net/tcp.c - mirrors/cros/chromiumos/third_party/u-boot - Git at Google

 // SPDX-License-Identifier: GPL-2.0
 /*
  * Copyright 2017 Duncan Hare, all rights reserved.
  */

 /*
  * General Desription:
  *
  * TCP support for the wget command, for fast file downloading.
  *
  * HTTP/TCP Receiver:
  *
  *      Prerequisites:  - own ethernet address
  *                      - own IP address
  *                      - Server IP address
  *                      - Server with TCP
  *                      - TCP application (eg wget)
  *      Next Step       HTTPS?
  */
 #include <common.h>
 #include <command.h>
 #include <console.h>
 #include <env_internal.h>
 #include <errno.h>
 #include <net.h>
 #include <net/tcp.h>

 /*
  * TCP sliding window  control used by us to request re-TX
  */
 static struct tcp_sack_v tcp_lost;

 /* TCP option timestamp */
 static u32 loc_timestamp;
 static u32 rmt_timestamp;

 static u32 tcp_seq_init;
 static u32 tcp_ack_edge;
 static u32 tcp_seq_max;

 static int tcp_activity_count;

 /*
  * Search for TCP_SACK and review the comments before the code section
  * TCP_SACK is the number of packets at the front of the stream
  */

 enum pkt_state {PKT, NOPKT};
 struct sack_r {
 	struct sack_edges se;
 	enum pkt_state st;
 };

 static struct sack_r edge_a[TCP_SACK];
 static unsigned int sack_idx;
 static unsigned int prev_len;

 /*
  * TCP lengths are stored as a rounded up number of 32 bit words.
  * Add 3 to length round up, rounded, then divided into the
  * length in 32 bit words.
  */
 #define LEN_B_TO_DW(x) ((x) >> 2)
 #define ROUND_TCPHDR_LEN(x) (LEN_B_TO_DW((x) + 3))
 #define SHIFT_TO_TCPHDRLEN_FIELD(x) ((x) << 4)
 #define GET_TCP_HDR_LEN_IN_BYTES(x) ((x) >> 2)

 /* TCP connection state */
 static enum tcp_state current_tcp_state;

 /* Current TCP RX packet handler */
 static rxhand_tcp *tcp_packet_handler;

 /**
  * tcp_get_tcp_state() - get current TCP state
  *
  * Return: Current TCP state
  */
 enum tcp_state tcp_get_tcp_state(void)
 {
 	return current_tcp_state;
 }

 /**
  * tcp_set_tcp_state() - set current TCP state
  * @new_state: new TCP state
  */
 void tcp_set_tcp_state(enum tcp_state new_state)
 {
 	current_tcp_state = new_state;
 }

 static void dummy_handler(uchar *pkt, unsigned int dport,
 			  struct in_addr sip, unsigned int sport,
 			  unsigned int len)
 {
 }

 /**
  * tcp_set_tcp_handler() - set a handler to receive data
  * @f: handler
  */
 void tcp_set_tcp_handler(rxhand_tcp *f)
 {
 	debug_cond(DEBUG_INT_STATE, "--- net_loop TCP handler set (%p)\n", f);
 	if (!f)
 		tcp_packet_handler = dummy_handler;
 	else
 		tcp_packet_handler = f;
 }

 /**
  * tcp_set_pseudo_header() - set TCP pseudo header
  * @pkt: the packet
  * @src: source IP address
  * @dest: destinaion IP address
  * @tcp_len: tcp length
  * @pkt_len: packet length
  *
  * Return: the checksum of the packet
  */
 u16 tcp_set_pseudo_header(uchar *pkt, struct in_addr src, struct in_addr dest,
 			  int tcp_len, int pkt_len)
 {
 	union tcp_build_pkt *b = (union tcp_build_pkt *)pkt;
 	int checksum_len;

 	/*
 	 * Pseudo header
 	 *
 	 * Zero the byte after the last byte so that the header checksum
 	 * will always work.
 	 */
 	pkt[pkt_len] = 0;

 	net_copy_ip((void *)&b->ph.p_src, &src);
 	net_copy_ip((void *)&b->ph.p_dst, &dest);
 	b->ph.rsvd = 0;
 	b->ph.p	= IPPROTO_TCP;
 	b->ph.len = htons(tcp_len);
 	checksum_len = tcp_len + PSEUDO_HDR_SIZE;

 	debug_cond(DEBUG_DEV_PKT,
 		   "TCP Pesudo  Header  (to=%pI4, from=%pI4, Len=%d)\n",
 		   &b->ph.p_dst, &b->ph.p_src, checksum_len);

 	return compute_ip_checksum(pkt + PSEUDO_PAD_SIZE, checksum_len);
 }

 /**
  * net_set_ack_options() - set TCP options in acknowledge packets
  * @b: the packet
  *
  * Return: TCP header length
  */
 int net_set_ack_options(union tcp_build_pkt *b)
 {
 	b->sack.hdr.tcp_hlen = SHIFT_TO_TCPHDRLEN_FIELD(LEN_B_TO_DW(TCP_HDR_SIZE));

 	b->sack.t_opt.kind = TCP_O_TS;
 	b->sack.t_opt.len = TCP_OPT_LEN_A;
 	b->sack.t_opt.t_snd = htons(loc_timestamp);
 	b->sack.t_opt.t_rcv = rmt_timestamp;
 	b->sack.sack_v.kind = TCP_1_NOP;
 	b->sack.sack_v.len = 0;

 	if (IS_ENABLED(CONFIG_PROT_TCP_SACK)) {
 		if (tcp_lost.len > TCP_OPT_LEN_2) {
 			debug_cond(DEBUG_DEV_PKT, "TCP ack opt lost.len %x\n",
 				   tcp_lost.len);
 			b->sack.sack_v.len = tcp_lost.len;
 			b->sack.sack_v.kind = TCP_V_SACK;
 			b->sack.sack_v.hill[0].l = htonl(tcp_lost.hill[0].l);
 			b->sack.sack_v.hill[0].r = htonl(tcp_lost.hill[0].r);

 			/*
 			 * These SACK structures are initialized with NOPs to
 			 * provide TCP header alignment padding. There are 4
 			 * SACK structures used for both header padding and
 			 * internally.
 			 */
 			b->sack.sack_v.hill[1].l = htonl(tcp_lost.hill[1].l);
 			b->sack.sack_v.hill[1].r = htonl(tcp_lost.hill[1].r);
 			b->sack.sack_v.hill[2].l = htonl(tcp_lost.hill[2].l);
 			b->sack.sack_v.hill[2].r = htonl(tcp_lost.hill[2].r);
 			b->sack.sack_v.hill[3].l = TCP_O_NOP;
 			b->sack.sack_v.hill[3].r = TCP_O_NOP;
 		}

 		b->sack.hdr.tcp_hlen = SHIFT_TO_TCPHDRLEN_FIELD(ROUND_TCPHDR_LEN(TCP_HDR_SIZE +
 										 TCP_TSOPT_SIZE +
 										 tcp_lost.len));
 	} else {
 		b->sack.sack_v.kind = 0;
 		b->sack.hdr.tcp_hlen = SHIFT_TO_TCPHDRLEN_FIELD(ROUND_TCPHDR_LEN(TCP_HDR_SIZE +
 										 TCP_TSOPT_SIZE));
 	}

