/* SPDX-License-Identifier: GPL-2.0 */ /* * BPF extensible scheduler class: Documentation/scheduler/sched-ext.rst * * Copyright (c) 2026 Meta Platforms, Inc. and affiliates. * Copyright (c) 2026 Tejun Heo */ #include #include "internal.h" #include "cid.h" /* * cid tables. * * Pointers are published once on first enable and never revoked. The default * mapping is populated before ops.init() runs; scx_bpf_cid_override() commits * before it returns. As long as the BPF scheduler only uses the tables from * those points onward, it sees a consistent view. */ s16 *scx_cid_to_cpu_tbl; s16 *scx_cpu_to_cid_tbl; struct scx_cid_topo *scx_cid_topo; #define SCX_CID_TOPO_NEG (struct scx_cid_topo) { \ .core_cid = -1, .core_idx = -1, .llc_cid = -1, .llc_idx = -1, \ .node_cid = -1, .node_idx = -1, \ } /* * Return @cpu's LLC shared_cpu_map. If cacheinfo isn't populated (offline or * !present), record @cpu in @fallbacks and return its node mask instead - the * worst that can happen is that the cpu's LLC becomes coarser than reality. */ static const struct cpumask *cpu_llc_mask(int cpu, struct cpumask *fallbacks) { struct cpu_cacheinfo *ci = get_cpu_cacheinfo(cpu); if (!ci || !ci->info_list || !ci->num_leaves) { cpumask_set_cpu(cpu, fallbacks); return cpumask_of_node(cpu_to_node(cpu)); } return &ci->info_list[ci->num_leaves - 1].shared_cpu_map; } /* Allocate the cid tables once on first enable; never freed. */ static s32 scx_cid_arrays_alloc(void) { u32 npossible = num_possible_cpus(); s16 *cid_to_cpu, *cpu_to_cid; struct scx_cid_topo *cid_topo; if (scx_cid_to_cpu_tbl) return 0; cid_to_cpu = kzalloc_objs(*scx_cid_to_cpu_tbl, npossible, GFP_KERNEL); cpu_to_cid = kzalloc_objs(*scx_cpu_to_cid_tbl, nr_cpu_ids, GFP_KERNEL); cid_topo = kmalloc_objs(*scx_cid_topo, npossible, GFP_KERNEL); if (!cid_to_cpu || !cpu_to_cid || !cid_topo) { kfree(cid_to_cpu); kfree(cpu_to_cid); kfree(cid_topo); return -ENOMEM; } WRITE_ONCE(scx_cid_to_cpu_tbl, cid_to_cpu); WRITE_ONCE(scx_cpu_to_cid_tbl, cpu_to_cid); WRITE_ONCE(scx_cid_topo, cid_topo); return 0; } /** * scx_cid_init - build the cid mapping * @sch: the scx_sched being initialized; used as the scx_error() target * * See "Topological CPU IDs" in cid.h for the model. Walk online cpus by * intersection at each level (parent_scratch & this_level_mask), which keeps * containment correct by construction and naturally splits a physical LLC * straddling two NUMA nodes into two LLC units. The caller must hold * cpus_read_lock. */ s32 scx_cid_init(struct scx_sched *sch) { cpumask_var_t to_walk __free(free_cpumask_var) = CPUMASK_VAR_NULL; cpumask_var_t node_scratch __free(free_cpumask_var) = CPUMASK_VAR_NULL; cpumask_var_t llc_scratch __free(free_cpumask_var) = CPUMASK_VAR_NULL; cpumask_var_t core_scratch __free(free_cpumask_var) = CPUMASK_VAR_NULL; cpumask_var_t llc_fallback __free(free_cpumask_var) = CPUMASK_VAR_NULL; cpumask_var_t online_no_topo __free(free_cpumask_var) = CPUMASK_VAR_NULL; u32 next_cid = 0; s32 next_node_idx = 0, next_llc_idx = 0, next_core_idx = 0; s32 cpu, ret; /* CMASK_MAX_WORDS in cid.bpf.h covers NR_CPUS up to 8192 */ BUILD_BUG_ON(NR_CPUS > 8192); lockdep_assert_cpus_held(); ret = scx_cid_arrays_alloc(); if (ret) return ret; if (!zalloc_cpumask_var(&to_walk, GFP_KERNEL) || !zalloc_cpumask_var(&node_scratch, GFP_KERNEL) || !zalloc_cpumask_var(&llc_scratch, GFP_KERNEL) || !zalloc_cpumask_var(&core_scratch, GFP_KERNEL) || !zalloc_cpumask_var(&llc_fallback, GFP_KERNEL) || !zalloc_cpumask_var(&online_no_topo, GFP_KERNEL)) return -ENOMEM; /* -1 sentinels for sparse-possible cpu id holes (0 is a valid cid) */ for (cpu = 0; cpu < nr_cpu_ids; cpu++) scx_cpu_to_cid_tbl[cpu] = -1; cpumask_copy(to_walk, cpu_online_mask); while (!cpumask_empty(to_walk)) { s32 next_cpu = cpumask_first(to_walk); s32 nid = cpu_to_node(next_cpu); s32 node_cid = next_cid; s32 node_idx; /* * No NUMA info: skip and let the tail loop assign a no-topo * cid. cpumask_of_node(-1) is undefined. */ if (nid < 0) { cpumask_clear_cpu(next_cpu, to_walk); continue; } node_idx = next_node_idx++; /* node_scratch = to_walk & this node */ cpumask_and(node_scratch, to_walk, cpumask_of_node(nid)); if (WARN_ON_ONCE(!cpumask_test_cpu(next_cpu, node_scratch))) return -EINVAL; while (!cpumask_empty(node_scratch)) { s32 ncpu = cpumask_first(node_scratch); const struct cpumask *llc_mask = cpu_llc_mask(ncpu, llc_fallback); s32 llc_cid = next_cid; s32 llc_idx = next_llc_idx++; /* llc_scratch = node_scratch & this llc */ cpumask_and(llc_scratch, node_scratch, llc_mask); if (WARN_ON_ONCE(!cpumask_test_cpu(ncpu, llc_scratch))) return -EINVAL; while (!cpumask_empty(llc_scratch)) { s32 lcpu = cpumask_first(llc_scratch); const struct cpumask *sib = topology_sibling_cpumask(lcpu); s32 core_cid = next_cid; s32 core_idx = next_core_idx++; s32 ccpu; /* core_scratch = llc_scratch & this core */ cpumask_and(core_scratch, llc_scratch, sib); if (WARN_ON_ONCE(!cpumask_test_cpu(lcpu, core_scratch))) return -EINVAL; for_each_cpu(ccpu, core_scratch) { s32 cid = next_cid++; scx_cid_to_cpu_tbl[cid] = ccpu; scx_cpu_to_cid_tbl[ccpu] = cid; scx_cid_topo[cid] = (struct scx_cid_topo){ .core_cid = core_cid, .core_idx = core_idx, .llc_cid = llc_cid, .llc_idx = llc_idx, .node_cid = node_cid, .node_idx = node_idx, }; cpumask_clear_cpu(ccpu, llc_scratch); cpumask_clear_cpu(ccpu, node_scratch); cpumask_clear_cpu(ccpu, to_walk); } } } } /* * No-topo section: any possible cpu without a cid - normally just the * not-online ones. Collect any currently-online cpus that land here in * @online_no_topo so we can warn about them at the end. */ for_each_cpu(cpu, cpu_possible_mask) { s32 cid; if (__scx_cpu_to_cid(cpu) != -1) continue; if (cpu_online(cpu)) cpumask_set_cpu(cpu, online_no_topo); cid = next_cid++; scx_cid_to_cpu_tbl[cid] = cpu; scx_cpu_to_cid_tbl[cpu] = cid; scx_cid_topo[cid] = SCX_CID_TOPO_NEG; } if (!cpumask_empty(llc_fallback)) pr_warn("scx_cid: cpus without cacheinfo, using node mask as llc: %*pbl\n", cpumask_pr_args(llc_fallback)); if (!cpumask_empty(online_no_topo)) pr_warn("scx_cid: online cpus with no usable topology: %*pbl\n", cpumask_pr_args(online_no_topo)); return 0; } /** * scx_cmask_clear - Zero every bit in @m's active range * @m: cmask to clear * * Storage past the active range is left as is. */ void scx_cmask_clear(struct scx_cmask *m) { u32 nr_words; if (!m->nr_cids) return; nr_words = (m->base + m->nr_cids - 1) / 64 - m->base / 64 + 1; memset(m->bits, 0, nr_words * sizeof(u64)); } /** * scx_cmask_fill - Set every bit in @m's active range * @m: cmask to fill * * Counterpart to scx_cmask_clear(). Storage past the active range is left as is. */ void scx_cmask_fill(struct scx_cmask *m) { u32 nr_words, head_bits, tail_bits; if (!m->nr_cids) return; nr_words = (m->base + m->nr_cids - 1) / 64 - m->base / 64 + 1; memset(m->bits, 