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tcpip.cpp
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tcpip.cpp
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// IP, ARP, UDP and TCP functions.
// Author: Guido Socher
// Copyright: GPL V2
//
// The TCP implementation uses some size optimisations which are valid
// only if all data can be sent in one single packet. This is however
// not a big limitation for a microcontroller as you will anyhow use
// small web-pages. The web server must send the entire web page in one
// packet. The client "web browser" as implemented here can also receive
// large pages.
//
// 2010-05-20 <[email protected]>
#ifndef ESP8266
#include "EtherCard.h"
#include "net.h"
#undef word // arduino nonsense
#define gPB ether.buffer
#define PINGPATTERN 0x42
// Avoid spurious pgmspace warnings - http://forum.jeelabs.net/node/327
// See also http://gcc.gnu.org/bugzilla/show_bug.cgi?id=34734
//#undef PROGMEM
//#define PROGMEM __attribute__(( section(".progmem.data") ))
//#undef PSTR
//#define PSTR(s) (__extension__({static prog_char c[] PROGMEM = (s); &c[0];}))
#define TCPCLIENT_SRC_PORT_H 11 //Source port (MSB) for TCP/IP client connections - hardcode all TCP/IP client connection from ports in range 2816-3071
static uint8_t tcpclient_src_port_l=1; // Source port (LSB) for tcp/ip client connections - increments on each TCP/IP request
static uint8_t tcp_fd; // a file descriptor, will be encoded into the port
static uint8_t tcp_client_state; //TCP connection state: 1=Send SYN, 2=SYN sent awaiting SYN+ACK, 3=Established, 4=Not used, 5=Closing, 6=Closed
static uint8_t tcp_client_port_h; // Destination port (MSB) of TCP/IP client connection
static uint8_t tcp_client_port_l; // Destination port (LSB) of TCP/IP client connection
static uint8_t (*client_tcp_result_cb)(uint8_t,uint8_t,uint16_t,uint16_t); // Pointer to callback function to handle response to current TCP/IP request
static uint16_t (*client_tcp_datafill_cb)(uint8_t); //Pointer to callback function to handle payload data in response to current TCP/IP request
static uint8_t www_fd; // ID of current http request (only one http request at a time - one of the 8 possible concurrent TCP/IP connections)
static void (*client_browser_cb)(uint8_t,uint16_t,uint16_t); // Pointer to callback function to handle result of current HTTP request
static const char *client_additionalheaderline; // Pointer to c-string additional http request header info
static const char *client_postval;
static const char *client_urlbuf; // Pointer to c-string path part of HTTP request URL
static const char *client_urlbuf_var; // Pointer to c-string filename part of HTTP request URL
static const char *client_hoststr; // Pointer to c-string hostname of current HTTP request
static void (*icmp_cb)(uint8_t *ip); // Pointer to callback function for ICMP ECHO response handler (triggers when localhost recieves ping respnse (pong))
static uint8_t gwmacaddr[6]; // Hardware (MAC) address of gateway router
static uint8_t waitgwmac; // Bitwise flags of gateway router status - see below for states
//Define gatweay router ARP statuses
#define WGW_INITIAL_ARP 1 // First reqest, no answer yet
#define WGW_HAVE_GW_MAC 2 // Have gateway router MAC
#define WGW_REFRESHING 4 // Refeshing but already have gateway MAC
#define WGW_ACCEPT_ARP_REPLY 8 // Accept an ARP reply
static uint16_t info_data_len; // Length of TCP/IP payload