 	/*
 	 * This returns the actual rounded up length of the
 	 * TCP header to add to the total packet length
 	 */

 	return GET_TCP_HDR_LEN_IN_BYTES(b->sack.hdr.tcp_hlen);
 }

 /**
  * net_set_ack_options() - set TCP options in SYN packets
  * @b: the packet
  */
 void net_set_syn_options(union tcp_build_pkt *b)
 {
 	if (IS_ENABLED(CONFIG_PROT_TCP_SACK))
 		tcp_lost.len = 0;

 	b->ip.hdr.tcp_hlen = 0xa0;

 	b->ip.mss.kind = TCP_O_MSS;
 	b->ip.mss.len = TCP_OPT_LEN_4;
 	b->ip.mss.mss = htons(TCP_MSS);
 	b->ip.scale.kind = TCP_O_SCL;
 	b->ip.scale.scale = TCP_SCALE;
 	b->ip.scale.len = TCP_OPT_LEN_3;
 	if (IS_ENABLED(CONFIG_PROT_TCP_SACK)) {
 		b->ip.sack_p.kind = TCP_P_SACK;
 		b->ip.sack_p.len = TCP_OPT_LEN_2;
 	} else {
 		b->ip.sack_p.kind = TCP_1_NOP;
 		b->ip.sack_p.len = TCP_1_NOP;
 	}
 	b->ip.t_opt.kind = TCP_O_TS;
 	b->ip.t_opt.len = TCP_OPT_LEN_A;
 	loc_timestamp = get_ticks();
 	rmt_timestamp = 0;
 	b->ip.t_opt.t_snd = 0;
 	b->ip.t_opt.t_rcv = 0;
 	b->ip.end = TCP_O_END;
 }

 int tcp_set_tcp_header(uchar *pkt, int dport, int sport, int payload_len,
 		       u8 action, u32 tcp_seq_num, u32 tcp_ack_num)
 {
 	union tcp_build_pkt *b = (union tcp_build_pkt *)pkt;
 	int pkt_hdr_len;
 	int pkt_len;
 	int tcp_len;

 	/*
 	 * Header: 5 32 bit words. 4 bits TCP header Length,
 	 *         4 bits reserved options
 	 */
 	b->ip.hdr.tcp_flags = action;
 	pkt_hdr_len = IP_TCP_HDR_SIZE;
 	b->ip.hdr.tcp_hlen = SHIFT_TO_TCPHDRLEN_FIELD(LEN_B_TO_DW(TCP_HDR_SIZE));

 	switch (action) {
 	case TCP_SYN:
 		debug_cond(DEBUG_DEV_PKT,
 			   "TCP Hdr:SYN (%pI4, %pI4, sq=%d, ak=%d)\n",
 			   &net_server_ip, &net_ip,
 			   tcp_seq_num, tcp_ack_num);
 		tcp_activity_count = 0;
 		net_set_syn_options(b);
 		tcp_seq_num = 0;
 		tcp_ack_num = 0;
 		pkt_hdr_len = IP_TCP_O_SIZE;
 		if (current_tcp_state == TCP_SYN_SENT) {  /* Too many SYNs */
 			action = TCP_FIN;
 			current_tcp_state = TCP_FIN_WAIT_1;
 		} else {
 			current_tcp_state = TCP_SYN_SENT;
 		}
 		break;
 	case TCP_ACK:
 		pkt_hdr_len = IP_HDR_SIZE + net_set_ack_options(b);
 		b->ip.hdr.tcp_flags = action;
 		debug_cond(DEBUG_DEV_PKT,
 			   "TCP Hdr:ACK (%pI4, %pI4, s=%d, a=%d, A=%x)\n",
 			   &net_server_ip, &net_ip, tcp_seq_num, tcp_ack_num,
 			   action);
 		break;
 	case TCP_FIN:
 		debug_cond(DEBUG_DEV_PKT,
 			   "TCP Hdr:FIN  (%pI4, %pI4, s=%d, a=%d)\n",
 			   &net_server_ip, &net_ip, tcp_seq_num, tcp_ack_num);
 		payload_len = 0;
 		pkt_hdr_len = IP_TCP_HDR_SIZE;
 		current_tcp_state = TCP_FIN_WAIT_1;
 		break;

 	/* Notify connection closing */

 	case (TCP_FIN | TCP_ACK):
 	case (TCP_FIN | TCP_ACK | TCP_PUSH):
 		if (current_tcp_state == TCP_CLOSE_WAIT)
 			current_tcp_state = TCP_CLOSING;

 		tcp_ack_edge++;
 		debug_cond(DEBUG_DEV_PKT,
 			   "TCP Hdr:FIN ACK PSH(%pI4, %pI4, s=%d, a=%d, A=%x)\n",
 			   &net_server_ip, &net_ip,
 			   tcp_seq_num, tcp_ack_edge, action);
 		fallthrough;
 	default:
 		pkt_hdr_len = IP_HDR_SIZE + net_set_ack_options(b);
 		b->ip.hdr.tcp_flags = action | TCP_PUSH | TCP_ACK;
 		debug_cond(DEBUG_DEV_PKT,
 			   "TCP Hdr:dft  (%pI4, %pI4, s=%d, a=%d, A=%x)\n",
 			   &net_server_ip, &net_ip,
 			   tcp_seq_num, tcp_ack_num, action);
 	}

 	pkt_len	= pkt_hdr_len + payload_len;
 	tcp_len	= pkt_len - IP_HDR_SIZE;

 	/* TCP Header */
 	b->ip.hdr.tcp_ack = htonl(tcp_ack_edge);
 	b->ip.hdr.tcp_src = htons(sport);
 	b->ip.hdr.tcp_dst = htons(dport);
 	b->ip.hdr.tcp_seq = htonl(tcp_seq_num);
 	tcp_seq_num = tcp_seq_num + payload_len;

 	/*
 	 * TCP window size - TCP header variable tcp_win.
 	 * Change tcp_win only if you have an understanding of network
 	 * overrun, congestion, TCP segment sizes, TCP windows, TCP scale,
 	 * queuing theory  and packet buffering. If there are too few buffers,
 	 * there will be data loss, recovery may work or the sending TCP,
 	 * the server, could abort the stream transmission.
 	 * MSS is governed by maximum Ethernet frame length.
 	 * The number of buffers is governed by the desire to have a queue of
 	 * full buffers to be processed at the destination to maximize
 	 * throughput. Temporary memory use for the boot phase on modern
 	 * SOCs is may not be considered a constraint to buffer space, if
 	 * it is, then the u-boot tftp or nfs kernel netboot should be
 	 * considered.
 	 */
 	b->ip.hdr.tcp_win = htons(PKTBUFSRX * TCP_MSS >> TCP_SCALE);

 	b->ip.hdr.tcp_xsum = 0;
 	b->ip.hdr.tcp_ugr = 0;

 	b->ip.hdr.tcp_xsum = tcp_set_pseudo_header(pkt, net_ip, net_server_ip,
 						   tcp_len, pkt_len);

 	net_set_ip_header((uchar *)&b->ip, net_server_ip, net_ip,
 			  pkt_len, IPPROTO_TCP);

 	return pkt_hdr_len;
 }

 /**
  * tcp_hole() - Selective Acknowledgment (Essential for fast stream transfer)
  * @tcp_seq_num: TCP sequence start number
  * @len: the length of sequence numbers
  * @tcp_seq_max: maximum of sequence numbers
  */
 void tcp_hole(u32 tcp_seq_num, u32 len, u32 tcp_seq_max)
 {
 	u32 idx_sack, sack_in;
 	u32 sack_end = TCP_SACK - 1;
 	u32 hill = 0;
 	enum pkt_state expect = PKT;
 	u32 seq = tcp_seq_num - tcp_seq_init;
 	u32 hol_l = tcp_ack_edge - tcp_seq_init;
 	u32 hol_r = 0;

