/*- * Copyright (c) 2010-2020 The NetBSD Foundation, Inc. * All rights reserved. * * This material is based upon work partially supported by The * NetBSD Foundation under a contract with Mindaugas Rasiukevicius. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. 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. * * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. 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 FOUNDATION 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. */ /* * BPF byte-code generation for NPF rules. * * Overview * * Each NPF rule is compiled into a BPF micro-program. There is a * BPF byte-code fragment for each higher-level filtering logic, * e.g. to match L4 protocol, IP/mask, etc. The generation process * combines multiple BPF-byte code fragments into one program. * * Basic case * * Consider a basic case where all filters should match. They * are expressed as logical conjunction, e.g.: * * A and B and C and D * * Each test (filter) criterion can be evaluated to true (match) or * false (no match) and the logic is as follows: * * - If the value is true, then jump to the "next" test (offset 0). * * - If the value is false, then jump to the JUMP_MAGIC value (0xff). * This "magic" value is used to indicate that it will have to be * patched at a later stage. * * Once all byte-code fragments are combined into one, then there * are two additional steps: * * - Two instructions are appended at the end of the program: "return * success" followed by "return failure". * * - All jumps with the JUMP_MAGIC value are patched to point to the * "return failure" instruction. * * Therefore, if all filter criteria will match, then the first * instruction will be reached, indicating a successful match of the * rule. Otherwise, if any of the criteria will not match, it will * take the failure path and the rule will not be matching. * * Grouping * * Filters can have groups, which have an effect of logical * disjunction, e.g.: * * A and B and (C or D) * * In such case, the logic inside the group has to be inverted i.e. * the jump values swapped. If the test value is true, then jump * out of the group; if false, then jump "next". At the end of the * group, an addition failure path is appended and the JUMP_MAGIC * uses within the group are patched to jump past the said path. * * For multi-word comparisons (IPv6 addresses), there is another * layer of grouping: * * A and B and ((C and D) or (E and F)) * * This strains the simple-minded JUMP_MAGIC logic, so for now, * when generating the jump-if-false targets for (C and D), we * simply count the number of instructions left to skip over. * * A better architecture might be to create asm-type labels for * the jt and jf continuations in the first pass, and then, once * their offsets are determined, go back and fill them in in the * second pass. This would simplify the logic (no need to compute * exactly how many instructions we're about to generate in a * chain of conditionals) and eliminate redundant RET #0 * instructions which are currently generated after some groups. */ #include __RCSID("$NetBSD: npf_bpf_comp.c,v 1.13.2.4 2024/11/17 13:58:11 martin Exp $"); #include #include #include #include #include #include #include #include #include #define __FAVOR_BSD #include #include #include #include #include #include #include #include "npfctl.h" /* * Note: clear X_EQ_L4OFF when register X is invalidated i.e. it stores * something other than L4 header offset. Generally, when BPF_LDX is used. */ #define FETCHED_L3 0x01 #define CHECKED_L4_PROTO 0x02 #define X_EQ_L4OFF 0x04 struct npf_bpf { /* * BPF program code, the allocated length (in bytes), the number * of logical blocks and the flags. */ struct bpf_program prog; size_t alen; unsigned nblocks; sa_family_t af; uint32_t flags; /* * Indicators whether we are inside the group and whether this * group is implementing inverted logic. * * The current group offset (counted in BPF instructions) * and block number at the start of the group. */ unsigned ingroup; bool invert; bool multiword; unsigned goff; unsigned gblock; /* Track inversion (excl. mark). */ uint32_t invflags; /* BPF marks, allocated length and the real length. */ uint32_t * marks; size_t malen; size_t mlen; }; /* * NPF success and failure values to be returned from BPF. */ #define NPF_BPF_SUCCESS ((u_int)-1) #define NPF_BPF_FAILURE 0 /* * Magic value to indicate the failure path, which is fixed up on completion. * Note: this is the longest jump offset in BPF, since the offset is one byte. */ #define JUMP_MAGIC 0xff /* Reduce re-allocations by expanding in 64 byte blocks. */ #define ALLOC_MASK (64 - 1) #define ALLOC_ROUND(x) (((x) + ALLOC_MASK) & ~ALLOC_MASK) #ifndef IPV6_VERSION #define IPV6_VERSION 0x60 #endif npf_bpf_t * npfctl_bpf_create(void) { return ecalloc(1, sizeof(npf_bpf_t)); } static void fixup_jumps(npf_bpf_t *ctx, u_int start, u_int end, bool swap) { struct bpf_program *bp = &ctx->prog; for (u_int i = start; i < end; i++) { struct bpf_insn *insn = &bp->bf_insns[i]; const u_int fail_off = end - i; bool seen_magic = false; if (fail_off >= JUMP_MAGIC) { errx(EXIT_FAILURE, "BPF generation error: " "the number of instructions is over the limit"); } if (BPF_CLASS(insn->code) != BPF_JMP) { continue; } if (BPF_OP(insn->code) == BPF_JA) { /* * BPF_JA can be used to jump to the failure path. * If we are swapping i.e. inside the group, then * jump "next"; groups have a failure path appended * at their end. */ if (insn->k == JUMP_MAGIC) { insn->k = swap ? 0 : fail_off; } continue; } /* * Fixup the "magic" value. Swap only the "magic" jumps. */ if (insn->jt == JUMP_MAGIC) { insn->jt = fail_off; seen_magic = true; } if (insn->jf == JUMP_MAGIC) { insn->jf = fail_off; seen_magic = true; } if (seen_magic && swap) { uint8_t jt = insn->jt; insn->jt = insn->jf; insn->jf = jt; } } } static void add_insns(npf_bpf_t *ctx, struct bpf_insn *insns, size_t count) { struct bpf_program *bp = &ctx->prog; size_t offset, len, reqlen; /* Note: bf_len is the count of instructions. */ offset = bp->bf_len * sizeof(struct bpf_insn); len = count * sizeof(struct bpf_insn); /* Ensure the memory buffer for the program. */ reqlen = ALLOC_ROUND(offset + len); if (reqlen > ctx->alen) { bp->bf_insns = erealloc(bp->bf_insns, reqlen); ctx->alen = reqlen; } /* Add the code block. */ memcpy((uint8_t *)bp->bf_insns + offset, insns, len); bp->bf_len += count; } static void add_bmarks(npf_bpf_t *ctx, const uint32_t *m, size_t len) { size_t reqlen, nargs = m[1]; if ((len / sizeof(uint32_t) - 2) != nargs) { errx(EXIT_FAILURE, "invalid BPF block description"); } reqlen = ALLOC_ROUND(ctx->mlen + len); if (reqlen > ctx->malen) { ctx->marks = erealloc(ctx->marks, reqlen); ctx->malen = reqlen; } memcpy((uint8_t *)ctx->marks + ctx->mlen, m, len); ctx->mlen += len; } static void done_block(npf_bpf_t *ctx, const uint32_t *m, size_t len) { add_bmarks(ctx, m, len); ctx->nblocks++; } struct bpf_program * npfctl_bpf_complete(npf_bpf_t *ctx) { struct bpf_program *bp = &ctx->prog; const u_int retoff = bp->bf_len; /* No instructions (optimised out). */ if (!bp->bf_len) return NULL; /* Add the return fragment (success and failure paths). */ struct bpf_insn insns_ret[] = { BPF_STMT(BPF_RET+BPF_K, NPF_BPF_SUCCESS), BPF_STMT(BPF_RET+BPF_K, NPF_BPF_FAILURE), }; add_insns(ctx, insns_ret, __arraycount(insns_ret)); /* Fixup all jumps to the main failure path. */ fixup_jumps(ctx, 0, retoff, false); return &ctx->prog; } const void * npfctl_bpf_bmarks(npf_bpf_t *ctx, size_t *len) { *len = ctx->mlen; return ctx->marks; } void npfctl_bpf_destroy(npf_bpf_t *ctx) { free(ctx->prog.bf_insns); free(ctx->marks); free(ctx); } /* * npfctl_bpf_group_enter: begin a logical group. It merely uses logical * disjunction (OR) for comparisons within the group. */ void npfctl_bpf_group_enter(npf_bpf_t *ctx, bool invert) { struct bpf_program *bp = &ctx->prog; assert(ctx->goff == 0); assert(ctx->gblock == 0); ctx->goff = bp->bf_len; ctx->gblock = ctx->nblocks; ctx->invert = invert; ctx->multiword = false; ctx->ingroup++; } void npfctl_bpf_group_exit(npf_bpf_t *ctx) { struct bpf_program *bp = &ctx->prog; const size_t curoff = bp->bf_len; assert(ctx->ingroup); ctx->ingroup--; /* * If we're not inverting, there were only zero or one options, * and the last comparison was not a multi-word comparison * requiring a fallthrough failure -- nothing to do. */ if (!ctx->invert && (ctx->nblocks - ctx->gblock) <= 1 && !ctx->multiword) { ctx->goff = ctx->gblock = 0; return; } /* * If inverting, then prepend a jump over the statement below. * On match, it will skip-through and the fail path will be taken. */ if (ctx->invert) { struct bpf_insn insns_ret[] = { BPF_STMT(BPF_JMP+BPF_JA, 1), }; add_insns(ctx, insns_ret, __arraycount(insns_ret)); } /* * Append a failure return as a fall-through i.e. if there is * no match within the group. */ struct bpf_insn insns_ret[] = { BPF_STMT(BPF_RET+BPF_K, NPF_BPF_FAILURE), }; add_insns(ctx, insns_ret, __arraycount(insns_ret)); /* * Adjust jump offsets: on match - jump outside the group i.e. * to the current offset. Otherwise, jump to the next instruction * which would lead to the fall-through code above if none matches. */ fixup_jumps(ctx, ctx->goff, curoff, true); ctx->goff = ctx->gblock = 0; } static void fetch_l3(npf_bpf_t *ctx, sa_family_t af, unsigned flags) { unsigned ver; switch (af) { case AF_INET: ver = IPVERSION; break; case AF_INET6: ver = IPV6_VERSION >> 4; break; case AF_UNSPEC: ver = 0; break; default: abort(); } /* * The memory store is populated with: * - BPF_MW_IPVER: IP version (4 or 6). * - BPF_MW_L4OFF: L4 header offset. * - BPF_MW_L4PROTO: L4 protocol. */ if ((ctx->flags & FETCHED_L3) == 0 || (af && ctx->af == 0)) { const uint8_t jt = ver ? 