static uint8_t seqnum = 0xa; // My initial tcp sequence number
static uint8_t result_fd = 123; // Session id of last reply
static const char* result_ptr; // Pointer to TCP/IP data
static unsigned long SEQ; // TCP/IP sequence number
#define CLIENTMSS 550
#define TCP_DATA_START ((uint16_t)TCP_SRC_PORT_H_P+(gPB[TCP_HEADER_LEN_P]>>4)*4) // Get offset of TCP/IP payload data
const unsigned char arpreqhdr[] PROGMEM = { 0,1,8,0,6,4,0,1 }; // ARP request header
const unsigned char iphdr[] PROGMEM = { 0x45,0,0,0x82,0,0,0x40,0,0x20 }; //IP header
const unsigned char ntpreqhdr[] PROGMEM = { 0xE3,0,4,0xFA,0,1,0,0,0,1 }; //NTP request header
const uint8_t allOnes[] = { 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF }; // Used for hardware (MAC) and IP broadcast addresses
static void fill_checksum(uint8_t dest, uint8_t off, uint16_t len,uint8_t type) {
const uint8_t* ptr = gPB + off;
uint32_t sum = type==1 ? IP_PROTO_UDP_V+len-8 :
type==2 ? IP_PROTO_TCP_V+len-8 : 0;
while(len >1) {
sum += (uint16_t) (((uint32_t)*ptr<<8)|*(ptr+1));
ptr+=2;
len-=2;
}
if (len)
sum += ((uint32_t)*ptr)<<8;
while (sum>>16)
sum = (uint16_t) sum + (sum >> 16);
uint16_t ck = ~ (uint16_t) sum;
gPB[dest] = ck>>8;
gPB[dest+1] = ck;
}
static void setMACs (const uint8_t *mac) {
EtherCard::copyMac(gPB + ETH_DST_MAC, mac);
EtherCard::copyMac(gPB + ETH_SRC_MAC, EtherCard::mymac);
}
static void setMACandIPs (const uint8_t *mac, const uint8_t *dst) {
setMACs(mac);
EtherCard::copyIp(gPB + IP_DST_P, dst);
EtherCard::copyIp(gPB + IP_SRC_P, EtherCard::myip);
}
static uint8_t check_ip_message_is_from(const uint8_t *ip) {
return memcmp(gPB + IP_SRC_P, ip, 4) == 0;
}
static uint8_t eth_type_is_arp_and_my_ip(uint16_t len) {
return len >= 41 && gPB[ETH_TYPE_H_P] == ETHTYPE_ARP_H_V &&
gPB[ETH_TYPE_L_P] == ETHTYPE_ARP_L_V &&
memcmp(gPB + ETH_ARP_DST_IP_P, EtherCard::myip, 4) == 0;
}
static uint8_t eth_type_is_ip_and_my_ip(uint16_t len) {
return len >= 42 && gPB[ETH_TYPE_H_P] == ETHTYPE_IP_H_V &&
gPB[ETH_TYPE_L_P] == ETHTYPE_IP_L_V &&
gPB[IP_HEADER_LEN_VER_P] == 0x45 &&
(memcmp(gPB + IP_DST_P, EtherCard::myip, 4) == 0 //not my IP
|| (memcmp(gPB + IP_DST_P, EtherCard::broadcastip, 4) == 0) //not subnet broadcast
|| (memcmp(gPB + IP_DST_P, allOnes, 4) == 0)); //not global broadcasts
//!@todo Handle multicast
}
static void fill_ip_hdr_checksum() {
gPB[IP_CHECKSUM_P] = 0;
gPB[IP_CHECKSUM_P+1] = 0;
gPB[IP_FLAGS_P] = 0x40; // don't fragment
gPB[IP_FLAGS_P+1] = 0; // fragement offset
gPB[IP_TTL_P] = 64; // ttl
fill_checksum(IP_CHECKSUM_P, IP_P, IP_HEADER_LEN,0);
}
static void make_eth_ip() {
setMACs(gPB + ETH_SRC_MAC);
EtherCard::copyIp(gPB + IP_DST_P, gPB + IP_SRC_P);
EtherCard::copyIp(gPB + IP_SRC_P, EtherCard::myip);
fill_ip_hdr_checksum();
}
static void step_seq(uint16_t rel_ack_num,uint8_t cp_seq) {
uint8_t i;
uint8_t tseq;
i = 4;
while(i>0) {
rel_ack_num = gPB[TCP_SEQ_H_P+i-1]+rel_ack_num;
tseq = gPB[TCP_SEQACK_H_P+i-1];
gPB[TCP_SEQACK_H_P+i-1] = rel_ack_num;
if (cp_seq)
gPB[TCP_SEQ_H_P+i-1] = tseq;
else
gPB[TCP_SEQ_H_P+i-1] = 0; // some preset value
rel_ack_num = rel_ack_num>>8;
i--;
}
}
static void make_tcphead(uint16_t rel_ack_num,uint8_t cp_seq) {
uint8_t i = gPB[TCP_DST_PORT_H_P];
gPB[TCP_DST_PORT_H_P] = gPB[TCP_SRC_PORT_H_P];
gPB[TCP_SRC_PORT_H_P] = i;
uint8_t j = gPB[TCP_DST_PORT_L_P];
gPB[TCP_DST_PORT_L_P] = gPB[TCP_SRC_PORT_L_P];
gPB[TCP_SRC_PORT_L_P] = j;
step_seq(rel_ack_num,cp_seq);