 	/* Place new seq number in correct place in receive array */
 	if (prev_len == 0)
 		prev_len = len;

 	idx_sack = sack_idx + ((tcp_seq_num - tcp_ack_edge) / prev_len);
 	if (idx_sack < TCP_SACK) {
 		edge_a[idx_sack].se.l = tcp_seq_num;
 		edge_a[idx_sack].se.r = tcp_seq_num + len;
 		edge_a[idx_sack].st = PKT;

 		/*
 		 * The fin (last) packet is not the same length as data
 		 * packets, and if it's length is recorded and used for
 		 *  array index calculation, calculation breaks.
 		 */
 		if (prev_len < len)
 			prev_len = len;
 	}

 	debug_cond(DEBUG_DEV_PKT,
 		   "TCP 1 seq %d, edg %d, len %d, sack_idx %d, sack_end %d\n",
 		    seq, hol_l, len, sack_idx, sack_end);

 	/* Right edge of contiguous stream, is the left edge of first hill */
 	hol_l = tcp_seq_num - tcp_seq_init;
 	hol_r = hol_l + len;

 	if (IS_ENABLED(CONFIG_PROT_TCP_SACK))
 		tcp_lost.len = TCP_OPT_LEN_2;

 	debug_cond(DEBUG_DEV_PKT,
 		   "TCP 1 in %d, seq %d, pkt_l %d, pkt_r %d, sack_idx %d, sack_end %d\n",
 		   idx_sack, seq, hol_l, hol_r, sack_idx, sack_end);

 	for (sack_in = sack_idx; sack_in < sack_end && hill < TCP_SACK_HILLS;
 	     sack_in++)  {
 		switch (expect) {
 		case NOPKT:
 			switch (edge_a[sack_in].st) {
 			case NOPKT:
 				debug_cond(DEBUG_INT_STATE, "N");
 				break;
 			case PKT:
 				debug_cond(DEBUG_INT_STATE, "n");
 				if (IS_ENABLED(CONFIG_PROT_TCP_SACK)) {
 					tcp_lost.hill[hill].l =
 						edge_a[sack_in].se.l;
 					tcp_lost.hill[hill].r =
 						edge_a[sack_in].se.r;
 				}
 				expect = PKT;
 				break;
 			}
 			break;
 		case PKT:
 			switch (edge_a[sack_in].st) {
 			case NOPKT:
 				debug_cond(DEBUG_INT_STATE, "p");
 				if (sack_in > sack_idx &&
 				    hill < TCP_SACK_HILLS) {
 					hill++;
 					if (IS_ENABLED(CONFIG_PROT_TCP_SACK))
 						tcp_lost.len += TCP_OPT_LEN_8;
 				}
 				expect = NOPKT;
 				break;
 			case PKT:
 				debug_cond(DEBUG_INT_STATE, "P");

 				if (tcp_ack_edge == edge_a[sack_in].se.l) {
 					tcp_ack_edge = edge_a[sack_in].se.r;
 					edge_a[sack_in].st = NOPKT;
 					sack_idx++;
 				} else {
 					if (IS_ENABLED(CONFIG_PROT_TCP_SACK) &&
 					    hill < TCP_SACK_HILLS)
 						tcp_lost.hill[hill].r =
 							edge_a[sack_in].se.r;
 				if (IS_ENABLED(CONFIG_PROT_TCP_SACK) &&
 				    sack_in == sack_end - 1)
 					tcp_lost.hill[hill].r =
 						edge_a[sack_in].se.r;
 				}
 				break;
 			}
 			break;
 		}
 	}
 	debug_cond(DEBUG_INT_STATE, "\n");
 	if (!IS_ENABLED(CONFIG_PROT_TCP_SACK) || tcp_lost.len <= TCP_OPT_LEN_2)
 		sack_idx = 0;
 }

 /**
  * tcp_parse_options() - parsing TCP options
  * @o: pointer to the option field.
  * @o_len: length of the option field.
  */
 void tcp_parse_options(uchar *o, int o_len)
 {
 	struct tcp_t_opt  *tsopt;
 	uchar *p = o;

 	/*
 	 * NOPs are options with a zero length, and thus are special.
 	 * All other options have length fields.
 	 */
 	for (p = o; p < (o + o_len); p = p + p[1]) {
 		if (!p[1])
 			return; /* Finished processing options */

 		switch (p[0]) {
 		case TCP_O_END:
 			return;
 		case TCP_O_MSS:
 		case TCP_O_SCL:
 		case TCP_P_SACK:
 		case TCP_V_SACK:
 			break;
 		case TCP_O_TS:
 			tsopt = (struct tcp_t_opt *)p;
 			rmt_timestamp = tsopt->t_snd;
 			return;
 		}

 		/* Process optional NOPs */
 		if (p[0] == TCP_O_NOP)
 			p++;
 	}
 }

 static u8 tcp_state_machine(u8 tcp_flags, u32 *tcp_seq_num, int payload_len)
 {
 	u8 tcp_fin = tcp_flags & TCP_FIN;
 	u8 tcp_syn = tcp_flags & TCP_SYN;
 	u8 tcp_rst = tcp_flags & TCP_RST;
 	u8 tcp_push = tcp_flags & TCP_PUSH;
 	u8 tcp_ack = tcp_flags & TCP_ACK;
 	u8 action = TCP_DATA;
 	int i;

 	/*
 	 * tcp_flags are examined to determine TX action in a given state
 	 * tcp_push is interpreted to mean "inform the app"
 	 * urg, ece, cer and nonce flags are not supported.
 	 *
 	 * exe and crw are use to signal and confirm knowledge of congestion.
 	 * This TCP only sends a file request and acks. If it generates
 	 * congestion, the network is broken.
 	 */
 	debug_cond(DEBUG_INT_STATE, "TCP STATE ENTRY %x\n", action);
 	if (tcp_rst) {
 		action = TCP_DATA;
 		current_tcp_state = TCP_CLOSED;
 		net_set_state(NETLOOP_FAIL);
 		debug_cond(DEBUG_INT_STATE, "TCP Reset %x\n", tcp_flags);
 		return TCP_RST;
 	}

