xref: /linux/tools/testing/selftests/bpf/progs/iters.c (revision 170aafe35cb98e0f3fbacb446ea86389fbce22ea)
1 // SPDX-License-Identifier: GPL-2.0
2 /* Copyright (c) 2023 Meta Platforms, Inc. and affiliates. */
3 
4 #include <stdbool.h>
5 #include <linux/bpf.h>
6 #include <bpf/bpf_helpers.h>
7 #include "bpf_misc.h"
8 #include "bpf_compiler.h"
9 
10 static volatile int zero = 0;
11 
12 int my_pid;
13 int arr[256];
14 int small_arr[16] SEC(".data.small_arr");
15 
16 struct {
17 	__uint(type, BPF_MAP_TYPE_HASH);
18 	__uint(max_entries, 10);
19 	__type(key, int);
20 	__type(value, int);
21 } amap SEC(".maps");
22 
23 #ifdef REAL_TEST
24 #define MY_PID_GUARD() if (my_pid != (bpf_get_current_pid_tgid() >> 32)) return 0
25 #else
26 #define MY_PID_GUARD() ({ })
27 #endif
28 
29 SEC("?raw_tp")
30 __failure __msg("math between map_value pointer and register with unbounded min value is not allowed")
31 int iter_err_unsafe_c_loop(const void *ctx)
32 {
33 	struct bpf_iter_num it;
34 	int *v, i = zero; /* obscure initial value of i */
35 
36 	MY_PID_GUARD();
37 
38 	bpf_iter_num_new(&it, 0, 1000);
39 	while ((v = bpf_iter_num_next(&it))) {
40 		i++;
41 	}
42 	bpf_iter_num_destroy(&it);
43 
44 	small_arr[i] = 123; /* invalid */
45 
46 	return 0;
47 }
48 
49 SEC("?raw_tp")
50 __failure __msg("unbounded memory access")
51 int iter_err_unsafe_asm_loop(const void *ctx)
52 {
53 	struct bpf_iter_num it;
54 
55 	MY_PID_GUARD();
56 
57 	asm volatile (
58 		"r6 = %[zero];" /* iteration counter */
59 		"r1 = %[it];" /* iterator state */
60 		"r2 = 0;"
61 		"r3 = 1000;"
62 		"r4 = 1;"
63 		"call %[bpf_iter_num_new];"
64 	"loop:"
65 		"r1 = %[it];"
66 		"call %[bpf_iter_num_next];"
67 		"if r0 == 0 goto out;"
68 		"r6 += 1;"
69 		"goto loop;"
70 	"out:"
71 		"r1 = %[it];"
72 		"call %[bpf_iter_num_destroy];"
73 		"r1 = %[small_arr];"
74 		"r2 = r6;"
75 		"r2 <<= 2;"
76 		"r1 += r2;"
77 		"*(u32 *)(r1 + 0) = r6;" /* invalid */
78 		:
79 		: [it]"r"(&it),
80 		  [small_arr]"r"(small_arr),
81 		  [zero]"r"(zero),
82 		  __imm(bpf_iter_num_new),
83 		  __imm(bpf_iter_num_next),
84 		  __imm(bpf_iter_num_destroy)
85 		: __clobber_common, "r6"
86 	);
87 
88 	return 0;
89 }
90 
91 SEC("raw_tp")
92 __success
93 int iter_while_loop(const void *ctx)
94 {
95 	struct bpf_iter_num it;
96 	int *v;
97 
98 	MY_PID_GUARD();
99 
100 	bpf_iter_num_new(&it, 0, 3);
101 	while ((v = bpf_iter_num_next(&it))) {
102 		bpf_printk("ITER_BASIC: E1 VAL: v=%d", *v);
103 	}
104 	bpf_iter_num_destroy(&it);
105 
106 	return 0;
107 }
108 
109 SEC("raw_tp")
110 __success
111 int iter_while_loop_auto_cleanup(const void *ctx)
112 {
113 	__attribute__((cleanup(bpf_iter_num_destroy))) struct bpf_iter_num it;
114 	int *v;
115 
116 	MY_PID_GUARD();
117 
118 	bpf_iter_num_new(&it, 0, 3);
119 	while ((v = bpf_iter_num_next(&it))) {
120 		bpf_printk("ITER_BASIC: E1 VAL: v=%d", *v);
121 	}
122 	/* (!) no explicit bpf_iter_num_destroy() */
123 
124 	return 0;
125 }
126 
127 SEC("raw_tp")
128 __success
129 int iter_for_loop(const void *ctx)
130 {
131 	struct bpf_iter_num it;
132 	int *v;
133 
134 	MY_PID_GUARD();
135 
136 	bpf_iter_num_new(&it, 5, 10);
137 	for (v = bpf_iter_num_next(&it); v; v = bpf_iter_num_next(&it)) {
138 		bpf_printk("ITER_BASIC: E2 VAL: v=%d", *v);
139 	}
140 	bpf_iter_num_destroy(&it);
141 
142 	return 0;
143 }
144 
145 SEC("raw_tp")
146 __success
147 int iter_bpf_for_each_macro(const void *ctx)
148 {
149 	int *v;
150 
151 	MY_PID_GUARD();
152 
153 	bpf_for_each(num, v, 5, 10) {
154 		bpf_printk("ITER_BASIC: E2 VAL: v=%d", *v);
155 	}
156 
157 	return 0;
158 }
159 
160 SEC("raw_tp")
161 __success
162 int iter_bpf_for_macro(const void *ctx)
163 {
164 	int i;
165 
166 	MY_PID_GUARD();
167 
168 	bpf_for(i, 5, 10) {
169 		bpf_printk("ITER_BASIC: E2 VAL: v=%d", i);
170 	}
171 
172 	return 0;
173 }
174 
175 SEC("raw_tp")
176 __success
177 int iter_pragma_unroll_loop(const void *ctx)
178 {
179 	struct bpf_iter_num it;
180 	int *v, i;
181 
182 	MY_PID_GUARD();
183 
184 	bpf_iter_num_new(&it, 0, 2);
185 	__pragma_loop_no_unroll
186 	for (i = 0; i < 3; i++) {
187 		v = bpf_iter_num_next(&it);
188 		bpf_printk("ITER_BASIC: E3 VAL: i=%d v=%d", i, v ? *v : -1);
189 	}
190 	bpf_iter_num_destroy(&it);
191 
192 	return 0;
193 }
194 
195 SEC("raw_tp")
196 __success
197 int iter_manual_unroll_loop(const void *ctx)
198 {
199 	struct bpf_iter_num it;
200 	int *v;
201 
202 	MY_PID_GUARD();
203 
204 	bpf_iter_num_new(&it, 100, 200);
205 	v = bpf_iter_num_next(&it);
206 	bpf_printk("ITER_BASIC: E4 VAL: v=%d", v ? *v : -1);
207 	v = bpf_iter_num_next(&it);
208 	bpf_printk("ITER_BASIC: E4 VAL: v=%d", v ? *v : -1);
209 	v = bpf_iter_num_next(&it);
210 	bpf_printk("ITER_BASIC: E4 VAL: v=%d", v ? *v : -1);
