// SPDX-License-Identifier: GPL-2.0-only /* Copyright (c) 2025 Meta Platforms, Inc. and affiliates. */ #include #include #include #include #include #include #define verbose(env, fmt, args...) bpf_verifier_log_write(env, fmt, ##args) struct per_frame_masks { spis_t may_read; /* stack slots that may be read by this instruction */ spis_t must_write; /* stack slots written by this instruction */ spis_t live_before; /* stack slots that may be read by this insn and its successors */ }; /* * A function instance keyed by (callsite, depth). * Encapsulates read and write marks for each instruction in the function. * Marks are tracked for each frame up to @depth. */ struct func_instance { struct hlist_node hl_node; u32 callsite; /* call insn that invoked this subprog (subprog_start for depth 0) */ u32 depth; /* call depth (0 = entry subprog) */ u32 subprog; /* subprog index */ u32 subprog_start; /* cached env->subprog_info[subprog].start */ u32 insn_cnt; /* cached number of insns in the function */ /* Per frame, per instruction masks, frames allocated lazily. */ struct per_frame_masks *frames[MAX_CALL_FRAMES]; bool must_write_initialized; }; struct live_stack_query { struct func_instance *instances[MAX_CALL_FRAMES]; /* valid in range [0..curframe] */ u32 callsites[MAX_CALL_FRAMES]; /* callsite[i] = insn calling frame i+1 */ u32 curframe; u32 insn_idx; }; struct bpf_liveness { DECLARE_HASHTABLE(func_instances, 8); /* maps (depth, callsite) to func_instance */ struct live_stack_query live_stack_query; /* cache to avoid repetitive ht lookups */ u32 subprog_calls; /* analyze_subprog() invocations */ }; /* * Hash/compare key for func_instance: (depth, callsite). * For depth == 0 (entry subprog), @callsite is the subprog start insn. * For depth > 0, @callsite is the call instruction index that invoked the subprog. */ static u32 instance_hash(u32 callsite, u32 depth) { u32 key[2] = { depth, callsite }; return jhash2(key, 2, 0); } static struct func_instance *find_instance(struct bpf_verifier_env *env, u32 callsite, u32 depth) { struct bpf_liveness *liveness = env->liveness; struct func_instance *f; u32 key = instance_hash(callsite, depth); hash_for_each_possible(liveness->func_instances, f, hl_node, key) if (f->depth == depth && f->callsite == callsite) return f; return NULL; } static struct func_instance *call_instance(struct bpf_verifier_env *env, struct func_instance *caller, u32 callsite, int subprog) { u32 depth = caller ? caller->depth + 1 : 0; u32 subprog_start = env->subprog_info[subprog].start; u32 lookup_key = depth > 0 ? callsite : subprog_start; struct func_instance *f; u32 hash; f = find_instance(env, lookup_key, depth); if (f) return f; f = kvzalloc(sizeof(*f), GFP_KERNEL_ACCOUNT); if (!f) return ERR_PTR(-ENOMEM); f->callsite = lookup_key; f->depth = depth; f->subprog = subprog; f->subprog_start = subprog_start; f->insn_cnt = (env->subprog_info + subprog + 1)->start - subprog_start; hash = instance_hash(lookup_key, depth); hash_add(env->liveness->func_instances, &f->hl_node, hash); return f; } static struct func_instance *lookup_instance(struct bpf_verifier_env *env, struct bpf_verifier_state *st, u32 frameno) { u32 callsite, subprog_start; struct func_instance *f; u32 key, depth; subprog_start = env->subprog_info[st->frame[frameno]->subprogno].start; callsite = frameno > 0 ? st->frame[frameno]->callsite : subprog_start; for (depth = frameno; ; depth--) { key = depth > 0 ? callsite : subprog_start; f = find_instance(env, key, depth); if (f || depth == 0) return f; } } int bpf_stack_liveness_init(struct bpf_verifier_env *env) { env->liveness = kvzalloc_obj(*env->liveness, GFP_KERNEL_ACCOUNT); if (!env->liveness) return -ENOMEM; hash_init(env->liveness->func_instances); return 0; } void bpf_stack_liveness_free(struct bpf_verifier_env *env) { struct func_instance *instance; struct hlist_node *tmp; int bkt, i; if (!env->liveness) return; hash_for_each_safe(env->liveness->func_instances, bkt, tmp, instance, hl_node) { for (i = 0; i <= instance->depth; i++) kvfree(instance->frames[i]); kvfree(instance); } kvfree(env->liveness); } /* * Convert absolute instruction index @insn_idx to an index relative * to start of the function corresponding to @instance. */ static int relative_idx(struct func_instance *instance, u32 insn_idx) { return insn_idx - instance->subprog_start; } static struct per_frame_masks *get_frame_masks(struct func_instance *instance, u32 frame, u32 insn_idx) { if (!instance->frames[frame]) return NULL; return &instance->frames[frame][relative_idx(instance, insn_idx)]; } static struct per_frame_masks *alloc_frame_masks(struct func_instance *instance, u32 frame, u32 insn_idx) { struct per_frame_masks *arr; if (!instance->frames[frame]) { arr = kvzalloc_objs(*arr, instance->insn_cnt, GFP_KERNEL_ACCOUNT); instance->frames[frame] = arr; if (!arr) return ERR_PTR(-ENOMEM); } return get_frame_masks(instance, frame, insn_idx); } /* Accumulate may_read masks for @frame at @insn_idx */ static int mark_stack_read(struct func_instance *instance, u32 frame, u32 insn_idx, spis_t mask) { struct per_frame_masks *masks; masks = alloc_frame_masks(instance, frame, insn_idx); if (IS_ERR(masks)) return PTR_ERR(masks); masks->may_read = spis_or(masks->may_read, mask); return 0; } static int mark_stack_write(struct func_instance *instance, u32 frame, u32 insn_idx, spis_t mask) { struct per_frame_masks *masks; masks = alloc_frame_masks(instance, frame, insn_idx); if (IS_ERR(masks)) return PTR_ERR(masks); masks->must_write = spis_or(masks->must_write, mask); return 0; } int bpf_jmp_offset(struct bpf_insn *insn) { u8 code = insn->code; if (code == (BPF_JMP32 | BPF_JA)) return insn->imm; return insn->off; } __diag_push(); __diag_ignore_all("-Woverride-init", "Allow field initialization overrides for opcode_info_tbl"); /* * Returns an array of instructions succ, with succ->items[0], ..., * succ->items[n-1] with successor instructions, where n=succ->cnt */ inline struct bpf_iarray * bpf_insn_successors(struct bpf_verifier_env *env, u32 idx) { static const struct opcode_info { bool can_jump; bool can_fallthrough; } opcode_info_tbl[256] = { [0 ... 255] = {.can_jump = false, .can_fallthrough = true}, #define _J(code, ...) \ [BPF_JMP | code] = __VA_ARGS__, \ [BPF_JMP32 | code] = __VA_ARGS__ _J(BPF_EXIT, {.can_jump = false, .can_fallthrough = false}), _J(BPF_JA, {.can_jump = true, .can_fallthrough = false}), _J(BPF_JEQ, {.can_jump = true, .can_fallthrough = true}), _J(BPF_JNE, {.can_jump = true, .can_fallthrough = true}), _J(BPF_JLT, {.can_jump = true, .can_fallthrough = true}), _J(BPF_JLE, {.can_jump = true, .can_fallthrough = true}), _J(BPF_JGT, {.can_jump = true, .can_fallthrough = true}), _J(BPF_JGE, {.can_jump = true, .can_fallthrough = true}), _J(BPF_JSGT, {.can_jump = true, .can_fallthrough = true}), _J(BPF_JSGE, {.can_jump = true, .can_fallthrough = true}), _J(BPF_JSLT, {.can_jump = true, .can_fallthrough = true}), _J(BPF_JSLE, {.can_jump = true, .can_fallthrough = true}), _J(BPF_JCOND, {.can_jump = true, .can_fallthrough = true}), _J(BPF_JSET, {.can_jump = true, .can_fallthrough = true}), #undef _J }; struct bpf_prog *prog = env->prog; struct bpf_insn *insn = &prog->insnsi[idx]; const struct opcode_info *opcode_info; struct bpf_iarray *succ, *jt; int insn_sz; jt = env->insn_aux_data[idx].jt; if (unlikely(jt)) return jt; /* pre-allocated array of size up to 2; reset cnt, as it may have been used already */ succ = env->succ; succ->cnt = 0; opcode_info = &opcode_info_tbl[BPF_CLASS(insn->code) | BPF_OP(insn->code)]; insn_sz = bpf_is_ldimm64(insn) ? 