0 : JUMP_MAGIC; const uint8_t jf = ver ? JUMP_MAGIC : 0; const bool ingroup = ctx->ingroup != 0; const bool invert = ctx->invert; /* * L3 block cannot be inserted in the middle of a group. * In fact, it never is. Check and start the group after. */ if (ingroup) { assert(ctx->nblocks == ctx->gblock); npfctl_bpf_group_exit(ctx); } /* * A <- IP version; A == expected-version? * If no particular version specified, check for non-zero. */ struct bpf_insn insns_af[] = { BPF_STMT(BPF_LD+BPF_W+BPF_MEM, BPF_MW_IPVER), BPF_JUMP(BPF_JMP+BPF_JEQ+BPF_K, ver, jt, jf), }; add_insns(ctx, insns_af, __arraycount(insns_af)); ctx->flags |= FETCHED_L3; ctx->af = af; if (af) { uint32_t mwords[] = { BM_IPVER, 1, af }; add_bmarks(ctx, mwords, sizeof(mwords)); } if (ingroup) { npfctl_bpf_group_enter(ctx, invert); } } else if (af && af != ctx->af) { errx(EXIT_FAILURE, "address family mismatch"); } if ((flags & X_EQ_L4OFF) != 0 && (ctx->flags & X_EQ_L4OFF) == 0) { /* X <- IP header length */ struct bpf_insn insns_hlen[] = { BPF_STMT(BPF_LDX+BPF_MEM, BPF_MW_L4OFF), }; add_insns(ctx, insns_hlen, __arraycount(insns_hlen)); ctx->flags |= X_EQ_L4OFF; } } static void bm_invert_checkpoint(npf_bpf_t *ctx, const unsigned opts) { uint32_t bm = 0; if (ctx->ingroup && ctx->invert) { const unsigned seen = ctx->invflags; if ((opts & MATCH_SRC) != 0 && (seen & MATCH_SRC) == 0) { bm = BM_SRC_NEG; } if ((opts & MATCH_DST) != 0 && (seen & MATCH_DST) == 0) { bm = BM_DST_NEG; } ctx->invflags |= opts & (MATCH_SRC | MATCH_DST); } if (bm) { uint32_t mwords[] = { bm, 0 }; add_bmarks(ctx, mwords, sizeof(mwords)); } } /* * npfctl_bpf_ipver: match the IP version. */ void npfctl_bpf_ipver(npf_bpf_t *ctx, sa_family_t af) { fetch_l3(ctx, af, 0); } /* * npfctl_bpf_proto: code block to match IP version and L4 protocol. */ void npfctl_bpf_proto(npf_bpf_t *ctx, unsigned proto) { struct bpf_insn insns_proto[] = { /* A <- L4 protocol; A == expected-protocol? */ BPF_STMT(BPF_LD+BPF_W+BPF_MEM, BPF_MW_L4PROTO), BPF_JUMP(BPF_JMP+BPF_JEQ+BPF_K, proto, 0, JUMP_MAGIC), }; add_insns(ctx, insns_proto, __arraycount(insns_proto)); uint32_t mwords[] = { BM_PROTO, 1, proto }; done_block(ctx, mwords, sizeof(mwords)); ctx->flags |= CHECKED_L4_PROTO; } /* * npfctl_bpf_cidr: code block to match IPv4 or IPv6 CIDR. * * => IP address shall be in the network byte order. */ void npfctl_bpf_cidr(npf_bpf_t *ctx, unsigned opts, sa_family_t af, const npf_addr_t *addr, const npf_netmask_t mask) { const uint32_t *awords = (const uint32_t *)addr; unsigned nwords, origlength, length, maxmask, off; assert(((opts & MATCH_SRC) != 0) ^ ((opts & MATCH_DST) != 0)); assert((mask && mask <= NPF_MAX_NETMASK) || mask == NPF_NO_NETMASK); switch (af) { case AF_INET: maxmask = 32; off = (opts & MATCH_SRC) ? offsetof(struct ip, ip_src) : offsetof(struct ip, ip_dst); nwords = sizeof(struct in_addr) / sizeof(uint32_t); break; case AF_INET6: maxmask = 128; off = (opts & MATCH_SRC) ? offsetof(struct ip6_hdr, ip6_src) : offsetof(struct ip6_hdr, ip6_dst); nwords = sizeof(struct in6_addr) / sizeof(uint32_t); break; default: abort(); } /* Ensure address family. */ fetch_l3(ctx, af, 0); length = origlength = (mask == NPF_NO_NETMASK) ? maxmask : mask; /* CAUTION: BPF operates in host byte-order. */ for (unsigned i = 0; i < nwords; i++) { const unsigned woff = i * sizeof(uint32_t); uint32_t word = ntohl(awords[i]); uint32_t wordmask; if (length >= 32) { /* The mask is a full word - do not apply it. */ wordmask = 0; length -= 32; } else if (length) { wordmask = 0xffffffff << (32 - length); length = 0; } else { /* The mask became zero - skip the rest. */ break; } /* A <- IP address (or one word of it) */ struct bpf_insn insns_ip[] = { BPF_STMT(BPF_LD+BPF_W+BPF_ABS, off + woff), }; add_insns(ctx, insns_ip, __arraycount(insns_ip)); /* A <- (A & MASK) */ if (wordmask) { struct bpf_insn insns_mask[] = { BPF_STMT(BPF_ALU+BPF_AND+BPF_K, wordmask), }; add_insns(ctx, insns_mask, __arraycount(insns_mask)); } /* * Determine how many instructions we have to jump * ahead if the match fails. * * - If this is the last word, we jump to the final * failure, JUMP_MAGIC. * * - If this is not the last word, we jump past the * remaining instructions to match this sequence. * Each 32-bit word in the sequence takes two * instructions (BPF_LD and BPF_JMP). If there is a * partial-word mask ahead, there will be one * additional instruction (BPF_ALU). */ uint8_t jf; if (i + 1 == (origlength + 31)/32) { jf = JUMP_MAGIC; } else { jf = 2*((origlength + 31)/32 - i - 1); if (origlength % 32 != 0 && wordmask == 0) jf += 1; } /* A == expected-IP-word ? */ struct bpf_insn insns_cmp[] = { BPF_JUMP(BPF_JMP+BPF_JEQ+BPF_K, word, 0, jf), }; add_insns(ctx, insns_cmp, __arraycount(insns_cmp)); } /* * If we checked a chain of words in sequence, mark this as a * multi-word comparison so if this is in a group there will be * a fallthrough case. * * XXX This is a little silly; the compiler should really just * record holes where conditional jumps need success/failure * continuations, and go back to fill in the holes when the * locations of the continuations are determined later. But * that requires restructuring this code a little more. */ ctx->multiword = (origlength + 31)/32 > 1; uint32_t mwords[] = { (opts & MATCH_SRC) ? BM_SRC_CIDR: BM_DST_CIDR, 6, af, mask, awords[0], awords[1], awords[2], awords[3], }; bm_invert_checkpoint(ctx, opts); done_block(ctx, mwords, sizeof(mwords)); } /* * npfctl_bpf_ports: code block to match TCP/UDP port range. * * => Port numbers shall be in the network byte order. */ void npfctl_bpf_ports(npf_bpf_t *ctx, unsigned opts, in_port_t from, in_port_t to) { const unsigned sport_off = offsetof(struct udphdr, uh_sport); const unsigned dport_off = offsetof(struct udphdr, uh_dport); unsigned off; /* TCP and UDP port offsets are the same. */ assert(sport_off == offsetof(struct tcphdr, th_sport)); assert(dport_off == offsetof(struct tcphdr, th_dport)); assert(ctx->flags & CHECKED_L4_PROTO); assert(((opts & MATCH_SRC) != 0) ^ ((opts & MATCH_DST) != 0)); off = (opts & MATCH_SRC) ? sport_off : dport_off; /* X <- IP header length */ fetch_l3(ctx, AF_UNSPEC, X_EQ_L4OFF); struct bpf_insn insns_fetch[] = { /* A <- port */ BPF_STMT(BPF_LD+BPF_H+BPF_IND, off), }; add_insns(ctx, insns_fetch, __arraycount(insns_fetch)); /* CAUTION: BPF operates in host byte-order. */ from = ntohs(from); to = ntohs(to); if (from == to) { /* Single port case. */ struct bpf_insn insns_port[] = { BPF_JUMP(BPF_JMP+BPF_JEQ+BPF_K, from, 0, JUMP_MAGIC), }; add_insns(ctx, insns_port, __arraycount(insns_port)); } else { /* Port range case. */ struct bpf_insn insns_range[] = { BPF_JUMP(BPF_JMP+BPF_JGE+BPF_K, from, 0, 1), BPF_JUMP(BPF_JMP+BPF_JGT+BPF_K, to, 0, 1), BPF_STMT(BPF_JMP+BPF_JA, JUMP_MAGIC), }; add_insns(ctx, insns_range, __arraycount(insns_range)); } uint32_t mwords[] = { (opts & MATCH_SRC) ? BM_SRC_PORTS : BM_DST_PORTS, 2, from, to }; done_block(ctx, mwords, sizeof(mwords)); } /* * npfctl_bpf_tcpfl: code block to match TCP flags. */ void npfctl_bpf_tcpfl(npf_bpf_t *ctx, uint8_t tf, uint8_t tf_mask) { const unsigned tcpfl_off = offsetof(struct tcphdr, th_flags); const bool usingmask = tf_mask != tf; /* X <- IP header length */ fetch_l3(ctx, AF_UNSPEC, X_EQ_L4OFF); if ((ctx->flags & CHECKED_L4_PROTO) == 0) { const unsigned jf = usingmask ? 