1 // SPDX-License-Identifier: GPL-2.0 2 3 #include <linux/bpf.h> 4 #include <bpf/bpf_helpers.h> 5 #include "bpf_misc.h" 6 7 /* Check that precision marks propagate through scalar IDs. 8 * Registers r{0,1,2} have the same scalar ID. 9 * Range information is propagated for scalars sharing same ID. 10 * Check that precision mark for r0 causes precision marks for r{1,2} 11 * when range information is propagated for 'if <reg> <op> <const>' insn. 12 */ 13 SEC("socket") 14 __success __log_level(2) 15 /* first 'if' branch */ 16 __msg("6: (0f) r3 += r0") 17 __msg("frame0: regs=r0 stack= before 4: (25) if r1 > 0x7 goto pc+0") 18 __msg("frame0: parent state regs=r0,r1,r2 stack=:") 19 __msg("frame0: regs=r0,r1,r2 stack= before 3: (bf) r2 = r0") 20 /* second 'if' branch */ 21 __msg("from 4 to 5: ") 22 __msg("6: (0f) r3 += r0") 23 __msg("frame0: regs=r0 stack= before 5: (bf) r3 = r10") 24 __msg("frame0: regs=r0 stack= before 4: (25) if r1 > 0x7 goto pc+0") 25 /* parent state already has r{0,1,2} as precise */ 26 __msg("frame0: parent state regs= stack=:") 27 __flag(BPF_F_TEST_STATE_FREQ) 28 __naked void linked_regs_bpf_k(void) 29 { 30 asm volatile ( 31 /* r0 = random number up to 0xff */ 32 "call %[bpf_ktime_get_ns];" 33 "r0 &= 0xff;" 34 /* tie r0.id == r1.id == r2.id */ 35 "r1 = r0;" 36 "r2 = r0;" 37 "if r1 > 7 goto +0;" 38 /* force r0 to be precise, this eventually marks r1 and r2 as 39 * precise as well because of shared IDs 40 */ 41 "r3 = r10;" 42 "r3 += r0;" 43 /* Mark r1 and r2 as alive. */ 44 "r1 = r1;" 45 "r2 = r2;" 46 "r0 = 0;" 47 "exit;" 48 : 49 : __imm(bpf_ktime_get_ns) 50 : __clobber_all); 51 } 52 53 /* Registers r{0,1,2} share same ID when 'if r1 > ...' insn is processed, 54 * check that verifier marks r{1,2} as precise while backtracking 55 * 'if r1 > ...' with r0 already marked. 56 */ 57 SEC("socket") 58 __success __log_level(2) 59 __flag(BPF_F_TEST_STATE_FREQ) 60 __msg("frame0: regs=r0 stack= before 5: (2d) if r1 > r3 goto pc+0") 61 __msg("frame0: parent state regs=r0,r1,r2,r3 stack=:") 62 __msg("frame0: regs=r0,r1,r2,r3 stack= before 4: (b7) r3 = 7") 63 __naked void linked_regs_bpf_x_src(void) 64 { 65 asm volatile ( 66 /* r0 = random number up to 0xff */ 67 "call %[bpf_ktime_get_ns];" 68 "r0 &= 0xff;" 69 /* tie r0.id == r1.id == r2.id */ 70 "r1 = r0;" 71 "r2 = r0;" 72 "r3 = 7;" 73 "if r1 > r3 goto +0;" 74 /* force r0 to be precise, this eventually marks r1 and r2 as 75 * precise as well because of shared IDs 76 */ 77 "r4 = r10;" 78 "r4 += r0;" 79 /* Mark r1 and r2 as alive. */ 80 "r1 = r1;" 81 "r2 = r2;" 82 "r0 = 0;" 83 "exit;" 84 : 85 : __imm(bpf_ktime_get_ns) 86 : __clobber_all); 87 } 88 89 /* Registers r{0,1,2} share same ID when 'if r1 > r3' insn is processed, 90 * check that verifier marks r{0,1,2} as precise while backtracking 91 * 'if r1 > r3' with r3 already marked. 