0xff, nr_words * sizeof(u64)); /* clear word-0 bits below base */ head_bits = m->base & 63; if (head_bits) m->bits[0] &= ~((1ULL << head_bits) - 1); /* clear last-word bits at or past base + nr_cids */ tail_bits = (m->base + m->nr_cids) & 63; if (tail_bits) m->bits[nr_words - 1] &= (1ULL << tail_bits) - 1; } /** * scx_cpumask_to_cmask - Translate a kernel cpumask into a cmask * @src: source cpumask * @dst: cmask to write * * Clear @dst's active range and set the bit for each cid whose cpu is in * @src and lies within that range. Out-of-range cids are silently ignored. */ void scx_cpumask_to_cmask(const struct cpumask *src, struct scx_cmask *dst) { s32 cpu; scx_cmask_clear(dst); for_each_cpu(cpu, src) { s32 cid = __scx_cpu_to_cid(cpu); if (cid >= 0) __scx_cmask_set(cid, dst); } } __bpf_kfunc_start_defs(); /** * scx_bpf_cid_override - Install an explicit cpu->cid mapping * @cpu_to_cid: array of nr_cpu_ids s32 entries (cid for each cpu) * @cpu_to_cid__sz: must be nr_cpu_ids * sizeof(s32) bytes * @aux: implicit BPF argument to access bpf_prog_aux hidden from BPF progs * * May only be called from ops.init() of the root scheduler. Replace the * topology-probed cid mapping with the caller-provided one. Each possible cpu * must map to a unique cid in [0, num_possible_cpus()). Topo info is cleared. * On invalid input, trigger scx_error() to abort the scheduler. */ __bpf_kfunc void scx_bpf_cid_override(const s32 *cpu_to_cid, u32 cpu_to_cid__sz, const struct bpf_prog_aux *aux) { cpumask_var_t seen __free(free_cpumask_var) = CPUMASK_VAR_NULL; struct scx_sched *sch; bool alloced; s32 cpu, cid; /* GFP_KERNEL alloc must happen before the rcu read section */ alloced = zalloc_cpumask_var(&seen, GFP_KERNEL); guard(rcu)(); sch = scx_prog_sched(aux); if (unlikely(!sch)) return; if (!alloced) { scx_error(sch, "scx_bpf_cid_override: failed to allocate cpumask"); return; } if (scx_parent(sch)) { scx_error(sch, "scx_bpf_cid_override() only allowed from root sched"); return; } if (cpu_to_cid__sz != nr_cpu_ids * sizeof(s32)) { scx_error(sch, "scx_bpf_cid_override: expected %zu bytes, got %u", nr_cpu_ids * sizeof(s32), cpu_to_cid__sz); return; } for_each_possible_cpu(cpu) { s32 c = cpu_to_cid[cpu]; if (!cid_valid(sch, c)) return; if (cpumask_test_and_set_cpu(c, seen)) { scx_error(sch, "cid %d assigned to multiple cpus", c); return; } scx_cpu_to_cid_tbl[cpu] = c; scx_cid_to_cpu_tbl[c] = cpu; } /* Invalidate stale topo info - the override carries no topology. */ for (cid = 0; cid < num_possible_cpus(); cid++) scx_cid_topo[cid] = SCX_CID_TOPO_NEG; } /** * scx_bpf_cid_to_cpu - Return the raw CPU id for @cid * @cid: cid to look up * @aux: implicit BPF argument to access bpf_prog_aux hidden from BPF progs * * Return the raw CPU id for @cid. Trigger scx_error() and return -EINVAL if * @cid is invalid. The cid<->cpu mapping is static for the lifetime of the * loaded scheduler, so the BPF side can cache the result to avoid repeated * kfunc invocations. */ __bpf_kfunc s32 scx_bpf_cid_to_cpu(s32 cid, const struct bpf_prog_aux *aux) { struct scx_sched *sch; guard(rcu)(); sch = scx_prog_sched(aux); if (unlikely(!sch)) return -EINVAL; return scx_cid_to_cpu(sch, cid); } /** * scx_bpf_cpu_to_cid - Return the cid for @cpu * @cpu: cpu to look up * @aux: implicit BPF argument to access bpf_prog_aux hidden from BPF progs * * Return the cid for @cpu. Trigger scx_error() and return -EINVAL if @cpu is * invalid. The cid<->cpu mapping is static for the lifetime of the loaded * scheduler, so the BPF side can cache the result to avoid repeated kfunc * invocations. */ __bpf_kfunc s32 scx_bpf_cpu_to_cid(s32 cpu, const struct bpf_prog_aux *aux) { struct scx_sched *sch; guard(rcu)(); sch = scx_prog_sched(aux); if (unlikely(!sch)) return -EINVAL; return scx_cpu_to_cid(sch, cpu); } /* * Set ops on cmasks. cmask_walk_op2() shares one walk across mutating * (and/or/copy/andnot) and predicate (subset/intersects) two-cmask forms; * cmask_walk_op1() does the same shape over a single cmask range. Every public * entry passes a compile-time-constant @op; cmask_walk_op{1,2}() and * cmask_word_op{1,2}() are __always_inline so the inner switch collapses to the * selected op and cmask_op2_is_pred() folds the predicate early-exit out of * mutating ops. * * Two-cmask ops only touch @dst bits inside the intersection of the two ranges; * bits outside stay untouched. In particular, scx_cmask_copy() does NOT zero * @dst bits that lie outside @src's range. * * The _RACY variants are otherwise identical to their non-racy counterpart but * read @src word-by-word via data_race(). Memory ordering with concurrent * writers is the caller's responsibility. */ enum cmask_op2 { /* mutating */ CMASK_OP2_AND, CMASK_OP2_OR, CMASK_OP2_OR_RACY, CMASK_OP2_COPY, CMASK_OP2_COPY_RACY, CMASK_OP2_ANDNOT, /* predicates - short-circuit when the per-word result is true */ CMASK_OP2_SUBSET, CMASK_OP2_INTERSECTS, }; static __always_inline bool cmask_op2_is_pred(const enum cmask_op2 op) { return op == CMASK_OP2_SUBSET || op == CMASK_OP2_INTERSECTS; } static __always_inline bool cmask_word_op2(u64 *av, const u64 *bp, u64 mask, const enum cmask_op2 op) { switch (op) { case CMASK_OP2_AND: *av &= ~mask | *bp; return false; case CMASK_OP2_OR: *av |= *bp & mask; return false; case CMASK_OP2_OR_RACY: *av |= data_race(*bp) & mask; return false; case CMASK_OP2_COPY: *av = (*av & ~mask) | (*bp & mask); return false; case CMASK_OP2_COPY_RACY: *av = (*av & ~mask) | (data_race(*bp) & mask); return false; case CMASK_OP2_ANDNOT: *av &= ~(*bp & mask); return false; case CMASK_OP2_SUBSET: /* stop on the first bit in @sub not set in @super */ return (*bp & ~*av) & mask; case CMASK_OP2_INTERSECTS: return (*av & *bp) & mask; } unreachable(); } /* * Walk the intersection of [@a_base, @a_base + @a_nr_cids) with [@b_base, * @b_base + @b_nr_cids) word by word, applying @op. Mutating ops walk all words * and return false; predicates return true on the first word whose per-word * test is true. Empty intersection returns false (matches "no bits to consider" * for both mutate and predicate). * * Base/nr_cids are taken as parameters so callers with snapshotted bounds can * drive the walk with values independent of the cmask's header. */ static __always_inline bool cmask_walk_op2(u64 *a_bits, u32 a_base, u32 a_nr_cids, const u64 *b_bits, u32 b_base, u32 b_nr_cids, const enum cmask_op2 op) { u32 lo = max(a_base, b_base); u32 hi = min(a_base + a_nr_cids, b_base + b_nr_cids); u32 a_word_off = a_base / 64; u32 b_word_off = b_base / 64; u32 lo_word = lo / 64; u32 hi_word = (hi - 1) / 64; u64 head_mask = GENMASK_U64(63, lo & 63); u64 tail_mask = GENMASK_U64((hi - 1) & 63, 0); u32 w; if (lo >= hi) return false; if (lo_word == hi_word) return cmask_word_op2(&a_bits[lo_word - a_word_off], &b_bits[lo_word - b_word_off], head_mask & tail_mask, op); if (cmask_word_op2(&a_bits[lo_word - a_word_off], &b_bits[lo_word - b_word_off], head_mask, op) && cmask_op2_is_pred(op)) return true; for (w = lo_word + 1; w < hi_word; w++) if (cmask_word_op2(&a_bits[w - a_word_off], &b_bits[w - b_word_off], ~0ULL, op) && cmask_op2_is_pred(op)) return true; return cmask_word_op2(&a_bits[hi_word - a_word_off], &b_bits[hi_word - b_word_off], tail_mask, op); } enum cmask_op1 { CMASK_OP1_ANY_SET, }; static __always_inline bool cmask_word_op1(const u64 *ap, u64 mask, const enum cmask_op1 op) { switch (op) { case CMASK_OP1_ANY_SET: return *ap & mask; } unreachable(); } /* * Walk [@a_base, @a_base + @a_nr_cids) of @a_bits word by word, applying @op. * Returns true on the first word whose per-word test is true; returns false if * no word matches or the range is empty. All current op1s short-circuit on * per-word true; if a non-predicate op1 lands here, add a cmask_op1_is_pred() * guard analogous to cmask_op2_is_pred(). */ static __always_inline bool cmask_walk_op1(const u64 *a_bits, u32 a_base, u32 a_nr_cids, const enum cmask_op1 op) { u32 lo = a_base; u32 hi = a_base + a_nr_cids; u32 a_word_off = a_base / 64; u32 lo_word = lo / 64; u32 hi_word = (hi - 1) / 64; u64 head_mask = GENMASK_U64(63, lo & 63); u64 tail_mask = GENMASK_U64((hi - 1) & 63, 0); u32 w; if (lo >= hi) return false; if (lo_word == hi_word) return cmask_word_op1(&a_bits[lo_word - a_word_off], head_mask & tail_mask, op); if (cmask_word_op1(&a_bits[lo_word - a_word_off], head_mask, op)) return true; for (w = lo_word + 1; w < hi_word; w++) if (cmask_word_op1(&a_bits[w - a_word_off], ~0ULL, op)) return true; return cmask_word_op1(&a_bits[hi_word - a_word_off], tail_mask, op); } void scx_cmask_and(struct scx_cmask *dst, const struct scx_cmask *src) { cmask_walk_op2(dst->bits, dst->base, dst->nr_cids, src->bits, src->base, src->nr_cids, CMASK_OP2_AND); } void scx_cmask_or(struct scx_cmask *dst, const struct scx_cmask *src) { cmask_walk_op2(dst->bits, dst->base, dst->nr_cids, src->bits, src->base, src->nr_cids, CMASK_OP2_OR); } /** * scx_cmask_or_racy - OR @src into @dst, reading @src without locking * * @src is read word-by-word through data_race(). Same per-bit independence * rationale as scx_cmask_copy_racy(). Memory ordering with writers is the * caller's responsibility. */ void scx_cmask_or_racy(struct scx_cmask *dst, const struct scx_cmask *src) { cmask_walk_op2(dst->bits, dst->base, dst->nr_cids, src->bits, src->base, src->nr_cids, CMASK_OP2_OR_RACY); } void scx_cmask_copy(struct scx_cmask *dst, const struct scx_cmask *src) { cmask_walk_op2(dst->bits, dst->base, dst->nr_cids, src->bits, src->base, src->nr_cids, CMASK_OP2_COPY); } /** * scx_cmask_copy_racy - Snapshot @src into @dst without locking * * @src is read word-by-word through data_race(). Head/tail masking matches * scx_cmask_copy(). Each bit in a cmask is independent, so partial updates * just leave some bits fresher than others. Memory ordering with writers is * the caller's responsibility. */ void scx_cmask_copy_racy(struct scx_cmask *dst, const struct scx_cmask *src) { cmask_walk_op2(dst->bits, dst->base, dst->nr_cids, src->bits, src->base, src->nr_cids, CMASK_OP2_COPY_RACY); } void scx_cmask_andnot(struct scx_cmask *dst, const struct scx_cmask *src) { cmask_walk_op2(dst->bits, dst->base, dst->nr_cids, src->bits, src->base, src->nr_cids, CMASK_OP2_ANDNOT); } /* * Return