3 : 2; assert(ctx->ingroup == 0); /* * A <- L4 protocol; A == TCP? If not, jump out. * * Note: the TCP flag matching might be without 'proto tcp' * when using a plain 'stateful' rule. In such case it also * handles other protocols, thus no strict TCP check. */ struct bpf_insn insns_tcp[] = { BPF_STMT(BPF_LD+BPF_W+BPF_MEM, BPF_MW_L4PROTO), BPF_JUMP(BPF_JMP+BPF_JEQ+BPF_K, IPPROTO_TCP, 0, jf), }; add_insns(ctx, insns_tcp, __arraycount(insns_tcp)); } struct bpf_insn insns_tf[] = { /* A <- TCP flags */ BPF_STMT(BPF_LD+BPF_B+BPF_IND, tcpfl_off), }; add_insns(ctx, insns_tf, __arraycount(insns_tf)); if (usingmask) { /* A <- (A & mask) */ struct bpf_insn insns_mask[] = { BPF_STMT(BPF_ALU+BPF_AND+BPF_K, tf_mask), }; add_insns(ctx, insns_mask, __arraycount(insns_mask)); } struct bpf_insn insns_cmp[] = { /* A == expected-TCP-flags? */ BPF_JUMP(BPF_JMP+BPF_JEQ+BPF_K, tf, 0, JUMP_MAGIC), }; add_insns(ctx, insns_cmp, __arraycount(insns_cmp)); uint32_t mwords[] = { BM_TCPFL, 2, tf, tf_mask }; done_block(ctx, mwords, sizeof(mwords)); } /* * npfctl_bpf_icmp: code block to match ICMP type and/or code. * Note: suitable for both the ICMPv4 and ICMPv6. */ void npfctl_bpf_icmp(npf_bpf_t *ctx, int type, int code) { const u_int type_off = offsetof(struct icmp, icmp_type); const u_int code_off = offsetof(struct icmp, icmp_code); assert(ctx->flags & CHECKED_L4_PROTO); assert(offsetof(struct icmp6_hdr, icmp6_type) == type_off); assert(offsetof(struct icmp6_hdr, icmp6_code) == code_off); assert(type != -1 || code != -1); /* X <- IP header length */ fetch_l3(ctx, AF_UNSPEC, X_EQ_L4OFF); if (type != -1) { struct bpf_insn insns_type[] = { BPF_STMT(BPF_LD+BPF_B+BPF_IND, type_off), BPF_JUMP(BPF_JMP+BPF_JEQ+BPF_K, type, 0, JUMP_MAGIC), }; add_insns(ctx, insns_type, __arraycount(insns_type)); uint32_t mwords[] = { BM_ICMP_TYPE, 1, type }; done_block(ctx, mwords, sizeof(mwords)); } if (code != -1) { struct bpf_insn insns_code[] = { BPF_STMT(BPF_LD+BPF_B+BPF_IND, code_off), BPF_JUMP(BPF_JMP+BPF_JEQ+BPF_K, code, 0, JUMP_MAGIC), }; add_insns(ctx, insns_code, __arraycount(insns_code)); uint32_t mwords[] = { BM_ICMP_CODE, 1, code }; done_block(ctx, mwords, sizeof(mwords)); } } #define SRC_FLAG_BIT (1U << 31) /* * npfctl_bpf_table: code block to match source/destination IP address * against NPF table specified by ID. */ void npfctl_bpf_table(npf_bpf_t *ctx, unsigned opts, unsigned tid) { const bool src = (opts & MATCH_SRC) != 0; struct bpf_insn insns_table[] = { BPF_STMT(BPF_LD+BPF_IMM, (src ? SRC_FLAG_BIT : 0) | tid), BPF_STMT(BPF_MISC+BPF_COP, NPF_COP_TABLE), BPF_JUMP(BPF_JMP+BPF_JEQ+BPF_K, 0, JUMP_MAGIC, 0), }; add_insns(ctx, insns_table, __arraycount(insns_table)); uint32_t mwords[] = { src ? BM_SRC_TABLE: BM_DST_TABLE, 1, tid }; bm_invert_checkpoint(ctx, opts); done_block(ctx, mwords, sizeof(mwords)); }