92 */ 93 SEC("socket") 94 __success __log_level(2) 95 __flag(BPF_F_TEST_STATE_FREQ) 96 __msg("frame0: regs=r3 stack= before 5: (2d) if r1 > r3 goto pc+0") 97 __msg("frame0: parent state regs=r0,r1,r2,r3 stack=:") 98 __msg("frame0: regs=r0,r1,r2,r3 stack= before 4: (b7) r3 = 7") 99 __naked void linked_regs_bpf_x_dst(void) 100 { 101 asm volatile ( 102 /* r0 = random number up to 0xff */ 103 "call %[bpf_ktime_get_ns];" 104 "r0 &= 0xff;" 105 /* tie r0.id == r1.id == r2.id */ 106 "r1 = r0;" 107 "r2 = r0;" 108 "r3 = 7;" 109 "if r1 > r3 goto +0;" 110 /* force r0 to be precise, this eventually marks r1 and r2 as 111 * precise as well because of shared IDs 112 */ 113 "r4 = r10;" 114 "r4 += r3;" 115 /* Mark r1 and r2 as alive. */ 116 "r0 = r0;" 117 "r1 = r1;" 118 "r2 = r2;" 119 "r0 = 0;" 120 "exit;" 121 : 122 : __imm(bpf_ktime_get_ns) 123 : __clobber_all); 124 } 125 126 /* Same as linked_regs_bpf_k, but break one of the 127 * links, note that r1 is absent from regs=... in __msg below. 128 */ 129 SEC("socket") 130 __success __log_level(2) 131 __msg("7: (0f) r3 += r0") 132 __msg("frame0: regs=r0 stack= before 6: (bf) r3 = r10") 133 __msg("frame0: parent state regs=r0 stack=:") 134 __msg("frame0: regs=r0 stack= before 5: (25) if r0 > 0x7 goto pc+0") 135 __msg("frame0: parent state regs=r0,r2 stack=:") 136 __flag(BPF_F_TEST_STATE_FREQ) 137 __naked void linked_regs_broken_link(void) 138 { 139 asm volatile ( 140 /* r0 = random number up to 0xff */ 141 "call %[bpf_ktime_get_ns];" 142 "r0 &= 0xff;" 143 /* tie r0.id == r1.id == r2.id */ 144 "r1 = r0;" 145 "r2 = r0;" 146 /* break link for r1, this is the only line that differs 147 * compared to the previous test 148 */ 149 "r1 = 0;" 150 "if r0 > 7 goto +0;" 151 /* force r0 to be precise, 152 * this eventually marks r2 as precise because of shared IDs 153 */ 154 "r3 = r10;" 155 "r3 += r0;" 156 /* Mark r1 and r2 as alive. */ 157 "r1 = r1;" 158 "r2 = r2;" 159 "r0 = 0;" 160 "exit;" 161 : 162 : __imm(bpf_ktime_get_ns) 163 : __clobber_all); 164 } 165 166 /* Check that precision marks propagate through scalar IDs. 167 * Use the same scalar ID in multiple stack frames, check that 168 * precision information is propagated up the call stack. 169 */ 170 SEC("socket") 171 __success __log_level(2) 172 __msg("17: (0f) r2 += r1") 173 /* Current state */ 174 __msg("frame2: last_idx 17 first_idx 14 subseq_idx -1 ") 175 __msg("frame2: regs=r1 stack= before 16: (bf) r2 = r10") 176 __msg("frame2: parent state regs=r1 stack=") 177 __msg("frame1: parent state regs= stack=") 178 __msg("frame0: parent state regs= stack=") 179 /* Parent state */ 180 __msg("frame2: last_idx 13 first_idx 13 subseq_idx 14 ") 181 __msg("frame2: regs=r1 stack= before 13: (25) if r1 > 0x7 goto pc+0") 182 __msg("frame2: parent state regs=r1 stack=") 183 /* frame1.r{6,7} are marked because mark_precise_scalar_ids() 184 * looks for all registers with frame2.r1.id in the current state 185 */ 186 __msg("frame1: parent state regs=r6,r7 stack=") 187 __msg("frame0: parent state regs=r6 stack=") 188 /* Parent state */ 189 __msg("frame2: last_idx 9 first_idx 9 subseq_idx 13") 190 __msg("frame2: regs=r1 stack= before 9: (85) call