gPB[TCP_CHECKSUM_H_P] = 0;
gPB[TCP_CHECKSUM_L_P] = 0;
gPB[TCP_HEADER_LEN_P] = 0x50;
}
static void make_arp_answer_from_request() {
setMACs(gPB + ETH_SRC_MAC);
gPB[ETH_ARP_OPCODE_H_P] = ETH_ARP_OPCODE_REPLY_H_V;
gPB[ETH_ARP_OPCODE_L_P] = ETH_ARP_OPCODE_REPLY_L_V;
EtherCard::copyMac(gPB + ETH_ARP_DST_MAC_P, gPB + ETH_ARP_SRC_MAC_P);
EtherCard::copyMac(gPB + ETH_ARP_SRC_MAC_P, EtherCard::mymac);
EtherCard::copyIp(gPB + ETH_ARP_DST_IP_P, gPB + ETH_ARP_SRC_IP_P);
EtherCard::copyIp(gPB + ETH_ARP_SRC_IP_P, EtherCard::myip);
EtherCard::packetSend(42);
}
static void make_echo_reply_from_request(uint16_t len) {
make_eth_ip();
gPB[ICMP_TYPE_P] = ICMP_TYPE_ECHOREPLY_V;
if (gPB[ICMP_CHECKSUM_P] > (0xFF-0x08))
gPB[ICMP_CHECKSUM_P+1]++;
gPB[ICMP_CHECKSUM_P] += 0x08;
EtherCard::packetSend(len);
}
void EtherCard::makeUdpReply (char *data,uint8_t datalen,uint16_t port) {
if (datalen>220)
datalen = 220;
gPB[IP_TOTLEN_H_P] = (IP_HEADER_LEN+UDP_HEADER_LEN+datalen) >>8;
gPB[IP_TOTLEN_L_P] = IP_HEADER_LEN+UDP_HEADER_LEN+datalen;
make_eth_ip();
gPB[UDP_DST_PORT_H_P] = gPB[UDP_SRC_PORT_H_P];
gPB[UDP_DST_PORT_L_P] = gPB[UDP_SRC_PORT_L_P];
gPB[UDP_SRC_PORT_H_P] = port>>8;
gPB[UDP_SRC_PORT_L_P] = port;
gPB[UDP_LEN_H_P] = (UDP_HEADER_LEN+datalen) >> 8;
gPB[UDP_LEN_L_P] = UDP_HEADER_LEN+datalen;
gPB[UDP_CHECKSUM_H_P] = 0;
gPB[UDP_CHECKSUM_L_P] = 0;
memcpy(gPB + UDP_DATA_P, data, datalen);
fill_checksum(UDP_CHECKSUM_H_P, IP_SRC_P, 16 + datalen,1);
packetSend(UDP_HEADER_LEN+IP_HEADER_LEN+ETH_HEADER_LEN+datalen);
}
static void make_tcp_synack_from_syn() {
gPB[IP_TOTLEN_H_P] = 0;
gPB[IP_TOTLEN_L_P] = IP_HEADER_LEN+TCP_HEADER_LEN_PLAIN+4;
make_eth_ip();
gPB[TCP_FLAGS_P] = TCP_FLAGS_SYNACK_V;
make_tcphead(1,0);
gPB[TCP_SEQ_H_P+0] = 0;
gPB[TCP_SEQ_H_P+1] = 0;
gPB[TCP_SEQ_H_P+2] = seqnum;
gPB[TCP_SEQ_H_P+3] = 0;
seqnum += 3;
gPB[TCP_OPTIONS_P] = 2;
gPB[TCP_OPTIONS_P+1] = 4;
gPB[TCP_OPTIONS_P+2] = 0x05;
gPB[TCP_OPTIONS_P+3] = 0x0;
gPB[TCP_HEADER_LEN_P] = 0x60;
gPB[TCP_WIN_SIZE] = 0x5; // 1400=0x578
gPB[TCP_WIN_SIZE+1] = 0x78;
fill_checksum(TCP_CHECKSUM_H_P, IP_SRC_P, 8+TCP_HEADER_LEN_PLAIN+4,2);
EtherCard::packetSend(IP_HEADER_LEN+TCP_HEADER_LEN_PLAIN+4+ETH_HEADER_LEN);
}
static uint16_t get_tcp_data_len() {
int16_t i = (((int16_t)gPB[IP_TOTLEN_H_P])<<8)|gPB[IP_TOTLEN_L_P];
i -= IP_HEADER_LEN;
i -= (gPB[TCP_HEADER_LEN_P]>>4)*4; // generate len in bytes;
if (i<=0)
i = 0;
return (uint16_t)i;
}
static void make_tcp_ack_from_any(int16_t datlentoack,uint8_t addflags) {
gPB[TCP_FLAGS_P] = TCP_FLAGS_ACK_V|addflags;
if (addflags!=TCP_FLAGS_RST_V && datlentoack==0)
datlentoack = 1;
make_tcphead(datlentoack,1); // no options
uint16_t j = IP_HEADER_LEN+TCP_HEADER_LEN_PLAIN;
gPB[IP_TOTLEN_H_P] = j>>8;
gPB[IP_TOTLEN_L_P] = j;
make_eth_ip();
gPB[TCP_WIN_SIZE] = 0x4; // 1024=0x400, 1280=0x500 2048=0x800 768=0x300
gPB[TCP_WIN_SIZE+1] = 0;
fill_checksum(TCP_CHECKSUM_H_P, IP_SRC_P, 8+TCP_HEADER_LEN_PLAIN,2);
EtherCard::packetSend(IP_HEADER_LEN+TCP_HEADER_LEN_PLAIN+ETH_HEADER_LEN);
}
static void make_tcp_ack_with_data_noflags(uint16_t dlen) {
uint16_t j = IP_HEADER_LEN+TCP_HEADER_LEN_PLAIN+dlen;
gPB[IP_TOTLEN_H_P] = j>>8;
gPB[IP_TOTLEN_L_P] = j;
fill_ip_hdr_checksum();
gPB[TCP_CHECKSUM_H_P] = 0;
gPB[TCP_CHECKSUM_L_P] = 0;
fill_checksum(TCP_CHECKSUM_H_P, IP_SRC_P, 8+TCP_HEADER_LEN_PLAIN+dlen,2);
EtherCard::packetSend(IP_HEADER_LEN+TCP_HEADER_LEN_PLAIN+dlen+ETH_HEADER_LEN);
}
void EtherCard::httpServerReply (uint16_t dlen) {
