#include #include #include #include #include #include #include #include #include static uint32_t rtl_device_pci = 0x00000000; static void find_rtl(uint32_t device, uint16_t vendorid, uint16_t deviceid, void * extra) { if ((vendorid == 0x10ec) && (deviceid == 0x8139)) { *((uint32_t *)extra) = device; } } #define RTL_PORT_MAC 0x00 #define RTL_PORT_MAR 0x08 #define RTL_PORT_TXSTAT 0x10 #define RTL_PORT_TXBUF 0x20 #define RTL_PORT_RBSTART 0x30 #define RTL_PORT_CMD 0x37 #define RTL_PORT_RXPTR 0x38 #define RTL_PORT_RXADDR 0x3A #define RTL_PORT_IMR 0x3C #define RTL_PORT_ISR 0x3E #define RTL_PORT_TCR 0x40 #define RTL_PORT_RCR 0x44 #define RTL_PORT_RXMISS 0x4C #define RTL_PORT_CONFIG 0x52 static int rtl_irq = 0; static uint32_t rtl_iobase = 0; static uint8_t * rtl_rx_buffer; static uint8_t * rtl_tx_buffer[5]; static uint8_t mac[6]; static uint8_t * last_packet = NULL; static uintptr_t rtl_rx_phys; static uintptr_t rtl_tx_phys[5]; static uint32_t cur_rx = 0; static int dirty_tx = 0; static int next_tx = 0; static list_t * rx_wait; static fs_node_t * irc_socket; static uint32_t seq_no = 0xff0000; static uint32_t ack_no = 0x0; static volatile uint8_t _lock; static int next_tx_buf(void) { int out; spin_lock(&_lock); out = next_tx; next_tx++; if (next_tx == 4) { next_tx = 0; } spin_unlock(&_lock); return out; } struct netif { void *extra; void (*write_packet)(struct sized_blob * payload); uint8_t hwaddr[6]; uint32_t source; }; static size_t build_tcp_packet(uint8_t * buffer, struct netif * netif, struct tcp_socket * socket, struct sized_blob * payload, uint16_t flags) { size_t offset = 0; struct ethernet_packet eth_out = { .source = { netif->hwaddr[0], netif->hwaddr[1], netif->hwaddr[2], netif->hwaddr[3], netif->hwaddr[4], netif->hwaddr[5] }, .destination = { socket->mac[0], socket->mac[1], socket->mac[2], socket->mac[3], socket->mac[4], socket->mac[5] }, .type = htons(0x0800), }; memcpy(&buffer[offset], ð_out, sizeof(struct ethernet_packet)); offset += sizeof(struct ethernet_packet); /* Prepare the IPv4 header */ uint16_t _length = htons(sizeof(struct ipv4_packet) + sizeof(struct tcp_header) + payload->size); uint16_t _ident = htons(1); struct ipv4_packet ipv4_out = { .version_ihl = ((0x4 << 4) | (0x5 << 0)), /* 4 = ipv4, 5 = no options */ .dscp_ecn = 0, /* not setting either of those */ .length = _length, .ident = _ident, .flags_fragment = 0, .ttl = 0x40, /* ... */ .protocol = IPV4_PROT_TCP, .checksum = 0, /* fill this in later */ .source = htonl(netif->source), .destination = htonl(socket->ip), }; uint16_t checksum = calculate_ipv4_checksum(&ipv4_out); ipv4_out.checksum = htons(checksum); memcpy(&buffer[offset], &ipv4_out, sizeof(struct ipv4_packet)); offset += sizeof(struct ipv4_packet); struct tcp_header tcp = { .source_port = htons(socket->port_recv), /* Ephemeral port */ .destination_port = htons(socket->port_dest), /* IRC */ .seq_number = htonl(socket->seq_no), .ack_number = flags & (TCP_FLAGS_ACK) ? htonl(socket->ack_no) : 0, .flags = htons(flags), .window_size = htons(1800), .checksum = 0, .urgent = 0, }; struct tcp_check_header check_hd = { .source = ipv4_out.source, .destination = ipv4_out.destination, .zeros = 0, .protocol = 6, .tcp_len = htons(sizeof(tcp)+payload->size), }; uint16_t t = calculate_tcp_checksum(&check_hd, &tcp, payload, payload->size); tcp.checksum = htons(t); memcpy(&buffer[offset], &tcp, sizeof(struct tcp_header)); offset += sizeof(struct tcp_header); memcpy(&buffer[offset], payload, payload->size); offset += payload->size; return offset; } static size_t write_tcp_packet(uint8_t * buffer, uint8_t * payload, size_t payload_size, uint16_t flags) { size_t offset = 0; /* Then, let's write an ethernet frame */ struct