pc+3") 191 /* frame1.r1 is marked because of backtracking of call instruction */ 192 __msg("frame1: parent state regs=r1,r6,r7 stack=") 193 __msg("frame0: parent state regs=r6 stack=") 194 /* Parent state */ 195 __msg("frame1: last_idx 8 first_idx 7 subseq_idx 9") 196 __msg("frame1: regs=r1,r6,r7 stack= before 8: (bf) r7 = r1") 197 __msg("frame1: regs=r1,r6 stack= before 7: (bf) r6 = r1") 198 __msg("frame1: parent state regs=r1 stack=") 199 __msg("frame0: parent state regs=r6 stack=") 200 /* Parent state */ 201 __msg("frame1: last_idx 4 first_idx 4 subseq_idx 7") 202 __msg("frame1: regs=r1 stack= before 4: (85) call pc+2") 203 __msg("frame0: parent state regs=r1,r6 stack=") 204 /* Parent state */ 205 __msg("frame0: last_idx 3 first_idx 1 subseq_idx 4") 206 __msg("frame0: regs=r1,r6 stack= before 3: (bf) r6 = r0") 207 __msg("frame0: regs=r0,r1 stack= before 2: (bf) r1 = r0") 208 __msg("frame0: regs=r0 stack= before 1: (57) r0 &= 255") 209 __flag(BPF_F_TEST_STATE_FREQ) 210 __naked void precision_many_frames(void) 211 { 212 asm volatile ( 213 /* r0 = random number up to 0xff */ 214 "call %[bpf_ktime_get_ns];" 215 "r0 &= 0xff;" 216 /* tie r0.id == r1.id == r6.id */ 217 "r1 = r0;" 218 "r6 = r0;" 219 "call precision_many_frames__foo;" 220 "r6 = r6;" /* mark r6 as live */ 221 "exit;" 222 : 223 : __imm(bpf_ktime_get_ns) 224 : __clobber_all); 225 } 226 227 static __naked __noinline __used 228 void precision_many_frames__foo(void) 229 { 230 asm volatile ( 231 /* conflate one of the register numbers (r6) with outer frame, 232 * to verify that those are tracked independently 233 */ 234 "r6 = r1;" 235 "r7 = r1;" 236 "call precision_many_frames__bar;" 237 "r6 = r6;" /* mark r6 as live */ 238 "r7 = r7;" /* mark r7 as live */ 239 "exit" 240 ::: __clobber_all); 241 } 242 243 static __naked __noinline __used 244 void precision_many_frames__bar(void) 245 { 246 asm volatile ( 247 "if r1 > 7 goto +0;" 248 "r6 = 0;" /* mark r6 as live */ 249 "r7 = 0;" /* mark r7 as live */ 250 /* force r1 to be precise, this eventually marks: 251 * - bar frame r1 252 * - foo frame r{1,6,7} 253 * - main frame r{1,6} 254 */ 255 "r2 = r10;" 256 "r2 += r1;" 257 "r0 = 0;" 258 "exit;" 259 ::: __clobber_all); 260 } 261 262 /* Check that scalars with the same IDs are marked precise on stack as 263 * well as in registers. 264 */ 265 SEC("socket") 266 __success __log_level(2) 267 __msg("11: (0f) r2 += r1") 268 /* foo frame */ 269 __msg("frame1: regs=r1 stack= before 10: (bf) r2 = r10") 270 __msg("frame1: regs=r1 stack= before 9: (25) if r1 > 0x7 goto pc+0") 271 __msg("frame1: regs=r1 stack=-8,-16 before 8: (7b) *(u64 *)(r10 -16) = r1") 272 __msg("frame1: regs=r1 stack=-8 before 7: (7b) *(u64 *)(r10 -8) = r1") 273 __msg("frame1: regs=r1 stack= before 4: (85) call pc+2") 274 /* main frame */ 275 __msg("frame0: regs=r1 stack=-8 before 3: (7b) *(u64 *)(r10 -8) = r1") 276 __msg("frame0: regs=r1 stack= before 2: (bf) r1 = r0") 277 __msg("frame0: regs=r0 stack= before 1: (57) r0 &= 255") 278 __flag(BPF_F_TEST_STATE_FREQ) 279 __naked void precision_stack(void) 280 { 281 asm volatile ( 282 /* r0 = random number up to 0xff */ 283 "call %[bpf_ktime_get_ns];" 284 "r0 &= 0xff;" 285 /* tie r0.id == r1.id == fp[-8].id */ 286 "r1 = r0;" 287 "*(u64*)(r10 - 8) = r1;" 288 "call precision_stack__foo;" 289 "r0 = 0;" 290 "exit;" 291 : 292 : __imm(bpf_ktime_get_ns) 293 : __clobber_all); 294 } 295 296 static __naked __noinline __used 297 void precision_stack__foo(void) 298 { 299 asm volatile ( 300 /* conflate one of the register numbers (r6) with outer frame, 301 * to verify that those are tracked independently 302 */ 303 "*(u64*)(r10 - 8) = r1;" 304 "*(u64*)(r10 - 16) = r1;" 305 "if r1 > 7 goto +0;" 306 /* force r1 to be precise, this eventually marks: 307 * - foo frame r1,fp{-8,-16} 308 * - main frame r1,fp{-8} 309 */ 310 "r2 = r10;" 311 "r2 += r1;" 312 "exit" 313 ::: __clobber_all); 314 } 315 316 /* Use two separate scalar IDs to check that these are propagated 317 * independently. 318 */ 319 SEC("socket") 320 __success __log_level(2) 321 /* r{6,7} */ 322 __msg("12: (0f) r3 += r7") 323 __msg("frame0: regs=r7 stack= before 11: (bf) r3 = r10") 324 __msg("frame0: regs=r7 stack= before 9: (25) if r7 > 0x7 goto pc+0") 325 /* ... skip some insns ... */ 326 __msg("frame0: regs=r6,r7 stack= before 3: (bf) r7 = r0") 327 __msg("frame0: regs=r0,r6 stack= before 2: (bf) r6 = r0") 328 /* r{8,9} */ 329 __msg("13: (0f) r3 += r9") 330 __msg("frame0: regs=r9 stack= before 12: (0f) r3 += r7") 331 /* ... skip some insns ... */ 332 __msg("frame0: regs=r9 stack= before 10: (25) if r9 > 0x7 goto pc+0") 333 __msg("frame0: regs=r8,r9 stack= before 7: (bf) r9 = r0") 334 __msg("frame0: regs=r0,r8 stack= before 6: (bf) r8 = r0") 335 __flag(BPF_F_TEST_STATE_FREQ) 336 __naked void precision_two_ids(void) 337 { 338 asm volatile ( 339 /* r6 = random number up to 0xff 340 * r6.id == r7.id 341 */ 342 "call %[bpf_ktime_get_ns];" 343 "r0 &= 0xff;" 344 "r6 = r0;" 345 "r7 = r0;" 346 /* same, but for r{8,9} */ 347 "call %[bpf_ktime_get_ns];" 348 "r0 &= 0xff;" 349 "r8 = r0;" 350 "r9 = r0;" 351 /* clear r0 id */ 352 "r0 = 0;" 353 /* propagate equal scalars precision */ 354 "if r7 > 7 goto +0;" 355 "if r9 > 7 goto +0;" 356 "r3 = r10;" 357 /* force r7 to be precise, this also marks r6 */ 358 "r3 += r7;" 359 /* force r9 to be precise, this also marks r8 */ 360 "r3 += r9;" 361 "r6 = r6;" /* mark r6 as live */ 362 "r8 = r8;" /* mark r8 as live */ 363 "exit;" 364 : 365 : __imm(bpf_ktime_get_ns) 366 : __clobber_all); 367 } 368 369 SEC("socket") 370 __success __log_level(2) 371 __flag(BPF_F_TEST_STATE_FREQ) 372 /* check that r0 and r6 have different IDs after 'if', 373 * collect_linked_regs() can't tie more than 6 registers for a single insn. 374 */ 375 __msg("8: (25) if r0 > 0x7 goto pc+0 ; R0=scalar(id=1") 376 __msg("14: (bf) r6 = r6 ; R6=scalar(id=2") 377 /* check that r{0-5} are marked precise after 'if' */ 378 __msg("frame0: regs=r0 stack= before 8: (25) if r0 > 0x7 goto pc+0") 