make_tcp_ack_from_any(info_data_len,0); // send ack for http get
gPB[TCP_FLAGS_P] = TCP_FLAGS_ACK_V|TCP_FLAGS_PUSH_V|TCP_FLAGS_FIN_V;
make_tcp_ack_with_data_noflags(dlen); // send data
}
static void get_seq() { //get the sequence number of packets after an ack from GET
SEQ =(((unsigned long)gPB[TCP_SEQ_H_P]*256+gPB[TCP_SEQ_H_P+1])*256+gPB[TCP_SEQ_H_P+2])*256+gPB[TCP_SEQ_H_P+3];
} //thanks to mstuetz for the missing (unsigned long)
static void set_seq() { //set the correct sequence number and calculate the next with the lenght of current packet
gPB[TCP_SEQ_H_P]= (SEQ & 0xff000000 ) >> 24;
gPB[TCP_SEQ_H_P+1]= (SEQ & 0xff0000 ) >> 16;
gPB[TCP_SEQ_H_P+2]= (SEQ & 0xff00 ) >> 8;
gPB[TCP_SEQ_H_P+3]= (SEQ & 0xff );
}
void EtherCard::httpServerReplyAck () {
make_tcp_ack_from_any(info_data_len,0); // send ack for http get
get_seq(); //get the sequence number of packets after an ack from GET
}
/*void EtherCard::httpServerReply_with_flags (uint16_t dlen, uint8_t flags, uint8_t dup) {
for(byte i=0;i<=dup;i++) {
set_seq();
gPB[TCP_FLAGS_P] = flags; // final packet
make_tcp_ack_with_data_noflags(dlen); // send data
}
SEQ=SEQ+dlen;
}*/
void EtherCard::httpServerReply_with_flags (uint16_t dlen , uint8_t flags) {
set_seq();
gPB[TCP_FLAGS_P] = flags; // final packet
make_tcp_ack_with_data_noflags(dlen); // send data
SEQ=SEQ+dlen;
}
void EtherCard::clientIcmpRequest(const uint8_t *destip) {
setMACandIPs(gwmacaddr, destip);
gPB[ETH_TYPE_H_P] = ETHTYPE_IP_H_V;
gPB[ETH_TYPE_L_P] = ETHTYPE_IP_L_V;
memcpy_P(gPB + IP_P,iphdr,9);
gPB[IP_TOTLEN_L_P] = 0x54;
gPB[IP_PROTO_P] = IP_PROTO_ICMP_V;
fill_ip_hdr_checksum();
gPB[ICMP_TYPE_P] = ICMP_TYPE_ECHOREQUEST_V;
gPB[ICMP_TYPE_P+1] = 0; // code
gPB[ICMP_CHECKSUM_H_P] = 0;
gPB[ICMP_CHECKSUM_L_P] = 0;
gPB[ICMP_IDENT_H_P] = 5; // some number
gPB[ICMP_IDENT_L_P] = EtherCard::myip[3]; // last byte of my IP
gPB[ICMP_IDENT_L_P+1] = 0; // seq number, high byte
gPB[ICMP_IDENT_L_P+2] = 1; // seq number, low byte, we send only 1 ping at a time
memset(gPB + ICMP_DATA_P, PINGPATTERN, 56);
fill_checksum(ICMP_CHECKSUM_H_P, ICMP_TYPE_P, 56+8,0);
packetSend(98);
}
void EtherCard::ntpRequest (uint8_t *ntpip,uint8_t srcport) {
setMACandIPs(gwmacaddr, ntpip);
gPB[ETH_TYPE_H_P] = ETHTYPE_IP_H_V;
gPB[ETH_TYPE_L_P] = ETHTYPE_IP_L_V;
memcpy_P(gPB + IP_P,iphdr,9);
gPB[IP_TOTLEN_L_P] = 0x4c;
gPB[IP_PROTO_P] = IP_PROTO_UDP_V;
fill_ip_hdr_checksum();
gPB[UDP_DST_PORT_H_P] = 0;
gPB[UDP_DST_PORT_L_P] = 0x7b; // ntp = 123
gPB[UDP_SRC_PORT_H_P] = 10;
gPB[UDP_SRC_PORT_L_P] = srcport; // lower 8 bit of src port
gPB[UDP_LEN_H_P] = 0;
gPB[UDP_LEN_L_P] = 56; // fixed len
gPB[UDP_CHECKSUM_H_P] = 0;
gPB[UDP_CHECKSUM_L_P] = 0;
memset(gPB + UDP_DATA_P, 0, 48);
memcpy_P(gPB + UDP_DATA_P,ntpreqhdr,10);
fill_checksum(UDP_CHECKSUM_H_P, IP_SRC_P, 16 + 48,1);
packetSend(90);
}
uint8_t EtherCard::ntpProcessAnswer (uint32_t *time,uint8_t dstport_l) {
if ((dstport_l && gPB[UDP_DST_PORT_L_P]!=dstport_l) || gPB[UDP_LEN_H_P]!=0 ||
gPB[UDP_LEN_L_P]!=56 || gPB[UDP_SRC_PORT_L_P]!=0x7b)
return 0;
((uint8_t*) time)[3] = gPB[0x52];
((uint8_t*) time)[2] = gPB[0x53];
((uint8_t*) time)[1] = gPB[0x54];
((uint8_t*) time)[0] = gPB[0x55];
return 1;
}
void EtherCard::udpPrepare (uint16_t sport, const uint8_t *dip, uint16_t dport) {
setMACandIPs(gwmacaddr, dip);
//!@todo Use destination MAC if on local subnet - that means checking address and performing ARP which may bloat software.