211 	v = bpf_iter_num_next(&it);
212 	bpf_printk("ITER_BASIC: E4 VAL: v=%d\n", v ? *v : -1);
213 	bpf_iter_num_destroy(&it);
214 
215 	return 0;
216 }
217 
218 SEC("raw_tp")
219 __success
220 int iter_multiple_sequential_loops(const void *ctx)
221 {
222 	struct bpf_iter_num it;
223 	int *v, i;
224 
225 	MY_PID_GUARD();
226 
227 	bpf_iter_num_new(&it, 0, 3);
228 	while ((v = bpf_iter_num_next(&it))) {
229 		bpf_printk("ITER_BASIC: E1 VAL: v=%d", *v);
230 	}
231 	bpf_iter_num_destroy(&it);
232 
233 	bpf_iter_num_new(&it, 5, 10);
234 	for (v = bpf_iter_num_next(&it); v; v = bpf_iter_num_next(&it)) {
235 		bpf_printk("ITER_BASIC: E2 VAL: v=%d", *v);
236 	}
237 	bpf_iter_num_destroy(&it);
238 
239 	bpf_iter_num_new(&it, 0, 2);
240 	__pragma_loop_no_unroll
241 	for (i = 0; i < 3; i++) {
242 		v = bpf_iter_num_next(&it);
243 		bpf_printk("ITER_BASIC: E3 VAL: i=%d v=%d", i, v ? *v : -1);
244 	}
245 	bpf_iter_num_destroy(&it);
246 
247 	bpf_iter_num_new(&it, 100, 200);
248 	v = bpf_iter_num_next(&it);
249 	bpf_printk("ITER_BASIC: E4 VAL: v=%d", v ? *v : -1);
250 	v = bpf_iter_num_next(&it);
251 	bpf_printk("ITER_BASIC: E4 VAL: v=%d", v ? *v : -1);
252 	v = bpf_iter_num_next(&it);
253 	bpf_printk("ITER_BASIC: E4 VAL: v=%d", v ? *v : -1);
254 	v = bpf_iter_num_next(&it);
255 	bpf_printk("ITER_BASIC: E4 VAL: v=%d\n", v ? *v : -1);
256 	bpf_iter_num_destroy(&it);
257 
258 	return 0;
259 }
260 
261 SEC("raw_tp")
262 __success
263 int iter_limit_cond_break_loop(const void *ctx)
264 {
265 	struct bpf_iter_num it;
266 	int *v, i = 0, sum = 0;
267 
268 	MY_PID_GUARD();
269 
270 	bpf_iter_num_new(&it, 0, 10);
271 	while ((v = bpf_iter_num_next(&it))) {
272 		bpf_printk("ITER_SIMPLE: i=%d v=%d", i, *v);
273 		sum += *v;
274 
275 		i++;
276 		if (i > 3)
277 			break;
278 	}
279 	bpf_iter_num_destroy(&it);
280 
281 	bpf_printk("ITER_SIMPLE: sum=%d\n", sum);
282 
283 	return 0;
284 }
285 
286 SEC("raw_tp")
287 __success
288 int iter_obfuscate_counter(const void *ctx)
289 {
290 	struct bpf_iter_num it;
291 	int *v, sum = 0;
292 	/* Make i's initial value unknowable for verifier to prevent it from
293 	 * pruning if/else branch inside the loop body and marking i as precise.
294 	 */
295 	int i = zero;
296 
297 	MY_PID_GUARD();
298 
299 	bpf_iter_num_new(&it, 0, 10);
300 	while ((v = bpf_iter_num_next(&it))) {
301 		int x;
302 
303 		i += 1;
304 
305 		/* If we initialized i as `int i = 0;` above, verifier would
306 		 * track that i becomes 1 on first iteration after increment
307 		 * above, and here verifier would eagerly prune else branch
308 		 * and mark i as precise, ruining open-coded iterator logic
309 		 * completely, as each next iteration would have a different
310 		 * *precise* value of i, and thus there would be no
311 		 * convergence of state. This would result in reaching maximum
312 		 * instruction limit, no matter what the limit is.
313 		 */
314 		if (i == 1)
315 			x = 123;
316 		else
317 			x = i * 3 + 1;
318 
319 		bpf_printk("ITER_OBFUSCATE_COUNTER: i=%d v=%d x=%d", i, *v, x);
320 
321 		sum += x;
322 	}
323 	bpf_iter_num_destroy(&it);
324 
325 	bpf_printk("ITER_OBFUSCATE_COUNTER: sum=%d\n", sum);
326 
327 	return 0;
328 }
329 
330 SEC("raw_tp")
331 __success
332 int iter_search_loop(const void *ctx)
333 {
334 	struct bpf_iter_num it;
335 	int *v, *elem = NULL;
336 	bool found = false;
337 
338 	MY_PID_GUARD();
339 
340 	bpf_iter_num_new(&it, 0, 10);
341 
342 	while ((v = bpf_iter_num_next(&it))) {
343 		bpf_printk("ITER_SEARCH_LOOP: v=%d", *v);
344 
345 		if (*v == 2) {
346 			found = true;
347 			elem = v;
348 			barrier_var(elem);
349 		}
350 	}
351 
352 	/* should fail to verify if bpf_iter_num_destroy() is here */
353 
354 	if (found)
355 		/* here found element will be wrong, we should have copied
356 		 * value to a variable, but here we want to make sure we can
357 		 * access memory after the loop anyways
358 		 */
359 		bpf_printk("ITER_SEARCH_LOOP: FOUND IT = %d!\n", *elem);
360 	else
361 		bpf_printk("ITER_SEARCH_LOOP: NOT FOUND IT!\n");
362 
363 	bpf_iter_num_destroy(&it);
364 
365 	return 0;
366 }
367 
368 SEC("raw_tp")
369 __success
370 int iter_array_fill(const void *ctx)
371 {
372 	int sum, i;
373 
374 	MY_PID_GUARD();
375 
376 	bpf_for(i, 0, ARRAY_SIZE(arr)) {
377 		arr[i] = i * 2;
378 	}
379 
380 	sum = 0;
381 	bpf_for(i, 0, ARRAY_SIZE(arr)) {
382 		sum += arr[i];
383 	}
384 
385 	bpf_printk("ITER_ARRAY_FILL: sum=%d (should be %d)\n", sum, 255 * 256);
386 
387 	return 0;
388 }
389 
390 static int arr2d[4][5];
391 static int arr2d_row_sums[4];
392 static int arr2d_col_sums[5];
393 
394 SEC("raw_tp")
395 __success
396 int iter_nested_iters(const void *ctx)
397 {
398 	int sum, row, col;