379 __msg("frame0: parent state regs=r0,r1,r2,r3,r4,r5 stack=:") 380 __naked void linked_regs_too_many_regs(void) 381 { 382 asm volatile ( 383 /* r0 = random number up to 0xff */ 384 "call %[bpf_ktime_get_ns];" 385 "r0 &= 0xff;" 386 /* tie r{0-6} IDs */ 387 "r1 = r0;" 388 "r2 = r0;" 389 "r3 = r0;" 390 "r4 = r0;" 391 "r5 = r0;" 392 "r6 = r0;" 393 /* propagate range for r{0-6} */ 394 "if r0 > 7 goto +0;" 395 /* keep r{1-5} live */ 396 "r1 = r1;" 397 "r2 = r2;" 398 "r3 = r3;" 399 "r4 = r4;" 400 "r5 = r5;" 401 /* make r6 appear in the log */ 402 "r6 = r6;" 403 /* force r0 to be precise, 404 * this would cause r{0-4} to be precise because of shared IDs 405 */ 406 "r7 = r10;" 407 "r7 += r0;" 408 "r0 = 0;" 409 "exit;" 410 : 411 : __imm(bpf_ktime_get_ns) 412 : __clobber_all); 413 } 414 415 SEC("socket") 416 __failure __log_level(2) 417 __flag(BPF_F_TEST_STATE_FREQ) 418 __msg("regs=r7 stack= before 5: (3d) if r8 >= r0") 419 __msg("parent state regs=r0,r7,r8") 420 __msg("regs=r0,r7,r8 stack= before 4: (25) if r0 > 0x1") 421 __msg("div by zero") 422 __naked void linked_regs_broken_link_2(void) 423 { 424 asm volatile ( 425 "call %[bpf_get_prandom_u32];" 426 "r7 = r0;" 427 "r8 = r0;" 428 "call %[bpf_get_prandom_u32];" 429 "if r0 > 1 goto +0;" 430 /* r7.id == r8.id, 431 * thus r7 precision implies r8 precision, 432 * which implies r0 precision because of the conditional below. 433 */ 434 "if r8 >= r0 goto 1f;" 435 /* break id relation between r7 and r8 */ 436 "r8 += r8;" 437 /* make r7 precise */ 438 "if r7 == 0 goto 1f;" 439 "r0 /= 0;" 440 "1:" 441 "r0 = 42;" 442 "exit;" 443 : 444 : __imm(bpf_get_prandom_u32) 445 : __clobber_all); 446 } 447 448 /* Check that mark_chain_precision() for one of the conditional jump 449 * operands does not trigger equal scalars precision propagation. 450 */ 451 SEC("socket") 452 __success __log_level(2) 453 __msg("3: (25) if r1 > 0x100 goto pc+0") 454 __msg("frame0: regs=r1 stack= before 2: (bf) r1 = r0") 455 __naked void cjmp_no_linked_regs_trigger(void) 456 { 457 asm volatile ( 458 /* r0 = random number up to 0xff */ 459 "call %[bpf_ktime_get_ns];" 460 "r0 &= 0xff;" 461 /* tie r0.id == r1.id */ 462 "r1 = r0;" 463 /* the jump below would be predicted, thus r1 would be marked precise, 464 * this should not imply precision mark for r0 465 */ 466 "if r1 > 256 goto +0;" 467 "r0 = 0;" 468 "exit;" 469 : 470 : __imm(bpf_ktime_get_ns) 471 : __clobber_all); 472 } 473 474 /* Verify that check_ids() is used by regsafe() for scalars. 475 * 476 * r9 = ... some pointer with range X ... 477 * r6 = ... unbound scalar ID=a ... 478 * r7 = ... unbound scalar ID=b ... 479 * if (r6 > r7) goto +1 480 * r7 = r6 481 * if (r7 > X) goto exit 482 * r9 += r6 483 * ... access memory using r9 ... 484 * 485 * The memory access is safe only if r7 is bounded, 486 * which is true for one branch and not true for another. 