 	switch  (current_tcp_state) {
 	case TCP_CLOSED:
 		debug_cond(DEBUG_INT_STATE, "TCP CLOSED %x\n", tcp_flags);
 		if (tcp_ack)
 			action = TCP_DATA;
 		else if (tcp_syn)
 			action = TCP_RST;
 		else if (tcp_fin)
 			action = TCP_DATA;
 		break;
 	case TCP_SYN_SENT:
 		debug_cond(DEBUG_INT_STATE, "TCP_SYN_SENT %x, %d\n",
 			   tcp_flags, *tcp_seq_num);
 		if (tcp_fin) {
 			action = action | TCP_PUSH;
 			current_tcp_state = TCP_CLOSE_WAIT;
 		}
 		if (tcp_syn) {
 			action = action | TCP_ACK | TCP_PUSH;
 			if (tcp_ack) {
 				tcp_seq_init = *tcp_seq_num;
 				*tcp_seq_num = *tcp_seq_num + 1;
 				tcp_seq_max = *tcp_seq_num;
 				tcp_ack_edge = *tcp_seq_num;
 				sack_idx = 0;
 				edge_a[sack_idx].se.l = *tcp_seq_num;
 				edge_a[sack_idx].se.r = *tcp_seq_num;
 				prev_len = 0;
 				current_tcp_state = TCP_ESTABLISHED;
 				for (i = 0; i < TCP_SACK; i++)
 					edge_a[i].st = NOPKT;
 			}
 		} else if (tcp_ack) {
 			action = TCP_DATA;
 		}

 		break;
 	case TCP_ESTABLISHED:
 		debug_cond(DEBUG_INT_STATE, "TCP_ESTABLISHED %x\n", tcp_flags);
 		if (*tcp_seq_num > tcp_seq_max)
 			tcp_seq_max = *tcp_seq_num;
 		if (payload_len > 0) {
 			tcp_hole(*tcp_seq_num, payload_len, tcp_seq_max);
 			tcp_fin = TCP_DATA;  /* cause standalone FIN */
 		}

 		if ((tcp_fin) &&
 		    (!IS_ENABLED(CONFIG_PROT_TCP_SACK) ||
 		     tcp_lost.len <= TCP_OPT_LEN_2)) {
 			action = action | TCP_FIN | TCP_PUSH | TCP_ACK;
 			current_tcp_state = TCP_CLOSE_WAIT;
 		} else if (tcp_ack) {
 			action = TCP_DATA;
 		}

 		if (tcp_syn)
 			action = TCP_ACK + TCP_RST;
 		else if (tcp_push)
 			action = action | TCP_PUSH;
 		break;
 	case TCP_CLOSE_WAIT:
 		debug_cond(DEBUG_INT_STATE, "TCP_CLOSE_WAIT (%x)\n", tcp_flags);
 		action = TCP_DATA;
 		break;
 	case TCP_FIN_WAIT_2:
 		debug_cond(DEBUG_INT_STATE, "TCP_FIN_WAIT_2 (%x)\n", tcp_flags);
 		if (tcp_ack) {
 			action = TCP_PUSH | TCP_ACK;
 			current_tcp_state = TCP_CLOSED;
 			puts("\n");
 		} else if (tcp_syn) {
 			action = TCP_DATA;
 		} else if (tcp_fin) {
 			action = TCP_DATA;
 		}
 		break;
 	case TCP_FIN_WAIT_1:
 		debug_cond(DEBUG_INT_STATE, "TCP_FIN_WAIT_1 (%x)\n", tcp_flags);
 		if (tcp_fin) {
 			action = TCP_ACK | TCP_FIN;
 			current_tcp_state = TCP_FIN_WAIT_2;
 		}
 		if (tcp_syn)
 			action = TCP_RST;
 		if (tcp_ack) {
 			current_tcp_state = TCP_CLOSED;
 			tcp_seq_num = tcp_seq_num + 1;
 		}
 		break;
 	case TCP_CLOSING:
 		debug_cond(DEBUG_INT_STATE, "TCP_CLOSING (%x)\n", tcp_flags);
 		if (tcp_ack) {
 			action = TCP_PUSH;
 			current_tcp_state = TCP_CLOSED;
 			puts("\n");
 		} else if (tcp_syn) {
 			action = TCP_RST;
 		} else if (tcp_fin) {
 			action = TCP_DATA;
 		}
 		break;
 	}
 	return action;
 }

 /**
  * rxhand_tcp_f() - process receiving data and call data handler.
  * @b: the packet
  * @pkt_len: the length of packet.
  */
 void rxhand_tcp_f(union tcp_build_pkt *b, unsigned int pkt_len)
 {
 	int tcp_len = pkt_len - IP_HDR_SIZE;
 	u16 tcp_rx_xsum = b->ip.hdr.ip_sum;
 	u8  tcp_action = TCP_DATA;
 	u32 tcp_seq_num, tcp_ack_num;
 	struct in_addr action_and_state;
 	int tcp_hdr_len, payload_len;

 	/* Verify IP header */
 	debug_cond(DEBUG_DEV_PKT,
 		   "TCP RX in RX Sum (to=%pI4, from=%pI4, len=%d)\n",
 		   &b->ip.hdr.ip_src, &b->ip.hdr.ip_dst, pkt_len);

 	b->ip.hdr.ip_src = net_server_ip;
 	b->ip.hdr.ip_dst = net_ip;
 	b->ip.hdr.ip_sum = 0;
 	if (tcp_rx_xsum != compute_ip_checksum(b, IP_HDR_SIZE)) {
 		debug_cond(DEBUG_DEV_PKT,
 			   "TCP RX IP xSum Error (%pI4, =%pI4, len=%d)\n",
 			   &net_ip, &net_server_ip, pkt_len);
 		return;
 	}

 	/* Build pseudo header and verify TCP header */
 	tcp_rx_xsum = b->ip.hdr.tcp_xsum;
 	b->ip.hdr.tcp_xsum = 0;
 	if (tcp_rx_xsum != tcp_set_pseudo_header((uchar *)b, b->ip.hdr.ip_src,
 						 b->ip.hdr.ip_dst, tcp_len,
 						 pkt_len)) {
 		debug_cond(DEBUG_DEV_PKT,
 			   "TCP RX TCP xSum Error (%pI4, %pI4, len=%d)\n",
 			   &net_ip, &net_server_ip, tcp_len);
 		return;
 	}

 	tcp_hdr_len = GET_TCP_HDR_LEN_IN_BYTES(b->ip.hdr.tcp_hlen);
 	payload_len = tcp_len - tcp_hdr_len;

 	if (tcp_hdr_len > TCP_HDR_SIZE)
 		tcp_parse_options((uchar *)b + IP_TCP_HDR_SIZE,
 				  tcp_hdr_len - TCP_HDR_SIZE);
 	/*
 	 * Incoming sequence and ack numbers are server's view of the numbers.
 	 * The app must swap the numbers when responding.
 	 */
 	tcp_seq_num = ntohl(b->ip.hdr.tcp_seq);
 	tcp_ack_num = ntohl(b->ip.hdr.tcp_ack);

 	/* Packets are not ordered. Send to app as received. */
 	tcp_action = tcp_state_machine(b->ip.hdr.tcp_flags,
 				       &tcp_seq_num, payload_len);

 	tcp_activity_count++;
 	if (tcp_activity_count > TCP_ACTIVITY) {
 		puts("| ");
 		tcp_activity_count = 0;
 	}

 	if ((tcp_action & TCP_PUSH) || payload_len > 0) {
 		debug_cond(DEBUG_DEV_PKT,
 			   "TCP Notify (action=%x, Seq=%d,Ack=%d,Pay%d)\n",
 			   tcp_action, tcp_seq_num, tcp_ack_num, payload_len);

 		action_and_state.s_addr = tcp_action;
 		(*tcp_packet_handler) ((uchar *)b + pkt_len - payload_len,
 				       tcp_seq_num, action_and_state,
 				       tcp_ack_num, payload_len);