399 
400 	MY_PID_GUARD();
401 
402 	bpf_for(row, 0, ARRAY_SIZE(arr2d)) {
403 		bpf_for( col, 0, ARRAY_SIZE(arr2d[0])) {
404 			arr2d[row][col] = row * col;
405 		}
406 	}
407 
408 	/* zero-initialize sums */
409 	sum = 0;
410 	bpf_for(row, 0, ARRAY_SIZE(arr2d)) {
411 		arr2d_row_sums[row] = 0;
412 	}
413 	bpf_for(col, 0, ARRAY_SIZE(arr2d[0])) {
414 		arr2d_col_sums[col] = 0;
415 	}
416 
417 	/* calculate sums */
418 	bpf_for(row, 0, ARRAY_SIZE(arr2d)) {
419 		bpf_for(col, 0, ARRAY_SIZE(arr2d[0])) {
420 			sum += arr2d[row][col];
421 			arr2d_row_sums[row] += arr2d[row][col];
422 			arr2d_col_sums[col] += arr2d[row][col];
423 		}
424 	}
425 
426 	bpf_printk("ITER_NESTED_ITERS: total sum=%d", sum);
427 	bpf_for(row, 0, ARRAY_SIZE(arr2d)) {
428 		bpf_printk("ITER_NESTED_ITERS: row #%d sum=%d", row, arr2d_row_sums[row]);
429 	}
430 	bpf_for(col, 0, ARRAY_SIZE(arr2d[0])) {
431 		bpf_printk("ITER_NESTED_ITERS: col #%d sum=%d%s",
432 			   col, arr2d_col_sums[col],
433 			   col == ARRAY_SIZE(arr2d[0]) - 1 ? "\n" : "");
434 	}
435 
436 	return 0;
437 }
438 
439 SEC("raw_tp")
440 __success
441 int iter_nested_deeply_iters(const void *ctx)
442 {
443 	int sum = 0;
444 
445 	MY_PID_GUARD();
446 
447 	bpf_repeat(10) {
448 		bpf_repeat(10) {
449 			bpf_repeat(10) {
450 				bpf_repeat(10) {
451 					bpf_repeat(10) {
452 						sum += 1;
453 					}
454 				}
455 			}
456 		}
457 		/* validate that we can break from inside bpf_repeat() */
458 		break;
459 	}
460 
461 	return sum;
462 }
463 
464 static __noinline void fill_inner_dimension(int row)
465 {
466 	int col;
467 
468 	bpf_for(col, 0, ARRAY_SIZE(arr2d[0])) {
469 		arr2d[row][col] = row * col;
470 	}
471 }
472 
473 static __noinline int sum_inner_dimension(int row)
474 {
475 	int sum = 0, col;
476 
477 	bpf_for(col, 0, ARRAY_SIZE(arr2d[0])) {
478 		sum += arr2d[row][col];
479 		arr2d_row_sums[row] += arr2d[row][col];
480 		arr2d_col_sums[col] += arr2d[row][col];
481 	}
482 
483 	return sum;
484 }
485 
486 SEC("raw_tp")
487 __success
488 int iter_subprog_iters(const void *ctx)
489 {
490 	int sum, row, col;
491 
492 	MY_PID_GUARD();
493 
494 	bpf_for(row, 0, ARRAY_SIZE(arr2d)) {
495 		fill_inner_dimension(row);
496 	}
497 
498 	/* zero-initialize sums */
499 	sum = 0;
500 	bpf_for(row, 0, ARRAY_SIZE(arr2d)) {
501 		arr2d_row_sums[row] = 0;
502 	}
503 	bpf_for(col, 0, ARRAY_SIZE(arr2d[0])) {
504 		arr2d_col_sums[col] = 0;
505 	}
506 
507 	/* calculate sums */
508 	bpf_for(row, 0, ARRAY_SIZE(arr2d)) {
509 		sum += sum_inner_dimension(row);
510 	}
511 
512 	bpf_printk("ITER_SUBPROG_ITERS: total sum=%d", sum);
513 	bpf_for(row, 0, ARRAY_SIZE(arr2d)) {
514 		bpf_printk("ITER_SUBPROG_ITERS: row #%d sum=%d",
515 			   row, arr2d_row_sums[row]);
516 	}
517 	bpf_for(col, 0, ARRAY_SIZE(arr2d[0])) {
518 		bpf_printk("ITER_SUBPROG_ITERS: col #%d sum=%d%s",
519 			   col, arr2d_col_sums[col],
520 			   col == ARRAY_SIZE(arr2d[0]) - 1 ? "\n" : "");
521 	}
522 
523 	return 0;
524 }
525 
526 struct {
527 	__uint(type, BPF_MAP_TYPE_ARRAY);
528 	__type(key, int);
529 	__type(value, int);
530 	__uint(max_entries, 1000);
531 } arr_map SEC(".maps");
532 
533 SEC("?raw_tp")
534 __failure __msg("invalid mem access 'scalar'")
535 int iter_err_too_permissive1(const void *ctx)
536 {
537 	int *map_val = NULL;
538 	int key = 0;
539 
540 	MY_PID_GUARD();
541 
542 	map_val = bpf_map_lookup_elem(&arr_map, &key);
543 	if (!map_val)
544 		return 0;
545 
546 	bpf_repeat(1000000) {
547 		map_val = NULL;
548 	}
549 
550 	*map_val = 123;
551 
552 	return 0;
553 }
554 
555 SEC("?raw_tp")
556 __failure __msg("invalid mem access 'map_value_or_null'")
557 int iter_err_too_permissive2(const void *ctx)
558 {
559 	int *map_val = NULL;
560 	int key = 0;
561 
562 	MY_PID_GUARD();
563 
564 	map_val = bpf_map_lookup_elem(&arr_map, &key);
565 	if (!map_val)
566 		return 0;
567 
568 	bpf_repeat(1000000) {
569 		map_val = bpf_map_lookup_elem(&arr_map, &key);
570 	}
571 
572 	*map_val = 123;
573 
574 	return 0;
575 }
576 
577 SEC("?raw_tp")
578 __failure __msg("invalid mem access 'map_value_or_null'")
579 int iter_err_too_permissive3(const void *ctx)
580 {
581 	int *map_val = NULL;
582 	int key = 0;
583 	bool found = false;
584 
585 	MY_PID_GUARD();
586 
587 	bpf_repeat(1000000) {
588 		map_val = bpf_map_lookup_elem(&arr_map, &key);
589 		found = true;
590 	}
591 
592 	if (found)
593 		*map_val = 123;
594 
595 	return 0;
596 }
597 
598 SEC("raw_tp")
599 __success
600 int iter_tricky_but_fine(const void *ctx)
601 {
602 	int *map_val = NULL;
603 	int key = 0;
604 	bool found = false;
605 
606 	MY_PID_GUARD();
607 
608 	bpf_repeat(1000000) {
609 		map_val = bpf_map_lookup_elem(&arr_map, &key);
610 		if (map_val) {