ethernet_packet eth_out = { .source = { mac[0], mac[1], mac[2], mac[3], mac[4], mac[5] }, .destination = BROADCAST_MAC, .type = htons(0x0800), }; memcpy(&buffer[offset], ð_out, sizeof(struct ethernet_packet)); offset += sizeof(struct ethernet_packet); /* Prepare the IPv4 header */ uint16_t _length = htons(sizeof(struct ipv4_packet) + sizeof(struct tcp_header) + payload_size); uint16_t _ident = htons(1); struct ipv4_packet ipv4_out = { .version_ihl = ((0x4 << 4) | (0x5 << 0)), /* 4 = ipv4, 5 = no options */ .dscp_ecn = 0, /* not setting either of those */ .length = _length, .ident = _ident, .flags_fragment = 0, .ttl = 0x40, .protocol = IPV4_PROT_TCP, .checksum = 0, /* fill this in later */ .source = htonl(ip_aton("10.0.2.15")), .destination = htonl(ip_aton("37.48.83.75")), //.destination = htonl(ip_aton("204.28.125.145")), //.destination = htonl(ip_aton("192.168.1.145")), //.destination = htonl(ip_aton("107.170.207.248")), }; uint16_t checksum = calculate_ipv4_checksum(&ipv4_out); ipv4_out.checksum = htons(checksum); memcpy(&buffer[offset], &ipv4_out, sizeof(struct ipv4_packet)); offset += sizeof(struct ipv4_packet); struct tcp_header tcp = { .source_port = htons(56667), /* Ephemeral port */ .destination_port = htons(6667), /* IRC */ //.destination_port = htons(23), .seq_number = htonl(seq_no), .ack_number = flags & (TCP_FLAGS_ACK) ? htonl(ack_no) : 0, .flags = htons(flags), .window_size = htons(1800), .checksum = 0, .urgent = 0, }; struct tcp_check_header check_hd = { .source = ipv4_out.source, .destination = ipv4_out.destination, .zeros = 0, .protocol = 6, .tcp_len = htons(sizeof(tcp)+payload_size), }; uint16_t t = calculate_tcp_checksum(&check_hd, &tcp, payload, payload_size); tcp.checksum = htons(t); memcpy(&buffer[offset], &tcp, sizeof(struct tcp_header)); offset += sizeof(struct tcp_header); memcpy(&buffer[offset], payload, payload_size); offset += payload_size; return offset; } static size_t write_dhcp_packet(uint8_t * buffer) { size_t offset = 0; size_t payload_size = sizeof(struct dhcp_packet); /* First, let's figure out how big this is supposed to be... */ uint8_t dhcp_options[] = { 53, /* Message type */ 1, /* Length: 1 */ 1, /* Discover */ 255, /* END */ }; payload_size += sizeof(dhcp_options); /* Then, let's write an ethernet frame */ struct ethernet_packet eth_out = { .source = { mac[0], mac[1], mac[2], mac[3], mac[4], mac[5] }, .destination = BROADCAST_MAC, .type = htons(0x0800), }; memcpy(&buffer[offset], ð_out, sizeof(struct ethernet_packet)); offset += sizeof(struct ethernet_packet); /* Prepare the IPv4 header */ uint16_t _length = htons(sizeof(struct ipv4_packet) + sizeof(struct udp_packet) + payload_size); uint16_t _ident = htons(1); struct ipv4_packet ipv4_out = { .version_ihl = ((0x4 << 4) | (0x5 << 0)), /* 4 = ipv4, 5 = no options */ .dscp_ecn = 0, /* not setting either of those */ .length = _length, .ident = _ident, .flags_fragment = 0, .ttl = 0x40, .protocol = IPV4_PROT_UDP, .checksum = 0, /* fill this in later */ .source = htonl(ip_aton("0.0.0.0")), .destination = htonl(ip_aton("255.255.255.255")), }; uint16_t checksum = calculate_ipv4_checksum(&ipv4_out); ipv4_out.checksum = htons(checksum); memcpy(&buffer[offset], &ipv4_out, sizeof(struct ipv4_packet)); offset += sizeof(struct ipv4_packet); uint16_t _udp_source = htons(68); uint16_t _udp_destination = htons(67); uint16_t _udp_length = htons(sizeof(struct udp_packet) + payload_size); /* Now let's build a UDP packet */ struct udp_packet udp_out = { .source_port = _udp_source, .destination_port = _udp_destination, .length = _udp_length, .checksum = 0, }; /* XXX calculate checksum here */ memcpy(&buffer[offset], &udp_out, sizeof(struct udp_packet)); offset += sizeof(struct udp_packet); /* BOOTP headers */ struct dhcp_packet bootp_out = { .op = 1, .htype = 1, .hlen = 6, /* mac address... */ .hops = 0, .xid = htonl(0x1337), /* transaction id */ .secs = 0, .flags = 0, .ciaddr = 0x000000, .yiaddr = 0x000000, .siaddr = 0x000000, .giaddr = 0x000000, .chaddr = {mac[0], mac[1], mac[2], mac[3], mac[4], mac[5], 0x00}, .sname = {0}, .file = {0}, .magic = htonl(DHCP_MAGIC), }; memcpy(&buffer[offset], &bootp_out, sizeof(struct dhcp_packet)); offset += sizeof(struct dhcp_packet); memcpy(&buffer[offset], &dhcp_options, sizeof(dhcp_options)); offset += sizeof(dhcp_options); return offset; } static size_t write_dns_packet(uint8_t * buffer, size_t queries_len, uint8_t * queries) { size_t offset = 0; size_t payload_size = sizeof(struct dns_packet) + queries_len; /* Then, let's write an ethernet frame */ struct ethernet_packet eth_out = { .source = { mac[0], mac[1], mac[2], mac[3], mac[4], mac[5] }, .destination = BROADCAST_MAC, .type = htons(0x0800), }; memcpy(&buffer[offset], ð_out, sizeof(struct ethernet_packet)); offset += sizeof(struct ethernet_packet); /* Prepare the IPv4 header */ uint16_t _length = htons(sizeof(struct ipv4_packet) + sizeof(struct udp_packet) + payload_size); uint16_t _ident = htons(1); struct ipv4_packet ipv4_out = { .version_ihl = ((0x4 << 4) | (0x5 << 0)), /* 4 = ipv4, 5 = no options */ .dscp_ecn = 0, /* not setting either of those */ .length = _length, .ident = _ident, .flags_fragment = 0, .ttl = 0x40, .protocol = IPV4_PROT_UDP, .checksum = 0, /* fill this in later */ .source = htonl(ip_aton("10.0.2.15")), .destination = htonl(ip_aton("10.0.2.3")), }; uint16_t checksum = calculate_ipv4_checksum(&ipv4_out); ipv4_out.checksum = htons(checksum); memcpy(&buffer[offset], &ipv4_out, sizeof(struct ipv4_packet)); offset += sizeof(struct ipv4_packet); uint16_t _udp_source = htons(50053); /* Use an ephemeral port */ uint16_t _udp_destination = htons(53); uint16_t _udp_length = htons(sizeof(struct udp_packet) + payload_size); /* Now let's build a UDP packet */ struct udp_packet udp_out = { .source_port = _udp_source, .destination_port = _udp_destination, .length = _udp_length, .checksum = 0, }; /* XXX calculate checksum here */ memcpy(&buffer[offset], &udp_out, sizeof(struct udp_packet)); offset += sizeof(struct udp_packet); /* DNS header */ struct dns_packet dns_out = { .qid = htons(0), .flags = htons(0x0100), /* Standard query */ .questions = htons(1), /* 1 question */ .answers = htons(0), .authorities = htons(0), .additional = htons(0), }; memcpy(&buffer[offset], &dns_out, sizeof(struct dns_packet)); offset += sizeof(struct dns_packet); memcpy(&buffer[offset], queries, queries_len); offset += queries_len; return offset; } static char irc_input[400] = {'\0'}; static char irc_prompt[100] = {'\0'}; static char irc_nick[32] = {'\0'}; static char irc_payload[512]; static volatile uint8_t irc_tty_lock = 0; //static struct netif rtl_netif; static void irc_send(char * payload) { int my_tx = next_tx_buf(); int l = strlen(payload); size_t packet_size = write_tcp_packet(rtl_tx_buffer[my_tx], (uint8_t *)payload, l, (TCP_FLAGS_ACK | DATA_OFFSET_5)); outportl(rtl_iobase + RTL_PORT_TXBUF + 4 * my_tx, rtl_tx_phys[my_tx]); outportl(rtl_iobase + RTL_PORT_TXSTAT + 4 * my_tx, packet_size); } static void handle_irc_packet(fs_node_t * tty, size_t size, uint8_t * packet) { char * c = (char *)packet; while ((uintptr_t)c < (uintptr_t)packet + size) { char * e = strstr(c, "\r\n"); if ((uintptr_t)e > (uintptr_t)packet + size) { break; } spin_lock(&irc_tty_lock); if (!e) { /* XXX */ c[size-1] = '\0'; fprintf(tty, "\r\033[36m%s\033[0m\033[K\n", c); goto prompt_; } e[0] = '\0'; if (startswith(c, "PING")) { char