// SPDX-License-Identifier: (GPL-2.0-only OR BSD-2-Clause) /* Copyright (C) 2018 Netronome Systems, Inc. */ #include #include #include #include "cfg.h" #include "main.h" #include "xlated_dumper.h" struct cfg { struct list_head funcs; int func_num; }; struct func_node { struct list_head l; struct list_head bbs; struct bpf_insn *start; struct bpf_insn *end; int idx; int bb_num; }; struct bb_node { struct list_head l; struct list_head e_prevs; struct list_head e_succs; struct bpf_insn *head; struct bpf_insn *tail; int idx; }; #define EDGE_FLAG_EMPTY 0x0 #define EDGE_FLAG_FALLTHROUGH 0x1 #define EDGE_FLAG_JUMP 0x2 struct edge_node { struct list_head l; struct bb_node *src; struct bb_node *dst; int flags; }; #define ENTRY_BLOCK_INDEX 0 #define EXIT_BLOCK_INDEX 1 #define NUM_FIXED_BLOCKS 2 #define func_prev(func) list_prev_entry(func, l) #define func_next(func) list_next_entry(func, l) #define bb_prev(bb) list_prev_entry(bb, l) #define bb_next(bb) list_next_entry(bb, l) #define entry_bb(func) func_first_bb(func) #define exit_bb(func) func_last_bb(func) #define cfg_first_func(cfg) \ list_first_entry(&cfg->funcs, struct func_node, l) #define cfg_last_func(cfg) \ list_last_entry(&cfg->funcs, struct func_node, l) #define func_first_bb(func) \ list_first_entry(&func->bbs, struct bb_node, l) #define func_last_bb(func) \ list_last_entry(&func->bbs, struct bb_node, l) static struct func_node *cfg_append_func(struct cfg *cfg, struct bpf_insn *insn) { struct func_node *new_func, *func; list_for_each_entry(func, &cfg->funcs, l) { if (func->start == insn) return func; else if (func->start > insn) break; } func = func_prev(func); new_func = calloc(1, sizeof(*new_func)); if (!new_func) { p_err("OOM when allocating FUNC node"); return NULL; } new_func->start = insn; new_func->idx = cfg->func_num; list_add(&new_func->l, &func->l); cfg->func_num++; return new_func; } static struct bb_node *func_append_bb(struct func_node *func, struct bpf_insn *insn) { struct bb_node *new_bb, *bb; list_for_each_entry(bb, &func->bbs, l) { if (bb->head == insn) return bb; else if (bb->head > insn) break; } bb = bb_prev(bb); new_bb = calloc(1, sizeof(*new_bb)); if (!new_bb) { p_err("OOM when allocating BB node"); return NULL; } new_bb->head = insn; INIT_LIST_HEAD(&new_bb->e_prevs); INIT_LIST_HEAD(&new_bb->e_succs); list_add(&new_bb->l, &bb->l); return new_bb; } static struct bb_node *func_insert_dummy_bb(struct list_head *after) { struct bb_node *bb; bb = calloc(1, sizeof(*bb)); if (!bb) { p_err("OOM when allocating BB node"); return NULL; } INIT_LIST_HEAD(&bb->e_prevs); INIT_LIST_HEAD(&bb->e_succs); list_add(&bb->l, after); return bb; } static bool cfg_partition_funcs(struct cfg *cfg, struct bpf_insn *cur, struct bpf_insn *end) { struct func_node *func, *last_func; func = cfg_append_func(cfg, cur); if (!func) return true; for (; cur < end; cur++) { if (cur->code != (BPF_JMP | BPF_CALL)) continue; if (cur->src_reg != BPF_PSEUDO_CALL) continue; func = cfg_append_func(cfg, cur + cur->off + 1); if (!func) return true; } last_func = cfg_last_func(cfg); last_func->end = end - 1; func = cfg_first_func(cfg); list_for_each_entry_from(func, &last_func->l, l) { func->end = func_next(func)->start - 1; } return