611 			found = true;
612 			break;
613 		}
614 	}
615 
616 	if (found)
617 		*map_val = 123;
618 
619 	return 0;
620 }
621 
622 #define __bpf_memzero(p, sz) bpf_probe_read_kernel((p), (sz), 0)
623 
624 SEC("raw_tp")
625 __success
626 int iter_stack_array_loop(const void *ctx)
627 {
628 	long arr1[16], arr2[16], sum = 0;
629 	int i;
630 
631 	MY_PID_GUARD();
632 
633 	/* zero-init arr1 and arr2 in such a way that verifier doesn't know
634 	 * it's all zeros; if we don't do that, we'll make BPF verifier track
635 	 * all combination of zero/non-zero stack slots for arr1/arr2, which
636 	 * will lead to O(2^(ARRAY_SIZE(arr1)+ARRAY_SIZE(arr2))) different
637 	 * states
638 	 */
639 	__bpf_memzero(arr1, sizeof(arr1));
640 	__bpf_memzero(arr2, sizeof(arr1));
641 
642 	/* validate that we can break and continue when using bpf_for() */
643 	bpf_for(i, 0, ARRAY_SIZE(arr1)) {
644 		if (i & 1) {
645 			arr1[i] = i;
646 			continue;
647 		} else {
648 			arr2[i] = i;
649 			break;
650 		}
651 	}
652 
653 	bpf_for(i, 0, ARRAY_SIZE(arr1)) {
654 		sum += arr1[i] + arr2[i];
655 	}
656 
657 	return sum;
658 }
659 
660 static __noinline void fill(struct bpf_iter_num *it, int *arr, __u32 n, int mul)
661 {
662 	int *t, i;
663 
664 	while ((t = bpf_iter_num_next(it))) {
665 		i = *t;
666 		if (i >= n)
667 			break;
668 		arr[i] =  i * mul;
669 	}
670 }
671 
672 static __noinline int sum(struct bpf_iter_num *it, int *arr, __u32 n)
673 {
674 	int *t, i, sum = 0;
675 
676 	while ((t = bpf_iter_num_next(it))) {
677 		i = *t;
678 		if ((__u32)i >= n)
679 			break;
680 		sum += arr[i];
681 	}
682 
683 	return sum;
684 }
685 
686 SEC("raw_tp")
687 __success
688 int iter_pass_iter_ptr_to_subprog(const void *ctx)
689 {
690 	int arr1[16], arr2[32];
691 	struct bpf_iter_num it;
692 	int n, sum1, sum2;
693 
694 	MY_PID_GUARD();
695 
696 	/* fill arr1 */
697 	n = ARRAY_SIZE(arr1);
698 	bpf_iter_num_new(&it, 0, n);
699 	fill(&it, arr1, n, 2);
700 	bpf_iter_num_destroy(&it);
701 
702 	/* fill arr2 */
703 	n = ARRAY_SIZE(arr2);
704 	bpf_iter_num_new(&it, 0, n);
705 	fill(&it, arr2, n, 10);
706 	bpf_iter_num_destroy(&it);
707 
708 	/* sum arr1 */
709 	n = ARRAY_SIZE(arr1);
710 	bpf_iter_num_new(&it, 0, n);
711 	sum1 = sum(&it, arr1, n);
712 	bpf_iter_num_destroy(&it);
713 
714 	/* sum arr2 */
715 	n = ARRAY_SIZE(arr2);
716 	bpf_iter_num_new(&it, 0, n);
717 	sum2 = sum(&it, arr2, n);
718 	bpf_iter_num_destroy(&it);
719 
720 	bpf_printk("sum1=%d, sum2=%d", sum1, sum2);
721 
722 	return 0;
723 }
724 
725 SEC("?raw_tp")
726 __failure
727 __msg("R1 type=scalar expected=fp")
728 __naked int delayed_read_mark(void)
729 {
730 	/* This is equivalent to C program below.
731 	 * The call to bpf_iter_num_next() is reachable with r7 values &fp[-16] and 0xdead.
732 	 * State with r7=&fp[-16] is visited first and follows r6 != 42 ... continue branch.
733 	 * At this point iterator next() call is reached with r7 that has no read mark.
734 	 * Loop body with r7=0xdead would only be visited if verifier would decide to continue
735 	 * with second loop iteration. Absence of read mark on r7 might affect state
736 	 * equivalent logic used for iterator convergence tracking.
737 	 *
738 	 * r7 = &fp[-16]
739 	 * fp[-16] = 0
740 	 * r6 = bpf_get_prandom_u32()
741 	 * bpf_iter_num_new(&fp[-8], 0, 10)
742 	 * while (bpf_iter_num_next(&fp[-8])) {
743 	 *   r6++
744 	 *   if (r6 != 42) {
745 	 *     r7 = 0xdead
746 	 *     continue;
747 	 *   }
748 	 *   bpf_probe_read_user(r7, 8, 0xdeadbeef); // this is not safe
749 	 * }
750 	 * bpf_iter_num_destroy(&fp[-8])
751 	 * return 0
752 	 */
753 	asm volatile (
754 		"r7 = r10;"
755 		"r7 += -16;"
756 		"r0 = 0;"
757 		"*(u64 *)(r7 + 0) = r0;"
758 		"call %[bpf_get_prandom_u32];"
759 		"r6 = r0;"
760 		"r1 = r10;"
761 		"r1 += -8;"
762 		"r2 = 0;"
763 		"r3 = 10;"
764 		"call %[bpf_iter_num_new];"
765 	"1:"
766 		"r1 = r10;"
767 		"r1 += -8;"
768 		"call %[bpf_iter_num_next];"
769 		"if r0 == 0 goto 2f;"
770 		"r6 += 1;"
771 		"if r6 != 42 goto 3f;"
772 		"r7 = 0xdead;"
773 		"goto 1b;"
774 	"3:"
775 		"r1 = r7;"
776 		"r2 = 8;"
777 		"r3 = 0xdeadbeef;"
778 		"call %[bpf_probe_read_user];"
779 		"goto 1b;"
780 	"2:"
781 		"r1 = r10;"
782 		"r1 += -8;"
783 		"call %[bpf_iter_num_destroy];"
784 		"r0 = 0;"
785 		"exit;"
786 		:
787 		: __imm(bpf_get_prandom_u32),
788 		  __imm(bpf_iter_num_new),
789 		  __imm(bpf_iter_num_next),
790 		  __imm(bpf_iter_num_destroy),
791 		  __imm(bpf_probe_read_user)
792 		: __clobber_all
793 	);
794 }
795 
796 SEC("?raw_tp")
797 __failure
798 __msg("math between fp pointer and register with unbounded")
799 __naked int delayed_precision_mark(void)
800 {
801 	/* This is equivalent to C program below.