2 : 1; if (opcode_info->can_fallthrough) succ->items[succ->cnt++] = idx + insn_sz; if (opcode_info->can_jump) succ->items[succ->cnt++] = idx + bpf_jmp_offset(insn) + 1; return succ; } __diag_pop(); static inline bool update_insn(struct bpf_verifier_env *env, struct func_instance *instance, u32 frame, u32 insn_idx) { spis_t new_before, new_after; struct per_frame_masks *insn, *succ_insn; struct bpf_iarray *succ; u32 s; bool changed; succ = bpf_insn_successors(env, insn_idx); if (succ->cnt == 0) return false; changed = false; insn = get_frame_masks(instance, frame, insn_idx); new_before = SPIS_ZERO; new_after = SPIS_ZERO; for (s = 0; s < succ->cnt; ++s) { succ_insn = get_frame_masks(instance, frame, succ->items[s]); new_after = spis_or(new_after, succ_insn->live_before); } /* * New "live_before" is a union of all "live_before" of successors * minus slots written by instruction plus slots read by instruction. * new_before = (new_after & ~insn->must_write) | insn->may_read */ new_before = spis_or(spis_and(new_after, spis_not(insn->must_write)), insn->may_read); changed |= !spis_equal(new_before, insn->live_before); insn->live_before = new_before; return changed; } /* Fixed-point computation of @live_before marks */ static void update_instance(struct bpf_verifier_env *env, struct func_instance *instance) { u32 i, frame, po_start, po_end; int *insn_postorder = env->cfg.insn_postorder; struct bpf_subprog_info *subprog; bool changed; instance->must_write_initialized = true; subprog = &env->subprog_info[instance->subprog]; po_start = subprog->postorder_start; po_end = (subprog + 1)->postorder_start; /* repeat until fixed point is reached */ do { changed = false; for (frame = 0; frame <= instance->depth; frame++) { if (!instance->frames[frame]) continue; for (i = po_start; i < po_end; i++) changed |= update_insn(env, instance, frame, insn_postorder[i]); } } while (changed); } static bool is_live_before(struct func_instance *instance, u32 insn_idx, u32 frameno, u32 half_spi) { struct per_frame_masks *masks; masks = get_frame_masks(instance, frameno, insn_idx); return masks && spis_test_bit(masks->live_before, half_spi); } int bpf_live_stack_query_init(struct bpf_verifier_env *env, struct bpf_verifier_state *st) { struct live_stack_query *q = &env->liveness->live_stack_query; struct func_instance *instance; u32 frame; memset(q, 0, sizeof(*q)); for (frame = 0; frame <= st->curframe; frame++) { instance = lookup_instance(env, st, frame); if (IS_ERR_OR_NULL(instance)) q->instances[frame] = NULL; else q->instances[frame] = instance; if (frame < st->curframe) q->callsites[frame] = st->frame[frame + 1]->callsite; } q->curframe = st->curframe; q->insn_idx = st->insn_idx; return 0; } bool bpf_stack_slot_alive(struct bpf_verifier_env *env, u32 frameno, u32 half_spi) { /* * Slot is alive if it is read before q->insn_idx in current func instance, * or if for some outer func instance: * - alive before callsite if callsite calls callback, otherwise * - alive after callsite */ struct live_stack_query *q = &env->liveness->live_stack_query; struct func_instance *instance, *curframe_instance; u32 i, callsite, rel; int cur_delta, delta; bool alive = false; curframe_instance = q->instances[q->curframe]; if (!curframe_instance) return true; cur_delta = (int)curframe_instance->depth - (int)q->curframe; rel = frameno + cur_delta; if (rel <= curframe_instance->depth) alive = is_live_before(curframe_instance, q->insn_idx, rel, half_spi); if (alive) return true; for (i = frameno; i < q->curframe; i++) { instance = q->instances[i]; if (!instance) return true; /* Map actual frameno to frame index within this instance */ delta = (int)instance->depth - (int)i; rel = frameno + delta; if (rel > instance->depth) return true; /* Get callsite from verifier state, not from instance callchain */ callsite = q->callsites[i]; alive = bpf_calls_callback(env, callsite) ? is_live_before(instance, callsite, rel, half_spi) : is_live_before(instance, callsite + 1, rel, half_spi); if (alive) return true; } return false; } static char *fmt_subprog(struct bpf_verifier_env *env, int subprog) { const char *name = env->subprog_info[subprog].name; snprintf(env->tmp_str_buf, sizeof(env->tmp_str_buf), "subprog#%d%s%s", subprog, name ? " " : "", name ? name : ""); return env->tmp_str_buf; } static char *fmt_instance(struct bpf_verifier_env *env, struct func_instance *instance) { snprintf(env->tmp_str_buf, sizeof(env->tmp_str_buf), "(d%d,cs%d)", instance->depth, instance->callsite); return env->tmp_str_buf; } static int spi_off(int spi) { return -(spi + 1) * BPF_REG_SIZE; } /* * When both halves of an 8-byte SPI are set, print as "-8","-16",... * When only one half is set, print as "-4h","-8h",... * Runs of 3+ consecutive fully-set SPIs are collapsed: "fp0-8..-24" */ static char *fmt_spis_mask(struct bpf_verifier_env *env, int frame, bool first, spis_t spis) { int buf_sz = sizeof(env->tmp_str_buf); char *buf = env->tmp_str_buf; int spi, n, run_start; buf[0] = '\0'; for (spi = 0; spi < STACK_SLOTS / 2 && buf_sz > 0; spi++) { bool lo = spis_test_bit(spis, spi * 2); bool hi = spis_test_bit(spis, spi * 2 + 1); const char *space = first ? "" : " "; if (!lo && !hi) continue; if (!lo || !hi) { /* half-spi */ n = scnprintf(buf, buf_sz, "%sfp%d%d%s", space, frame, spi_off(spi) + (lo ? STACK_SLOT_SZ : 0), "h"); } else if (spi + 2 < STACK_SLOTS / 2 && spis_test_bit(spis, spi * 2 + 2) && spis_test_bit(spis, spi * 2 + 3) && spis_test_bit(spis, spi * 2 + 4) && spis_test_bit(spis, spi * 2 + 5)) { /* 3+ consecutive full spis */ run_start = spi; while (spi + 1 < STACK_SLOTS / 2 && spis_test_bit(spis, (spi + 1) * 2) && spis_test_bit(spis, (spi + 1) * 2 + 1)) spi++; n = scnprintf(buf, buf_sz, "%sfp%d%d..%d", space, frame, spi_off(run_start), spi_off(spi)); } else { /* just a full spi */ n = scnprintf(buf, buf_sz, "%sfp%d%d", space, frame, spi_off(spi)); } first = false; buf += n; buf_sz -= n; } return env->tmp_str_buf; } static void print_instance(struct bpf_verifier_env *env, struct func_instance *instance) { int start = env->subprog_info[instance->subprog].start; struct bpf_insn *insns = env->prog->insnsi; struct per_frame_masks *masks; int len = instance->insn_cnt; int insn_idx, frame, i; bool has_use, has_def; u64 pos, insn_pos; if (!