 	} else if (tcp_action != TCP_DATA) {
 		debug_cond(DEBUG_DEV_PKT,
 			   "TCP Action (action=%x,Seq=%d,Ack=%d,Pay=%d)\n",
 			   tcp_action, tcp_seq_num, tcp_ack_num, payload_len);

 		/*
 		 * Warning: Incoming Ack & Seq sequence numbers are transposed
 		 * here to outgoing Seq & Ack sequence numbers
 		 */
 		net_send_tcp_packet(0, ntohs(b->ip.hdr.tcp_src),
 				    ntohs(b->ip.hdr.tcp_dst),
 				    (tcp_action & (~TCP_PUSH)),
 				    tcp_seq_num, tcp_ack_num);
 	}
 }
	// SPDX-License-Identifier: GPL-2.0
	/*
	* Copyright 2017 Duncan Hare, all rights reserved.
	*/

	/*
	* General Desription:
	*
	* TCP support for the wget command, for fast file downloading.
	*
	* HTTP/TCP Receiver:
	*
	* Prerequisites: - own ethernet address
	* - own IP address
	* - Server IP address
	* - Server with TCP
	* - TCP application (eg wget)
	* Next Step HTTPS?
	*/
	#include <common.h>
	#include <command.h>
	#include <console.h>
	#include <env_internal.h>
	#include <errno.h>
	#include <net.h>
	#include <net/tcp.h>

	/*
	* TCP sliding window control used by us to request re-TX
	*/
	static struct tcp_sack_v tcp_lost;

	/* TCP option timestamp */
	static u32 loc_timestamp;
	static u32 rmt_timestamp;

	static u32 tcp_seq_init;
	static u32 tcp_ack_edge;
	static u32 tcp_seq_max;

	static int tcp_activity_count;

	/*
	* Search for TCP_SACK and review the comments before the code section
	* TCP_SACK is the number of packets at the front of the stream
	*/

	enum pkt_state {PKT, NOPKT};
	struct sack_r {
	struct sack_edges se;
	enum pkt_state st;
	};

	static struct sack_r edge_a[TCP_SACK];
	static unsigned int sack_idx;
	static unsigned int prev_len;

	/*
	* TCP lengths are stored as a rounded up number of 32 bit words.
	* Add 3 to length round up, rounded, then divided into the
	* length in 32 bit words.
	*/
	#define LEN_B_TO_DW(x) ((x) >> 2)
	#define ROUND_TCPHDR_LEN(x) (LEN_B_TO_DW((x) + 3))
	#define SHIFT_TO_TCPHDRLEN_FIELD(x) ((x) << 4)
	#define GET_TCP_HDR_LEN_IN_BYTES(x) ((x) >> 2)

	/* TCP connection state */
	static enum tcp_state current_tcp_state;

	/* Current TCP RX packet handler */
	static rxhand_tcp *tcp_packet_handler;

	/**
	* tcp_get_tcp_state() - get current TCP state
	*
	* Return: Current TCP state
	*/
	enum tcp_state tcp_get_tcp_state(void)
	{
	return current_tcp_state;
	}

	/**
	* tcp_set_tcp_state() - set current TCP state
	* @new_state: new TCP state
	*/
	void tcp_set_tcp_state(enum tcp_state new_state)
	{
	current_tcp_state = new_state;
	}

	static void dummy_handler(uchar *pkt, unsigned int dport,
	struct in_addr sip, unsigned int sport,
	unsigned int len)
	{
	}

	/**
	* tcp_set_tcp_handler() - set a handler to receive data
	* @f: handler
	*/
	void tcp_set_tcp_handler(rxhand_tcp *f)
	{
	debug_cond(DEBUG_INT_STATE, "--- net_loop TCP handler set (%p)\n", f);
	if (!f)
	tcp_packet_handler = dummy_handler;
	else
	tcp_packet_handler = f;
	}

	/**
	* tcp_set_pseudo_header() - set TCP pseudo header
	* @pkt: the packet
	* @src: source IP address
	* @dest: destinaion IP address
	* @tcp_len: tcp length
	* @pkt_len: packet length
	*
	* Return: the checksum of the packet
	*/
	u16 tcp_set_pseudo_header(uchar *pkt, struct in_addr src, struct in_addr dest,
	int tcp_len, int pkt_len)
	{
	union tcp_build_pkt b = (union tcp_build_pkt )pkt;
	int checksum_len;

	/*
	* Pseudo header
	*
	* Zero the byte after the last byte so that the header checksum
	* will always work.
	*/
	pkt[pkt_len] = 0;

	net_copy_ip((void *)&b->ph.p_src, &src);
	net_copy_ip((void *)&b->ph.p_dst, &dest);
	b->ph.rsvd = 0;
	b->ph.p = IPPROTO_TCP;
	b->ph.len = htons(tcp_len);
	checksum_len = tcp_len + PSEUDO_HDR_SIZE;

	debug_cond(DEBUG_DEV_PKT,
	"TCP Pesudo Header (to=%pI4, from=%pI4, Len=%d)\n",
	&b->ph.p_dst, &b->ph.p_src, checksum_len);

	return compute_ip_checksum(pkt + PSEUDO_PAD_SIZE, checksum_len);
	}

	/**
	* net_set_ack_options() - set TCP options in acknowledge packets
	* @b: the packet
	*
	* Return: TCP header length
	*/
	int net_set_ack_options(union tcp_build_pkt *b)
	{
	b->sack.hdr.tcp_hlen = SHIFT_TO_TCPHDRLEN_FIELD(LEN_B_TO_DW(TCP_HDR_SIZE));

	b->sack.t_opt.kind = TCP_O_TS;
	b->sack.t_opt.len = TCP_OPT_LEN_A;
	b->sack.t_opt.t_snd = htons(loc_timestamp);
	b->sack.t_opt.t_rcv = rmt_timestamp;
	b->sack.sack_v.kind = TCP_1_NOP;
	b->sack.sack_v.len = 0;

	if (IS_ENABLED(CONFIG_PROT_TCP_SACK)) {
	if (tcp_lost.len > TCP_OPT_LEN_2) {
	debug_cond(DEBUG_DEV_PKT, "TCP ack opt lost.len %x\n",
	tcp_lost.len);
	b->sack.sack_v.len = tcp_lost.len;
	b->sack.sack_v.kind = TCP_V_SACK;
	b->sack.sack_v.hill[0].l = htonl(tcp_lost.hill[0].l);
	b->sack.sack_v.hill[0].r = htonl(tcp_lost.hill[0].r);

	/*
	* These SACK structures are initialized with NOPs to
	* provide TCP header alignment padding. There are 4
	* SACK structures used for both header padding and
	* internally.
	*/
	b->sack.sack_v.hill[1].l = htonl(tcp_lost.hill[1].l);
	b->sack.sack_v.hill[1].r = htonl(tcp_lost.hill[1].r);
	b->sack.sack_v.hill[2].l = htonl(tcp_lost.hill[2].l);
	b->sack.sack_v.hill[2].r = htonl(tcp_lost.hill[2].r);
	b->sack.sack_v.hill[3].l = TCP_O_NOP;
	b->sack.sack_v.hill[3].r = TCP_O_NOP;
	}

	b->sack.hdr.tcp_hlen = SHIFT_TO_TCPHDRLEN_FIELD(ROUND_TCPHDR_LEN(TCP_HDR_SIZE +
	TCP_TSOPT_SIZE +
	tcp_lost.len));
	} else {
	b->sack.sack_v.kind = 0;
	b->sack.hdr.tcp_hlen = SHIFT_TO_TCPHDRLEN_FIELD(ROUND_TCPHDR_LEN(TCP_HDR_SIZE +
	TCP_TSOPT_SIZE));
	}