802 	 * The test is similar to delayed_iter_mark but verifies that incomplete
803 	 * precision don't fool verifier.
804 	 * The call to bpf_iter_num_next() is reachable with r7 values -16 and -32.
805 	 * State with r7=-16 is visited first and follows r6 != 42 ... continue branch.
806 	 * At this point iterator next() call is reached with r7 that has no read
807 	 * and precision marks.
808 	 * Loop body with r7=-32 would only be visited if verifier would decide to continue
809 	 * with second loop iteration. Absence of precision mark on r7 might affect state
810 	 * equivalent logic used for iterator convergence tracking.
811 	 *
812 	 * r8 = 0
813 	 * fp[-16] = 0
814 	 * r7 = -16
815 	 * r6 = bpf_get_prandom_u32()
816 	 * bpf_iter_num_new(&fp[-8], 0, 10)
817 	 * while (bpf_iter_num_next(&fp[-8])) {
818 	 *   if (r6 != 42) {
819 	 *     r7 = -32
820 	 *     r6 = bpf_get_prandom_u32()
821 	 *     continue;
822 	 *   }
823 	 *   r0 = r10
824 	 *   r0 += r7
825 	 *   r8 = *(u64 *)(r0 + 0)           // this is not safe
826 	 *   r6 = bpf_get_prandom_u32()
827 	 * }
828 	 * bpf_iter_num_destroy(&fp[-8])
829 	 * return r8
830 	 */
831 	asm volatile (
832 		"r8 = 0;"
833 		"*(u64 *)(r10 - 16) = r8;"
834 		"r7 = -16;"
835 		"call %[bpf_get_prandom_u32];"
836 		"r6 = r0;"
837 		"r1 = r10;"
838 		"r1 += -8;"
839 		"r2 = 0;"
840 		"r3 = 10;"
841 		"call %[bpf_iter_num_new];"
842 	"1:"
843 		"r1 = r10;"
844 		"r1 += -8;\n"
845 		"call %[bpf_iter_num_next];"
846 		"if r0 == 0 goto 2f;"
847 		"if r6 != 42 goto 3f;"
848 		"r7 = -33;"
849 		"call %[bpf_get_prandom_u32];"
850 		"r6 = r0;"
851 		"goto 1b;\n"
852 	"3:"
853 		"r0 = r10;"
854 		"r0 += r7;"
855 		"r8 = *(u64 *)(r0 + 0);"
856 		"call %[bpf_get_prandom_u32];"
857 		"r6 = r0;"
858 		"goto 1b;\n"
859 	"2:"
860 		"r1 = r10;"
861 		"r1 += -8;"
862 		"call %[bpf_iter_num_destroy];"
863 		"r0 = r8;"
864 		"exit;"
865 		:
866 		: __imm(bpf_get_prandom_u32),
867 		  __imm(bpf_iter_num_new),
868 		  __imm(bpf_iter_num_next),
869 		  __imm(bpf_iter_num_destroy),
870 		  __imm(bpf_probe_read_user)
871 		: __clobber_all
872 	);
873 }
874 
875 SEC("?raw_tp")
876 __failure
877 __msg("math between fp pointer and register with unbounded")
878 __flag(BPF_F_TEST_STATE_FREQ)
879 __naked int loop_state_deps1(void)
880 {
881 	/* This is equivalent to C program below.
882 	 *
883 	 * The case turns out to be tricky in a sense that:
884 	 * - states with c=-25 are explored only on a second iteration
885 	 *   of the outer loop;
886 	 * - states with read+precise mark on c are explored only on
887 	 *   second iteration of the inner loop and in a state which
888 	 *   is pushed to states stack first.
889 	 *
890 	 * Depending on the details of iterator convergence logic
891 	 * verifier might stop states traversal too early and miss
892 	 * unsafe c=-25 memory access.
893 	 *
894 	 *   j = iter_new();		 // fp[-16]
895 	 *   a = 0;			 // r6
896 	 *   b = 0;			 // r7
897 	 *   c = -24;			 // r8
898 	 *   while (iter_next(j)) {
899 	 *     i = iter_new();		 // fp[-8]
900 	 *     a = 0;			 // r6
901 	 *     b = 0;			 // r7
902 	 *     while (iter_next(i)) {
903 	 *	 if (a == 1) {
904 	 *	   a = 0;
905 	 *	   b = 1;
906 	 *	 } else if (a == 0) {
907 	 *	   a = 1;
908 	 *	   if (random() == 42)
909 	 *	     continue;
910 	 *	   if (b == 1) {
911 	 *	     *(r10 + c) = 7;  // this is not safe
912 	 *	     iter_destroy(i);
913 	 *	     iter_destroy(j);
914 	 *	     return;
915 	 *	   }
916 	 *	 }
917 	 *     }
918 	 *     iter_destroy(i);
919 	 *     a = 0;
920 	 *     b = 0;
921 	 *     c = -25;
922 	 *   }
923 	 *   iter_destroy(j);
924 	 *   return;
925 	 */
926 	asm volatile (
927 		"r1 = r10;"
928 		"r1 += -16;"
929 		"r2 = 0;"
930 		"r3 = 10;"
931 		"call %[bpf_iter_num_new];"
932 		"r6 = 0;"
933 		"r7 = 0;"
934 		"r8 = -24;"
935 	"j_loop_%=:"
936 		"r1 = r10;"
937 		"r1 += -16;"
938 		"call %[bpf_iter_num_next];"
939 		"if r0 == 0 goto j_loop_end_%=;"
940 		"r1 = r10;"
941 		"r1 += -8;"
942 		"r2 = 0;"
943 		"r3 = 10;"
944 		"call %[bpf_iter_num_new];"
945 		"r6 = 0;"
946 		"r7 = 0;"
947 	"i_loop_%=:"
948 		"r1 = r10;"
949 		"r1 += -8;"
950 		"call %[bpf_iter_num_next];"
951 		"if r0 == 0 goto i_loop_end_%=;"
952 	"check_one_r6_%=:"
953 		"if r6 != 1 goto check_zero_r6_%=;"
954 		"r6 = 0;"
955 		"r7 = 1;"
956 		"goto i_loop_%=;"
957 	"check_zero_r6_%=:"
958 		"if r6 != 0 goto i_loop_%=;"
959 		"r6 = 1;"
960 		"call %[bpf_get_prandom_u32];"
961 		"if r0 != 42 goto check_one_r7_%=;"
962 		"goto i_loop_%=;"
963 	"check_one_r7_%=:"
964 		"if r7 != 1 goto i_loop_%=;"
965 		"r0 = r10;"
966 		"r0 += r8;"
967 		"r1 = 7;"
968 		"*(u64 *)(r0 + 0) = r1;"
969 		"r1 = r10;"
970 		"r1 += -8;"
971 		"call %[bpf_iter_num_destroy];"
972 		"r1 = r10;"
973 		"r1 += -16;"
974 		"call %[bpf_iter_num_destroy];"
975 		"r0 = 0;"
976 		"exit;"
977 	"i_loop_end_%=:"
978 		"r1 = r10;"
979 		"r1 += -8;"
980 		"call %[bpf_iter_num_destroy];"
981 		"r6 = 0;"
982 		"r7 = 0;"
983 		"r8 = -25;"
984 		"goto j_loop_%=;"
985 	"j_loop_end_%=:"
986 		"r1 = r10;"
987 		"r1 += -16;"
988 		"call %[bpf_iter_num_destroy];"
989 		"r0 = 0;"
990 		"exit;"
991 		:
992 		: __imm(bpf_get_prandom_u32),
993 		  __imm(bpf_iter_num_new),
994 		  __imm(bpf_iter_num_next),
995 		  __imm(bpf_iter_num_destroy)
996 		: __clobber_all
997 	);
998 }
999 
1000 SEC("?raw_tp")
1001 __failure
1002 __msg("math between fp pointer and register with unbounded")
1003 __flag(BPF_F_TEST_STATE_FREQ)
1004 __naked int loop_state_deps2(void)
1005 {
1006 	/* This is equivalent to C program below.
