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#include <assert.h>
#include <drivers/pit.h>
#include <network/bytes.h>
#include <network/ipv4.h>
#include <network/udp.h>
#include <socket.h>
extern uint8_t ip_address[4];
#define CWR (1 << 7)
#define ECE (1 << 6)
#define URG (1 << 5)
#define ACK (1 << 4)
#define PSH (1 << 3)
#define RST (1 << 2)
#define SYN (1 << 1)
#define FIN (1 << 0)
struct __attribute__((__packed__)) TCP_HEADER {
uint16_t src_port;
uint16_t dst_port;
uint32_t seq_num;
uint32_t ack_num;
uint8_t reserved : 4;
uint8_t data_offset : 4;
uint8_t flags;
uint16_t window_size;
uint16_t checksum;
uint16_t urgent_pointer;
};
struct __attribute__((__packed__)) PSEUDO_TCP_HEADER {
uint32_t src_addr;
uint32_t dst_addr;
uint8_t zero;
uint8_t protocol;
uint16_t tcp_length;
uint16_t src_port;
uint16_t dst_port;
uint32_t seq_num;
uint32_t ack_num;
uint8_t reserved : 4;
uint8_t data_offset : 4;
uint8_t flags;
uint16_t window_size;
uint16_t checksum_zero; // ?????
uint16_t urgent_pointer;
};
uint16_t tcp_checksum(uint16_t *buffer, int size) {
unsigned long cksum = 0;
while (size > 1) {
cksum += *buffer++;
size -= sizeof(uint16_t);
}
if (size)
cksum += *(uint8_t *)buffer;
cksum = (cksum >> 16) + (cksum & 0xffff);
cksum += (cksum >> 16);
return (uint16_t)(~cksum);
}
void tcp_calculate_checksum(uint8_t src_ip[4], uint8_t dst_ip[4],
const uint8_t *payload, uint16_t payload_length,
struct TCP_HEADER *header) {
struct PSEUDO_TCP_HEADER ps = {0};
memcpy(&ps.src_addr, src_ip, sizeof(uint32_t));
memcpy(&ps.dst_addr, dst_ip, sizeof(uint32_t));
ps.protocol = 6;
ps.tcp_length = htons(20 + payload_length);
ps.src_port = header->src_port;
ps.dst_port = header->dst_port;
ps.seq_num = header->seq_num;
ps.ack_num = header->ack_num;
ps.data_offset = header->data_offset;
ps.reserved = header->reserved;
ps.flags = header->flags;
ps.window_size = header->window_size;
ps.urgent_pointer = header->urgent_pointer;
// ps.options = 0;
int buffer_length = sizeof(ps) + payload_length;
uint8_t buffer[buffer_length];
memcpy(buffer, &ps, sizeof(ps));
memcpy(buffer + sizeof(ps), payload, payload_length);
header->checksum = tcp_checksum((uint16_t *)buffer, buffer_length);
}
void tcp_close_connection(struct INCOMING_TCP_CONNECTION *inc) {
struct TCP_HEADER header = {0};
header.src_port = htons(inc->dst_port);
header.dst_port = inc->n_port;
header.seq_num = htonl(inc->seq_num);
header.ack_num = htonl(inc->ack_num);
header.data_offset = 5;
header.reserved = 0;
header.flags = FIN | ACK;
header.window_size = htons(512);
header.urgent_pointer = 0;
uint32_t dst_ip;
memcpy(&dst_ip, inc->ip, sizeof(dst_ip));
uint8_t payload[0];
uint16_t payload_length = 0;
tcp_calculate_checksum(ip_address, inc->ip, (const uint8_t *)payload,
payload_length, &header);
int send_len = sizeof(header) + payload_length;
uint8_t send_buffer[send_len];
memcpy(send_buffer, &header, sizeof(header));
memcpy(send_buffer + sizeof(header), payload, payload_length);
send_ipv4_packet(dst_ip, 6, send_buffer, send_len);
}
void send_tcp_packet(struct INCOMING_TCP_CONNECTION *inc, uint8_t *payload,
uint16_t payload_length) {
struct TCP_HEADER header = {0};
header.src_port = htons(inc->dst_port);
header.dst_port = inc->n_port;
header.seq_num = htonl(inc->seq_num);
header.ack_num = htonl(inc->ack_num);
header.data_offset = 5;
header.reserved = 0;
header.flags = PSH | ACK;
header.window_size = htons(512);
header.urgent_pointer = 0;
uint32_t dst_ip;
memcpy(&dst_ip, inc->ip, sizeof(dst_ip));
tcp_calculate_checksum(ip_address, inc->ip, (const uint8_t *)payload,
payload_length, &header);
int send_len = sizeof(header) + payload_length;
uint8_t send_buffer[send_len];
memcpy(send_buffer, &header, sizeof(header));
memcpy(send_buffer + sizeof(header), payload, payload_length);
send_ipv4_packet(dst_ip, 6, send_buffer, send_len);
inc->seq_num += payload_length;
}
void send_empty_tcp_message(struct INCOMING_TCP_CONNECTION *inc, uint8_t flags,
uint32_t inc_seq_num, uint16_t n_dst_port,
uint16_t n_src_port) {
struct TCP_HEADER header = {0};
header.src_port = n_dst_port;
header.dst_port = n_src_port;
header.seq_num = 0;
header.ack_num = htonl(inc_seq_num + 1);
header.data_offset = 5;
header.reserved = 0;
header.flags = flags;
header.window_size = htons(512); // TODO: What does this actually mean?
