d",&log_level);
if(0<=log_level&&log_level<log_end)
{
}
else
{
log_bare(log_fatal,"invalid log_level\n");
myexit(-1);
}
}
}
if(strcmp(argv[i],"--disable-color")==0)
{
enable_log_color=0;
}
}
mylog(log_info,"argc=%d ", argc);
for (i = 0; i < argc; i++) {
log_bare(log_info, "%s ", argv[i]);
}
log_bare(log_info, "\n");
if (argc == 1)
{
print_help();
myexit(-1);
}
int no_l = 1, no_r = 1;
while ((opt = getopt_long(argc, argv, "l:r:d:t:hcspk:j:m:",long_options,&option_index)) != -1)
{
//string opt_key;
//opt_key+=opt;
switch (opt)
{
case 'p':
multi_process_mode=1;
break;
case 'k':
sscanf(optarg,"%s\n",key_string);
mylog(log_debug,"key=%s\n",key_string);
if(strlen(key_string)==0)
{
mylog(log_fatal,"key len=0??\n");
myexit(-1);
}
break;
case 'm':
sscanf(optarg,"%d\n",&max_pending_packet);
if(max_pending_packet<1000)
{
mylog(log_fatal,"max_pending_packet must be >1000\n");
myexit(-1);
}
break;
case 'j':
if (strchr(optarg, ':') == 0)
{
int jitter;
sscanf(optarg,"%d\n",&jitter);
if(jitter<0 ||jitter>1000*100)
{
mylog(log_fatal,"jitter must be between 0 and 100,000(10 second)\n");
myexit(-1);
}
jitter_min=0;
jitter_max=jitter;
}
else
{
sscanf(optarg,"%d:%d\n",&jitter_min,&jitter_max);
if(jitter_min<0 ||jitter_max<0||jitter_min>jitter_max)
{
mylog(log_fatal," must satisfy 0<=jmin<=jmax\n");
myexit(-1);
}
}
break;
case 't':
if (strchr(optarg, ':') == 0)
{
int dup_delay=-1;
sscanf(optarg,"%d\n",&dup_delay);
if(dup_delay<1||dup_delay>1000*100)
{
mylog(log_fatal,"dup_delay must be between 1 and 100,000(10 second)\n");
myexit(-1);
}
dup_delay_min=dup_delay_max=dup_delay;
}
else
{
sscanf(optarg,"%d:%d\n",&dup_delay_min,&dup_delay_max);
if(dup_delay_min<1 ||dup_delay_max<1||dup_delay_min>dup_delay_max)
{
mylog(log_fatal," must satisfy 1<=dmin<=dmax\n");
myexit(-1);
}
}
break;
case 'd':
dup_num=-1;
sscanf(optarg,"%d\n",&dup_num);
if(dup_num<0 ||dup_num>5)
{
mylog(log_fatal,"dup_num must be between 0 and 5\n");
myexit(-1);
}
dup_num+=1;
break;
case 'c':
is_client = 1;
break;
case 's':
is_server = 1;
break;
case 'l':
no_l = 0;
if (strchr(optarg, ':') != 0)
{
sscanf(optarg, "%[^:]:%d", local_address, &local_port);
}
else
{
mylog(log_fatal," -r ip:port\n");
myexit(1);
strcpy(local_address, "127.0.0.1");
sscanf(optarg, "%d", &local_port);
}
break;
case 'r':
no_r = 0;
if (strchr(optarg, ':') != 0)
{
//printf("in :\n");
//printf("%s\n",optarg);
sscanf(optarg, "%[^:]:%d", remote_address, &remote_port);
//printf("%d\n",remote_port);
}
else
{
mylog(log_fatal," -r ip:port\n");
myexit(1);
strcpy(remote_address, "127.0.0.1");
sscanf(optarg, "%d", &remote_port);
}
break;
case 'h':
break;
case 1:
if(strcmp(long_options[option_index].name,"log-level")==0)
{
}
else if(strcmp(long_options[option_index].name,"disable-filter")==0)
{
disable_replay_filter=1;
//enable_log_color=0;
}
else if(strcmp(long_options[option_index].name,"disable-color")==0)
{
//enable_log_color=0;
}
else if(strcmp(long_options[option_index].name,"log-position")==0)
{
enable_log_position=1;
}
else if(strcmp(long_options[option_index].name,"random-drop")==0)
{
sscanf(optarg,"%d",&random_drop);
if(random_drop<0||random_drop>10000)
{
mylog(log_fatal,"random_drop must be between 0 10000 \n");
myexit(-1);
}
}
else if(strcmp(long_options[option_index].name,"report")==0)
{
sscanf(optarg,"%d",&report_interval);
if(report_interval<=0)
{
mylog(log_fatal,"report_interval must be >0 \n");
myexit(-1);
}
}
else if(strcmp(long_options[option_index].name,"sock-buf")==0)
{
int tmp=-1;
sscanf(optarg,"%d",&tmp);
if(10<=tmp&&tmp<=10*1024)
{
socket_buf_size=tmp*1024;
}
else
{
mylog(log_fatal,"sock-buf value must be between 1 and 10240 (kbyte) \n");
myexit(-1);
}
}
else
{
mylog(log_fatal,"unknown option\n");
myexit(-1);
}
break;
default:
mylog(log_fatal,"unknown option <%x>", opt);
myexit(-1);
}
}
if (no_l)
mylog(log_fatal,"error: -i not found\n");
if (no_r)
mylog(log_fatal,"error: -o not found\n");
if (no_l || no_r)
myexit(-1);
if (is_client == 0 && is_server == 0)
{
mylog(log_fatal,"-s -c hasnt been set\n");
myexit(-1);
}
if (is_client == 1 && is_server == 1)
{
mylog(log_fatal,"-s -c cant be both set\n");
myexit(-1);
}
}
int main(int argc, char *argv[])
{
dup2(1, 2); //redirect stderr to stdout
int i, j, k;
process_arg(argc,argv);
init_random_number_fd();
anti_replay.prepare();
remote_address_uint32=inet_addr(remote_address);
if(!multi_process_mode)
{
event_loop();
}
else
{
}
return 0;
}