1007 	 *
1008 	 * The case turns out to be tricky in a sense that:
1009 	 * - states with read+precise mark on c are explored only on a second
1010 	 *   iteration of the first inner loop and in a state which is pushed to
1011 	 *   states stack first.
1012 	 * - states with c=-25 are explored only on a second iteration of the
1013 	 *   second inner loop and in a state which is pushed to states stack
1014 	 *   first.
1015 	 *
1016 	 * Depending on the details of iterator convergence logic
1017 	 * verifier might stop states traversal too early and miss
1018 	 * unsafe c=-25 memory access.
1019 	 *
1020 	 *   j = iter_new();             // fp[-16]
1021 	 *   a = 0;                      // r6
1022 	 *   b = 0;                      // r7
1023 	 *   c = -24;                    // r8
1024 	 *   while (iter_next(j)) {
1025 	 *     i = iter_new();           // fp[-8]
1026 	 *     a = 0;                    // r6
1027 	 *     b = 0;                    // r7
1028 	 *     while (iter_next(i)) {
1029 	 *       if (a == 1) {
1030 	 *         a = 0;
1031 	 *         b = 1;
1032 	 *       } else if (a == 0) {
1033 	 *         a = 1;
1034 	 *         if (random() == 42)
1035 	 *           continue;
1036 	 *         if (b == 1) {
1037 	 *           *(r10 + c) = 7;     // this is not safe
1038 	 *           iter_destroy(i);
1039 	 *           iter_destroy(j);
1040 	 *           return;
1041 	 *         }
1042 	 *       }
1043 	 *     }
1044 	 *     iter_destroy(i);
1045 	 *     i = iter_new();           // fp[-8]
1046 	 *     a = 0;                    // r6
1047 	 *     b = 0;                    // r7
1048 	 *     while (iter_next(i)) {
1049 	 *       if (a == 1) {
1050 	 *         a = 0;
1051 	 *         b = 1;
1052 	 *       } else if (a == 0) {
1053 	 *         a = 1;
1054 	 *         if (random() == 42)
1055 	 *           continue;
1056 	 *         if (b == 1) {
1057 	 *           a = 0;
1058 	 *           c = -25;
1059 	 *         }
1060 	 *       }
1061 	 *     }
1062 	 *     iter_destroy(i);
1063 	 *   }
1064 	 *   iter_destroy(j);
1065 	 *   return;
1066 	 */
1067 	asm volatile (
1068 		"r1 = r10;"
1069 		"r1 += -16;"
1070 		"r2 = 0;"
1071 		"r3 = 10;"
1072 		"call %[bpf_iter_num_new];"
1073 		"r6 = 0;"
1074 		"r7 = 0;"
1075 		"r8 = -24;"
1076 	"j_loop_%=:"
1077 		"r1 = r10;"
1078 		"r1 += -16;"
1079 		"call %[bpf_iter_num_next];"
1080 		"if r0 == 0 goto j_loop_end_%=;"
1081 
1082 		/* first inner loop */
1083 		"r1 = r10;"
1084 		"r1 += -8;"
1085 		"r2 = 0;"
1086 		"r3 = 10;"
1087 		"call %[bpf_iter_num_new];"
1088 		"r6 = 0;"
1089 		"r7 = 0;"
1090 	"i_loop_%=:"
1091 		"r1 = r10;"
1092 		"r1 += -8;"
1093 		"call %[bpf_iter_num_next];"
1094 		"if r0 == 0 goto i_loop_end_%=;"
1095 	"check_one_r6_%=:"
1096 		"if r6 != 1 goto check_zero_r6_%=;"
1097 		"r6 = 0;"
1098 		"r7 = 1;"
1099 		"goto i_loop_%=;"
1100 	"check_zero_r6_%=:"
1101 		"if r6 != 0 goto i_loop_%=;"
1102 		"r6 = 1;"
1103 		"call %[bpf_get_prandom_u32];"
1104 		"if r0 != 42 goto check_one_r7_%=;"
1105 		"goto i_loop_%=;"
1106 	"check_one_r7_%=:"
1107 		"if r7 != 1 goto i_loop_%=;"
1108 		"r0 = r10;"
1109 		"r0 += r8;"
1110 		"r1 = 7;"
1111 		"*(u64 *)(r0 + 0) = r1;"
1112 		"r1 = r10;"
1113 		"r1 += -8;"
1114 		"call %[bpf_iter_num_destroy];"
1115 		"r1 = r10;"
1116 		"r1 += -16;"
1117 		"call %[bpf_iter_num_destroy];"
1118 		"r0 = 0;"
1119 		"exit;"
1120 	"i_loop_end_%=:"
1121 		"r1 = r10;"
1122 		"r1 += -8;"
1123 		"call %[bpf_iter_num_destroy];"
1124 
1125 		/* second inner loop */
1126 		"r1 = r10;"
1127 		"r1 += -8;"
1128 		"r2 = 0;"
1129 		"r3 = 10;"
1130 		"call %[bpf_iter_num_new];"
1131 		"r6 = 0;"
1132 		"r7 = 0;"
1133 	"i2_loop_%=:"
1134 		"r1 = r10;"
1135 		"r1 += -8;"
1136 		"call %[bpf_iter_num_next];"
1137 		"if r0 == 0 goto i2_loop_end_%=;"
1138 	"check2_one_r6_%=:"
1139 		"if r6 != 1 goto check2_zero_r6_%=;"
1140 		"r6 = 0;"
1141 		"r7 = 1;"
1142 		"goto i2_loop_%=;"
1143 	"check2_zero_r6_%=:"
1144 		"if r6 != 0 goto i2_loop_%=;"
1145 		"r6 = 1;"
1146 		"call %[bpf_get_prandom_u32];"
1147 		"if r0 != 42 goto check2_one_r7_%=;"
1148 		"goto i2_loop_%=;"
1149 	"check2_one_r7_%=:"
1150 		"if r7 != 1 goto i2_loop_%=;"
1151 		"r6 = 0;"
1152 		"r8 = -25;"
1153 		"goto i2_loop_%=;"
1154 	"i2_loop_end_%=:"
1155 		"r1 = r10;"
1156 		"r1 += -8;"
1157 		"call %[bpf_iter_num_destroy];"
1158 
1159 		"r6 = 0;"
1160 		"r7 = 0;"
1161 		"goto j_loop_%=;"
1162 	"j_loop_end_%=:"
1163 		"r1 = r10;"
1164 		"r1 += -16;"
1165 		"call %[bpf_iter_num_destroy];"
1166 		"r0 = 0;"
1167 		"exit;"
1168 		:
1169 		: __imm(bpf_get_prandom_u32),
1170 		  __imm(bpf_iter_num_new),
1171 		  __imm(bpf_iter_num_next),
1172 		  __imm(bpf_iter_num_destroy)
1173 		: __clobber_all
1174 	);
1175 }
1176 
1177 SEC("?raw_tp")
1178 __success
1179 __naked int triple_continue(void)
1180 {
1181 	/* This is equivalent to C program below.