(env->log.level & BPF_LOG_LEVEL2)) return; verbose(env, "stack use/def %s ", fmt_subprog(env, instance->subprog)); verbose(env, "%s:\n", fmt_instance(env, instance)); for (i = 0; i < len; i++) { insn_idx = start + i; has_use = false; has_def = false; pos = env->log.end_pos; verbose(env, "%3d: ", insn_idx); bpf_verbose_insn(env, &insns[insn_idx]); bpf_vlog_reset(&env->log, env->log.end_pos - 1); /* remove \n */ insn_pos = env->log.end_pos; verbose(env, "%*c;", bpf_vlog_alignment(insn_pos - pos), ' '); pos = env->log.end_pos; verbose(env, " use: "); for (frame = instance->depth; frame >= 0; --frame) { masks = get_frame_masks(instance, frame, insn_idx); if (!masks || spis_is_zero(masks->may_read)) continue; verbose(env, "%s", fmt_spis_mask(env, frame, !has_use, masks->may_read)); has_use = true; } if (!has_use) bpf_vlog_reset(&env->log, pos); pos = env->log.end_pos; verbose(env, " def: "); for (frame = instance->depth; frame >= 0; --frame) { masks = get_frame_masks(instance, frame, insn_idx); if (!masks || spis_is_zero(masks->must_write)) continue; verbose(env, "%s", fmt_spis_mask(env, frame, !has_def, masks->must_write)); has_def = true; } if (!has_def) bpf_vlog_reset(&env->log, has_use ? pos : insn_pos); verbose(env, "\n"); if (bpf_is_ldimm64(&insns[insn_idx])) i++; } } static int cmp_instances(const void *pa, const void *pb) { struct func_instance *a = *(struct func_instance **)pa; struct func_instance *b = *(struct func_instance **)pb; int dcallsite = (int)a->callsite - b->callsite; int ddepth = (int)a->depth - b->depth; if (dcallsite) return dcallsite; if (ddepth) return ddepth; return 0; } /* print use/def slots for all instances ordered by callsite first, then by depth */ static int print_instances(struct bpf_verifier_env *env) { struct func_instance *instance, **sorted_instances; struct bpf_liveness *liveness = env->liveness; int i, bkt, cnt; cnt = 0; hash_for_each(liveness->func_instances, bkt, instance, hl_node) cnt++; sorted_instances = kvmalloc_objs(*sorted_instances, cnt, GFP_KERNEL_ACCOUNT); if (!sorted_instances) return -ENOMEM; cnt = 0; hash_for_each(liveness->func_instances, bkt, instance, hl_node) sorted_instances[cnt++] = instance; sort(sorted_instances, cnt, sizeof(*sorted_instances), cmp_instances, NULL); for (i = 0; i < cnt; i++) print_instance(env, sorted_instances[i]); kvfree(sorted_instances); return 0; } /* * Per-register tracking state for compute_subprog_args(). * Tracks which frame's FP a value is derived from * and the byte offset from that frame's FP. * * The .frame field forms a lattice with three levels of precision: * * precise {frame=N, off=V} -- known absolute frame index and byte offset * | * offset-imprecise {frame=N, cnt=0} * | -- known frame identity, unknown offset * fully-imprecise {frame=ARG_IMPRECISE, mask=bitmask} * -- unknown frame identity; .mask is a * bitmask of which frame indices might be * involved * * At CFG merge points, arg_track_join() moves down the lattice: * - same frame + same offset -> precise * - same frame + different offset -> offset-imprecise * - different frames -> fully-imprecise (bitmask OR) * * At memory access sites (LDX/STX/ST), offset-imprecise marks only * the known frame's access mask as SPIS_ALL, while fully-imprecise * iterates bits in the bitmask and routes each frame to its target. */ #define MAX_ARG_OFFSETS 4 struct arg_track { union { s16 off[MAX_ARG_OFFSETS]; /* byte offsets; off_cnt says how many */ u16 mask; /* arg bitmask when arg == ARG_IMPRECISE */ }; s8 frame; /* absolute frame index, or enum arg_track_state */ s8 off_cnt; /* 0 = offset-imprecise, 1-4 = # of precise offsets */ }; enum arg_track_state { ARG_NONE = -1, /* not derived from any argument */ ARG_UNVISITED = -2, /* not yet reached by dataflow */ ARG_IMPRECISE = -3, /* lost identity; .mask is arg bitmask */ }; /* Track callee stack slots fp-8 through fp-512 (64 slots of 8 bytes each) */ #define MAX_ARG_SPILL_SLOTS 64 static bool arg_is_visited(const struct arg_track *at) { return at->frame != ARG_UNVISITED; } static bool arg_is_fp(const struct arg_track *at) { return at->frame >= 0 || at->frame == ARG_IMPRECISE; } static void verbose_arg_track(struct bpf_verifier_env *env, struct arg_track *at) { int i; switch (at->frame) { case ARG_NONE: verbose(env, "_"); break; case ARG_UNVISITED: verbose(env, "?"); break; case ARG_IMPRECISE: verbose(env, "IMP%x", at->mask); break; default: /* frame >= 0: absolute frame index */ if (at->off_cnt == 0) { verbose(env, "fp%d ?", at->frame); } else { for (i = 0; i < at->off_cnt; i++) { if (i) verbose(env, "|"); verbose(env, "fp%d%+d", at->frame, at->off[i]); } } break; } } static bool arg_track_eq(const struct arg_track *a, const struct arg_track *b) { int i; if (a->frame != b->frame) return false; if (a->frame == ARG_IMPRECISE) return a->mask == b->mask; if (a->frame < 0) return true; if (a->off_cnt != b->off_cnt) return false; for (i = 0; i < a->off_cnt; i++) if (a->off[i] != b->off[i]) return false; return true; } static struct arg_track arg_single(s8 arg, s16 off) { struct arg_track at = {}; at.frame = arg; at.off[0] = off; at.off_cnt = 1; return at; } /* * Merge two sorted offset arrays, deduplicate. * Returns off_cnt=0 if the result exceeds MAX_ARG_OFFSETS. * Both args must have the same frame and off_cnt > 0. */ static struct arg_track arg_merge_offsets(struct arg_track a, struct arg_track b) { struct arg_track result = { .frame = a.frame }; struct arg_track imp = { .frame = a.frame }; int i = 0, j = 0, k = 0; while (i < a.off_cnt && j < b.off_cnt) { s16 v; if (a.off[i] <= b.off[j]) { v = a.off[i++]; if (v == b.off[j]) j++; } else { v = b.off[j++]; } if (k > 0 && result.off[k - 1] == v) continue; if (k >= MAX_ARG_OFFSETS) return imp; result.off[k++] = v; } while (i < a.off_cnt) { if (k >= MAX_ARG_OFFSETS) return imp; result.off[k++] = a.off[i++]; } while (j < b.off_cnt) { if (k >= MAX_ARG_OFFSETS) return imp; result.off[k++] = b.off[j++]; } result.off_cnt = k; return result; } /* * Merge two arg_tracks into ARG_IMPRECISE, collecting the frame * bits from both operands. Precise frame indices (frame >= 0) * contribute a single bit; existing ARG_IMPRECISE values * contribute their full bitmask. */ static struct arg_track arg_join_imprecise(struct arg_track a, struct arg_track b) { u32 m = 0; if (a.frame >= 0) m |= BIT(a.frame); else if (a.frame == ARG_IMPRECISE) m |= a.mask; if (b.frame >= 0) m |= BIT(b.frame); else if (b.frame == ARG_IMPRECISE) m |= b.mask; return (struct arg_track){ .mask = m, .frame = ARG_IMPRECISE }; } /* Join two arg_track values at merge points */ static struct arg_track __arg_track_join(struct arg_track a, struct arg_track b) { if (!arg_is_visited(&b)) return a; if (!arg_is_visited(&a)) return b; if (a.frame == b.frame && a.frame >= 0) { /* Both offset-imprecise: stay imprecise */ if (a.off_cnt == 0 || b.off_cnt == 0) return (struct arg_track){ .frame = a.frame }; /* Merge offset sets; falls back to off_cnt=0 if >4 */ return arg_merge_offsets(a, b); } /* * args are different, but one of them is known * arg + none -> arg * none + arg -> arg * * none + none -> none */ if (a.frame == ARG_NONE && b.frame == ARG_NONE) return a; if (a.frame >= 0 && b.frame == ARG_NONE) { /* * When joining single fp-N add fake fp+0 to * keep stack_use and prevent stack_def */ if (a.off_cnt == 1) return arg_merge_offsets(a, arg_single(a.frame, 0)); return a; } if (b.frame >= 0 && a.frame == ARG_NONE) { if (b.off_cnt == 1) return arg_merge_offsets(b, arg_single(b.frame, 0)); return b; } return arg_join_imprecise(a, b); } static bool arg_track_join(struct bpf_verifier_env *env, int idx, int target, int r, struct arg_track *in, struct arg_track out) { struct arg_track old = *in; struct arg_track new_val = __arg_track_join(old, out); if (arg_track_eq(&new_val, &old)) return false; *in = new_val; if (!