tmp[100]; char * t = strstr(c, ":"); sprintf(tmp, "PONG %s\r\n", t); irc_send(tmp); goto prompt_; } char * user; char * command; char * channel; char * message; user = c; command = strstr(user, " "); if (!command) { fprintf(tty, "\r\033[36m%s\033[0m\033[K\n", user); goto prompt_; } command[0] = '\0'; command++; channel = strstr(command, " "); if (!channel) { fprintf(tty, "\r\033[36m%s %s\033[0m\033[K\n", user, command); goto prompt_; } channel[0] = '\0'; channel++; if (!strcmp(command, "PRIVMSG")) { message = strstr(channel, " "); if (!message) { fprintf(tty, "\r\033[36m%s %s %s\033[0m\033[K\n", user, command, channel); goto prompt_; } message[0] = '\0'; message++; if (message[0] == ':') { message++; } if (user[0] == ':') { user++; } char * t = strstr(user, "!"); if (t) { t[0] = '\0'; } t = strstr(user, "@"); if (t) { t[0] = '\0'; } uint16_t hr, min, sec; get_time(&hr, &min, &sec); if (startswith(message, "\001ACTION ")) { message = message + 8; char * x = strstr(message, "\001"); if (x) *x = '\0'; fprintf(tty, "\r%2d:%2d:%2d * \033[32m%s\033[0m:\033[34m%s\033[0m %s\033[K\n", hr, min, sec, user, channel, message); } else { fprintf(tty, "\r%2d:%2d:%2d \033[90m<\033[32m%s\033[0m:\033[34m%s\033[90m>\033[0m %s\033[K\n", hr, min, sec, user, channel, message); } } else { fprintf(tty, "\r\033[36m%s %s %s\033[0m\033[K\n", user, command, channel); } prompt_: /* Redraw prompt */ fprintf(tty, "%s", irc_prompt); fprintf(tty, "%s", irc_input); spin_unlock(&irc_tty_lock); if (!e) break; c = e + 2; } } static char * fgets(char * buf, int size, fs_node_t * stream) { char * x = buf; int collected = 0; while (collected < size) { int r = read_fs(stream, 0, 1, (unsigned char *)x); collected += r; if (r == -1) return NULL; if (!r) break; if (*x == '\n') break; x += r; } x++; *x = '\0'; return buf; } static void rtl_ircd(void * data, char * name) { fs_node_t * tty = data; char * buf = malloc(4096); while (1) { fgets(buf, 4096, irc_socket); size_t len = strlen(buf); handle_irc_packet(tty, len, (unsigned char *)buf); } } static size_t print_dns_name(fs_node_t * tty, struct dns_packet * dns, size_t offset) { uint8_t * bytes = (uint8_t *)dns; while (1) { uint8_t c = bytes[offset]; if (c == 0) { offset++; return offset; } else if (c >= 0xC0) { uint16_t ref = ((c - 0xC0) << 8) + bytes[offset+1]; print_dns_name(tty, dns, ref); offset++; offset++; return offset; } else { for (int i = 0; i < c; ++i) { fprintf(tty,"%c",bytes[offset+1+i]); } fprintf(tty,"."); offset += c + 1; } } } static void parse_dns_response(fs_node_t * tty, void * last_packet) { struct ethernet_packet * eth = (struct ethernet_packet *)last_packet; uint16_t eth_type = ntohs(eth->type); fprintf(tty, "Ethernet II, Src: (%2x:%2x:%2x:%2x:%2x:%2x), Dst: (%2x:%2x:%2x:%2x:%2x:%2x) [type=%4x)\n", eth->source[0], eth->source[1], eth->source[2], eth->source[3], eth->source[4], eth->source[5], eth->destination[0], eth->destination[1], eth->destination[2], eth->destination[3], eth->destination[4], eth->destination[5], eth_type); struct ipv4_packet * ipv4 = (struct ipv4_packet *)eth->payload; uint32_t src_addr = ntohl(ipv4->source); uint32_t dst_addr = ntohl(ipv4->destination); uint16_t length = ntohs(ipv4->length); char src_ip[16]; char dst_ip[16]; ip_ntoa(src_addr, src_ip); ip_ntoa(dst_addr, dst_ip); fprintf(tty, "IP packet [%s → %s] length=%d bytes\n", src_ip, dst_ip, length); struct udp_packet * udp = (struct udp_packet *)ipv4->payload; uint16_t src_port = ntohs(udp->source_port); uint16_t dst_port = ntohs(udp->destination_port); uint16_t udp_len = ntohs(udp->length); fprintf(tty, "UDP [%d → %d] length=%d bytes\n", src_port, dst_port, udp_len); struct dns_packet * dns = (struct dns_packet *)udp->payload; uint16_t