487 */ 488 SEC("socket") 489 __failure __msg("register with unbounded min value") 490 __flag(BPF_F_TEST_STATE_FREQ) 491 __naked void check_ids_in_regsafe(void) 492 { 493 asm volatile ( 494 /* Bump allocated stack */ 495 "r1 = 0;" 496 "*(u64*)(r10 - 8) = r1;" 497 /* r9 = pointer to stack */ 498 "r9 = r10;" 499 "r9 += -8;" 500 /* r7 = ktime_get_ns() */ 501 "call %[bpf_ktime_get_ns];" 502 "r7 = r0;" 503 /* r6 = ktime_get_ns() */ 504 "call %[bpf_ktime_get_ns];" 505 "r6 = r0;" 506 /* if r6 > r7 is an unpredictable jump */ 507 "if r6 > r7 goto l1_%=;" 508 "r7 = r6;" 509 "l1_%=:" 510 /* if r7 > 4 ...; transfers range to r6 on one execution path 511 * but does not transfer on another 512 */ 513 "if r7 > 4 goto l2_%=;" 514 /* Access memory at r9[r6], r6 is not always bounded */ 515 "r9 += r6;" 516 "r0 = *(u8*)(r9 + 0);" 517 "l2_%=:" 518 "r0 = 0;" 519 "exit;" 520 : 521 : __imm(bpf_ktime_get_ns) 522 : __clobber_all); 523 } 524 525 /* Similar to check_ids_in_regsafe. 526 * The l0 could be reached in two states: 527 * 528 * (1) r6{.id=A}, r7{.id=A}, r8{.id=B} 529 * (2) r6{.id=B}, r7{.id=A}, r8{.id=B} 530 * 531 * Where (2) is not safe, as "r7 > 4" check won't propagate range for it. 532 * This example would be considered safe without changes to 533 * mark_chain_precision() to track scalar values with equal IDs. 534 */ 535 SEC("socket") 536 __failure __msg("register with unbounded min value") 537 __flag(BPF_F_TEST_STATE_FREQ) 538 __naked void check_ids_in_regsafe_2(void) 539 { 540 asm volatile ( 541 /* Bump allocated stack */ 542 "r1 = 0;" 543 "*(u64*)(r10 - 8) = r1;" 544 /* r9 = pointer to stack */ 545 "r9 = r10;" 546 "r9 += -16;" 547 /* r8 = ktime_get_ns() */ 548 "call %[bpf_ktime_get_ns];" 549 "r8 = r0;" 550 /* r7 = ktime_get_ns() */ 551 "call %[bpf_ktime_get_ns];" 552 "r7 = r0;" 553 /* r6 = ktime_get_ns() */ 554 "call %[bpf_ktime_get_ns];" 555 "r6 = r0;" 556 /* scratch .id from r0 */ 557 "r0 = 0;" 558 /* if r6 > r7 is an unpredictable jump */ 559 "if r6 > r7 goto l1_%=;" 560 /* tie r6 and r7 .id */ 561 "r6 = r7;" 562 "l0_%=:" 563 /* if r7 > 4 exit(0) */ 564 "if r7 > 4 goto l2_%=;" 565 /* Access memory at r9[r6] */ 566 "r9 += r6;" 567 "r9 += r7;" 568 "r9 += r8;" 569 "r0 = *(u8*)(r9 + 0);" 570 "l2_%=:" 571 "r0 = 0;" 572 "exit;" 573 "l1_%=:" 574 /* tie r6 and r8 .id */ 575 "r6 = r8;" 576 "goto l0_%=;" 577 : 578 : __imm(bpf_ktime_get_ns) 579 : __clobber_all); 580 } 581 582 /* Check that scalar IDs *are not* generated on register to register 583 * assignments if source register is a constant. 584 * 585 * If such IDs *are* generated the 'l1' below would be reached in 586 * two states: 587 * 588 * (1) r1{.id=A}, r2{.id=A} 589 * (2) r1{.id=C}, r2{.id=C} 590 * 591 * Thus forcing 'if r1 == r2' verification twice. 