(env->log.level & BPF_LOG_LEVEL2) || !arg_is_visited(&old)) return true; verbose(env, "arg JOIN insn %d -> %d ", idx, target); if (r >= 0) verbose(env, "r%d: ", r); else verbose(env, "fp%+d: ", r * 8); verbose_arg_track(env, &old); verbose(env, " + "); verbose_arg_track(env, &out); verbose(env, " => "); verbose_arg_track(env, &new_val); verbose(env, "\n"); return true; } /* * Compute the result when an ALU op destroys offset precision. * If a single arg is identifiable, preserve it with OFF_IMPRECISE. * If two different args are involved or one is already ARG_IMPRECISE, * the result is fully ARG_IMPRECISE. */ static void arg_track_alu64(struct arg_track *dst, const struct arg_track *src) { WARN_ON_ONCE(!arg_is_visited(dst)); WARN_ON_ONCE(!arg_is_visited(src)); if (dst->frame >= 0 && (src->frame == ARG_NONE || src->frame == dst->frame)) { /* * rX += rY where rY is not arg derived * rX += rX */ dst->off_cnt = 0; return; } if (src->frame >= 0 && dst->frame == ARG_NONE) { /* * rX += rY where rX is not arg derived * rY identity leaks into rX */ dst->off_cnt = 0; dst->frame = src->frame; return; } if (dst->frame == ARG_NONE && src->frame == ARG_NONE) return; *dst = arg_join_imprecise(*dst, *src); } static bool arg_add(s16 off, s64 delta, s16 *out) { s16 d = delta; if (d != delta) return true; return check_add_overflow(off, d, out); } static void arg_padd(struct arg_track *at, s64 delta) { int i; if (at->off_cnt == 0) return; for (i = 0; i < at->off_cnt; i++) { s16 new_off; if (arg_add(at->off[i], delta, &new_off)) { at->off_cnt = 0; return; } at->off[i] = new_off; } } /* * Convert a byte offset from FP to a callee stack slot index. * Returns -1 if out of range or not 8-byte aligned. * Slot 0 = fp-8, slot 1 = fp-16, ..., slot 7 = fp-64, .... */ static int fp_off_to_slot(s16 off) { if (off >= 0 || off < -(int)(MAX_ARG_SPILL_SLOTS * 8)) return -1; if (off % 8) return -1; return (-off) / 8 - 1; } static struct arg_track fill_from_stack(struct bpf_insn *insn, struct arg_track *at_out, int reg, struct arg_track *at_stack_out, int depth) { struct arg_track imp = { .mask = (1u << (depth + 1)) - 1, .frame = ARG_IMPRECISE }; struct arg_track result = { .frame = ARG_NONE }; int cnt, i; if (reg == BPF_REG_FP) { int slot = fp_off_to_slot(insn->off); return slot >= 0 ? at_stack_out[slot] : imp; } cnt = at_out[reg].off_cnt; if (cnt == 0) return imp; for (i = 0; i < cnt; i++) { s16 fp_off, slot; if (arg_add(at_out[reg].off[i], insn->off, &fp_off)) return imp; slot = fp_off_to_slot(fp_off); if (slot < 0) return imp; result = __arg_track_join(result, at_stack_out[slot]); } return result; } /* * Spill @val to all possible stack slots indicated by the FP offsets in @reg. * For an 8-byte store, single candidate slot gets @val. multi-slots are joined. * sub-8-byte store joins with ARG_NONE. * When exact offset is unknown conservatively add reg values to all slots in at_stack_out. */ static void spill_to_stack(struct bpf_insn *insn, struct arg_track *at_out, int reg, struct arg_track *at_stack_out, struct arg_track *val, u32 sz) { struct arg_track none = { .frame = ARG_NONE }; struct arg_track new_val = sz == 8 ? *val : none; int cnt, i; if (reg == BPF_REG_FP) { int slot = fp_off_to_slot(insn->off); if (slot >= 0) at_stack_out[slot] = new_val; return; } cnt = at_out[reg].off_cnt; if (cnt == 0) { for (int slot = 0; slot < MAX_ARG_SPILL_SLOTS; slot++) at_stack_out[slot] = __arg_track_join(at_stack_out[slot], new_val); return; } for (i = 0; i < cnt; i++) { s16 fp_off; int slot; if (arg_add(at_out[reg].off[i], insn->off, &fp_off)) continue; slot = fp_off_to_slot(fp_off); if (slot < 0) continue; if (cnt == 1) at_stack_out[slot] = new_val; else at_stack_out[slot] = __arg_track_join(at_stack_out[slot], new_val); } } /* * Clear all tracked callee stack slots overlapping the byte range * [off, off+sz-1] where off is a negative FP-relative offset. */ static void clear_overlapping_stack_slots(struct arg_track *at_stack, s16 off, u32 sz, int cnt) { struct arg_track none = { .frame = ARG_NONE }; if (cnt == 0) { for (int i = 0; i < MAX_ARG_SPILL_SLOTS; i++) at_stack[i] = __arg_track_join(at_stack[i], none); return; } for (int i = 0; i < MAX_ARG_SPILL_SLOTS; i++) { int slot_start = -((i + 1) * 8); int slot_end = slot_start + 8; if (slot_start < off + (int)sz && slot_end > off) { if (cnt == 1) at_stack[i] = none; else at_stack[i] = __arg_track_join(at_stack[i], none); } } } /* * Clear stack slots overlapping all possible FP offsets in @reg. */ static void clear_stack_for_all_offs(struct bpf_insn *insn, struct arg_track *at_out, int reg, struct arg_track *at_stack_out, u32 sz) { int cnt, i; if (reg == BPF_REG_FP) { clear_overlapping_stack_slots(at_stack_out, insn->off, sz, 1); return; } cnt = at_out[reg].off_cnt; if (cnt == 0) { clear_overlapping_stack_slots(at_stack_out, 0, sz, cnt); return; } for (i = 0; i < cnt; i++) { s16 fp_off; if (arg_add(at_out[reg].off[i], insn->off, &fp_off)) { clear_overlapping_stack_slots(at_stack_out, 0, sz, 0); break; } clear_overlapping_stack_slots(at_stack_out, fp_off, sz, cnt); } } static void arg_track_log(struct bpf_verifier_env *env, struct bpf_insn *insn, int idx, struct arg_track *at_in, struct arg_track *at_stack_in, struct arg_track *at_out, struct arg_track *at_stack_out) { bool printed = false; int i; if (!(env->log.level & BPF_LOG_LEVEL2)) return; for (i = 0; i < MAX_BPF_REG; i++) { if (arg_track_eq(&at_out[i], &at_in[i])) continue; if (!printed) { verbose(env, "%3d: ", idx); bpf_verbose_insn(env, insn); bpf_vlog_reset(&env->log, env->log.end_pos - 1); printed = true; } verbose(env, "\tr%d: ", i); verbose_arg_track(env, &at_in[i]); verbose(env, " -> "); verbose_arg_track(env, &at_out[i]); } for (i = 0; i < MAX_ARG_SPILL_SLOTS; i++) { if (arg_track_eq(&at_stack_out[i], &at_stack_in[i])) continue; if (!printed) { verbose(env, "%3d: ", idx); bpf_verbose_insn(env, insn); bpf_vlog_reset(&env->log, env->log.end_pos - 1); printed = true; } verbose(env, "\tfp%+d: ", -(i + 1) * 8); verbose_arg_track(env, &at_stack_in[i]); verbose(env, " -> "); verbose_arg_track(env, &at_stack_out[i]); } if (printed) verbose(env, "\n"); } static bool can_be_local_fp(int depth, int regno, struct arg_track *at) { return regno == BPF_REG_FP || at->frame == depth || (at->frame == ARG_IMPRECISE && (at->mask & BIT(depth))); } /* * Pure dataflow transfer function for arg_track state. * Updates at_out[] based on how the instruction modifies registers. * Tracks spill/fill, but not other memory accesses. */ static void arg_track_xfer(struct bpf_verifier_env *env, struct bpf_insn *insn, int insn_idx, struct arg_track *at_out, struct arg_track *at_stack_out, struct func_instance *instance, u32 *callsites) { int depth = instance->depth; u8 class = BPF_CLASS(insn->code); u8 code = BPF_OP(insn->code); struct arg_track *dst = &at_out[insn->dst_reg]; struct arg_track *src = &at_out[insn->src_reg]; struct arg_track none = { .frame = ARG_NONE }; int r; if (class == BPF_ALU64 && BPF_SRC(insn->code) == BPF_K) { if (code == BPF_MOV) { *dst = none; } else if (dst->frame >= 0) { if (code == BPF_ADD) arg_padd(dst, insn->imm); else if (code == BPF_SUB) arg_padd(dst, -(s64)insn->imm); else /* Any other 64-bit alu on the pointer makes it imprecise */ dst->off_cnt = 0; } /* else if dst->frame is imprecise it stays so */ } else if (class == BPF_ALU64 && BPF_SRC(insn->code) == BPF_X) { if (code == BPF_MOV) { if (insn->off == 0) { *dst = *src; } else { /* addr_space_cast destroys a pointer */ *dst = none; } } else { arg_track_alu64(dst, src); } } else if (class == BPF_ALU) { /* * 32-bit alu destroys the pointer. * If src was a pointer it cannot leak into dst */ *dst = none; } else if (class == BPF_JMP && code == BPF_CALL) { /* * at_stack_out[slot] is not cleared by the helper and subprog calls. * The fill_from_stack() may return the stale spill — which is an FP-derived arg_track * (the value that was originally spilled there). The loaded register then carries * a phantom FP-derived identity that doesn't correspond to what's actually in the slot. * This phantom FP pointer propagates forward, and wherever it's subsequently used * (as a helper argument, another store, etc.), it sets stack liveness bits. * Those bits correspond to stack accesses that don't actually happen. * So the effect is over-reporting stack liveness — marking slots as live that aren't * actually accessed. The verifier preserves more state than necessary across calls, * which is conservative. * * helpers can scratch stack slots, but they won't make a valid pointer out of it. * subprogs are allowed to write into parent slots, but they cannot write * _any_ FP-derived pointer into it (either their own or parent's FP). */ for (r = BPF_REG_0; r <= BPF_REG_5; r++) at_out[r] = none; } else if (class == BPF_LDX) { u32 sz = bpf_size_to_bytes(BPF_SIZE(insn->code)); bool src_is_local_fp = can_be_local_fp(depth, insn->src_reg, src); /* * Reload from callee stack: if src is current-frame FP-derived * and the load is an 8-byte BPF_MEM, try to restore the spill * identity. For imprecise sources fill_from_stack() returns * ARG_IMPRECISE (off_cnt == 0). */ if (src_is_local_fp && BPF_MODE(insn->code) == BPF_MEM && sz == 8) { *dst = fill_from_stack(insn, at_out, insn->src_reg, at_stack_out, depth); } else if (src->frame >= 0 && src->frame < depth && BPF_MODE(insn->code) == BPF_MEM && sz == 8) { struct arg_track *parent_stack = env->callsite_at_stack[callsites[src->frame]]; *dst = fill_from_stack(insn, at_out, insn->src_reg, parent_stack, src->frame); } else if (src->frame == ARG_IMPRECISE && !(src->mask & BIT(depth)) && src->mask && BPF_MODE(insn->code) == BPF_MEM && sz == 8) { /* * Imprecise src with only parent-frame bits: * conservative fallback. */ *dst = *src; } else { *dst = none; } } else if (class == BPF_LD && BPF_MODE(insn->code) == BPF_IMM) { *dst = none; } else if (class == BPF_STX) { u32 sz = bpf_size_to_bytes(BPF_SIZE(insn->code)); bool dst_is_local_fp; /* Track spills to current-frame FP-derived callee stack */ dst_is_local_fp = can_be_local_fp(depth, insn->dst_reg, dst); if (dst_is_local_fp && BPF_MODE(insn->code) == BPF_MEM) spill_to_stack(insn, at_out, insn->dst_reg, at_stack_out, src, sz); if (BPF_MODE(insn->code) == BPF_ATOMIC) { if (dst_is_local_fp && insn->imm != BPF_LOAD_ACQ) clear_stack_for_all_offs(insn, at_out, insn->dst_reg, at_stack_out, sz); if (insn->imm == BPF_CMPXCHG) at_out[BPF_REG_0] = none; else if (insn->imm == BPF_LOAD_ACQ) *dst = none; else if (insn->imm & BPF_FETCH) *src = none; } } else if (class == BPF_ST && BPF_MODE(insn->code) == BPF_MEM) { u32 sz = bpf_size_to_bytes(BPF_SIZE(insn->code)); bool dst_is_local_fp = can_be_local_fp(depth, insn->dst_reg, dst); /* BPF_ST to FP-derived dst: clear overlapping stack slots */ if (dst_is_local_fp) clear_stack_for_all_offs(insn, at_out, insn->dst_reg, at_stack_out, sz); } } /* * Record access_bytes from helper/kfunc or load/store insn. * access_bytes > 0: stack read * access_bytes < 0: stack write * access_bytes == S64_MIN: unknown — conservative, mark [0..slot] as read * access_bytes == 0: no access * */ static int record_stack_access_off(struct func_instance *instance, s64 fp_off, s64 access_bytes, u32 frame, u32 insn_idx) { s32 slot_hi, slot_lo; spis_t mask; if (fp_off >= 0) /* * out of bounds stack access doesn't contribute * into actual stack liveness. It will be rejected * by the main verifier pass later. */ return 0; if (access_bytes == S64_MIN) { /* helper/kfunc read unknown amount of bytes from fp_off until fp+0 */ slot_hi = (-fp_off - 1) / STACK_SLOT_SZ; mask = SPIS_ZERO; spis_or_range(&mask, 0, slot_hi); return mark_stack_read(instance, frame, insn_idx, mask); } if (access_bytes > 0) { /* Mark any touched slot as use */ slot_hi = (-fp_off - 1) / STACK_SLOT_SZ; slot_lo = max_t(s32, (-fp_off - access_bytes) / STACK_SLOT_SZ, 0); mask = SPIS_ZERO; spis_or_range(&mask, slot_lo, slot_hi); return mark_stack_read(instance, frame, insn_idx, mask); } else if (access_bytes < 0) { /* Mark only fully covered slots as def */ access_bytes = -access_bytes; slot_hi = (-fp_off) / STACK_SLOT_SZ - 1; slot_lo = max_t(s32, (-fp_off - access_bytes + STACK_SLOT_SZ - 1) / STACK_SLOT_SZ, 0); if (slot_lo <= slot_hi) { mask = SPIS_ZERO; spis_or_range(&mask, slot_lo, slot_hi); return mark_stack_write(instance, frame, insn_idx, mask); } } return 0; } /* * 'arg' is FP-derived argument to helper/kfunc or load/store that * reads (positive) or writes (negative) 'access_bytes' into 'use' or 'def'. */ static int record_stack_access(struct func_instance *instance, const struct arg_track *arg, s64 access_bytes, u32 frame, u32 insn_idx) { int i, err; if (access_bytes == 0) return 0; if (arg->off_cnt == 0) { if (access_bytes > 0 || access_bytes == S64_MIN) return mark_stack_read(instance, frame, insn_idx, SPIS_ALL); return 0; } if (access_bytes != S64_MIN && access_bytes < 0 && arg->off_cnt != 1) /* multi-offset write cannot set stack_def */ return 0; for (i = 0; i < arg->off_cnt; i++) { err = record_stack_access_off(instance, arg->off[i], access_bytes, frame, insn_idx); if (err) return err; } return 0; } /* * When a pointer is ARG_IMPRECISE, conservatively mark every frame in * the bitmask as fully used. */ static int record_imprecise(struct func_instance *instance, u32 mask, u32 insn_idx) { int depth = instance->depth; int f, err; for (f = 0; mask; f++, mask >>= 1) { if (!