dns_questions = ntohs(dns->questions); uint16_t dns_answers = ntohs(dns->answers); fprintf(tty, "DNS - %d queries, %d answers\n", dns_questions, dns_answers); fprintf(tty, "Queries:\n"); int offset = sizeof(struct dns_packet); int queries = 0; uint8_t * bytes = (uint8_t *)dns; while (queries < dns_questions) { offset = print_dns_name(tty, dns, offset); uint16_t * d = (uint16_t *)&bytes[offset]; fprintf(tty, " - Type: %4x %4x\n", ntohs(d[0]), ntohs(d[1])); offset += 4; queries++; } fprintf(tty, "Answers:\n"); int answers = 0; while (answers < dns_answers) { offset = print_dns_name(tty, dns, offset); uint16_t * d = (uint16_t *)&bytes[offset]; fprintf(tty, " - Type: %4x %4x; ", ntohs(d[0]), ntohs(d[1])); offset += 4; uint32_t * t = (uint32_t *)&bytes[offset]; fprintf(tty, "TTL: %d; ", ntohl(t[0])); offset += 4; uint16_t * l = (uint16_t *)&bytes[offset]; int _l = ntohs(l[0]); fprintf(tty, "len: %d; ", _l); offset += 2; if (_l == 4) { uint32_t * i = (uint32_t *)&bytes[offset]; char ip[16]; ip_ntoa(ntohl(i[0]), ip); fprintf(tty, " Address: %s\n", ip); } else { if (ntohs(d[0]) == 5) { fprintf(tty, "CNAME: "); print_dns_name(tty, dns, offset); fprintf(tty, "\n"); } else { fprintf(tty, "dunno\n"); } } offset += _l; answers++; } } static void rtl_irq_handler(struct regs *r) { uint16_t status = inports(rtl_iobase + RTL_PORT_ISR); outports(rtl_iobase + RTL_PORT_ISR, status); irq_ack(rtl_irq); if (status & 0x01 || status & 0x02) { /* Receive */ while((inportb(rtl_iobase + RTL_PORT_CMD) & 0x01) == 0) { int offset = cur_rx % 0x2000; #if 0 uint16_t buf_addr = inports(rtl_iobase + RTL_PORT_RXADDR); uint16_t buf_ptr = inports(rtl_iobase + RTL_PORT_RXPTR); uint8_t cmd = inportb(rtl_iobase + RTL_PORT_CMD); #endif uint32_t * buf_start = (uint32_t *)((uintptr_t)rtl_rx_buffer + offset); uint32_t rx_status = buf_start[0]; int rx_size = rx_status >> 16; if (rx_status & (0x0020 | 0x0010 | 0x0004 | 0x0002)) { debug_print(WARNING, "rx error :("); } else { uint8_t * buf_8 = (uint8_t *)&(buf_start[1]); last_packet = buf_8; } cur_rx = (cur_rx + rx_size + 4 + 3) & ~3; outports(rtl_iobase + RTL_PORT_RXPTR, cur_rx - 16); } wakeup_queue(rx_wait); } if (status & 0x08 || status & 0x04) { unsigned int i = inportl(rtl_iobase + RTL_PORT_TXSTAT + 4 * dirty_tx); (void)i; dirty_tx++; if (dirty_tx == 5) dirty_tx = 0; } } static void rtl_netd(void * data, char * name) { fs_node_t * tty = data; { fprintf(tty, "Sending DNS query...\n"); uint8_t queries[] = { 3,'i','r','c', 8,'f','r','e','e','n','o','d','e', 3,'n','e','t', 0, 0x00, 0x01, /* A */ 0x00, 0x01, /* IN */ }; int my_tx = next_tx_buf(); size_t packet_size = write_dns_packet(rtl_tx_buffer[my_tx], sizeof(queries), queries); outportl(rtl_iobase + RTL_PORT_TXBUF + 4 * my_tx, rtl_tx_phys[my_tx]); outportl(rtl_iobase + RTL_PORT_TXSTAT + 4 * my_tx, packet_size); } sleep_on(rx_wait); parse_dns_response(tty, last_packet); { fprintf(tty, "Sending DNS query...\n"); uint8_t queries[] = { 7,'n','y','a','n','c','a','t', 5,'d','a','k','k','o', 2,'u','s', 0, 0x00, 0x01, /* A */ 0x00, 0x01, /* IN */ }; int my_tx = next_tx_buf(); size_t packet_size = write_dns_packet(rtl_tx_buffer[my_tx], sizeof(queries), queries); outportl(rtl_iobase + RTL_PORT_TXBUF + 4 * my_tx, rtl_tx_phys[my_tx]); outportl(rtl_iobase + RTL_PORT_TXSTAT + 4 * my_tx, packet_size); } sleep_on(rx_wait); parse_dns_response(tty, last_packet); { fprintf(tty, "Sending TCP syn\n"); int my_tx = next_tx_buf(); uint8_t payload[] = { 0 }; size_t packet_size = write_tcp_packet(rtl_tx_buffer[my_tx], payload, 0, (TCP_FLAGS_SYN | DATA_OFFSET_5)); outportl(rtl_iobase + RTL_PORT_TXBUF + 4 * my_tx, rtl_tx_phys[my_tx]); outportl(rtl_iobase + RTL_PORT_TXSTAT + 4 * my_tx, packet_size); } sleep_on(rx_wait); { struct ethernet_packet * eth = (struct ethernet_packet *)last_packet; uint16_t eth_type = ntohs(eth->type); fprintf(tty, "Ethernet II, Src: (%2x:%2x:%2x:%2x:%2x:%2x), Dst: (%2x:%2x:%2x:%2x:%2x:%2x) [type=%4x)\n", eth->source[0], eth->source[1], eth->source[2], eth->source[3], eth->source[4], eth->source[5], eth->destination[0], eth->destination[1], eth->destination[2], eth->destination[3], eth->destination[4], eth->destination[5], eth_type); struct ipv4_packet * ipv4 = (struct ipv4_packet *)eth->payload; uint32_t src_addr = ntohl(ipv4->source); uint32_t dst_addr = ntohl(ipv4->destination); uint16_t length = ntohs(ipv4->length); char src_ip[16]; char dst_ip[16]; ip_ntoa(src_addr, src_ip); ip_ntoa(dst_addr, dst_ip); fprintf(tty, "IP packet [%s → %s] length=%d bytes\n", src_ip, dst_ip, length); struct tcp_header * tcp = (struct tcp_header *)ipv4->payload; ack_no = ntohl(tcp->seq_number) + 1; seq_no = ntohl(tcp->ack_number); } { fprintf(tty, "Sending TCP ack\n"); int my_tx = next_tx_buf(); uint8_t payload[] = { 0 }; size_t packet_size = write_tcp_packet(rtl_tx_buffer[my_tx], payload, 0, (TCP_FLAGS_ACK | DATA_OFFSET_5)); outportl(rtl_iobase + RTL_PORT_TXBUF + 4 * my_tx, rtl_tx_phys[my_tx]); outportl(rtl_iobase + RTL_PORT_TXSTAT + 4 * my_tx, packet_size); } irc_socket = make_pipe(4096); vfs_mount("/dev/net_irc", irc_socket); while (1) { sleep_on(rx_wait); { struct ethernet_packet * eth = (struct ethernet_packet *)last_packet; struct ipv4_packet * ipv4 = (struct ipv4_packet *)eth->payload; struct tcp_header * tcp = (struct tcp_header *)ipv4->payload; uint32_t l__ = ntohs(ipv4->length) - sizeof(struct tcp_header) - sizeof(struct ipv4_packet); if (ntohs(tcp->flags) & TCP_FLAGS_ACK) { seq_no = ntohl(tcp->ack_number); } ack_no = ntohl(tcp->seq_number) + l__; if (l__ < 0xFFFF) { /* Look up source port in table of sockets */ if (ntohs(tcp->source_port) == 6667) { write_fs(irc_socket, 0, l__, tcp->payload); } else { write_fs(tty, 0, l__, tcp->payload); } } } { int my_tx = next_tx_buf(); uint8_t payload[] = { 0 }; size_t packet_size = write_tcp_packet(rtl_tx_buffer[my_tx], payload, 0, (TCP_FLAGS_ACK | DATA_OFFSET_5)); outportl(rtl_iobase + RTL_PORT_TXBUF + 4 * my_tx, rtl_tx_phys[my_tx]); outportl(rtl_iobase + RTL_PORT_TXSTAT + 4 * my_tx, packet_size); } } } static int irc_readline(fs_node_t * dev, char * linebuf, int max) { int read = 0; tty_set_unbuffered(dev); while (read < max) { uint8_t buf[1]; int r = read_fs(dev, 0, 1, (unsigned char *)buf); if (!r) { debug_print(WARNING, "Read nothing?"); continue; } spin_lock(&irc_tty_lock); linebuf[read] = buf[0]; if (buf[0] == '\n') { linebuf[read] = 0; spin_unlock(&irc_tty_lock); break; } else if (buf[0] == 0x08) { if (read > 0) { fprintf(dev, "\010 \010"); read--; linebuf[read] = 0; } } else if (buf[0] < ' ') { switch (buf[0]) { case 0x0C: /* ^L */ /* Should reset display here */ spin_unlock(&irc_tty_lock); break; default: /* do nothing */ spin_unlock(&irc_tty_lock); break; } } else { fprintf(dev, "%c", buf[0]); read += r; } spin_unlock(&irc_tty_lock); } tty_set_buffered(dev); return read; } DEFINE_SHELL_FUNCTION(irc_test, "irc test") { char * payloads[] = { "NICK toarutest\r\nUSER toaru 0 * :Toaru Test\r\nJOIN #levchins\r\n\0\0\0", "PRIVMSG #levchins :99 bottles of beer on the wall\r\n\0\0", "PRIVMSG #levchins :99 bottles of beer\r\n\0\0", "PRIVMSG #levchins :Take one down\r\n\0\0", "PRIVMSG #levchins :pass it around\r\n\0\0", "PRIVMSG #levchins :98 bottles of beer on the wall\r\n\0\0", "PART #levchins :Thank you, and good night!