false; } static bool is_jmp_insn(__u8 code) { return BPF_CLASS(code) == BPF_JMP || BPF_CLASS(code) == BPF_JMP32; } static bool func_partition_bb_head(struct func_node *func) { struct bpf_insn *cur, *end; struct bb_node *bb; cur = func->start; end = func->end; INIT_LIST_HEAD(&func->bbs); bb = func_append_bb(func, cur); if (!bb) return true; for (; cur <= end; cur++) { if (is_jmp_insn(cur->code)) { __u8 opcode = BPF_OP(cur->code); if (opcode == BPF_EXIT || opcode == BPF_CALL) continue; bb = func_append_bb(func, cur + cur->off + 1); if (!bb) return true; if (opcode != BPF_JA) { bb = func_append_bb(func, cur + 1); if (!bb) return true; } } } return false; } static void func_partition_bb_tail(struct func_node *func) { unsigned int bb_idx = NUM_FIXED_BLOCKS; struct bb_node *bb, *last; last = func_last_bb(func); last->tail = func->end; bb = func_first_bb(func); list_for_each_entry_from(bb, &last->l, l) { bb->tail = bb_next(bb)->head - 1; bb->idx = bb_idx++; } last->idx = bb_idx++; func->bb_num = bb_idx; } static bool func_add_special_bb(struct func_node *func) { struct bb_node *bb; bb = func_insert_dummy_bb(&func->bbs); if (!bb) return true; bb->idx = ENTRY_BLOCK_INDEX; bb = func_insert_dummy_bb(&func_last_bb(func)->l); if (!bb) return true; bb->idx = EXIT_BLOCK_INDEX; return false; } static bool func_partition_bb(struct func_node *func) { if (func_partition_bb_head(func)) return true; func_partition_bb_tail(func); return false; } static struct bb_node *func_search_bb_with_head(struct func_node *func, struct bpf_insn *insn) { struct bb_node *bb; list_for_each_entry(bb, &func->bbs, l) { if (bb->head == insn) return bb; } return NULL; } static struct edge_node *new_edge(struct bb_node *src, struct bb_node *dst, int flags) { struct edge_node *e; e = calloc(1, sizeof(*e)); if (!e) { p_err("OOM when allocating edge node"); return NULL; } if (src) e->src = src; if (dst) e->dst = dst; e->flags |= flags; return e; } static bool func_add_bb_edges(struct func_node *func) { struct bpf_insn *insn; struct edge_node *e; struct bb_node *bb; bb = entry_bb(func); e = new_edge(bb, bb_next(bb), EDGE_FLAG_FALLTHROUGH); if (!e) return true; list_add_tail(&e->l, &bb->e_succs); bb = exit_bb(func); e = new_edge(bb_prev(bb), bb, EDGE_FLAG_FALLTHROUGH); if (!e) return true; list_add_tail(&e->l, &bb->e_prevs); bb = entry_bb(func); bb = bb_next(bb); list_for_each_entry_from(bb, &exit_bb(func)->l, l) { e = new_edge(bb, NULL, EDGE_FLAG_EMPTY); if (!e) return true; e->src = bb; insn = bb->tail; if (!is_jmp_insn(insn->code) || BPF_OP(insn->code) == BPF_EXIT) { e->dst = bb_next(bb); e->flags |= EDGE_FLAG_FALLTHROUGH; list_add_tail(&e->l, &bb->e_succs); continue; } else if (BPF_OP(insn->code) == BPF_JA) { e->dst = func_search_bb_with_head(func, insn + insn->off + 1); e->flags |= EDGE_FLAG_JUMP; list_add_tail(&e->l, &bb->e_succs); continue; } e->dst = bb_next(bb); e->flags |= EDGE_FLAG_FALLTHROUGH; list_add_tail(&e->l, &bb->e_succs); e = new_edge(bb, NULL, EDGE_FLAG_JUMP); if (!e) return true; e->src = bb; e->dst = func_search_bb_with_head(func, insn + insn->off + 1); list_add_tail(&e->l, &bb->e_succs); } return false; } static bool cfg_build(struct cfg *cfg, struct bpf_insn *insn, unsigned int