(mask & 1)) continue; if (f <= depth) { err = mark_stack_read(instance, f, insn_idx, SPIS_ALL); if (err) return err; } } return 0; } /* Record load/store access for a given 'at' state of 'insn'. */ static int record_load_store_access(struct bpf_verifier_env *env, struct func_instance *instance, struct arg_track *at, int insn_idx) { struct bpf_insn *insn = &env->prog->insnsi[insn_idx]; int depth = instance->depth; s32 sz = bpf_size_to_bytes(BPF_SIZE(insn->code)); u8 class = BPF_CLASS(insn->code); struct arg_track resolved, *ptr; int oi; switch (class) { case BPF_LDX: ptr = &at[insn->src_reg]; break; case BPF_STX: if (BPF_MODE(insn->code) == BPF_ATOMIC) { if (insn->imm == BPF_STORE_REL) sz = -sz; if (insn->imm == BPF_LOAD_ACQ) ptr = &at[insn->src_reg]; else ptr = &at[insn->dst_reg]; } else { ptr = &at[insn->dst_reg]; sz = -sz; } break; case BPF_ST: ptr = &at[insn->dst_reg]; sz = -sz; break; default: return 0; } /* Resolve offsets: fold insn->off into arg_track */ if (ptr->off_cnt > 0) { resolved.off_cnt = ptr->off_cnt; resolved.frame = ptr->frame; for (oi = 0; oi < ptr->off_cnt; oi++) { if (arg_add(ptr->off[oi], insn->off, &resolved.off[oi])) { resolved.off_cnt = 0; break; } } ptr = &resolved; } if (ptr->frame >= 0 && ptr->frame <= depth) return record_stack_access(instance, ptr, sz, ptr->frame, insn_idx); if (ptr->frame == ARG_IMPRECISE) return record_imprecise(instance, ptr->mask, insn_idx); /* ARG_NONE: not derived from any frame pointer, skip */ return 0; } /* Record stack access for a given 'at' state of helper/kfunc 'insn' */ static int record_call_access(struct bpf_verifier_env *env, struct func_instance *instance, struct arg_track *at, int insn_idx) { struct bpf_insn *insn = &env->prog->insnsi[insn_idx]; int depth = instance->depth; struct bpf_call_summary cs; int r, err = 0, num_params = 5; if (bpf_pseudo_call(insn)) return 0; if (bpf_get_call_summary(env, insn, &cs)) num_params = cs.num_params; for (r = BPF_REG_1; r < BPF_REG_1 + num_params; r++) { int frame = at[r].frame; s64 bytes; if (!arg_is_fp(&at[r])) continue; if (bpf_helper_call(insn)) { bytes = bpf_helper_stack_access_bytes(env, insn, r - 1, insn_idx); } else if (bpf_pseudo_kfunc_call(insn)) { bytes = bpf_kfunc_stack_access_bytes(env, insn, r - 1, insn_idx); } else { for (int f = 0; f <= depth; f++) { err = mark_stack_read(instance, f, insn_idx, SPIS_ALL); if (err) return err; } return 0; } if (bytes == 0) continue; if (frame >= 0 && frame <= depth) err = record_stack_access(instance, &at[r], bytes, frame, insn_idx); else if (frame == ARG_IMPRECISE) err = record_imprecise(instance, at[r].mask, insn_idx); if (err) return err; } return 0; } /* * For a calls_callback helper, find the callback subprog and determine * which caller register maps to which callback register for FP passthrough. */ static int find_callback_subprog(struct bpf_verifier_env *env, struct bpf_insn *insn, int insn_idx, int *caller_reg, int *callee_reg) { struct bpf_insn_aux_data *aux = &env->insn_aux_data[insn_idx]; int cb_reg = -1; *caller_reg = -1; *callee_reg = -1; if (!bpf_helper_call(insn)) return -1; switch (insn->imm) { case BPF_FUNC_loop: /* bpf_loop(nr, cb, ctx, flags): cb=R2, R3->cb R2 */ cb_reg = BPF_REG_2; *caller_reg = BPF_REG_3; *callee_reg = BPF_REG_2; break; case BPF_FUNC_for_each_map_elem: /* for_each_map_elem(map, cb, ctx, flags): cb=R2, R3->cb R4 */ cb_reg = BPF_REG_2; *caller_reg = BPF_REG_3; *callee_reg = BPF_REG_4; break; case BPF_FUNC_find_vma: /* find_vma(task, addr, cb, ctx, flags): cb=R3, R4->cb R3 */ cb_reg = BPF_REG_3; *caller_reg = BPF_REG_4; *callee_reg = BPF_REG_3; break; case BPF_FUNC_user_ringbuf_drain: /* user_ringbuf_drain(map, cb, ctx, flags): cb=R2, R3->cb R2 */ cb_reg = BPF_REG_2; *caller_reg = BPF_REG_3; *callee_reg = BPF_REG_2; break; default: return -1; } if (!(aux->const_reg_subprog_mask & BIT(cb_reg))) return -2; return aux->const_reg_vals[cb_reg]; } /* Per-subprog intermediate state kept alive across analysis phases */ struct subprog_at_info { struct arg_track (*at_in)[MAX_BPF_REG]; int len; }; static void print_subprog_arg_access(struct bpf_verifier_env *env, int subprog, struct subprog_at_info *info, struct arg_track (*at_stack_in)[MAX_ARG_SPILL_SLOTS]) { struct bpf_insn *insns = env->prog->insnsi; int start = env->subprog_info[subprog].start; int len = info->len; int i, r; if (!(env->log.level & BPF_LOG_LEVEL2)) return; verbose(env, "%s:\n", fmt_subprog(env, subprog)); for (i = 0; i < len; i++) { int idx = start + i; bool has_extra = false; u8 cls = BPF_CLASS(insns[idx].code); bool is_ldx_stx_call = cls == BPF_LDX || cls == BPF_STX || insns[idx].code == (BPF_JMP | BPF_CALL); verbose(env, "%3d: ", idx); bpf_verbose_insn(env, &insns[idx]); /* Collect what needs printing */ if (is_ldx_stx_call && arg_is_visited(&info->at_in[i][0])) { for (r = 0; r < MAX_BPF_REG - 1; r++) if (arg_is_fp(&info->at_in[i][r])) has_extra = true; } if (is_ldx_stx_call) { for (r = 0; r < MAX_ARG_SPILL_SLOTS; r++) if (arg_is_fp(&at_stack_in[i][r])) has_extra = true; } if (!has_extra) { if (bpf_is_ldimm64(&insns[idx])) i++; continue; } bpf_vlog_reset(&env->log, env->log.end_pos - 1); verbose(env, " //"); if (is_ldx_stx_call && info->at_in && arg_is_visited(&info->at_in[i][0])) { for (r = 0; r < MAX_BPF_REG - 1; r++) { if (!arg_is_fp(&info->at_in[i][r])) continue; verbose(env, " r%d=", r); verbose_arg_track(env, &info->at_in[i][r]); } } if (is_ldx_stx_call) { for (r = 0; r < MAX_ARG_SPILL_SLOTS; r++) { if (!arg_is_fp(&at_stack_in[i][r])) continue; verbose(env, " fp%+d=", -(r + 1) * 8); verbose_arg_track(env, &at_stack_in[i][r]); } } verbose(env, "\n"); if (bpf_is_ldimm64(&insns[idx])) i++; } } /* * Compute arg tracking dataflow for a single subprog. * Runs forward fixed-point with arg_track_xfer(), then records * memory accesses in a single linear pass over converged state. * * @callee_entry: pre-populated entry state for R1-R5 * NULL for main (subprog 0). * @info: stores at_in, len for debug printing. */ static int compute_subprog_args(struct bpf_verifier_env *env, struct subprog_at_info *info, struct arg_track *callee_entry, struct func_instance *instance, u32 *callsites) { int subprog = instance->subprog; struct bpf_insn *insns = env->prog->insnsi; int depth = instance->depth; int start = env->subprog_info[subprog].start; int po_start = env->subprog_info[subprog].postorder_start; int end = env->subprog_info[subprog + 1].start; int po_end = env->subprog_info[subprog + 1].postorder_start; int len = end - start; struct arg_track (*at_in)[MAX_BPF_REG] = NULL; struct arg_track at_out[MAX_BPF_REG]; struct arg_track (*at_stack_in)[MAX_ARG_SPILL_SLOTS] = NULL; struct arg_track *at_stack_out = NULL; struct arg_track unvisited = { .frame = ARG_UNVISITED }; struct arg_track none = { .frame = ARG_NONE }; bool changed; int i, p, r, err = -ENOMEM; at_in = kvmalloc_objs(*at_in, len, GFP_KERNEL_ACCOUNT); if (!at_in) goto err_free; at_stack_in = kvmalloc_objs(*at_stack_in, len, GFP_KERNEL_ACCOUNT); if (!at_stack_in) goto err_free; at_stack_out = kvmalloc_objs(*at_stack_out, MAX_ARG_SPILL_SLOTS, GFP_KERNEL_ACCOUNT); if (!at_stack_out) goto err_free; for (i = 0; i < len; i++) { for (r = 0; r < MAX_BPF_REG; r++) at_in[i][r] = unvisited; for (r = 0; r < MAX_ARG_SPILL_SLOTS; r++) at_stack_in[i][r] = unvisited; } for (r = 0; r < MAX_BPF_REG; r++) at_in[0][r] = none; /* Entry: R10 is always precisely the current frame's FP */ at_in[0][BPF_REG_FP] = arg_single(depth, 0); /* R1-R5: from caller or ARG_NONE for main */ if (callee_entry) { for (r = BPF_REG_1; r <= BPF_REG_5; r++) at_in[0][r] = callee_entry[r]; } /* Entry: all stack slots are ARG_NONE */ for (r = 0; r < MAX_ARG_SPILL_SLOTS; r++) at_stack_in[0][r] = none; if (env->log.level & BPF_LOG_LEVEL2) verbose(env, "subprog#%d: analyzing (depth %d)...