// see http://tldp.org/HOWTO/Multicast-HOWTO-2.html
// multicast or broadcast address, https://github.com/jcw/ethercard/issues/59
if ((dip[0] & 0xF0) == 0xE0 || *((unsigned long*) dip) == 0xFFFFFFFF)
EtherCard::copyMac(gPB + ETH_DST_MAC, allOnes);
gPB[ETH_TYPE_H_P] = ETHTYPE_IP_H_V;
gPB[ETH_TYPE_L_P] = ETHTYPE_IP_L_V;
memcpy_P(gPB + IP_P,iphdr,9);
gPB[IP_TOTLEN_H_P] = 0;
gPB[IP_PROTO_P] = IP_PROTO_UDP_V;
gPB[UDP_DST_PORT_H_P] = (dport>>8);
gPB[UDP_DST_PORT_L_P] = dport;
gPB[UDP_SRC_PORT_H_P] = (sport>>8);
gPB[UDP_SRC_PORT_L_P] = sport;
gPB[UDP_LEN_H_P] = 0;
gPB[UDP_CHECKSUM_H_P] = 0;
gPB[UDP_CHECKSUM_L_P] = 0;
}
void EtherCard::udpTransmit (uint16_t datalen) {
gPB[IP_TOTLEN_H_P] = (IP_HEADER_LEN+UDP_HEADER_LEN+datalen) >> 8;
gPB[IP_TOTLEN_L_P] = IP_HEADER_LEN+UDP_HEADER_LEN+datalen;
fill_ip_hdr_checksum();
gPB[UDP_LEN_H_P] = (UDP_HEADER_LEN+datalen) >>8;
gPB[UDP_LEN_L_P] = UDP_HEADER_LEN+datalen;
fill_checksum(UDP_CHECKSUM_H_P, IP_SRC_P, 16 + datalen,1);
packetSend(UDP_HEADER_LEN+IP_HEADER_LEN+ETH_HEADER_LEN+datalen);
}
void EtherCard::sendUdp (const char *data, uint8_t datalen, uint16_t sport,
const uint8_t *dip, uint16_t dport) {
udpPrepare(sport, dip, dport);
if (datalen>220)
datalen = 220;
memcpy(gPB + UDP_DATA_P, data, datalen);
udpTransmit(datalen);
}
void EtherCard::sendWol (uint8_t *wolmac) {
setMACandIPs(allOnes, allOnes);
gPB[ETH_TYPE_H_P] = ETHTYPE_IP_H_V;
gPB[ETH_TYPE_L_P] = ETHTYPE_IP_L_V;
memcpy_P(gPB + IP_P,iphdr,9);
gPB[IP_TOTLEN_L_P] = 0x82;
gPB[IP_PROTO_P] = IP_PROTO_UDP_V;
fill_ip_hdr_checksum();
gPB[UDP_DST_PORT_H_P] = 0;
gPB[UDP_DST_PORT_L_P] = 0x9; // wol = normally 9
gPB[UDP_SRC_PORT_H_P] = 10;
gPB[UDP_SRC_PORT_L_P] = 0x42; // source port does not matter
gPB[UDP_LEN_H_P] = 0;
gPB[UDP_LEN_L_P] = 110; // fixed len
gPB[UDP_CHECKSUM_H_P] = 0;
gPB[UDP_CHECKSUM_L_P] = 0;
copyMac(gPB + UDP_DATA_P, allOnes);
uint8_t pos = UDP_DATA_P;
for (uint8_t m = 0; m < 16; ++m) {
pos += 6;
copyMac(gPB + pos, wolmac);
}
fill_checksum(UDP_CHECKSUM_H_P, IP_SRC_P, 16 + 102,1);
packetSend(pos + 6);
}
// make a arp request
static void client_arp_whohas(uint8_t *ip_we_search) {
setMACs(allOnes);
gPB[ETH_TYPE_H_P] = ETHTYPE_ARP_H_V;
gPB[ETH_TYPE_L_P] = ETHTYPE_ARP_L_V;
memcpy_P(gPB + ETH_ARP_P,arpreqhdr,8);
memset(gPB + ETH_ARP_DST_MAC_P, 0, 6);
EtherCard::copyMac(gPB + ETH_ARP_SRC_MAC_P, EtherCard::mymac);
EtherCard::copyIp(gPB + ETH_ARP_DST_IP_P, ip_we_search);
EtherCard::copyIp(gPB + ETH_ARP_SRC_IP_P, EtherCard::myip);
waitgwmac |= WGW_ACCEPT_ARP_REPLY;
EtherCard::packetSend(42);
}
uint8_t EtherCard::clientWaitingGw () {
return !(waitgwmac & WGW_HAVE_GW_MAC);
}
static uint8_t client_store_gw_mac() {
if (memcmp(gPB + ETH_ARP_SRC_IP_P, EtherCard::gwip, 4) != 0)
return 0;
EtherCard::copyMac(gwmacaddr, gPB + ETH_ARP_SRC_MAC_P);
return 1;
}
// static void client_gw_arp_refresh() {
// if (waitgwmac & WGW_HAVE_GW_MAC)
// waitgwmac |= WGW_REFRESHING;
// }
void EtherCard::setGwIp (const uint8_t *gwipaddr) {
delaycnt = 0; //request gateway ARP lookup
waitgwmac = WGW_INITIAL_ARP; // causes an arp request in the packet loop
copyIp(gwip, gwipaddr);
}
void EtherCard::updateBroadcastAddress()
{
for(uint8_t i=0; i<4; i++)
broadcastip[i] = myip[i] | ~netmask[i];
}
static void client_syn(uint8_t srcport,uint8_t dstport_h,uint8_t dstport_l) {
setMACandIPs(gwmacaddr, EtherCard::hisip);
gPB[ETH_TYPE_H_P] = ETHTYPE_IP_H_V;
gPB[ETH_TYPE_L_P] = ETHTYPE_IP_L_V;
memcpy_P(gPB + IP_P,iphdr,9);
gPB[IP_TOTLEN_L_P] = 44; // good for syn
gPB[IP_PROTO_P] = IP_PROTO_TCP_V;
fill_ip_hdr_checksum();
gPB[TCP_DST_PORT_H_P] = dstport_h;
gPB[TCP_DST_PORT_L_P] = dstport_l;
gPB[TCP_SRC_PORT_H_P] = TCPCLIENT_SRC_PORT_H;
gPB[TCP_SRC_PORT_L_P] = srcport; // lower 8 bit of src port
memset(gPB + TCP_SEQ_H_P, 0, 8);