1182 	 * High branching factor of the loop body turned out to be
1183 	 * problematic for one of the iterator convergence tracking
1184 	 * algorithms explored.
1185 	 *
1186 	 * r6 = bpf_get_prandom_u32()
1187 	 * bpf_iter_num_new(&fp[-8], 0, 10)
1188 	 * while (bpf_iter_num_next(&fp[-8])) {
1189 	 *   if (bpf_get_prandom_u32() != 42)
1190 	 *     continue;
1191 	 *   if (bpf_get_prandom_u32() != 42)
1192 	 *     continue;
1193 	 *   if (bpf_get_prandom_u32() != 42)
1194 	 *     continue;
1195 	 *   r0 += 0;
1196 	 * }
1197 	 * bpf_iter_num_destroy(&fp[-8])
1198 	 * return 0
1199 	 */
1200 	asm volatile (
1201 		"r1 = r10;"
1202 		"r1 += -8;"
1203 		"r2 = 0;"
1204 		"r3 = 10;"
1205 		"call %[bpf_iter_num_new];"
1206 	"loop_%=:"
1207 		"r1 = r10;"
1208 		"r1 += -8;"
1209 		"call %[bpf_iter_num_next];"
1210 		"if r0 == 0 goto loop_end_%=;"
1211 		"call %[bpf_get_prandom_u32];"
1212 		"if r0 != 42 goto loop_%=;"
1213 		"call %[bpf_get_prandom_u32];"
1214 		"if r0 != 42 goto loop_%=;"
1215 		"call %[bpf_get_prandom_u32];"
1216 		"if r0 != 42 goto loop_%=;"
1217 		"r0 += 0;"
1218 		"goto loop_%=;"
1219 	"loop_end_%=:"
1220 		"r1 = r10;"
1221 		"r1 += -8;"
1222 		"call %[bpf_iter_num_destroy];"
1223 		"r0 = 0;"
1224 		"exit;"
1225 		:
1226 		: __imm(bpf_get_prandom_u32),
1227 		  __imm(bpf_iter_num_new),
1228 		  __imm(bpf_iter_num_next),
1229 		  __imm(bpf_iter_num_destroy)
1230 		: __clobber_all
1231 	);
1232 }
1233 
1234 SEC("?raw_tp")
1235 __success
1236 __naked int widen_spill(void)
1237 {
1238 	/* This is equivalent to C program below.
1239 	 * The counter is stored in fp[-16], if this counter is not widened
1240 	 * verifier states representing loop iterations would never converge.
1241 	 *
1242 	 * fp[-16] = 0
1243 	 * bpf_iter_num_new(&fp[-8], 0, 10)
1244 	 * while (bpf_iter_num_next(&fp[-8])) {
1245 	 *   r0 = fp[-16];
1246 	 *   r0 += 1;
1247 	 *   fp[-16] = r0;
1248 	 * }
1249 	 * bpf_iter_num_destroy(&fp[-8])
1250 	 * return 0
1251 	 */
1252 	asm volatile (
1253 		"r0 = 0;"
1254 		"*(u64 *)(r10 - 16) = r0;"
1255 		"r1 = r10;"
1256 		"r1 += -8;"
1257 		"r2 = 0;"
1258 		"r3 = 10;"
1259 		"call %[bpf_iter_num_new];"
1260 	"loop_%=:"
1261 		"r1 = r10;"
1262 		"r1 += -8;"
1263 		"call %[bpf_iter_num_next];"
1264 		"if r0 == 0 goto loop_end_%=;"
1265 		"r0 = *(u64 *)(r10 - 16);"
1266 		"r0 += 1;"
1267 		"*(u64 *)(r10 - 16) = r0;"
1268 		"goto loop_%=;"
1269 	"loop_end_%=:"
1270 		"r1 = r10;"
1271 		"r1 += -8;"
1272 		"call %[bpf_iter_num_destroy];"
1273 		"r0 = 0;"
1274 		"exit;"
1275 		:
1276 		: __imm(bpf_iter_num_new),
1277 		  __imm(bpf_iter_num_next),
1278 		  __imm(bpf_iter_num_destroy)
1279 		: __clobber_all
1280 	);
1281 }
1282 
1283 SEC("raw_tp")
1284 __success
1285 __naked int checkpoint_states_deletion(void)
1286 {
1287 	/* This is equivalent to C program below.
1288 	 *
1289 	 *   int *a, *b, *c, *d, *e, *f;
1290 	 *   int i, sum = 0;
1291 	 *   bpf_for(i, 0, 10) {
1292 	 *     a = bpf_map_lookup_elem(&amap, &i);
1293 	 *     b = bpf_map_lookup_elem(&amap, &i);
1294 	 *     c = bpf_map_lookup_elem(&amap, &i);
1295 	 *     d = bpf_map_lookup_elem(&amap, &i);
1296 	 *     e = bpf_map_lookup_elem(&amap, &i);
1297 	 *     f = bpf_map_lookup_elem(&amap, &i);
1298 	 *     if (a) sum += 1;
1299 	 *     if (b) sum += 1;
1300 	 *     if (c) sum += 1;
1301 	 *     if (d) sum += 1;
1302 	 *     if (e) sum += 1;
1303 	 *     if (f) sum += 1;
1304 	 *   }
1305 	 *   return 0;
1306 	 *
1307 	 * The body of the loop spawns multiple simulation paths
1308 	 * with different combination of NULL/non-NULL information for a/b/c/d/e/f.