	/*
	* This returns the actual rounded up length of the
	* TCP header to add to the total packet length
	*/

	return GET_TCP_HDR_LEN_IN_BYTES(b->sack.hdr.tcp_hlen);
	}

	/**
	* net_set_ack_options() - set TCP options in SYN packets
	* @b: the packet
	*/
	void net_set_syn_options(union tcp_build_pkt *b)
	{
	if (IS_ENABLED(CONFIG_PROT_TCP_SACK))
	tcp_lost.len = 0;

	b->ip.hdr.tcp_hlen = 0xa0;

	b->ip.mss.kind = TCP_O_MSS;
	b->ip.mss.len = TCP_OPT_LEN_4;
	b->ip.mss.mss = htons(TCP_MSS);
	b->ip.scale.kind = TCP_O_SCL;
	b->ip.scale.scale = TCP_SCALE;
	b->ip.scale.len = TCP_OPT_LEN_3;
	if (IS_ENABLED(CONFIG_PROT_TCP_SACK)) {
	b->ip.sack_p.kind = TCP_P_SACK;
	b->ip.sack_p.len = TCP_OPT_LEN_2;
	} else {
	b->ip.sack_p.kind = TCP_1_NOP;
	b->ip.sack_p.len = TCP_1_NOP;
	}
	b->ip.t_opt.kind = TCP_O_TS;
	b->ip.t_opt.len = TCP_OPT_LEN_A;
	loc_timestamp = get_ticks();
	rmt_timestamp = 0;
	b->ip.t_opt.t_snd = 0;
	b->ip.t_opt.t_rcv = 0;
	b->ip.end = TCP_O_END;
	}

	int tcp_set_tcp_header(uchar *pkt, int dport, int sport, int payload_len,
	u8 action, u32 tcp_seq_num, u32 tcp_ack_num)
	{
	union tcp_build_pkt b = (union tcp_build_pkt )pkt;
	int pkt_hdr_len;
	int pkt_len;
	int tcp_len;

	/*
	* Header: 5 32 bit words. 4 bits TCP header Length,
	* 4 bits reserved options
	*/
	b->ip.hdr.tcp_flags = action;
	pkt_hdr_len = IP_TCP_HDR_SIZE;
	b->ip.hdr.tcp_hlen = SHIFT_TO_TCPHDRLEN_FIELD(LEN_B_TO_DW(TCP_HDR_SIZE));

	switch (action) {
	case TCP_SYN:
	debug_cond(DEBUG_DEV_PKT,
	"TCP Hdr:SYN (%pI4, %pI4, sq=%d, ak=%d)\n",
	&net_server_ip, &net_ip,
	tcp_seq_num, tcp_ack_num);
	tcp_activity_count = 0;
	net_set_syn_options(b);
	tcp_seq_num = 0;
	tcp_ack_num = 0;
	pkt_hdr_len = IP_TCP_O_SIZE;
	if (current_tcp_state == TCP_SYN_SENT) { /* Too many SYNs */
	action = TCP_FIN;
	current_tcp_state = TCP_FIN_WAIT_1;
	} else {
	current_tcp_state = TCP_SYN_SENT;
	}
	break;
	case TCP_ACK:
	pkt_hdr_len = IP_HDR_SIZE + net_set_ack_options(b);
	b->ip.hdr.tcp_flags = action;
	debug_cond(DEBUG_DEV_PKT,
	"TCP Hdr:ACK (%pI4, %pI4, s=%d, a=%d, A=%x)\n",
	&net_server_ip, &net_ip, tcp_seq_num, tcp_ack_num,
	action);
	break;
	case TCP_FIN:
	debug_cond(DEBUG_DEV_PKT,
	"TCP Hdr:FIN (%pI4, %pI4, s=%d, a=%d)\n",
	&net_server_ip, &net_ip, tcp_seq_num, tcp_ack_num);
	payload_len = 0;
	pkt_hdr_len = IP_TCP_HDR_SIZE;
	current_tcp_state = TCP_FIN_WAIT_1;
	break;

	/* Notify connection closing */

	case (TCP_FIN \| TCP_ACK):
	case (TCP_FIN \| TCP_ACK \| TCP_PUSH):
	if (current_tcp_state == TCP_CLOSE_WAIT)
	current_tcp_state = TCP_CLOSING;

	tcp_ack_edge++;
	debug_cond(DEBUG_DEV_PKT,
	"TCP Hdr:FIN ACK PSH(%pI4, %pI4, s=%d, a=%d, A=%x)\n",
	&net_server_ip, &net_ip,
	tcp_seq_num, tcp_ack_edge, action);
	fallthrough;
	default:
	pkt_hdr_len = IP_HDR_SIZE + net_set_ack_options(b);
	b->ip.hdr.tcp_flags = action \| TCP_PUSH \| TCP_ACK;
	debug_cond(DEBUG_DEV_PKT,
	"TCP Hdr:dft (%pI4, %pI4, s=%d, a=%d, A=%x)\n",
	&net_server_ip, &net_ip,
	tcp_seq_num, tcp_ack_num, action);
	}

	pkt_len = pkt_hdr_len + payload_len;
	tcp_len = pkt_len - IP_HDR_SIZE;

	/* TCP Header */
	b->ip.hdr.tcp_ack = htonl(tcp_ack_edge);
	b->ip.hdr.tcp_src = htons(sport);
	b->ip.hdr.tcp_dst = htons(dport);
	b->ip.hdr.tcp_seq = htonl(tcp_seq_num);
	tcp_seq_num = tcp_seq_num + payload_len;

	/*
	* TCP window size - TCP header variable tcp_win.
	* Change tcp_win only if you have an understanding of network
	* overrun, congestion, TCP segment sizes, TCP windows, TCP scale,
	* queuing theory and packet buffering. If there are too few buffers,
	* there will be data loss, recovery may work or the sending TCP,
	* the server, could abort the stream transmission.
	* MSS is governed by maximum Ethernet frame length.
	* The number of buffers is governed by the desire to have a queue of
	* full buffers to be processed at the destination to maximize
	* throughput. Temporary memory use for the boot phase on modern
	* SOCs is may not be considered a constraint to buffer space, if
	* it is, then the u-boot tftp or nfs kernel netboot should be
	* considered.
	*/
	b->ip.hdr.tcp_win = htons(PKTBUFSRX * TCP_MSS >> TCP_SCALE);

	b->ip.hdr.tcp_xsum = 0;
	b->ip.hdr.tcp_ugr = 0;

	b->ip.hdr.tcp_xsum = tcp_set_pseudo_header(pkt, net_ip, net_server_ip,
	tcp_len, pkt_len);

	net_set_ip_header((uchar *)&b->ip, net_server_ip, net_ip,
	pkt_len, IPPROTO_TCP);

	return pkt_hdr_len;
	}

	/**
	* tcp_hole() - Selective Acknowledgment (Essential for fast stream transfer)
	* @tcp_seq_num: TCP sequence start number
	* @len: the length of sequence numbers
	* @tcp_seq_max: maximum of sequence numbers
	*/
	void tcp_hole(u32 tcp_seq_num, u32 len, u32 tcp_seq_max)
	{
	u32 idx_sack, sack_in;
	u32 sack_end = TCP_SACK - 1;
	u32 hill = 0;
	enum pkt_state expect = PKT;
	u32 seq = tcp_seq_num - tcp_seq_init;
	u32 hol_l = tcp_ack_edge - tcp_seq_init;
	u32 hol_r = 0;

