/* * esp_encrypt.c : IPSec ESP encrypt node * * Copyright (c) 2015 Cisco and/or its affiliates. * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at: * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include #include #include #include #include #include #include #define foreach_esp_encrypt_next \ _(DROP, "error-drop") \ _(IP4_LOOKUP, "ip4-lookup") \ _(IP6_LOOKUP, "ip6-lookup") \ _(INTERFACE_OUTPUT, "interface-output") #define _(v, s) ESP_ENCRYPT_NEXT_##v, typedef enum { foreach_esp_encrypt_next #undef _ ESP_ENCRYPT_N_NEXT, } esp_encrypt_next_t; #define foreach_esp_encrypt_error \ _(RX_PKTS, "ESP pkts received") \ _(NO_BUFFER, "No buffer (packet dropped)") \ _(DECRYPTION_FAILED, "ESP encryption failed") \ _(SEQ_CYCLED, "sequence number cycled") typedef enum { #define _(sym,str) ESP_ENCRYPT_ERROR_##sym, foreach_esp_encrypt_error #undef _ ESP_ENCRYPT_N_ERROR, } esp_encrypt_error_t; static char *esp_encrypt_error_strings[] = { #define _(sym,string) string, foreach_esp_encrypt_error #undef _ }; typedef struct { u32 sa_index; u32 spi; u32 seq; u8 udp_encap; ipsec_crypto_alg_t crypto_alg; ipsec_integ_alg_t integ_alg; } esp_encrypt_trace_t; /* packet trace format function */ static u8 * format_esp_encrypt_trace (u8 * s, va_list * args) { CLIB_UNUSED (vlib_main_t * vm) = va_arg (*args, vlib_main_t *); CLIB_UNUSED (vlib_node_t * node) = va_arg (*args, vlib_node_t *); esp_encrypt_trace_t *t = va_arg (*args, esp_encrypt_trace_t *); s = format (s, "esp: sa-index %d spi %u seq %u crypto %U integrity %U%s", t->sa_index, t->spi, t->seq, format_ipsec_crypto_alg, t->crypto_alg, format_ipsec_integ_alg, t->integ_alg, t->udp_encap ? " udp-encap-enabled" : ""); return s; } always_inline void esp_encrypt_cbc (vlib_main_t * vm, ipsec_sa_t * sa, u8 * in, u8 * out, size_t in_len, u8 * key, u8 * iv) { vnet_crypto_op_t _op, *op = &_op; if (PREDICT_FALSE (sa->crypto_enc_op_type == VNET_CRYPTO_OP_NONE)) return; op->op = sa->crypto_enc_op_type; op->flags = VNET_CRYPTO_OP_FLAG_INIT_IV; op->iv = iv; op->src = in; op->dst = out; op->len = in_len; op->key = key; vnet_crypto_process_ops (vm, op, 1); } always_inline uword esp_encrypt_inline (vlib_main_t * vm, vlib_node_runtime_t * node, vlib_frame_t * from_frame, int is_ip6) { u32 *from = vlib_frame_vector_args (from_frame); u32 n_left_from = from_frame->n_vectors; ipsec_main_t *im = &ipsec_main; u32 new_bufs[VLIB_FRAME_SIZE]; vlib_buffer_t *i_bufs[VLIB_FRAME_SIZE], **ib = i_bufs; vlib_buffer_t *o_bufs[VLIB_FRAME_SIZE], **ob = o_bufs; u16 nexts[VLIB_FRAME_SIZE], *next = nexts; u32 n_alloc, thread_index = vm->thread_index; n_alloc = vlib_buffer_alloc (vm, new_bufs, n_left_from); if (n_alloc != n_left_from) { vlib_node_increment_counter (vm, node->node_index, ESP_ENCRYPT_ERROR_NO_BUFFER, n_left_from - n_alloc); if (n_alloc == 0) goto done; n_left_from = n_alloc; } vlib_get_buffers (vm, from, ib, n_left_from); vlib_get_buffers (vm, new_bufs, ob, n_left_from); while (n_left_from > 0) { u32 sa_index0; ipsec_sa_t *sa0; ip4_and_esp_header_t *oh0 = 0; ip6_and_esp_header_t *ih6_0, *oh6_0 = 0; ip4_and_udp_and_esp_header_t *iuh0, *ouh0 = 0; esp_header_t *o_esp0; esp_footer_t *f0; u8 ip_udp_hdr_size; u8 next_hdr_type; u32 ip_proto = 0; u8 transport_mode = 0; u32 esp_seq_err; next[0] = ESP_ENCRYPT_NEXT_DROP; sa_index0 = vnet_buffer (ib[0])->ipsec.sad_index; sa0 = pool_elt_at_index (im->sad, sa_index0); vlib_prefetch_combined_counter (&ipsec_sa_counters, thread_index, sa_index0); esp_seq_err = esp_seq_advance (sa0); /* grab free buffer */ ob[0]->flags = VLIB_BUFFER_TOTAL_LENGTH_VALID; ob[0]->current_data = sizeof (ethernet_header_t); iuh0 = vlib_buffer_get_current (ib[0]); if (is_ip6) { ih6_0 = vlib_buffer_get_current (ib[0]); next_hdr_type = IP_PROTOCOL_IPV6; oh6_0 = vlib_buffer_get_current (ob[0]); oh6_0->ip6.ip_version_traffic_class_and_flow_label = ih6_0->ip6.ip_version_traffic_class_and_flow_label; oh6_0->ip6.protocol = IP_PROTOCOL_IPSEC_ESP; ip_udp_hdr_size = sizeof (ip6_header_t); o_esp0 = vlib_buffer_get_current (ob[0]) + ip_udp_hdr_size; oh6_0->ip6.hop_limit = 254; oh6_0->ip6.src_address.as_u64[0] = ih6_0->ip6.src_address.as_u64[0]; oh6_0->ip6.src_address.as_u64[1] = ih6_0->ip6.src_address.as_u64[1]; oh6_0->ip6.dst_address.as_u64[0] = ih6_0->ip6.dst_address.as_u64[0]; oh6_0->ip6.dst_address.as_u64[1] = ih6_0->ip6.dst_address.as_u64[1]; o_esp0->spi = clib_net_to_host_u32 (sa0->spi); o_esp0->seq = clib_net_to_host_u32 (sa0->seq); ip_proto = ih6_0->ip6.protocol; next[0] = ESP_ENCRYPT_NEXT_IP6_LOOKUP; } else { next_hdr_type = IP_PROTOCOL_IP_IN_IP; oh0 = vlib_buffer_get_current (ob[0]); ouh0 = vlib_buffer_get_current (ob[0]); oh0->ip4.ip_version_and_header_length = 0x45; oh0->ip4.tos = iuh0->ip4.tos; oh0->ip4.fragment_id = 0; oh0->ip4.flags_and_fragment_offset = 0; oh0->ip4.ttl = 254; if (sa0->udp_encap) { ouh0->udp.src_port = clib_host_to_net_u16 (UDP_DST_PORT_ipsec); ouh0->udp.dst_port = clib_host_to_net_u16 (UDP_DST_PORT_ipsec); ouh0->udp.checksum = 0; ouh0->ip4.protocol = IP_PROTOCOL_UDP; ip_udp_hdr_size = sizeof (udp_header_t) + sizeof (ip4_header_t); } else { oh0->ip4.protocol = IP_PROTOCOL_IPSEC_ESP; ip_udp_hdr_size = sizeof (ip4_header_t); } o_esp0 = vlib_buffer_get_current (ob[0]) + ip_udp_hdr_size; oh0->ip4.src_address.as_u32 = iuh0->ip4.src_address.as_u32; oh0->ip4.dst_address.as_u32 = iuh0->ip4.dst_address.as_u32; o_esp0->spi = clib_net_to_host_u32 (sa0->spi); o_esp0->seq = clib_net_to_host_u32 (sa0->seq); ip_proto = iuh0->ip4.protocol; next[0] = ESP_ENCRYPT_NEXT_IP4_LOOKUP; } if (PREDICT_TRUE (!is_ip6 && sa0->is_tunnel && !sa0->is_tunnel_ip6)) { oh0->ip4.src_address.as_u32 = sa0->tunnel_src_addr.ip4.as_u32; oh0->ip4.dst_address.as_u32 = sa0->tunnel_dst_addr.ip4.as_u32; next[0] = sa0->dpo[IPSEC_PROTOCOL_ESP].dpoi_next_node; vnet_buffer (ob[0])->ip.adj_index[VLIB_TX] = sa0->dpo[IPSEC_PROTOCOL_ESP].dpoi_index; } else if (is_ip6 && sa0->is_tunnel && sa0->is_tunnel_ip6) { oh6_0->ip6.src_address.as_u64[0] = sa0->tunnel_src_addr.ip6.as_u64[0]; oh6_0->ip6.src_address.as_u64[1] = sa0->tunnel_src_addr.ip6.as_u64[1]; oh6_0->ip6.dst_address.as_u64[0] = sa0->tunnel_dst_addr.ip6.as_u64[0]; oh6_0->ip6.dst_address.as_u64[1] = sa0->tunnel_dst_addr.ip6.as_u64[1]; next[0] = sa0->dpo[IPSEC_PROTOCOL_ESP].dpoi_next_node; vnet_buffer (ob[0])->ip.adj_index[VLIB_TX] = sa0->dpo[IPSEC_PROTOCOL_ESP].dpoi_index; } else { next_hdr_type = ip_proto; if (vnet_buffer (ib[0])->sw_if_index[VLIB_TX] != ~0) { transport_mode = 1; ethernet_header_t *ieh0, *oeh0; ieh0 = (ethernet_header_t *) ((u8 *) vlib_buffer_get_current (ib[0]) - sizeof (ethernet_header_t)); oeh0 = (ethernet_header_t *) ob[0]->data; clib_memcpy_fast (oeh0, ieh0, sizeof (ethernet_header_t)); next[0] = ESP_ENCRYPT_NEXT_INTERFACE_OUTPUT; vnet_buffer (ob[0])->sw_if_index[VLIB_TX] = vnet_buffer (ib[0])->sw_if_index[VLIB_TX]; } if (is_ip6) vlib_buffer_advance (ib[0], sizeof (ip6_header_t)); else vlib_buffer_advance (ib[0], sizeof (ip4_header_t)); } ASSERT (sa0->crypto_alg < IPSEC_CRYPTO_N_ALG); vlib_increment_combined_counter (&ipsec_sa_counters, thread_index, sa_index0, 1, ib[0]->current_length); if (PREDICT_TRUE (sa0->crypto_alg != IPSEC_CRYPTO_ALG_NONE)) { const int BLOCK_SIZE = sa0->crypto_block_size; const int IV_SIZE = sa0->crypto_iv_size; int blocks = 1 + (ib[0]->current_length + 1) / BLOCK_SIZE; /* pad packet in input buffer */ u8 pad_bytes = BLOCK_SIZE * blocks - 2 - ib[0]->current_length; u8 i; u8 *padding = vlib_buffer_get_current (ib[0]) + ib[0]->current_length; ib[0]->current_length = BLOCK_SIZE * blocks; for (i = 0; i < pad_bytes; ++i) { padding[i] = i + 1; } f0 = vlib_buffer_get_current (ib[0]) + ib[0]->current_length - 2; f0->pad_length = pad_bytes; f0->next_header = next_hdr_type; ob[0]->current_length = ip_udp_hdr_size + sizeof (esp_header_t) + BLOCK_SIZE * blocks + IV_SIZE; vnet_buffer (ob[0])->sw_if_index[VLIB_RX] = vnet_buffer (ib[0])->sw_if_index[VLIB_RX]; u8 *iv = vlib_buffer_get_current (ob[0]) + ip_udp_hdr_size + sizeof (esp_header_t); clib_memcpy_fast ((u8 *) vlib_buffer_get_current (ob[0]) + ip_udp_hdr_size + sizeof (esp_header_t), iv, IV_SIZE); esp_encrypt_cbc (vm, sa0, (u8 *) vlib_buffer_get_current (ib[0]), (u8 *) vlib_buffer_get_current (ob[0]) + ip_udp_hdr_size + sizeof (esp_header_t) + IV_SIZE, BLOCK_SIZE * blocks, sa0->crypto_key.data, iv); } ob[0]->current_length += hmac_calc (vm, sa0, (u8 *) o_esp0, ob[0]->current_length - ip_udp_hdr_size, vlib_buffer_get_current (ob[0]) + ob[0]->current_length); if (is_ip6) { oh6_0->ip6.payload_length = clib_host_to_net_u16 (vlib_buffer_length_in_chain (vm, ob[0]) - sizeof (ip6_header_t)); } else { oh0->ip4.length = clib_host_to_net_u16 (vlib_buffer_length_in_chain (vm, ob[0])); oh0->ip4.checksum = ip4_header_checksum (&oh0->ip4); if (sa0->udp_encap) { ouh0->udp.length = clib_host_to_net_u16 (clib_net_to_host_u16 (oh0->ip4.length) - ip4_header_bytes (&oh0->ip4)); } } if (transport_mode) vlib_buffer_reset (ob[0]); if (PREDICT_FALSE (esp_seq_err)) { ob[0]->error = node->errors[ESP_ENCRYPT_ERROR_SEQ_CYCLED]; next[0] = ESP_ENCRYPT_NEXT_DROP; } if (PREDICT_FALSE (ib[0]->flags & VLIB_BUFFER_IS_TRACED)) { if (ob[0]) { ob[0]->flags |= VLIB_BUFFER_IS_TRACED; ob[0]->trace_index = ib[0]->trace_index; esp_encrypt_trace_t *tr = vlib_add_trace (vm, node, ob[0], sizeof (*tr)); tr->sa_index = sa_index0; tr->spi = sa0->spi; tr->seq = sa0->seq - 1; tr->udp_encap = sa0->udp_encap; tr->crypto_alg = sa0->crypto_alg; tr->integ_alg = sa0->integ_alg; } } /* next */ n_left_from -= 1; ib += 1; ob += 1; next += 1; } vlib_node_increment_counter (vm, node->node_index, ESP_ENCRYPT_ERROR_RX_PKTS, n_alloc); vlib_buffer_enqueue_to_next (vm, node, new_bufs, nexts, n_alloc); done: vlib_buffer_free (vm, from, from_frame->n_vectors); return n_alloc; } VLIB_NODE_FN (esp4_encrypt_node) (vlib_main_t * vm, vlib_node_runtime_t * node, vlib_frame_t * from_frame) { return esp_encrypt_inline (vm, node, from_frame, 0 /* is_ip6 */ ); } /* *INDENT-OFF* */ VLIB_REGISTER_NODE (esp4_encrypt_node) = { .name = "esp4-encrypt", .vector_size = sizeof (u32), .format_trace = format_esp_encrypt_trace, .type = VLIB_NODE_TYPE_INTERNAL, .n_errors = ARRAY_LEN(esp_encrypt_error_strings), .error_strings = esp_encrypt_error_strings, .n_next_nodes = ESP_ENCRYPT_N_NEXT, .next_nodes = { #define _(s,n) [ESP_ENCRYPT_NEXT_##s] = n, foreach_esp_encrypt_next #undef _ }, }; /* *INDENT-ON* */ VLIB_NODE_FN (esp6_encrypt_node) (vlib_main_t * vm, vlib_node_runtime_t * node, vlib_frame_t * from_frame) { return esp_encrypt_inline (vm, node, from_frame, 1 /* is_ip6 */ ); } /* *INDENT-OFF* */ VLIB_REGISTER_NODE (esp6_encrypt_node) = { .name = "esp6-encrypt", .vector_size = sizeof (u32), .format_trace = format_esp_encrypt_trace, .type = VLIB_NODE_TYPE_INTERNAL, .n_errors = ARRAY_LEN(esp_encrypt_error_strings), .error_strings = esp_encrypt_error_strings, .n_next_nodes = ESP_ENCRYPT_N_NEXT, .next_nodes = { #define _(s,n) [ESP_ENCRYPT_NEXT_##s] = n, foreach_esp_encrypt_next #undef _ }, }; /* *INDENT-ON* */ /* * fd.io coding-style-patch-verification: ON * * Local Variables: * eval: (c-set-style "gnu") * End: */