/*- * BSD LICENSE * * Copyright(c) 2016 Intel Corporation. All rights reserved. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * * Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in * the documentation and/or other materials provided with the * distribution. * * Neither the name of Intel Corporation nor the names of its * contributors may be used to endorse or promote products derived * from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT * OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ /* * Security Policies */ #include #include #include #include #include #include "ipsec.h" #define MAX_ACL_RULE_NUM 1000 /* * Rule and trace formats definitions. */ enum { PROTO_FIELD_IPV4, SRC_FIELD_IPV4, DST_FIELD_IPV4, SRCP_FIELD_IPV4, DSTP_FIELD_IPV4, NUM_FIELDS_IPV4 }; /* * That effectively defines order of IPV4 classifications: * - PROTO * - SRC IP ADDRESS * - DST IP ADDRESS * - PORTS (SRC and DST) */ enum { RTE_ACL_IPV4_PROTO, RTE_ACL_IPV4_SRC, RTE_ACL_IPV4_DST, RTE_ACL_IPV4_PORTS, RTE_ACL_IPV4_NUM }; struct rte_acl_field_def ip4_defs[NUM_FIELDS_IPV4] = { { .type = RTE_ACL_FIELD_TYPE_BITMASK, .size = sizeof(uint8_t), .field_index = PROTO_FIELD_IPV4, .input_index = RTE_ACL_IPV4_PROTO, .offset = 0, }, { .type = RTE_ACL_FIELD_TYPE_MASK, .size = sizeof(uint32_t), .field_index = SRC_FIELD_IPV4, .input_index = RTE_ACL_IPV4_SRC, .offset = offsetof(struct ip, ip_src) - offsetof(struct ip, ip_p) }, { .type = RTE_ACL_FIELD_TYPE_MASK, .size = sizeof(uint32_t), .field_index = DST_FIELD_IPV4, .input_index = RTE_ACL_IPV4_DST, .offset = offsetof(struct ip, ip_dst) - offsetof(struct ip, ip_p) }, { .type = RTE_ACL_FIELD_TYPE_RANGE, .size = sizeof(uint16_t), .field_index = SRCP_FIELD_IPV4, .input_index = RTE_ACL_IPV4_PORTS, .offset = sizeof(struct ip) - offsetof(struct ip, ip_p) }, { .type = RTE_ACL_FIELD_TYPE_RANGE, .size = sizeof(uint16_t), .field_index = DSTP_FIELD_IPV4, .input_index = RTE_ACL_IPV4_PORTS, .offset = sizeof(struct ip) - offsetof(struct ip, ip_p) + sizeof(uint16_t) }, }; RTE_ACL_RULE_DEF(acl4_rules, RTE_DIM(ip4_defs)); const struct acl4_rules acl4_rules_out[] = { { .data = {.userdata = PROTECT(5), .category_mask = 1, .priority = 1}, /* destination IPv4 */ .field[2] = {.value.u32 = IPv4(192, 168, 105, 0), .mask_range.u32 = 24,}, /* source port */ .field[3] = {.value.u16 = 0, .mask_range.u16 = 0xffff,}, /* destination port */ .field[4] = {.value.u16 = 0, .mask_range.u16 = 0xffff,} }, { .data = {.userdata = PROTECT(6), .category_mask = 1, .priority = 1}, /* destination IPv4 */ .field[2] = {.value.u32 = IPv4(192, 168, 106, 0), .mask_range.u32 = 24,}, /* source port */ .field[3] = {.value.u16 = 0, .mask_range.u16 = 0xffff,}, /* destination port */ .field[4] = {.value.u16 = 0, .mask_range.u16 = 0xffff,} }, { .data = {.userdata = PROTECT(10), .category_mask = 1, .priority = 1}, /* destination IPv4 */ .field[2] = {.value.u32 = IPv4(192, 168, 175, 0), .mask_range.u32 = 24,}, /* source port */ .field[3] = {.value.u16 = 0, .mask_range.u16 = 0xffff,}, /* destination