	/* Place new seq number in correct place in receive array */
	if (prev_len == 0)
	prev_len = len;

	idx_sack = sack_idx + ((tcp_seq_num - tcp_ack_edge) / prev_len);
	if (idx_sack < TCP_SACK) {
	edge_a[idx_sack].se.l = tcp_seq_num;
	edge_a[idx_sack].se.r = tcp_seq_num + len;
	edge_a[idx_sack].st = PKT;

	/*
	* The fin (last) packet is not the same length as data
	* packets, and if it's length is recorded and used for
	* array index calculation, calculation breaks.
	*/
	if (prev_len < len)
	prev_len = len;
	}

	debug_cond(DEBUG_DEV_PKT,
	"TCP 1 seq %d, edg %d, len %d, sack_idx %d, sack_end %d\n",
	seq, hol_l, len, sack_idx, sack_end);

	/* Right edge of contiguous stream, is the left edge of first hill */
	hol_l = tcp_seq_num - tcp_seq_init;
	hol_r = hol_l + len;

	if (IS_ENABLED(CONFIG_PROT_TCP_SACK))
	tcp_lost.len = TCP_OPT_LEN_2;

	debug_cond(DEBUG_DEV_PKT,
	"TCP 1 in %d, seq %d, pkt_l %d, pkt_r %d, sack_idx %d, sack_end %d\n",
	idx_sack, seq, hol_l, hol_r, sack_idx, sack_end);

	for (sack_in = sack_idx; sack_in < sack_end && hill < TCP_SACK_HILLS;
	sack_in++) {
	switch (expect) {
	case NOPKT:
	switch (edge_a[sack_in].st) {
	case NOPKT:
	debug_cond(DEBUG_INT_STATE, "N");
	break;
	case PKT:
	debug_cond(DEBUG_INT_STATE, "n");
	if (IS_ENABLED(CONFIG_PROT_TCP_SACK)) {
	tcp_lost.hill[hill].l =
	edge_a[sack_in].se.l;
	tcp_lost.hill[hill].r =
	edge_a[sack_in].se.r;
	}
	expect = PKT;
	break;
	}
	break;
	case PKT:
	switch (edge_a[sack_in].st) {
	case NOPKT:
	debug_cond(DEBUG_INT_STATE, "p");
	if (sack_in > sack_idx &&
	hill < TCP_SACK_HILLS) {
	hill++;
	if (IS_ENABLED(CONFIG_PROT_TCP_SACK))
	tcp_lost.len += TCP_OPT_LEN_8;
	}
	expect = NOPKT;
	break;
	case PKT:
	debug_cond(DEBUG_INT_STATE, "P");

	if (tcp_ack_edge == edge_a[sack_in].se.l) {
	tcp_ack_edge = edge_a[sack_in].se.r;
	edge_a[sack_in].st = NOPKT;
	sack_idx++;
	} else {
	if (IS_ENABLED(CONFIG_PROT_TCP_SACK) &&
	hill < TCP_SACK_HILLS)
	tcp_lost.hill[hill].r =
	edge_a[sack_in].se.r;
	if (IS_ENABLED(CONFIG_PROT_TCP_SACK) &&
	sack_in == sack_end - 1)
	tcp_lost.hill[hill].r =
	edge_a[sack_in].se.r;
	}
	break;
	}
	break;
	}
	}
	debug_cond(DEBUG_INT_STATE, "\n");
	if (!IS_ENABLED(CONFIG_PROT_TCP_SACK) \|\| tcp_lost.len <= TCP_OPT_LEN_2)
	sack_idx = 0;
	}

	/**
	* tcp_parse_options() - parsing TCP options
	* @o: pointer to the option field.
	* @o_len: length of the option field.
	*/
	void tcp_parse_options(uchar *o, int o_len)
	{
	struct tcp_t_opt *tsopt;
	uchar *p = o;

	/*
	* NOPs are options with a zero length, and thus are special.
	* All other options have length fields.
	*/
	for (p = o; p < (o + o_len); p = p + p[1]) {
	if (!p[1])
	return; /* Finished processing options */

	switch (p[0]) {
	case TCP_O_END:
	return;
	case TCP_O_MSS:
	case TCP_O_SCL:
	case TCP_P_SACK:
	case TCP_V_SACK:
	break;
	case TCP_O_TS:
	tsopt = (struct tcp_t_opt *)p;
	rmt_timestamp = tsopt->t_snd;
	return;
	}

	/* Process optional NOPs */
	if (p[0] == TCP_O_NOP)
	p++;
	}
	}

	static u8 tcp_state_machine(u8 tcp_flags, u32 *tcp_seq_num, int payload_len)
	{
	u8 tcp_fin = tcp_flags & TCP_FIN;
	u8 tcp_syn = tcp_flags & TCP_SYN;
	u8 tcp_rst = tcp_flags & TCP_RST;
	u8 tcp_push = tcp_flags & TCP_PUSH;
	u8 tcp_ack = tcp_flags & TCP_ACK;
	u8 action = TCP_DATA;
	int i;

	/*
	* tcp_flags are examined to determine TX action in a given state
	* tcp_push is interpreted to mean "inform the app"
	* urg, ece, cer and nonce flags are not supported.
	*
	* exe and crw are use to signal and confirm knowledge of congestion.
	* This TCP only sends a file request and acks. If it generates
	* congestion, the network is broken.
	*/
	debug_cond(DEBUG_INT_STATE, "TCP STATE ENTRY %x\n", action);
	if (tcp_rst) {
	action = TCP_DATA;
	current_tcp_state = TCP_CLOSED;
	net_set_state(NETLOOP_FAIL);
	debug_cond(DEBUG_INT_STATE, "TCP Reset %x\n", tcp_flags);
	return TCP_RST;
	}

	switch (current_tcp_state) {
	case TCP_CLOSED:
	debug_cond(DEBUG_INT_STATE, "TCP CLOSED %x\n", tcp_flags);
	if (tcp_ack)
	action = TCP_DATA;
	else if (tcp_syn)
	action = TCP_RST;
	else if (tcp_fin)
	action = TCP_DATA;
	break;
	case TCP_SYN_SENT:
	debug_cond(DEBUG_INT_STATE, "TCP_SYN_SENT %x, %d\n",
	tcp_flags, *tcp_seq_num);
	if (tcp_fin) {
	action = action \| TCP_PUSH;
	current_tcp_state = TCP_CLOSE_WAIT;
	}
	if (tcp_syn) {
	action = action \| TCP_ACK \| TCP_PUSH;
	if (tcp_ack) {
	tcp_seq_init = *tcp_seq_num;
	tcp_seq_num = tcp_seq_num + 1;
	tcp_seq_max = *tcp_seq_num;
	tcp_ack_edge = *tcp_seq_num;
	sack_idx = 0;
	edge_a[sack_idx].se.l = *tcp_seq_num;
	edge_a[sack_idx].se.r = *tcp_seq_num;
	prev_len = 0;
	current_tcp_state = TCP_ESTABLISHED;
	for (i = 0; i < TCP_SACK; i++)
	edge_a[i].st = NOPKT;
	}
	} else if (tcp_ack) {
	action = TCP_DATA;
	}