\r\n\0\0", "QUIT\r\n\0\0", }; for (unsigned int i = 0; i < sizeof(payloads) / sizeof(uint8_t *); ++i) { int my_tx = next_tx_buf(); int l = strlen(payloads[i]); size_t packet_size = write_tcp_packet(rtl_tx_buffer[my_tx], (uint8_t *)payloads[i], l, (TCP_FLAGS_ACK | DATA_OFFSET_5)); outportl(rtl_iobase + RTL_PORT_TXBUF + 4 * my_tx, rtl_tx_phys[my_tx]); outportl(rtl_iobase + RTL_PORT_TXSTAT + 4 * my_tx, packet_size); unsigned long s, ss; relative_time(0, 500, &s, &ss); sleep_until((process_t *)current_process, s, ss); switch_task(0); } return 0; } DEFINE_SHELL_FUNCTION(irc_init, "irc connector") { if (argc < 2) { fprintf(tty, "Specify a username\n"); return 1; } memcpy(irc_nick, argv[1], strlen(argv[1])+1); sprintf(irc_payload, "NICK %s\r\nUSER %s * 0 :%s\r\n", irc_nick, irc_nick, irc_nick); irc_send(irc_payload); return 0; } DEFINE_SHELL_FUNCTION(irc_join, "irc channel tool") { if (argc < 2) { fprintf(tty, "Specify a channel.\n"); return 1; } char * channel = argv[1]; sprintf(irc_payload, "JOIN %s\r\n", channel); irc_send(irc_payload); sprintf(irc_prompt, "\r[%s] ", channel); while (1) { fprintf(tty, irc_prompt); int c = irc_readline(tty, irc_input, 400); spin_lock(&irc_tty_lock); irc_input[c] = '\0'; if (startswith(irc_input, "/part")) { fprintf(tty, "\n"); sprintf(irc_payload, "PART %s\r\n", channel); irc_send(irc_payload); spin_unlock(&irc_tty_lock); break; } if (startswith(irc_input, "/me ")) { char * m = strstr(irc_input, " "); m++; uint16_t hr, min, sec; get_time(&hr, &min, &sec); fprintf(tty, "\r%2d:%2d:%2d * \033[35m%s\033[0m:\033[34m%s\033[0m %s\n\033[K", hr, min, sec, irc_nick, channel, m); sprintf(irc_payload, "PRIVMSG %s :\1ACTION %s\1\r\n", channel, m); irc_send(irc_payload); } else { uint16_t hr, min, sec; get_time(&hr, &min, &sec); fprintf(tty, "\r%2d:%2d:%2d \033[90m<\033[35m%s\033[0m:\033[34m%s\033[90m>\033[0m %s\n\033[K", hr, min, sec, irc_nick, channel, irc_input); sprintf(irc_payload, "PRIVMSG %s :%s\r\n", channel, irc_input); irc_send(irc_payload); } memset(irc_input, 0x00, sizeof(irc_input)); spin_unlock(&irc_tty_lock); } memset(irc_prompt, 0x00, sizeof(irc_prompt)); memset(irc_input, 0x00, sizeof(irc_input)); return 0; } DEFINE_SHELL_FUNCTION(rtl, "rtl8139 experiments") { if (rtl_device_pci) { fprintf(tty, "Located an RTL 8139: 0x%x\n", rtl_device_pci); uint16_t command_reg = pci_read_field(rtl_device_pci, PCI_COMMAND, 4); fprintf(tty, "COMMAND register before: 0x%4x\n", command_reg); if (command_reg & (1 << 2)) { fprintf(tty, "Bus mastering already enabled.\n"); } else { command_reg |= (1 << 2); /* bit 2 */ fprintf(tty, "COMMAND register after: 0x%4x\n", command_reg); pci_write_field(rtl_device_pci, PCI_COMMAND, 4, command_reg); command_reg = pci_read_field(rtl_device_pci, PCI_COMMAND, 4); fprintf(tty, "COMMAND register after: 0x%4x\n", command_reg); } rtl_irq = pci_read_field(rtl_device_pci, PCI_INTERRUPT_LINE, 1); fprintf(tty, "Interrupt Line: %x\n", rtl_irq); irq_install_handler(rtl_irq, rtl_irq_handler); uint32_t rtl_bar0 = pci_read_field(rtl_device_pci, PCI_BAR0, 4); uint32_t rtl_bar1 = pci_read_field(rtl_device_pci, PCI_BAR1, 4); fprintf(tty, "BAR0: 0x%8x\n", rtl_bar0); fprintf(tty, "BAR1: 0x%8x\n", rtl_bar1); rtl_iobase = 0x00000000; if (rtl_bar0 & 0x00000001) { rtl_iobase = rtl_bar0 & 0xFFFFFFFC; } else { fprintf(tty, "This doesn't seem right! RTL8139 should be using an I/O BAR; this looks like a memory bar."); } fprintf(tty, "RTL iobase: 0x%x\n", rtl_iobase); rx_wait = list_create(); fprintf(tty, "Determining mac address...\n"); for (int i = 0; i < 6; ++i) { mac[i] = inports(rtl_iobase + RTL_PORT_MAC + i); } fprintf(tty, "%2x:%2x:%2x:%2x:%2x:%2x\n", mac[0], mac[1], mac[2], mac[3], mac[4], mac[5]); fprintf(tty, "Enabling RTL8139.\n"); outportb(rtl_iobase + RTL_PORT_CONFIG, 0x0); fprintf(tty, "Resetting RTL8139.