1309 	 * Each combination is unique from states_equal() point of view.
1310 	 * Explored states checkpoint is created after each iterator next call.
1311 	 * Iterator convergence logic expects that eventually current state
1312 	 * would get equal to one of the explored states and thus loop
1313 	 * exploration would be finished (at-least for a specific path).
1314 	 * Verifier evicts explored states with high miss to hit ratio
1315 	 * to to avoid comparing current state with too many explored
1316 	 * states per instruction.
1317 	 * This test is designed to "stress test" eviction policy defined using formula:
1318 	 *
1319 	 *    sl->miss_cnt > sl->hit_cnt * N + N // if true sl->state is evicted
1320 	 *
1321 	 * Currently N is set to 64, which allows for 6 variables in this test.
1322 	 */
1323 	asm volatile (
1324 		"r6 = 0;"                  /* a */
1325 		"r7 = 0;"                  /* b */
1326 		"r8 = 0;"                  /* c */
1327 		"*(u64 *)(r10 - 24) = r6;" /* d */
1328 		"*(u64 *)(r10 - 32) = r6;" /* e */
1329 		"*(u64 *)(r10 - 40) = r6;" /* f */
1330 		"r9 = 0;"                  /* sum */
1331 		"r1 = r10;"
1332 		"r1 += -8;"
1333 		"r2 = 0;"
1334 		"r3 = 10;"
1335 		"call %[bpf_iter_num_new];"
1336 	"loop_%=:"
1337 		"r1 = r10;"
1338 		"r1 += -8;"
1339 		"call %[bpf_iter_num_next];"
1340 		"if r0 == 0 goto loop_end_%=;"
1341 
1342 		"*(u64 *)(r10 - 16) = r0;"
1343 
1344 		"r1 = %[amap] ll;"
1345 		"r2 = r10;"
1346 		"r2 += -16;"
1347 		"call %[bpf_map_lookup_elem];"
1348 		"r6 = r0;"
1349 
1350 		"r1 = %[amap] ll;"
1351 		"r2 = r10;"
1352 		"r2 += -16;"
1353 		"call %[bpf_map_lookup_elem];"
1354 		"r7 = r0;"
1355 
1356 		"r1 = %[amap] ll;"
1357 		"r2 = r10;"
1358 		"r2 += -16;"
1359 		"call %[bpf_map_lookup_elem];"
1360 		"r8 = r0;"
1361 
1362 		"r1 = %[amap] ll;"
1363 		"r2 = r10;"
1364 		"r2 += -16;"
1365 		"call %[bpf_map_lookup_elem];"
1366 		"*(u64 *)(r10 - 24) = r0;"
1367 
1368 		"r1 = %[amap] ll;"
1369 		"r2 = r10;"
1370 		"r2 += -16;"
1371 		"call %[bpf_map_lookup_elem];"
1372 		"*(u64 *)(r10 - 32) = r0;"
1373 
1374 		"r1 = %[amap] ll;"
1375 		"r2 = r10;"
1376 		"r2 += -16;"
1377 		"call %[bpf_map_lookup_elem];"
1378 		"*(u64 *)(r10 - 40) = r0;"
1379 
1380 		"if r6 == 0 goto +1;"
1381 		"r9 += 1;"
1382 		"if r7 == 0 goto +1;"
1383 		"r9 += 1;"
1384 		"if r8 == 0 goto +1;"
1385 		"r9 += 1;"
1386 		"r0 = *(u64 *)(r10 - 24);"
1387 		"if r0 == 0 goto +1;"
1388 		"r9 += 1;"
1389 		"r0 = *(u64 *)(r10 - 32);"
1390 		"if r0 == 0 goto +1;"
1391 		"r9 += 1;"
1392 		"r0 = *(u64 *)(r10 - 40);"
1393 		"if r0 == 0 goto +1;"
1394 		"r9 += 1;"
1395 
1396 		"goto loop_%=;"
1397 	"loop_end_%=:"
1398 		"r1 = r10;"
1399 		"r1 += -8;"
1400 		"call %[bpf_iter_num_destroy];"
1401 		"r0 = 0;"
1402 		"exit;"
1403 		:
1404 		: __imm(bpf_map_lookup_elem),
1405 		  __imm(bpf_iter_num_new),
1406 		  __imm(bpf_iter_num_next),
1407 		  __imm(bpf_iter_num_destroy),
1408 		  __imm_addr(amap)
1409 		: __clobber_all
1410 	);
1411 }
1412 
1413 struct {
1414 	int data[32];
1415 	int n;
1416 } loop_data;
1417 
1418 SEC("raw_tp")
1419 __success
1420 int iter_arr_with_actual_elem_count(const void *ctx)
1421 {
1422 	int i, n = loop_data.n, sum = 0;
1423 
1424 	if (n > ARRAY_SIZE(loop_data.data))
1425 		return 0;
1426 
1427 	bpf_for(i, 0, n) {
1428 		/* no rechecking of i against ARRAY_SIZE(loop_data.n) */
1429 		sum += loop_data.data[i];
1430 	}
1431 
1432 	return sum;
1433 }
1434 
1435 __u32 upper, select_n, result;
1436 __u64 global;
1437 
1438 static __noinline bool nest_2(char *str)
1439 {
1440 	/* some insns (including branch insns) to ensure stacksafe() is triggered
1441 	 * in nest_2(). This way, stacksafe() can compare frame associated with nest_1().
1442 	 */
1443 	if (str[0] == 't')
1444 		return true;
1445 	if (str[1] == 'e')
1446 		return true;
1447 	if (str[2] == 's')
1448 		return true;
1449 	if (str[3] == 't')
1450 		return true;
1451 	return false;
1452 }
1453 
1454 static __noinline bool nest_1(int n)
1455 {
1456 	/* case 0: allocate stack, case 1: no allocate stack */
1457 	switch (n) {
1458 	case 0: {
1459 		char comm[16];
1460 
1461 		if (bpf_get_current_comm(comm, 16))
1462 			return false;
1463 		return nest_2(comm);
1464 	}
1465 	case 1:
1466 		return nest_2((char *)&global);
1467 	default:
1468 		return false;
1469 	}
1470 }
1471 
1472 SEC("raw_tp")
1473 __success
1474 int iter_subprog_check_stacksafe(const void *ctx)
1475 {
1476 	long i;
1477 
1478 	bpf_for(i, 0, upper) {
1479 		if (!nest_1(select_n)) {
1480 			result = 1;
1481 			return 0;
1482 		}
1483 	}
1484 
1485 	result = 2;
1486 	return 0;
1487 }
1488 
1489 char _license[] SEC("license") = "GPL";
1490