	break;
	case TCP_ESTABLISHED:
	debug_cond(DEBUG_INT_STATE, "TCP_ESTABLISHED %x\n", tcp_flags);
	if (*tcp_seq_num > tcp_seq_max)
	tcp_seq_max = *tcp_seq_num;
	if (payload_len > 0) {
	tcp_hole(*tcp_seq_num, payload_len, tcp_seq_max);
	tcp_fin = TCP_DATA; /* cause standalone FIN */
	}

	if ((tcp_fin) &&
	(!IS_ENABLED(CONFIG_PROT_TCP_SACK) \|\|
	tcp_lost.len <= TCP_OPT_LEN_2)) {
	action = action \| TCP_FIN \| TCP_PUSH \| TCP_ACK;
	current_tcp_state = TCP_CLOSE_WAIT;
	} else if (tcp_ack) {
	action = TCP_DATA;
	}

	if (tcp_syn)
	action = TCP_ACK + TCP_RST;
	else if (tcp_push)
	action = action \| TCP_PUSH;
	break;
	case TCP_CLOSE_WAIT:
	debug_cond(DEBUG_INT_STATE, "TCP_CLOSE_WAIT (%x)\n", tcp_flags);
	action = TCP_DATA;
	break;
	case TCP_FIN_WAIT_2:
	debug_cond(DEBUG_INT_STATE, "TCP_FIN_WAIT_2 (%x)\n", tcp_flags);
	if (tcp_ack) {
	action = TCP_PUSH \| TCP_ACK;
	current_tcp_state = TCP_CLOSED;
	puts("\n");
	} else if (tcp_syn) {
	action = TCP_DATA;
	} else if (tcp_fin) {
	action = TCP_DATA;
	}
	break;
	case TCP_FIN_WAIT_1:
	debug_cond(DEBUG_INT_STATE, "TCP_FIN_WAIT_1 (%x)\n", tcp_flags);
	if (tcp_fin) {
	action = TCP_ACK \| TCP_FIN;
	current_tcp_state = TCP_FIN_WAIT_2;
	}
	if (tcp_syn)
	action = TCP_RST;
	if (tcp_ack) {
	current_tcp_state = TCP_CLOSED;
	tcp_seq_num = tcp_seq_num + 1;
	}
	break;
	case TCP_CLOSING:
	debug_cond(DEBUG_INT_STATE, "TCP_CLOSING (%x)\n", tcp_flags);
	if (tcp_ack) {
	action = TCP_PUSH;
	current_tcp_state = TCP_CLOSED;
	puts("\n");
	} else if (tcp_syn) {
	action = TCP_RST;
	} else if (tcp_fin) {
	action = TCP_DATA;
	}
	break;
	}
	return action;
	}

	/**
	* rxhand_tcp_f() - process receiving data and call data handler.
	* @b: the packet
	* @pkt_len: the length of packet.
	*/
	void rxhand_tcp_f(union tcp_build_pkt *b, unsigned int pkt_len)
	{
	int tcp_len = pkt_len - IP_HDR_SIZE;
	u16 tcp_rx_xsum = b->ip.hdr.ip_sum;
	u8 tcp_action = TCP_DATA;
	u32 tcp_seq_num, tcp_ack_num;
	struct in_addr action_and_state;
	int tcp_hdr_len, payload_len;

	/* Verify IP header */
	debug_cond(DEBUG_DEV_PKT,
	"TCP RX in RX Sum (to=%pI4, from=%pI4, len=%d)\n",
	&b->ip.hdr.ip_src, &b->ip.hdr.ip_dst, pkt_len);

	b->ip.hdr.ip_src = net_server_ip;
	b->ip.hdr.ip_dst = net_ip;
	b->ip.hdr.ip_sum = 0;
	if (tcp_rx_xsum != compute_ip_checksum(b, IP_HDR_SIZE)) {
	debug_cond(DEBUG_DEV_PKT,
	"TCP RX IP xSum Error (%pI4, =%pI4, len=%d)\n",
	&net_ip, &net_server_ip, pkt_len);
	return;
	}

	/* Build pseudo header and verify TCP header */
	tcp_rx_xsum = b->ip.hdr.tcp_xsum;
	b->ip.hdr.tcp_xsum = 0;
	if (tcp_rx_xsum != tcp_set_pseudo_header((uchar *)b, b->ip.hdr.ip_src,
	b->ip.hdr.ip_dst, tcp_len,
	pkt_len)) {
	debug_cond(DEBUG_DEV_PKT,
	"TCP RX TCP xSum Error (%pI4, %pI4, len=%d)\n",
	&net_ip, &net_server_ip, tcp_len);
	return;
	}

	tcp_hdr_len = GET_TCP_HDR_LEN_IN_BYTES(b->ip.hdr.tcp_hlen);
	payload_len = tcp_len - tcp_hdr_len;

	if (tcp_hdr_len > TCP_HDR_SIZE)
	tcp_parse_options((uchar *)b + IP_TCP_HDR_SIZE,
	tcp_hdr_len - TCP_HDR_SIZE);
	/*
	* Incoming sequence and ack numbers are server's view of the numbers.
	* The app must swap the numbers when responding.
	*/
	tcp_seq_num = ntohl(b->ip.hdr.tcp_seq);
	tcp_ack_num = ntohl(b->ip.hdr.tcp_ack);

	/* Packets are not ordered. Send to app as received. */
	tcp_action = tcp_state_machine(b->ip.hdr.tcp_flags,
	&tcp_seq_num, payload_len);

	tcp_activity_count++;
	if (tcp_activity_count > TCP_ACTIVITY) {
	puts("\| ");
	tcp_activity_count = 0;
	}

	if ((tcp_action & TCP_PUSH) \|\| payload_len > 0) {
	debug_cond(DEBUG_DEV_PKT,
	"TCP Notify (action=%x, Seq=%d,Ack=%d,Pay%d)\n",
	tcp_action, tcp_seq_num, tcp_ack_num, payload_len);

	action_and_state.s_addr = tcp_action;
	(tcp_packet_handler) ((uchar )b + pkt_len - payload_len,
	tcp_seq_num, action_and_state,
	tcp_ack_num, payload_len);

	} else if (tcp_action != TCP_DATA) {
	debug_cond(DEBUG_DEV_PKT,
	"TCP Action (action=%x,Seq=%d,Ack=%d,Pay=%d)\n",
	tcp_action, tcp_seq_num, tcp_ack_num, payload_len);

	/*
	* Warning: Incoming Ack & Seq sequence numbers are transposed
	* here to outgoing Seq & Ack sequence numbers
	*/
	net_send_tcp_packet(0, ntohs(b->ip.hdr.tcp_src),
	ntohs(b->ip.hdr.tcp_dst),
	(tcp_action & (~TCP_PUSH)),
	tcp_seq_num, tcp_ack_num);
	}
	}