port */ .field[4] = {.value.u16 = 0, .mask_range.u16 = 0xffff,} }, { .data = {.userdata = PROTECT(11), .category_mask = 1, .priority = 1}, /* destination IPv4 */ .field[2] = {.value.u32 = IPv4(192, 168, 176, 0), .mask_range.u32 = 24,}, /* source port */ .field[3] = {.value.u16 = 0, .mask_range.u16 = 0xffff,}, /* destination port */ .field[4] = {.value.u16 = 0, .mask_range.u16 = 0xffff,} }, { .data = {.userdata = PROTECT(15), .category_mask = 1, .priority = 1}, /* destination IPv4 */ .field[2] = {.value.u32 = IPv4(192, 168, 200, 0), .mask_range.u32 = 24,}, /* source port */ .field[3] = {.value.u16 = 0, .mask_range.u16 = 0xffff,}, /* destination port */ .field[4] = {.value.u16 = 0, .mask_range.u16 = 0xffff,} }, { .data = {.userdata = PROTECT(16), .category_mask = 1, .priority = 1}, /* destination IPv4 */ .field[2] = {.value.u32 = IPv4(192, 168, 201, 0), .mask_range.u32 = 24,}, /* source port */ .field[3] = {.value.u16 = 0, .mask_range.u16 = 0xffff,}, /* destination port */ .field[4] = {.value.u16 = 0, .mask_range.u16 = 0xffff,} }, { .data = {.userdata = PROTECT(25), .category_mask = 1, .priority = 1}, /* destination IPv4 */ .field[2] = {.value.u32 = IPv4(192, 168, 55, 0), .mask_range.u32 = 24,}, /* source port */ .field[3] = {.value.u16 = 0, .mask_range.u16 = 0xffff,}, /* destination port */ .field[4] = {.value.u16 = 0, .mask_range.u16 = 0xffff,} }, { .data = {.userdata = PROTECT(26), .category_mask = 1, .priority = 1}, /* destination IPv4 */ .field[2] = {.value.u32 = IPv4(192, 168, 56, 0), .mask_range.u32 = 24,}, /* source port */ .field[3] = {.value.u16 = 0, .mask_range.u16 = 0xffff,}, /* destination port */ .field[4] = {.value.u16 = 0, .mask_range.u16 = 0xffff,} }, { .data = {.userdata = BYPASS, .category_mask = 1, .priority = 1}, /* destination IPv4 */ .field[2] = {.value.u32 = IPv4(192, 168, 240, 0), .mask_range.u32 = 24,}, /* source port */ .field[3] = {.value.u16 = 0, .mask_range.u16 = 0xffff,}, /* destination port */ .field[4] = {.value.u16 = 0, .mask_range.u16 = 0xffff,} }, { .data = {.userdata = BYPASS, .category_mask = 1, .priority = 1}, /* destination IPv4 */ .field[2] = {.value.u32 = IPv4(192, 168, 241, 0), .mask_range.u32 = 24,}, /* source port */ .field[3] = {.value.u16 = 0, .mask_range.u16 = 0xffff,}, /* destination port */ .field[4] = {.value.u16 = 0, .mask_range.u16 = 0xffff,} } }; const struct acl4_rules acl4_rules_in[] = { { .data = {.userdata = PROTECT(105), .category_mask = 1, .priority = 1}, /* destination IPv4 */ .field[2] = {.value.u32 = IPv4(192, 168, 115, 0), .mask_range.u32 = 24,}, /* source port */ .field[3] = {.value.u16 = 0, .mask_range.u16 = 0xffff,}, /* destination port */ .field[4] = {.value.u16 = 0, .mask_range.u16 = 0xffff,} }, { .data = {.userdata = PROTECT(106), .category_mask = 1, .priority = 1}, /* destination IPv4 */ .field[2] = {.value.u32 = IPv4(192, 168, 116, 0), .mask_range.u32 = 24,}, /* source port */ .field[3] = {.value.u16 = 0, .mask_range.u16 = 0xffff,}, /* destination port */ .field[4] = {.value.u16 = 