\n", subprog, depth); /* Forward fixed-point iteration in reverse post order */ redo: changed = false; for (p = po_end - 1; p >= po_start; p--) { int idx = env->cfg.insn_postorder[p]; int i = idx - start; struct bpf_insn *insn = &insns[idx]; struct bpf_iarray *succ; if (!arg_is_visited(&at_in[i][0]) && !arg_is_visited(&at_in[i][1])) continue; memcpy(at_out, at_in[i], sizeof(at_out)); memcpy(at_stack_out, at_stack_in[i], MAX_ARG_SPILL_SLOTS * sizeof(*at_stack_out)); arg_track_xfer(env, insn, idx, at_out, at_stack_out, instance, callsites); arg_track_log(env, insn, idx, at_in[i], at_stack_in[i], at_out, at_stack_out); /* Propagate to successors within this subprogram */ succ = bpf_insn_successors(env, idx); for (int s = 0; s < succ->cnt; s++) { int target = succ->items[s]; int ti; /* Filter: stay within the subprogram's range */ if (target < start || target >= end) continue; ti = target - start; for (r = 0; r < MAX_BPF_REG; r++) changed |= arg_track_join(env, idx, target, r, &at_in[ti][r], at_out[r]); for (r = 0; r < MAX_ARG_SPILL_SLOTS; r++) changed |= arg_track_join(env, idx, target, -r - 1, &at_stack_in[ti][r], at_stack_out[r]); } } if (changed) goto redo; /* Record memory accesses using converged at_in (RPO skips dead code) */ for (p = po_end - 1; p >= po_start; p--) { int idx = env->cfg.insn_postorder[p]; int i = idx - start; struct bpf_insn *insn = &insns[idx]; err = record_load_store_access(env, instance, at_in[i], idx); if (err) goto err_free; if (insn->code == (BPF_JMP | BPF_CALL)) { err = record_call_access(env, instance, at_in[i], idx); if (err) goto err_free; } if (bpf_pseudo_call(insn) || bpf_calls_callback(env, idx)) { kvfree(env->callsite_at_stack[idx]); env->callsite_at_stack[idx] = kvmalloc_objs(*env->callsite_at_stack[idx], MAX_ARG_SPILL_SLOTS, GFP_KERNEL_ACCOUNT); if (!env->callsite_at_stack[idx]) { err = -ENOMEM; goto err_free; } memcpy(env->callsite_at_stack[idx], at_stack_in[i], sizeof(struct arg_track) * MAX_ARG_SPILL_SLOTS); } } info->at_in = at_in; at_in = NULL; info->len = len; print_subprog_arg_access(env, subprog, info, at_stack_in); err = 0; err_free: kvfree(at_stack_out); kvfree(at_stack_in); kvfree(at_in); return err; } /* Return true if any of R1-R5 is derived from a frame pointer. */ static bool has_fp_args(struct arg_track *args) { for (int r = BPF_REG_1; r <= BPF_REG_5; r++) if (args[r].frame != ARG_NONE) return true; return false; } /* * Merge a freshly analyzed instance into the original. * may_read: union (any pass might read the slot). * must_write: intersection (only slots written on ALL passes are guaranteed). * live_before is recomputed by a subsequent update_instance() on @dst. */ static void merge_instances(struct func_instance *dst, struct func_instance *src) { int f, i; for (f = 0; f <= dst->depth; f++) { if (!src->frames[f]) { /* This pass didn't touch frame f — must_write intersects with empty. */ if (dst->frames[f]) for (i = 0; i < dst->insn_cnt; i++) dst->frames[f][i].must_write = SPIS_ZERO; continue; } if (!dst->frames[f]) { /* Previous pass didn't touch frame f — take src, zero must_write. */ dst->frames[f] = src->frames[f]; src->frames[f] = NULL; for (i = 0; i < dst->insn_cnt; i++) dst->frames[f][i].must_write = SPIS_ZERO; continue; } for (i = 0; i < dst->insn_cnt; i++) { dst->frames[f][i].may_read = spis_or(dst->frames[f][i].may_read, src->frames[f][i].may_read); dst->frames[f][i].must_write = spis_and(dst->frames[f][i].must_write, src->frames[f][i].must_write); } } } static struct func_instance *fresh_instance(struct func_instance *src) { struct func_instance *f; f = kvzalloc_obj(*f, GFP_KERNEL_ACCOUNT); if (!f) return ERR_PTR(-ENOMEM); f->callsite = src->callsite; f->depth = src->depth; f->subprog = src->subprog; f->subprog_start = src->subprog_start; f->insn_cnt = src->insn_cnt; return f; } static void free_instance(struct func_instance *instance) { int i; for (i = 0; i <= instance->depth; i++) kvfree(instance->frames[i]); kvfree(instance); } /* * Recursively analyze a subprog with specific 'entry_args'. * Each callee is analyzed with the exact args from its call site. * * Args are recomputed for each call because the dataflow result at_in[] * depends on the entry args and frame depth. Consider: A->C->D and B->C->D * Callsites in A and B pass different args into C, so C is recomputed. * Then within C the same callsite passes different args into D. */ static int analyze_subprog(struct bpf_verifier_env *env, struct arg_track *entry_args, struct subprog_at_info *info, struct func_instance *instance, u32 *callsites) { int subprog = instance->subprog; int depth = instance->depth; struct bpf_insn *insns = env->prog->insnsi; int start = env->subprog_info[subprog].start; int po_start = env->subprog_info[subprog].postorder_start; int po_end = env->subprog_info[subprog + 1].postorder_start; struct func_instance *prev_instance = NULL; int j, err; if (++env->liveness->subprog_calls > 10000) { verbose(env, "liveness analysis exceeded complexity limit (%d calls)\n", env->liveness->subprog_calls); return -E2BIG; } if (need_resched()) cond_resched(); /* * When an instance is reused (must_write_initialized == true), * record into a fresh instance and merge afterward. This avoids * stale must_write marks for instructions not reached in this pass. */ if (instance->must_write_initialized) { struct func_instance *fresh = fresh_instance(instance); if (IS_ERR(fresh)) return PTR_ERR(fresh); prev_instance = instance; instance = fresh; } /* Free prior analysis if this subprog was already visited */ kvfree(info[subprog].at_in); info[subprog].at_in = NULL; err = compute_subprog_args(env, &info[subprog], entry_args, instance, callsites); if (err) goto out_free; /* For each reachable call site in the subprog, recurse into callees */ for (int p = po_start; p < po_end; p++) { int idx = env->cfg.insn_postorder[p]; struct arg_track callee_args[BPF_REG_5 + 1]; struct arg_track none = { .frame = ARG_NONE }; struct bpf_insn *insn = &insns[idx]; struct func_instance *callee_instance; int callee, target; int caller_reg, cb_callee_reg; j = idx - start; /* relative index within this subprog */ if (bpf_pseudo_call(insn)) { target = idx + insn->imm + 1; callee = bpf_find_subprog(env, target); if (callee < 0) continue; /* Build entry args: R1-R5 from at_in at call site */ for (int r = BPF_REG_1; r <= BPF_REG_5; r++) callee_args[r] = info[subprog].at_in[j][r]; } else if (bpf_calls_callback(env, idx)) { callee = find_callback_subprog(env, insn, idx, &caller_reg, &cb_callee_reg); if (callee == -2) { /* * same bpf_loop() calls two different callbacks and passes * stack pointer to them */ if (info[subprog].at_in[j][caller_reg].frame == ARG_NONE) continue; for (int f = 0; f <= depth; f++) { err = mark_stack_read(instance, f, idx, SPIS_ALL); if (err) goto out_free; } continue; } if (callee < 0) continue; for (int r = BPF_REG_1; r <= BPF_REG_5; r++) callee_args[r] = none; callee_args[cb_callee_reg] = info[subprog].at_in[j][caller_reg]; } else { continue; } if (!has_fp_args(callee_args)) continue; if (depth == MAX_CALL_FRAMES - 1) { err = -EINVAL; goto out_free; } callee_instance = call_instance(env, instance, idx, callee); if (IS_ERR(callee_instance)) { err = PTR_ERR(callee_instance); goto out_free; } callsites[depth] = idx; err = analyze_subprog(env, callee_args, info, callee_instance, callsites); if (err) goto out_free; /* Pull callee's entry liveness back to caller's callsite */ { u32 callee_start = callee_instance->subprog_start; struct per_frame_masks *entry; for (int f = 0; f < callee_instance->depth; f++) { entry = get_frame_masks(callee_instance, f, callee_start); if (!entry) continue; err = mark_stack_read(instance, f, idx, entry->live_before); if (err) goto out_free; } } } if (prev_instance) { merge_instances(prev_instance, instance); free_instance(instance); instance = prev_instance; } update_instance(env, instance); return 0; out_free: if (prev_instance) free_instance(instance); return err; } int bpf_compute_subprog_arg_access(struct bpf_verifier_env *env) { u32 callsites[MAX_CALL_FRAMES] = {}; int insn_cnt = env->prog->len; struct func_instance *instance; struct subprog_at_info *info; int k, err = 0; info = kvzalloc_objs(*info, env->subprog_cnt, GFP_KERNEL_ACCOUNT); if (!info) return -ENOMEM; env->callsite_at_stack = kvzalloc_objs(*env->callsite_at_stack, insn_cnt, GFP_KERNEL_ACCOUNT); if (!env->callsite_at_stack) { kvfree(info); return -ENOMEM; } instance = call_instance(env, NULL, 0, 0); if (IS_ERR(instance)) { err = PTR_ERR(instance); goto out; } err = analyze_subprog(env, NULL, info, instance, callsites); if (err) goto out; /* * Subprogs and callbacks that don't receive FP-derived arguments * cannot access ancestor stack frames, so they were skipped during * the recursive walk above. Async callbacks (timer, workqueue) are * also not reachable from the main program's call graph. Analyze * all unvisited subprogs as independent roots at depth 0. * * Use reverse topological order (callers before callees) so that * each subprog is analyzed before its callees, allowing the * recursive walk inside analyze_subprog() to naturally * reach nested callees that also lack FP-derived args. */ for (k = env->subprog_cnt - 1; k >= 0; k--) { int sub = env->subprog_topo_order[k]; if (info[sub].at_in && !bpf_subprog_is_global(env, sub)) continue; instance = call_instance(env, NULL, 0, sub); if (IS_ERR(instance)) { err = PTR_ERR(instance); goto out; } err = analyze_subprog(env, NULL, info, instance, callsites); if (err) goto out; } if (env->log.level & BPF_LOG_LEVEL2) err = print_instances(env); out: for (k = 0; k < insn_cnt; k++) kvfree(env->callsite_at_stack[k]); kvfree(env->callsite_at_stack); env->callsite_at_stack = NULL; for (k = 0; k < env->subprog_cnt; k++) kvfree(info[k].at_in); kvfree(info); return err; } /* Each field is a register bitmask */ struct insn_live_regs { u16 use; /* registers read by instruction */ u16 def; /* registers written by instruction */ u16 in; /* registers that may be alive before instruction */ u16 out; /* registers that may be alive after instruction */ }; /* Bitmask with 1s for all caller saved registers */ #define ALL_CALLER_SAVED_REGS ((1u << CALLER_SAVED_REGS) - 1) /* Compute info->{use,def} fields for the instruction */ static void compute_insn_live_regs(struct bpf_verifier_env *env, struct bpf_insn *insn, struct insn_live_regs *info) { struct bpf_call_summary cs; u8 class = BPF_CLASS(insn->code); u8 code = BPF_OP(insn->code); u8 mode = BPF_MODE(insn->code); u16 src = BIT(insn->src_reg); u16 dst = BIT(insn->dst_reg); u16 r0 = BIT(0); u16 def = 0; u16 use = 0xffff; switch (class) { case BPF_LD: switch (mode) { case BPF_IMM: if (BPF_SIZE(insn->code) == BPF_DW) { def = dst; use = 0; } break; case BPF_LD | BPF_ABS: case BPF_LD | BPF_IND: /* stick with defaults */ break; } break; case BPF_LDX: switch (mode) { case BPF_MEM: case BPF_MEMSX: def = dst; use = src; break; } break; case BPF_ST: switch (mode) { case BPF_MEM: def = 0; use = dst; break; } break; case BPF_STX: switch (mode) { case BPF_MEM: def = 0; use = dst | src; break; case BPF_ATOMIC: switch (insn->imm) { case BPF_CMPXCHG: use = r0 | dst | src; def = r0; break; case BPF_LOAD_ACQ: def = dst; use = src; break; case BPF_STORE_REL: def = 0; use = dst | src; break; default: use = dst | src; if (insn->imm & BPF_FETCH) def = src; else def = 0; } break; } break; case BPF_ALU: case BPF_ALU64: switch (code) { case BPF_END: use = dst; def = dst; break; case BPF_MOV: def = dst; if (BPF_SRC(insn->code) == BPF_K) use = 0; else use = src; break; default: def = dst; if (BPF_SRC(insn->code) == BPF_K) use = dst; else use = dst | src; } break; case BPF_JMP: case BPF_JMP32: switch (code) { case BPF_JA: def = 0; if (BPF_SRC(insn->code) == BPF_X) use = dst; else use = 0; break; case BPF_JCOND: def = 0; use = 0; break; case BPF_EXIT: def = 0; use = r0; break; case BPF_CALL: def = ALL_CALLER_SAVED_REGS; use = def & ~BIT(BPF_REG_0); if (bpf_get_call_summary(env, insn, &cs)) use = GENMASK(cs.num_params, 1); break; default: def = 0; if (BPF_SRC(insn->code) == BPF_K) use = dst; else use = dst | src; } break; } info->def = def; info->use = use; } /* Compute may-live registers after each instruction in the program. * The register is live after the instruction I if it is read by some * instruction S following I during program execution and is not * overwritten between I and S. * * Store result in env->insn_aux_data[i].live_regs. */ int bpf_compute_live_registers(struct bpf_verifier_env *env) { struct bpf_insn_aux_data *insn_aux = env->insn_aux_data; struct bpf_insn *insns = env->prog->insnsi; struct insn_live_regs *state; int insn_cnt = env->prog->len; int err = 0, i, j; bool changed; /* Use the following algorithm: * - define the following: * - I.use : a set of all registers read by instruction I; * - I.def : a set of all registers written by instruction I; * - I.in : a set of all registers that may be alive before I execution; * - I.out : a set of all registers that may be alive after I execution; * - insn_successors(I): a set of instructions S that might immediately * follow I for some program execution; * - associate separate empty sets 'I.in' and 'I.out' with each instruction; * - visit each instruction in a postorder and update * state[i].in, state[i].out as follows: * * state[i].out = U [state[s].in for S in insn_successors(i)] * state[i].in = (state[i].out / state[i].def) U state[i].use * * (where U stands for set union, / stands for set difference) * - repeat the computation while {in,out} fields changes for * any instruction. */ state = kvzalloc_objs(*state, insn_cnt, GFP_KERNEL_ACCOUNT); if (!state) { err = -ENOMEM; goto out; } for (i = 0; i < insn_cnt; ++i) compute_insn_live_regs(env, &insns[i], &state[i]); /* Forward pass: resolve stack access through FP-derived pointers */ err = bpf_compute_subprog_arg_access(env); if (err) goto out; changed = true; while (changed) { changed = false; for (i = 0; i < env->cfg.cur_postorder; ++i) { int insn_idx = env->cfg.insn_postorder[i]; struct insn_live_regs *live = &state[insn_idx]; struct bpf_iarray *succ; u16 new_out = 0; u16 new_in = 0; succ = bpf_insn_successors(env, insn_idx); for (int s = 0; s < succ->cnt; ++s) new_out |= state[succ->items[s]].in; new_in = (new_out & ~live->def) | live->use; if (new_out != live->out || new_in != live->in) { live->in = new_in; live->out = new_out; changed = true; } } } for (i = 0; i < insn_cnt; ++i) insn_aux[i].live_regs_before = state[i].in; if (env->log.level & BPF_LOG_LEVEL2) { verbose(env, "Live regs before insn:\n"); for (i = 0; i < insn_cnt; ++i) { if (env->insn_aux_data[i].scc) verbose(env, "%3d ", env->insn_aux_data[i].scc); else verbose(env, " "); verbose(env, "%3d: ", i); for (j = BPF_REG_0; j < BPF_REG_10; ++j) if (insn_aux[i].live_regs_before & BIT(j)) verbose(env, "%d", j); else verbose(env, "."); verbose(env, " "); bpf_verbose_insn(env, &insns[i]); if (bpf_is_ldimm64(&insns[i])) i++; } } out: kvfree(state); return err; }