\n"); outportb(rtl_iobase + RTL_PORT_CMD, 0x10); while ((inportb(rtl_iobase + 0x37) & 0x10) != 0) { } fprintf(tty, "Done resetting RTL8139.\n"); for (int i = 0; i < 5; ++i) { rtl_tx_buffer[i] = (void*)kvmalloc_p(0x1000, &rtl_tx_phys[i]); for (int j = 0; j < 60; ++j) { rtl_tx_buffer[i][j] = 0xF0; } } rtl_rx_buffer = (uint8_t *)kvmalloc_p(0x3000, &rtl_rx_phys); memset(rtl_rx_buffer, 0x00, 0x3000); fprintf(tty, "Buffers:\n"); fprintf(tty, " rx 0x%x [phys 0x%x and 0x%x and 0x%x]\n", rtl_rx_buffer, rtl_rx_phys, map_to_physical((uintptr_t)rtl_rx_buffer + 0x1000), map_to_physical((uintptr_t)rtl_rx_buffer + 0x2000)); for (int i = 0; i < 5; ++i) { fprintf(tty, " tx 0x%x [phys 0x%x]\n", rtl_tx_buffer[i], rtl_tx_phys[i]); } fprintf(tty, "Initializing receive buffer.\n"); outportl(rtl_iobase + RTL_PORT_RBSTART, rtl_rx_phys); fprintf(tty, "Enabling IRQs.\n"); outports(rtl_iobase + RTL_PORT_IMR, 0x8000 | /* PCI error */ 0x4000 | /* PCS timeout */ 0x40 | /* Rx FIFO over */ 0x20 | /* Rx underrun */ 0x10 | /* Rx overflow */ 0x08 | /* Tx error */ 0x04 | /* Tx okay */ 0x02 | /* Rx error */ 0x01 /* Rx okay */ ); /* TOK, ROK */ fprintf(tty, "Configuring transmit\n"); outportl(rtl_iobase + RTL_PORT_TCR, 0 ); fprintf(tty, "Configuring receive buffer.\n"); outportl(rtl_iobase + RTL_PORT_RCR, (0) | /* 8K receive */ 0x08 | /* broadcast */ 0x01 /* all physical */ ); fprintf(tty, "Enabling receive and transmit.\n"); outportb(rtl_iobase + RTL_PORT_CMD, 0x08 | 0x04); fprintf(tty, "Resetting rx stats\n"); outportl(rtl_iobase + RTL_PORT_RXMISS, 0); { fprintf(tty, "Sending DHCP discover\n"); size_t packet_size = write_dhcp_packet(rtl_tx_buffer[next_tx]); outportl(rtl_iobase + RTL_PORT_TXBUF + 4 * next_tx, rtl_tx_phys[next_tx]); outportl(rtl_iobase + RTL_PORT_TXSTAT + 4 * next_tx, packet_size); next_tx++; if (next_tx == 4) { next_tx = 0; } } sleep_on(rx_wait); { struct ethernet_packet * eth = (struct ethernet_packet *)last_packet; uint16_t eth_type = ntohs(eth->type); fprintf(tty, "Ethernet II, Src: (%2x:%2x:%2x:%2x:%2x:%2x), Dst: (%2x:%2x:%2x:%2x:%2x:%2x) [type=%4x)\n", eth->source[0], eth->source[1], eth->source[2], eth->source[3], eth->source[4], eth->source[5], eth->destination[0], eth->destination[1], eth->destination[2], eth->destination[3], eth->destination[4], eth->destination[5], eth_type); struct ipv4_packet * ipv4 = (struct ipv4_packet *)eth->payload; uint32_t src_addr = ntohl(ipv4->source); uint32_t dst_addr = ntohl(ipv4->destination); uint16_t length = ntohs(ipv4->length); char src_ip[16]; char dst_ip[16]; ip_ntoa(src_addr, src_ip); ip_ntoa(dst_addr, dst_ip); fprintf(tty, "IP packet [%s → %s] length=%d bytes\n", src_ip, dst_ip, length); struct udp_packet * udp = (struct udp_packet *)ipv4->payload;; uint16_t src_port = ntohs(udp->source_port); uint16_t dst_port = ntohs(udp->destination_port); uint16_t udp_len = ntohs(udp->length); fprintf(tty, "UDP [%d → %d] length=%d bytes\n", src_port, dst_port, udp_len); struct dhcp_packet * dhcp = (struct dhcp_packet *)udp->payload; uint32_t yiaddr = ntohl(dhcp->yiaddr); char yiaddr_ip[16]; ip_ntoa(yiaddr, yiaddr_ip); fprintf(tty, "DHCP Offer: %s\n", yiaddr_ip); } fprintf(tty, "Card is configured, going to start worker thread now.\n"); create_kernel_tasklet(rtl_netd, "[netd]", tty); create_kernel_tasklet(rtl_ircd, "[ircd]", tty); } else { return -1; } return 0; } static int init(void) { BIND_SHELL_FUNCTION(rtl); BIND_SHELL_FUNCTION(irc_test); BIND_SHELL_FUNCTION(irc_init); BIND_SHELL_FUNCTION(irc_join); pci_scan(&find_rtl, -1, &rtl_device_pci); if (!rtl_device_pci) { debug_print(ERROR, "No RTL 8139 found?"); return 1; } return 0; } static int fini(void) { return 0; } MODULE_DEF(rtl, init, fini); MODULE_DEPENDS(debugshell); MODULE_DEPENDS(net);