Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Eduard Zingerman | 1086 | 100.00% | 3 | 100.00% |
Total | 1086 | 3 |
// SPDX-License-Identifier: GPL-2.0 #include <linux/bpf.h> #include <bpf/bpf_helpers.h> #include "bpf_misc.h" struct { __uint(type, BPF_MAP_TYPE_ARRAY); __uint(max_entries, 8); __type(key, __u32); __type(value, __u64); } map SEC(".maps"); struct { __uint(type, BPF_MAP_TYPE_USER_RINGBUF); __uint(max_entries, 8); } ringbuf SEC(".maps"); struct vm_area_struct; struct bpf_map; struct buf_context { char *buf; }; struct num_context { __u64 i; __u64 j; }; __u8 choice_arr[2] = { 0, 1 }; static int unsafe_on_2nd_iter_cb(__u32 idx, struct buf_context *ctx) { if (idx == 0) { ctx->buf = (char *)(0xDEAD); return 0; } if (bpf_probe_read_user(ctx->buf, 8, (void *)(0xBADC0FFEE))) return 1; return 0; } SEC("?raw_tp") __failure __msg("R1 type=scalar expected=fp") int unsafe_on_2nd_iter(void *unused) { char buf[4]; struct buf_context loop_ctx = { .buf = buf }; bpf_loop(100, unsafe_on_2nd_iter_cb, &loop_ctx, 0); return 0; } static int unsafe_on_zero_iter_cb(__u32 idx, struct num_context *ctx) { ctx->i = 0; return 0; } SEC("?raw_tp") __failure __msg("invalid access to map value, value_size=2 off=32 size=1") int unsafe_on_zero_iter(void *unused) { struct num_context loop_ctx = { .i = 32 }; bpf_loop(100, unsafe_on_zero_iter_cb, &loop_ctx, 0); return choice_arr[loop_ctx.i]; } static int widening_cb(__u32 idx, struct num_context *ctx) { ++ctx->i; return 0; } SEC("?raw_tp") __success int widening(void *unused) { struct num_context loop_ctx = { .i = 0, .j = 1 }; bpf_loop(100, widening_cb, &loop_ctx, 0); /* loop_ctx.j is not changed during callback iteration, * verifier should not apply widening to it. */ return choice_arr[loop_ctx.j]; } static int loop_detection_cb(__u32 idx, struct num_context *ctx) { for (;;) {} return 0; } SEC("?raw_tp") __failure __msg("infinite loop detected") int loop_detection(void *unused) { struct num_context loop_ctx = { .i = 0 }; bpf_loop(100, loop_detection_cb, &loop_ctx, 0); return 0; } static __always_inline __u64 oob_state_machine(struct num_context *ctx) { switch (ctx->i) { case 0: ctx->i = 1; break; case 1: ctx->i = 32; break; } return 0; } static __u64 for_each_map_elem_cb(struct bpf_map *map, __u32 *key, __u64 *val, void *data) { return oob_state_machine(data); } SEC("?raw_tp") __failure __msg("invalid access to map value, value_size=2 off=32 size=1") int unsafe_for_each_map_elem(void *unused) { struct num_context loop_ctx = { .i = 0 }; bpf_for_each_map_elem(&map, for_each_map_elem_cb, &loop_ctx, 0); return choice_arr[loop_ctx.i]; } static __u64 ringbuf_drain_cb(struct bpf_dynptr *dynptr, void *data) { return oob_state_machine(data); } SEC("?raw_tp") __failure __msg("invalid access to map value, value_size=2 off=32 size=1") int unsafe_ringbuf_drain(void *unused) { struct num_context loop_ctx = { .i = 0 }; bpf_user_ringbuf_drain(&ringbuf, ringbuf_drain_cb, &loop_ctx, 0); return choice_arr[loop_ctx.i]; } static __u64 find_vma_cb(struct task_struct *task, struct vm_area_struct *vma, void *data) { return oob_state_machine(data); } SEC("?raw_tp") __failure __msg("invalid access to map value, value_size=2 off=32 size=1") int unsafe_find_vma(void *unused) { struct task_struct *task = bpf_get_current_task_btf(); struct num_context loop_ctx = { .i = 0 }; bpf_find_vma(task, 0, find_vma_cb, &loop_ctx, 0); return choice_arr[loop_ctx.i]; } static int iter_limit_cb(__u32 idx, struct num_context *ctx) { ctx->i++; return 0; } SEC("?raw_tp") __success int bpf_loop_iter_limit_ok(void *unused) { struct num_context ctx = { .i = 0 }; bpf_loop(1, iter_limit_cb, &ctx, 0); return choice_arr[ctx.i]; } SEC("?raw_tp") __failure __msg("invalid access to map value, value_size=2 off=2 size=1") int bpf_loop_iter_limit_overflow(void *unused) { struct num_context ctx = { .i = 0 }; bpf_loop(2, iter_limit_cb, &ctx, 0); return choice_arr[ctx.i]; } static int iter_limit_level2a_cb(__u32 idx, struct num_context *ctx) { ctx->i += 100; return 0; } static int iter_limit_level2b_cb(__u32 idx, struct num_context *ctx) { ctx->i += 10; return 0; } static int iter_limit_level1_cb(__u32 idx, struct num_context *ctx) { ctx->i += 1; bpf_loop(1, iter_limit_level2a_cb, ctx, 0); bpf_loop(1, iter_limit_level2b_cb, ctx, 0); return 0; } /* Check that path visiting every callback function once had been * reached by verifier. Variables 'ctx{1,2}i' below serve as flags, * with each decimal digit corresponding to a callback visit marker. */ SEC("socket") __success __retval(111111) int bpf_loop_iter_limit_nested(void *unused) { struct num_context ctx1 = { .i = 0 }; struct num_context ctx2 = { .i = 0 }; __u64 a, b, c; bpf_loop(1, iter_limit_level1_cb, &ctx1, 0); bpf_loop(1, iter_limit_level1_cb, &ctx2, 0); a = ctx1.i; b = ctx2.i; /* Force 'ctx1.i' and 'ctx2.i' precise. */ c = choice_arr[(a + b) % 2]; /* This makes 'c' zero, but neither clang nor verifier know it. */ c /= 10; /* Make sure that verifier does not visit 'impossible' states: * enumerate all possible callback visit masks. */ if (a != 0 && a != 1 && a != 11 && a != 101 && a != 111 && b != 0 && b != 1 && b != 11 && b != 101 && b != 111) asm volatile ("r0 /= 0;" ::: "r0"); return 1000 * a + b + c; } char _license[] SEC("license") = "GPL";
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