gPB[TCP_SEQ_H_P+2] = seqnum;
seqnum += 3;
gPB[TCP_HEADER_LEN_P] = 0x60; // 0x60=24 len: (0x60>>4) * 4
gPB[TCP_FLAGS_P] = TCP_FLAGS_SYN_V;
gPB[TCP_WIN_SIZE] = 0x3; // 1024 = 0x400 768 = 0x300, initial window
gPB[TCP_WIN_SIZE+1] = 0x0;
gPB[TCP_CHECKSUM_H_P] = 0;
gPB[TCP_CHECKSUM_L_P] = 0;
gPB[TCP_CHECKSUM_L_P+1] = 0;
gPB[TCP_CHECKSUM_L_P+2] = 0;
gPB[TCP_OPTIONS_P] = 2;
gPB[TCP_OPTIONS_P+1] = 4;
gPB[TCP_OPTIONS_P+2] = (CLIENTMSS>>8);
gPB[TCP_OPTIONS_P+3] = (uint8_t) CLIENTMSS;
fill_checksum(TCP_CHECKSUM_H_P, IP_SRC_P, 8 +TCP_HEADER_LEN_PLAIN+4,2);
// 4 is the tcp mss option:
EtherCard::packetSend(IP_HEADER_LEN+TCP_HEADER_LEN_PLAIN+ETH_HEADER_LEN+4);
}
uint8_t EtherCard::clientTcpReq (uint8_t (*result_cb)(uint8_t,uint8_t,uint16_t,uint16_t),
uint16_t (*datafill_cb)(uint8_t),uint16_t port) {
client_tcp_result_cb = result_cb;
client_tcp_datafill_cb = datafill_cb;
tcp_client_port_h = port>>8;
tcp_client_port_l = port;
tcp_client_state = 1; // Flag to packetloop to initiate a TCP/IP session by send a syn
tcp_fd = (tcp_fd + 1) & 7;
return tcp_fd;
}
static uint16_t www_client_internal_datafill_cb(uint8_t fd) {
BufferFiller bfill = EtherCard::tcpOffset();
if (fd==www_fd) {
if (client_postval == 0) {
bfill.emit_p(PSTR("GET $F$S HTTP/1.0\r\n"
"Host: $F\r\n"
"$F\r\n"
"\r\n"), client_urlbuf,
client_urlbuf_var,
client_hoststr, client_additionalheaderline);
} else {
const char* ahl = client_additionalheaderline;
const char* var = client_urlbuf_var;
bfill.emit_p(PSTR("POST $F$S HTTP/1.0\r\n"
"Host: $F\r\n"
"$F$S"
"Accept: */*\r\n"
"Content-Length: $D\r\n"
"Content-Type: application/json\r\n"
"\r\n"
"$S"), client_urlbuf,
var ? var : "",
client_hoststr,
ahl != 0 ? ahl : PSTR(""),
ahl != 0 ? "\r\n" : "",
strlen(client_postval),
client_postval);
}
}
return bfill.position();
}
static uint16_t www_client_internal_datafill_cb_ramhost(uint8_t fd) {
BufferFiller bfill = EtherCard::tcpOffset();
if (fd==www_fd) {
if (client_postval == 0) {
bfill.emit_p(PSTR("GET $F$S HTTP/1.0\r\n"
"Host: $S\r\n"
"$F\r\n"
"\r\n"), client_urlbuf,
client_urlbuf_var,
client_hoststr, client_additionalheaderline);
} else {
const char* ahl = client_additionalheaderline;
const char* var = client_urlbuf_var;
bfill.emit_p(PSTR("POST $F$S HTTP/1.0\r\n"
"Host: $S\r\n"
"$F$S"
"Accept: */*\r\n"
"Content-Length: $D\r\n"
"Content-Type: application/json\r\n"
"\r\n"
"$S"), client_urlbuf,
var ? var : "",
client_hoststr,
ahl != 0 ? ahl : PSTR(""),
ahl != 0 ? "\r\n" : "",
strlen(client_postval),
client_postval);
}
}
return bfill.position();
}
static uint8_t www_client_internal_result_cb(uint8_t fd, uint8_t statuscode, uint16_t datapos, uint16_t len_of_data) {
if (fd!=www_fd)
(*client_browser_cb)(4,0,0);
else if (statuscode==0 && len_of_data>12 && client_browser_cb) {
uint8_t f = strncmp("200",(char *)&(gPB[datapos+9]),3) != 0;
(*client_browser_cb)(f, ((uint16_t)TCP_SRC_PORT_H_P+(gPB[TCP_HEADER_LEN_P]>>4)*4),len_of_data);
}
return 0;
}
void EtherCard::browseUrl (const char *urlbuf, const char *urlbuf_varpart, const char *hoststr, void (*callback)(uint8_t,uint16_t,uint16_t)) {
browseUrl(urlbuf, urlbuf_varpart, hoststr, PSTR("Accept: text/html"), callback);
}
void EtherCard::browseUrlRamHost (const char *urlbuf, const char *urlbuf_varpart, const char *hoststr, void (*callback)(uint8_t,uint16_t,uint16_t)) {
browseUrlRamHost(urlbuf, urlbuf_varpart, hoststr, PSTR("Accept: text/html"), callback);
}
void EtherCard::browseUrl (const char *urlbuf, const char *urlbuf_varpart, const char *hoststr, const char *additionalheaderline, void (*callback)(uint8_t,uint16_t,uint16_t)) {
client_urlbuf = urlbuf;
client_urlbuf_var = urlbuf_varpart;
client_hoststr = hoststr;
client_additionalheaderline = additionalheaderline;
client_postval = 0;
client_browser_cb = callback;