0, .mask_range.u16 = 0xffff,} }, { .data = {.userdata = PROTECT(110), .category_mask = 1, .priority = 1}, /* destination IPv4 */ .field[2] = {.value.u32 = IPv4(192, 168, 185, 0), .mask_range.u32 = 24,}, /* source port */ .field[3] = {.value.u16 = 0, .mask_range.u16 = 0xffff,}, /* destination port */ .field[4] = {.value.u16 = 0, .mask_range.u16 = 0xffff,} }, { .data = {.userdata = PROTECT(111), .category_mask = 1, .priority = 1}, /* destination IPv4 */ .field[2] = {.value.u32 = IPv4(192, 168, 186, 0), .mask_range.u32 = 24,}, /* source port */ .field[3] = {.value.u16 = 0, .mask_range.u16 = 0xffff,}, /* destination port */ .field[4] = {.value.u16 = 0, .mask_range.u16 = 0xffff,} }, { .data = {.userdata = PROTECT(115), .category_mask = 1, .priority = 1}, /* destination IPv4 */ .field[2] = {.value.u32 = IPv4(192, 168, 210, 0), .mask_range.u32 = 24,}, /* source port */ .field[3] = {.value.u16 = 0, .mask_range.u16 = 0xffff,}, /* destination port */ .field[4] = {.value.u16 = 0, .mask_range.u16 = 0xffff,} }, { .data = {.userdata = PROTECT(116), .category_mask = 1, .priority = 1}, /* destination IPv4 */ .field[2] = {.value.u32 = IPv4(192, 168, 211, 0), .mask_range.u32 = 24,}, /* source port */ .field[3] = {.value.u16 = 0, .mask_range.u16 = 0xffff,}, /* destination port */ .field[4] = {.value.u16 = 0, .mask_range.u16 = 0xffff,} }, { .data = {.userdata = PROTECT(125), .category_mask = 1, .priority = 1}, /* destination IPv4 */ .field[2] = {.value.u32 = IPv4(192, 168, 65, 0), .mask_range.u32 = 24,}, /* source port */ .field[3] = {.value.u16 = 0, .mask_range.u16 = 0xffff,}, /* destination port */ .field[4] = {.value.u16 = 0, .mask_range.u16 = 0xffff,} }, { .data = {.userdata = PROTECT(126), .category_mask = 1, .priority = 1}, /* destination IPv4 */ .field[2] = {.value.u32 = IPv4(192, 168, 66, 0), .mask_range.u32 = 24,}, /* source port */ .field[3] = {.value.u16 = 0, .mask_range.u16 = 0xffff,}, /* destination port */ .field[4] = {.value.u16 = 0, .mask_range.u16 = 0xffff,} }, { .data = {.userdata = BYPASS, .category_mask = 1, .priority = 1}, /* destination IPv4 */ .field[2] = {.value.u32 = IPv4(192, 168, 245, 0), .mask_range.u32 = 24,}, /* source port */ .field[3] = {.value.u16 = 0, .mask_range.u16 = 0xffff,}, /* destination port */ .field[4] = {.value.u16 = 0, .mask_range.u16 = 0xffff,} }, { .data = {.userdata = BYPASS, .category_mask = 1, .priority = 1}, /* destination IPv4 */ .field[2] = {.value.u32 = IPv4(192, 168, 246, 0), .mask_range.u32 = 24,}, /* source port */ .field[3] = {.value.u16 = 0, .mask_range.u16 = 0xffff,}, /* destination port */ .field[4] = {.value.u16 = 0, .mask_range.u16 = 0xffff,} } }; static void print_one_ip4_rule(const struct acl4_rules *rule, int32_t extra) { uint8_t a, b, c, d; uint32_t_to_char(rule->field[SRC_FIELD_IPV4].value.u32, &a, &b, &c, &d); printf("%hhu.%hhu.%hhu.%hhu/%u ", a, b, c, d, rule->field[SRC_FIELD_IPV4].mask_range.u32); uint32_t_to_char(rule->field[DST_FIELD_IPV4].value.u32, &a, &b, &c, &d); printf("%hhu.%hhu.%hhu.