header.urgent_pointer = 0;
char payload[0];
tcp_calculate_checksum(ip_address, inc->ip, (const uint8_t *)payload, 0,
&header);
uint32_t dst_ip;
memcpy(&dst_ip, inc->ip, sizeof(dst_ip));
send_ipv4_packet(dst_ip, 6, (const uint8_t *)&header, sizeof(header));
}
void handle_tcp(uint8_t src_ip[4], const uint8_t *payload,
uint32_t payload_length) {
const struct TCP_HEADER *inc_header = (const struct TCP_HEADER *)payload;
uint16_t n_src_port = *(uint16_t *)(payload);
uint16_t n_dst_port = *(uint16_t *)(payload + 2);
uint32_t n_seq_num = *(uint32_t *)(payload + 4);
uint32_t n_ack_num = *(uint32_t *)(payload + 8);
uint8_t flags = *(payload + 13);
uint16_t src_port = htons(n_src_port);
(void)src_port;
uint16_t dst_port = htons(n_dst_port);
uint32_t seq_num = htonl(n_seq_num);
uint32_t ack_num = htonl(n_ack_num);
(void)ack_num;
if (SYN == flags) {
kprintf("GOT SYN UPTIME: %d\n", pit_num_ms());
struct INCOMING_TCP_CONNECTION *inc;
if (!(inc = handle_incoming_tcp_connection(src_ip, n_src_port, dst_port)))
return;
memcpy(inc->ip, src_ip, sizeof(uint8_t[4]));
inc->seq_num = 0;
inc->ack_num = seq_num + 1;
inc->connection_closed = 0;
inc->requesting_connection_close = 0;
send_empty_tcp_message(inc, SYN | ACK, seq_num, n_dst_port, n_src_port);
inc->seq_num++;
return;
}
struct INCOMING_TCP_CONNECTION *inc =
get_incoming_tcp_connection(src_ip, n_src_port);
if (!inc)
return;
if (flags == (FIN | ACK)) {
if (inc->requesting_connection_close) {
send_empty_tcp_message(inc, ACK, seq_num, n_dst_port, n_src_port);
inc->connection_closed = 1;
} else {
send_empty_tcp_message(inc, FIN | ACK, seq_num, n_dst_port, n_src_port);
}
inc->seq_num++;
inc->connection_closed = 1;
return;
}
if (flags & ACK) {
// inc->seq_num = ack_num;
}
if (flags & PSH) {
kprintf("send ipv4 packet: %x\n", pit_num_ms());
uint16_t tcp_payload_length =
payload_length - inc_header->data_offset * sizeof(uint32_t);
fifo_object_write(
(uint8_t *)(payload + inc_header->data_offset * sizeof(uint32_t)), 0,
tcp_payload_length, inc->data_file);
// Send back a ACK
struct TCP_HEADER header = {0};
header.src_port = n_dst_port;
header.dst_port = n_src_port;
header.seq_num = htonl(inc->seq_num);
inc->ack_num = seq_num + tcp_payload_length;
header.ack_num = htonl(seq_num + tcp_payload_length);
header.data_offset = 5;
header.reserved = 0;
header.flags = ACK;
header.window_size = htons(512); // TODO: What does this actually mean?
header.urgent_pointer = 0;
char payload[0];
tcp_calculate_checksum(ip_address, src_ip, (const uint8_t *)payload, 0,
&header);
uint32_t dst_ip;
memcpy(&dst_ip, src_ip, sizeof(dst_ip));
send_ipv4_packet(dst_ip, 6, (const uint8_t *)&header, sizeof(header));
kprintf("after ipv4 packet: %x\n", pit_num_ms());
return;
}
}
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