www_fd = clientTcpReq(&www_client_internal_result_cb,&www_client_internal_datafill_cb,hisport);
}
void EtherCard::browseUrlRamHost (const char *urlbuf, const char *urlbuf_varpart, const char *hoststr, const char *additionalheaderline, void (*callback)(uint8_t,uint16_t,uint16_t)) {
client_urlbuf = urlbuf;
client_urlbuf_var = urlbuf_varpart;
client_hoststr = hoststr;
client_additionalheaderline = additionalheaderline;
client_postval = 0;
client_browser_cb = callback;
www_fd = clientTcpReq(&www_client_internal_result_cb,&www_client_internal_datafill_cb_ramhost,hisport);
}
void EtherCard::httpPost (const char *urlbuf, const char *hoststr, const char *additionalheaderline, const char *postval, void (*callback)(uint8_t,uint16_t,uint16_t)) {
client_urlbuf = urlbuf;
client_urlbuf_var = 0;
client_hoststr = hoststr;
client_additionalheaderline = additionalheaderline;
client_postval = postval;
client_browser_cb = callback;
www_fd = clientTcpReq(&www_client_internal_result_cb,&www_client_internal_datafill_cb,hisport);
}
void EtherCard::httpPostVar (const char *urlbuf, const char *hoststr, const char *urlbuf_varpart, const char *postval, void (*callback)(uint8_t,uint16_t,uint16_t)) {
client_urlbuf = urlbuf;
client_urlbuf_var = urlbuf_varpart;
client_hoststr = hoststr;
client_additionalheaderline = 0;
client_postval = postval;
client_browser_cb = callback;
www_fd = clientTcpReq(&www_client_internal_result_cb,&www_client_internal_datafill_cb,hisport);
}
static uint16_t tcp_datafill_cb(uint8_t fd) {
uint16_t len = Stash::length();
Stash::extract(0, len, EtherCard::tcpOffset());
Stash::cleanup();
EtherCard::tcpOffset()[len] = 0;
#if SERIAL
Serial.print("REQUEST: ");
Serial.println(len);
Serial.println((char*) EtherCard::tcpOffset());
#endif
result_fd = 123; // bogus value
return len;
}
static uint8_t tcp_result_cb(uint8_t fd, uint8_t status, uint16_t datapos, uint16_t datalen) {
if (status == 0) {
result_fd = fd; // a valid result has been received, remember its session id
result_ptr = (char*) ether.buffer + datapos;
// result_ptr[datalen] = 0;
}
return 1;
}
uint8_t EtherCard::tcpSend () {
www_fd = clientTcpReq(&tcp_result_cb, &tcp_datafill_cb, hisport);
return www_fd;
}
const char* EtherCard::tcpReply (uint8_t fd) {
if (result_fd != fd)
return 0;
result_fd = 123; // set to a bogus value to prevent future match
return result_ptr;
}
void EtherCard::registerPingCallback (void (*callback)(uint8_t *srcip)) {
icmp_cb = callback;
}
uint8_t EtherCard::packetLoopIcmpCheckReply (const uint8_t *ip_monitoredhost) {
return gPB[IP_PROTO_P]==IP_PROTO_ICMP_V &&
gPB[ICMP_TYPE_P]==ICMP_TYPE_ECHOREPLY_V &&
gPB[ICMP_DATA_P]== PINGPATTERN &&
check_ip_message_is_from(ip_monitoredhost);
}
uint16_t EtherCard::accept(const uint16_t port, uint16_t plen) {
uint16_t pos;
if (gPB[TCP_DST_PORT_H_P] == (port >> 8) &&
gPB[TCP_DST_PORT_L_P] == ((uint8_t) port))
{ //Packet targetted at specified port
if (gPB[TCP_FLAGS_P] & TCP_FLAGS_SYN_V)
make_tcp_synack_from_syn(); //send SYN+ACK
else if (gPB[TCP_FLAGS_P] & TCP_FLAGS_ACK_V)
{ //This is an acknowledgement to our SYN+ACK so let's start processing that payload
info_data_len = get_tcp_data_len();
if (info_data_len > 0)
{ //Got some data
pos = TCP_DATA_START; // TCP_DATA_START is a formula
if (pos <= plen - 8)
return pos;
}
else if (gPB[TCP_FLAGS_P] & TCP_FLAGS_FIN_V)
make_tcp_ack_from_any(0,0); //No data so close connection
}
}
return 0;
}
uint16_t EtherCard::packetLoop (uint16_t plen) {
uint16_t len;
if(using_dhcp){
ether.DhcpStateMachine(plen);
}
if (plen==0) {
//Check every 65536 (no-packet) cycles whether we need to retry ARP request for gateway
if ((waitgwmac & WGW_INITIAL_ARP || waitgwmac & WGW_REFRESHING) &&
delaycnt==0 && isLinkUp())
client_arp_whohas(gwip);
delaycnt++;