len) { int cnt = len / sizeof(*insn); struct func_node *func; INIT_LIST_HEAD(&cfg->funcs); if (cfg_partition_funcs(cfg, insn, insn + cnt)) return true; list_for_each_entry(func, &cfg->funcs, l) { if (func_partition_bb(func) || func_add_special_bb(func)) return true; if (func_add_bb_edges(func)) return true; } return false; } static void cfg_destroy(struct cfg *cfg) { struct func_node *func, *func2; list_for_each_entry_safe(func, func2, &cfg->funcs, l) { struct bb_node *bb, *bb2; list_for_each_entry_safe(bb, bb2, &func->bbs, l) { struct edge_node *e, *e2; list_for_each_entry_safe(e, e2, &bb->e_prevs, l) { list_del(&e->l); free(e); } list_for_each_entry_safe(e, e2, &bb->e_succs, l) { list_del(&e->l); free(e); } list_del(&bb->l); free(bb); } list_del(&func->l); free(func); } } static void draw_bb_node(struct func_node *func, struct bb_node *bb, struct dump_data *dd, bool opcodes, bool linum) { const char *shape; if (bb->idx == ENTRY_BLOCK_INDEX || bb->idx == EXIT_BLOCK_INDEX) shape = "Mdiamond"; else shape = "record"; printf("\tfn_%d_bb_%d [shape=%s,style=filled,label=\"", func->idx, bb->idx, shape); if (bb->idx == ENTRY_BLOCK_INDEX) { printf("ENTRY"); } else if (bb->idx == EXIT_BLOCK_INDEX) { printf("EXIT"); } else { unsigned int start_idx; printf("{\\\n"); start_idx = bb->head - func->start; dump_xlated_for_graph(dd, bb->head, bb->tail, start_idx, opcodes, linum); printf("}"); } printf("\"];\n\n"); } static void draw_bb_succ_edges(struct func_node *func, struct bb_node *bb) { const char *style = "\"solid,bold\""; const char *color = "black"; int func_idx = func->idx; struct edge_node *e; int weight = 10; if (list_empty(&bb->e_succs)) return; list_for_each_entry(e, &bb->e_succs, l) { printf("\tfn_%d_bb_%d:s -> fn_%d_bb_%d:n [style=%s, color=%s, weight=%d, constraint=true", func_idx, e->src->idx, func_idx, e->dst->idx, style, color, weight); printf("];\n"); } } static void func_output_bb_def(struct func_node *func, struct dump_data *dd, bool opcodes, bool linum) { struct bb_node *bb; list_for_each_entry(bb, &func->bbs, l) { draw_bb_node(func, bb, dd, opcodes, linum); } } static void func_output_edges(struct func_node *func) { int func_idx = func->idx; struct bb_node *bb; list_for_each_entry(bb, &func->bbs, l) { draw_bb_succ_edges(func, bb); } /* Add an invisible edge from ENTRY to EXIT, this is to * improve the graph layout. */ printf("\tfn_%d_bb_%d:s -> fn_%d_bb_%d:n [style=\"invis\", constraint=true];\n", func_idx, ENTRY_BLOCK_INDEX, func_idx, EXIT_BLOCK_INDEX); } static void cfg_dump(struct cfg *cfg, struct dump_data *dd, bool opcodes, bool linum) { struct func_node *func; printf("digraph \"DOT graph for eBPF program\" {\n"); list_for_each_entry(func, &cfg->funcs, l) { printf("subgraph \"cluster_%d\" {\n\tstyle=\"dashed\";\n\tcolor=\"black\";\n\tlabel=\"func_%d ()\";\n", func->idx, func->idx); func_output_bb_def(func, dd, opcodes, linum); func_output_edges(func); printf("}\n"); } printf("}\n"); } void dump_xlated_cfg(struct dump_data *dd, void *buf, unsigned int len, bool opcodes, bool linum) { struct bpf_insn *insn = buf; struct cfg cfg; memset(&cfg, 0, sizeof(cfg)); if (cfg_build(&cfg, insn, len)) return; cfg_dump(&cfg, dd, opcodes, linum); cfg_destroy(&cfg); }