%hhu/%u ", a, b, c, d, rule->field[DST_FIELD_IPV4].mask_range.u32); printf("%hu : %hu %hu : %hu 0x%hhx/0x%hhx ", rule->field[SRCP_FIELD_IPV4].value.u16, rule->field[SRCP_FIELD_IPV4].mask_range.u16, rule->field[DSTP_FIELD_IPV4].value.u16, rule->field[DSTP_FIELD_IPV4].mask_range.u16, rule->field[PROTO_FIELD_IPV4].value.u8, rule->field[PROTO_FIELD_IPV4].mask_range.u8); if (extra) printf("0x%x-0x%x-0x%x ", rule->data.category_mask, rule->data.priority, rule->data.userdata); } static inline void dump_ip4_rules(const struct acl4_rules *rule, int32_t num, int32_t extra) { int32_t i; for (i = 0; i < num; i++, rule++) { printf("\t%d:", i + 1); print_one_ip4_rule(rule, extra); printf("\n"); } } static struct rte_acl_ctx * acl4_init(const char *name, int32_t socketid, const struct acl4_rules *rules, uint32_t rules_nb) { char s[PATH_MAX]; struct rte_acl_param acl_param; struct rte_acl_config acl_build_param; struct rte_acl_ctx *ctx; printf("Creating SP context with %u max rules\n", MAX_ACL_RULE_NUM); memset(&acl_param, 0, sizeof(acl_param)); /* Create ACL contexts */ snprintf(s, sizeof(s), "%s_%d", name, socketid); printf("IPv4 %s entries [%u]:\n", s, rules_nb); dump_ip4_rules(rules, rules_nb, 1); acl_param.name = s; acl_param.socket_id = socketid; acl_param.rule_size = RTE_ACL_RULE_SZ(RTE_DIM(ip4_defs)); acl_param.max_rule_num = MAX_ACL_RULE_NUM; ctx = rte_acl_create(&acl_param); if (ctx == NULL) rte_exit(EXIT_FAILURE, "Failed to create ACL context\n"); if (rte_acl_add_rules(ctx, (const struct rte_acl_rule *)rules, rules_nb) < 0) rte_exit(EXIT_FAILURE, "add rules failed\n"); /* Perform builds */ memset(&acl_build_param, 0, sizeof(acl_build_param)); acl_build_param.num_categories = DEFAULT_MAX_CATEGORIES; acl_build_param.num_fields = RTE_DIM(ip4_defs); memcpy(&acl_build_param.defs, ip4_defs, sizeof(ip4_defs)); if (rte_acl_build(ctx, &acl_build_param) != 0) rte_exit(EXIT_FAILURE, "Failed to build ACL trie\n"); rte_acl_dump(ctx); return ctx; } void sp4_init(struct socket_ctx *ctx, int32_t socket_id, uint32_t ep) { const char *name; const struct acl4_rules *rules_out, *rules_in; uint32_t nb_out_rules, nb_in_rules; if (ctx == NULL) rte_exit(EXIT_FAILURE, "NULL context.\n"); if (ctx->sp_ip4_in != NULL) rte_exit(EXIT_FAILURE, "Inbound SP DB for socket %u already " "initialized\n", socket_id); if (ctx->sp_ip4_out != NULL) rte_exit(EXIT_FAILURE, "Outbound SP DB for socket %u already " "initialized\n", socket_id); if (ep == 0) { rules_out = acl4_rules_out; nb_out_rules = RTE_DIM(acl4_rules_out); rules_in = acl4_rules_in; nb_in_rules = RTE_DIM(acl4_rules_in); } else if (ep == 1) { rules_out = acl4_rules_in; nb_out_rules = RTE_DIM(acl4_rules_in); rules_in = acl4_rules_out; nb_in_rules = RTE_DIM(acl4_rules_out); } else rte_exit(EXIT_FAILURE, "Invalid EP value %u. " "Only 0 or 1 supported.\n", ep); name = "sp_ip4_in"; ctx->sp_ip4_in = (struct sp_ctx *)acl4_init(name, socket_id, rules_in, nb_in_rules); name = "sp_ip4_out"; ctx->sp_ip4_out = (struct sp_ctx *)acl4_init(name, socket_id, rules_out, nb_out_rules); }