//Initiate TCP/IP session if pending
if (tcp_client_state==1 && (waitgwmac & WGW_HAVE_GW_MAC)) { // send a syn
tcp_client_state = 2;
tcpclient_src_port_l++; // allocate a new port
client_syn(((tcp_fd<<5) | (0x1f & tcpclient_src_port_l)),tcp_client_port_h,tcp_client_port_l);
}
return 0;
}
if (eth_type_is_arp_and_my_ip(plen))
{ //Service ARP request
if (gPB[ETH_ARP_OPCODE_L_P]==ETH_ARP_OPCODE_REQ_L_V)
make_arp_answer_from_request();
if (waitgwmac & WGW_ACCEPT_ARP_REPLY && (gPB[ETH_ARP_OPCODE_L_P]==ETH_ARP_OPCODE_REPLY_L_V) && client_store_gw_mac())
waitgwmac = WGW_HAVE_GW_MAC;
return 0;
}
if (eth_type_is_ip_and_my_ip(plen)==0)
{ //Not IP so ignoring
//!@todo Add other protocols (and make each optional at compile time)
return 0;
}
if (gPB[IP_PROTO_P]==IP_PROTO_ICMP_V && gPB[ICMP_TYPE_P]==ICMP_TYPE_ECHOREQUEST_V)
{ //Service ICMP echo request (ping)
if (icmp_cb)
(*icmp_cb)(&(gPB[IP_SRC_P]));
make_echo_reply_from_request(plen);
return 0;
}
if (ether.udpServerListening() && gPB[IP_PROTO_P]==IP_PROTO_UDP_V)
{ //Call UDP server handler (callback) if one is defined for this packet
if(ether.udpServerHasProcessedPacket(plen))
return 0; //An UDP server handler (callback) has processed this packet
}
if (plen<54 && gPB[IP_PROTO_P]!=IP_PROTO_TCP_V )
return 0; //Packet flagged as TCP but shorter than minimum TCP packet length
if (gPB[TCP_DST_PORT_H_P]==TCPCLIENT_SRC_PORT_H)
{ //Source port is in range reserved (by EtherCard) for client TCP/IP connections
if (check_ip_message_is_from(hisip)==0)
return 0; //Not current TCP/IP connection (only handle one at a time)
if (gPB[TCP_FLAGS_P] & TCP_FLAGS_RST_V)
{ //TCP reset flagged
if (client_tcp_result_cb)
(*client_tcp_result_cb)((gPB[TCP_DST_PORT_L_P]>>5)&0x7,3,0,0);
tcp_client_state = 5;
return 0;
}
len = get_tcp_data_len();
if (tcp_client_state==2)
{ //Waiting for SYN-ACK
if ((gPB[TCP_FLAGS_P] & TCP_FLAGS_SYN_V) && (gPB[TCP_FLAGS_P] &TCP_FLAGS_ACK_V))
{ //SYN and ACK flags set so this is an acknowledgement to our SYN
make_tcp_ack_from_any(0,0);
gPB[TCP_FLAGS_P] = TCP_FLAGS_ACK_V|TCP_FLAGS_PUSH_V;
if (client_tcp_datafill_cb)
len = (*client_tcp_datafill_cb)((gPB[TCP_SRC_PORT_L_P]>>5)&0x7);
else
len = 0;
tcp_client_state = 3;
make_tcp_ack_with_data_noflags(len);
}
else
{ //Expecting SYN+ACK so reset and resend SYN
tcp_client_state = 1; // retry
len++;
if (gPB[TCP_FLAGS_P] & TCP_FLAGS_ACK_V)
len = 0;
make_tcp_ack_from_any(len,TCP_FLAGS_RST_V);
}
return 0;
}
if (tcp_client_state==3 && len>0)
{ //TCP connection established so read data
if (client_tcp_result_cb) {
uint16_t tcpstart = TCP_DATA_START; // TCP_DATA_START is a formula
if (tcpstart>plen-8)
tcpstart = plen-8; // dummy but save
uint16_t save_len = len;
if (tcpstart+len>plen)
save_len = plen-tcpstart;
(*client_tcp_result_cb)((gPB[TCP_DST_PORT_L_P]>>5)&0x7,0,tcpstart,save_len); //Call TCP handler (callback) function
if(persist_tcp_connection)
{ //Keep connection alive by sending ACK
make_tcp_ack_from_any(len,TCP_FLAGS_PUSH_V);
}
else
{ //Close connection
make_tcp_ack_from_any(len,TCP_FLAGS_PUSH_V|TCP_FLAGS_FIN_V);
tcp_client_state = 6;
}
return 0;
}
}
if (tcp_client_state != 5)
{ //
if (gPB[TCP_FLAGS_P] & TCP_FLAGS_FIN_V) {
if(tcp_client_state == 3) {
return 0; // In some instances FIN is received *before* DATA. If that is the case, we just return here and keep looking for the data packet
}
make_tcp_ack_from_any(len+1,TCP_FLAGS_PUSH_V|TCP_FLAGS_FIN_V);
tcp_client_state = 6; // connection terminated
} else if (len>0) {
make_tcp_ack_from_any(len,0);
}
}
return 0;
}
//If we are here then this is a TCP/IP packet targetted at us and not related to out client connection so accept
return accept(hisport, plen);
}
void EtherCard::persistTcpConnection(bool persist){
persist_tcp_connection = persist;
}
#endif