true if @cm has any bit set in [@lo, @hi). Caller must ensure * [@lo, @hi) is contained in @cm's range. */ static bool cmask_any_set_in_range(const struct scx_cmask *cm, u32 lo, u32 hi) { if (lo >= hi) return false; return cmask_walk_op1(&cm->bits[lo / 64 - cm->base / 64], lo, hi - lo, CMASK_OP1_ANY_SET); } /** * scx_cmask_subset - test whether @sub is a subset of @super * @sub: cmask to test * @super: cmask to test against * * Return true iff every set bit of @sub is also set in @super. */ bool scx_cmask_subset(const struct scx_cmask *sub, const struct scx_cmask *super) { u32 super_end = super->base + super->nr_cids; u32 sub_end = sub->base + sub->nr_cids; /* * Set bits in @sub outside @super's range can't be in @super, so any * such bit means not a subset. The walk below only visits words * common to both ranges, so these need a separate scan. */ if (sub->base < super->base && cmask_any_set_in_range(sub, sub->base, min(super->base, sub_end))) return false; if (sub_end > super_end && cmask_any_set_in_range(sub, max(sub->base, super_end), sub_end)) return false; return !cmask_walk_op2((u64 *)super->bits, super->base, super->nr_cids, sub->bits, sub->base, sub->nr_cids, CMASK_OP2_SUBSET); } bool scx_cmask_intersects(const struct scx_cmask *a, const struct scx_cmask *b) { return cmask_walk_op2((u64 *)a->bits, a->base, a->nr_cids, b->bits, b->base, b->nr_cids, CMASK_OP2_INTERSECTS); } /** * scx_cmask_empty - Test whether @m has no bits set * @m: cmask to test * * Return true iff @m's active range has no bits set. */ bool scx_cmask_empty(const struct scx_cmask *m) { return !cmask_any_set_in_range(m, m->base, m->base + m->nr_cids); } /** * scx_bpf_cid_topo - Copy out per-cid topology info * @cid: cid to look up * @out__uninit: where to copy the topology info; fully written by this call * @aux: implicit BPF argument to access bpf_prog_aux hidden from BPF progs * * Fill @out__uninit with the topology info for @cid. Trigger scx_error() if * @cid is out of range. If @cid is valid but in the no-topo section, all fields * are set to -1. */ __bpf_kfunc void scx_bpf_cid_topo(s32 cid, struct scx_cid_topo *out__uninit, const struct bpf_prog_aux *aux) { struct scx_sched *sch; guard(rcu)(); sch = scx_prog_sched(aux); if (unlikely(!sch) || !cid_valid(sch, cid)) { *out__uninit = SCX_CID_TOPO_NEG; return; } *out__uninit = READ_ONCE(scx_cid_topo)[cid]; } __bpf_kfunc_end_defs(); BTF_KFUNCS_START(scx_kfunc_ids_init) BTF_ID_FLAGS(func, scx_bpf_cid_override, KF_IMPLICIT_ARGS | KF_SLEEPABLE) BTF_KFUNCS_END(scx_kfunc_ids_init) static const struct btf_kfunc_id_set scx_kfunc_set_init = { .owner = THIS_MODULE, .set = &scx_kfunc_ids_init, .filter = scx_kfunc_context_filter, }; BTF_KFUNCS_START(scx_kfunc_ids_cid) BTF_ID_FLAGS(func, scx_bpf_cid_to_cpu, KF_IMPLICIT_ARGS) BTF_ID_FLAGS(func, scx_bpf_cpu_to_cid, KF_IMPLICIT_ARGS) BTF_ID_FLAGS(func, scx_bpf_cid_topo, KF_IMPLICIT_ARGS) BTF_KFUNCS_END(scx_kfunc_ids_cid) static const struct btf_kfunc_id_set scx_kfunc_set_cid = { .owner = THIS_MODULE, .set = &scx_kfunc_ids_cid, }; int scx_cid_kfunc_init(void) { return register_btf_kfunc_id_set(BPF_PROG_TYPE_STRUCT_OPS, &scx_kfunc_set_init) ?: register_btf_kfunc_id_set(BPF_PROG_TYPE_STRUCT_OPS, &scx_kfunc_set_cid) ?: register_btf_kfunc_id_set(BPF_PROG_TYPE_TRACING, &scx_kfunc_set_cid) ?: register_btf_kfunc_id_set(BPF_PROG_TYPE_SYSCALL, &scx_kfunc_set_cid); }