592 */ 593 SEC("socket") 594 __success __log_level(2) 595 __msg("11: (1d) if r3 == r4 goto pc+0") 596 __msg("frame 0: propagating r3,r4") 597 __msg("11: safe") 598 __msg("processed 15 insns") 599 __flag(BPF_F_TEST_STATE_FREQ) 600 __naked void no_scalar_id_for_const(void) 601 { 602 asm volatile ( 603 "call %[bpf_ktime_get_ns];" 604 /* unpredictable jump */ 605 "if r0 > 7 goto l0_%=;" 606 /* possibly generate same scalar ids for r3 and r4 */ 607 "r1 = 0;" 608 "r1 = r1;" 609 "r3 = r1;" 610 "r4 = r1;" 611 "goto l1_%=;" 612 "l0_%=:" 613 /* possibly generate different scalar ids for r3 and r4 */ 614 "r1 = 0;" 615 "r2 = 0;" 616 "r3 = r1;" 617 "r4 = r2;" 618 "l1_%=:" 619 /* predictable jump, marks r3 and r4 precise */ 620 "if r3 == r4 goto +0;" 621 "r0 = 0;" 622 "exit;" 623 : 624 : __imm(bpf_ktime_get_ns) 625 : __clobber_all); 626 } 627 628 /* Same as no_scalar_id_for_const() but for 32-bit values */ 629 SEC("socket") 630 __success __log_level(2) 631 __msg("11: (1e) if w3 == w4 goto pc+0") 632 __msg("frame 0: propagating r3,r4") 633 __msg("11: safe") 634 __msg("processed 15 insns") 635 __flag(BPF_F_TEST_STATE_FREQ) 636 __naked void no_scalar_id_for_const32(void) 637 { 638 asm volatile ( 639 "call %[bpf_ktime_get_ns];" 640 /* unpredictable jump */ 641 "if r0 > 7 goto l0_%=;" 642 /* possibly generate same scalar ids for r3 and r4 */ 643 "w1 = 0;" 644 "w1 = w1;" 645 "w3 = w1;" 646 "w4 = w1;" 647 "goto l1_%=;" 648 "l0_%=:" 649 /* possibly generate different scalar ids for r3 and r4 */ 650 "w1 = 0;" 651 "w2 = 0;" 652 "w3 = w1;" 653 "w4 = w2;" 654 "l1_%=:" 655 /* predictable jump, marks r1 and r2 precise */ 656 "if w3 == w4 goto +0;" 657 "r0 = 0;" 658 "exit;" 659 : 660 : __imm(bpf_ktime_get_ns) 661 : __clobber_all); 662 } 663 664 /* Check that unique scalar IDs are ignored when new verifier state is 665 * compared to cached verifier state. For this test: 666 * - cached state has no id on r1 667 * - new state has a unique id on r1 668 */ 669 SEC("socket") 670 __success __log_level(2) 671 __msg("6: (25) if r6 > 0x7 goto pc+1") 672 __msg("7: (57) r1 &= 255") 673 __msg("8: (bf) r2 = r10") 674 __msg("from 6 to 8: safe") 675 __msg("processed 12 insns") 676 __flag(BPF_F_TEST_STATE_FREQ) 677 __naked void ignore_unique_scalar_ids_cur(void) 678 { 679 asm volatile ( 680 "call %[bpf_ktime_get_ns];" 681 "r6 = r0;" 682 "call %[bpf_ktime_get_ns];" 683 "r0 &= 0xff;" 684 /* r1.id == r0.id */ 685 "r1 = r0;" 686 /* make r1.id unique */ 687 "r0 = 0;" 688 "if r6 > 7 goto l0_%=;" 689 /* clear r1 id, but keep the range compatible */ 690 "r1 &= 0xff;" 691 "l0_%=:" 692 /* get here in two states: 693 * - first: r1 has no id (cached state) 694 * - second: r1 has a unique id (should be considered equivalent) 695 */ 696 "r2 = r10;" 697 "r2 += r1;" 698 "exit;" 699 : 700 : __imm(bpf_ktime_get_ns) 701 : __clobber_all); 702 } 703 704 /* Check that unique scalar IDs are ignored when new verifier state is 705 * compared to cached verifier state. For this test: 706 * - cached state has a unique id on r1 707 * - new state has no id on r1 708 */ 709 SEC("socket") 710 __success __log_level(2) 711 __msg("6: (25) if r6 > 0x7 goto pc+1") 712 __msg("7: (05) goto pc+1") 713 __msg("9: (bf) r2 = r10") 714 __msg("9: safe") 715 __msg("processed 13 insns") 716 __flag(BPF_F_TEST_STATE_FREQ) 717 __naked void ignore_unique_scalar_ids_old(void) 718 { 719 asm volatile ( 720 "call %[bpf_ktime_get_ns];" 721 "r6 = r0;" 722 "call %[bpf_ktime_get_ns];" 723 "r0 &= 0xff;" 724 /* r1.id == r0.id */ 725 "r1 = r0;" 726 /* make r1.id unique */ 727 "r0 = 0;" 728 "if r6 > 7 goto l1_%=;" 729 "goto l0_%=;" 730 "l1_%=:" 731 /* clear r1 id, but keep the range compatible */ 732 "r1 &= 0xff;" 733 "l0_%=:" 734 /* get here in two states: 735 * - first: r1 has a unique id (cached state) 736 * - second: r1 has no id (should be considered equivalent) 737 */ 738 "r2 = r10;" 739 "r2 += r1;" 740 "exit;" 741 : 742 : __imm(bpf_ktime_get_ns) 743 : __clobber_all); 744 } 745 746 /* Check that two registers with 0 scalar IDs in a verified state can be mapped 747 * to the same scalar ID in current state. 748 */ 749 SEC("socket") 750 __success __log_level(2) 751 /* The states should be equivalent on reaching insn 12. 752 */ 753 __msg("12: safe") 754 __msg("processed 17 insns") 755 __flag(BPF_F_TEST_STATE_FREQ) 756 __naked void two_nil_old_ids_one_cur_id(void) 757 { 758 asm volatile ( 759 /* Give unique scalar IDs to r{6,7} */ 760 "call %[bpf_ktime_get_ns];" 761 "r0 &= 0xff;" 762 "r6 = r0;" 763 "r6 *= 1;" 764 "call %[bpf_ktime_get_ns];" 765 "r0 &= 0xff;" 766 "r7 = r0;" 767 "r7 *= 1;" 768 "r0 = 0;" 769 /* Maybe make r{6,7} IDs identical */ 770 "if r6 > r7 goto l0_%=;" 771 "goto l1_%=;" 772 "l0_%=:" 773 "r6 = r7;" 774 "l1_%=:" 775 /* Mark r{6,7} precise. 776 * Get here in two states: 777 * - first: r6{.id=0}, r7{.id=0} (cached state) 778 * - second: r6{.id=A}, r7{.id=A} 779 * Verifier considers such states equivalent. 780 * Thus "exit;" would be verified only once. 781 */ 782 "r2 = r10;" 783 "r2 += r6;" 784 "r2 += r7;" 785 "exit;" 786 : 787 : __imm(bpf_ktime_get_ns) 788 : __clobber_all); 789 } 790 791 /* Check that two different scalar IDs in a verified state can't be 792 * mapped to the same scalar ID in current state. 793 */ 794 SEC("socket") 795 __success __log_level(2) 796 /* The exit instruction should be reachable from two states, 797 * use two matches and "processed .. insns" to ensure this. 798 */ 799 __msg("15: (95) exit") 800 __msg("15: (95) exit") 801 __msg("processed 20 insns") 802 __flag(BPF_F_TEST_STATE_FREQ) 803 __naked void two_old_ids_one_cur_id(void) 804 { 805 asm volatile ( 806 /* Give unique scalar IDs to r{6,7} */ 807 "call %[bpf_ktime_get_ns];" 808 "r0 &= 0xff;" 809 "r6 = r0;" 810 "r8 = r0;" 811 "call %[bpf_ktime_get_ns];" 812 "r0 &= 0xff;" 813 "r7 = r0;" 814 "r9 = r0;" 815 "r0 = 0;" 816 /* Maybe make r{6,7} IDs identical */ 817 "if r6 > r7 goto l0_%=;" 818 "goto l1_%=;" 819 "l0_%=:" 820 "r6 = r7;" 821 "l1_%=:" 822 /* Mark r{6,7} precise. 823 * Get here in two states: 824 * - first: r6{.id=A}, r7{.id=B} (cached state) 825 * - second: r6{.id=A}, r7{.id=A} 826 * Currently we don't want to consider such states equivalent. 827 * Thus "exit;" would be verified twice. 828 */ 829 "r2 = r10;" 830 "r2 += r6;" 831 "r2 += r7;" 832 "exit;" 833 : 834 : __imm(bpf_ktime_get_ns) 835 : __clobber_all); 836 } 837 838 SEC("socket") 839 /* Note the flag, see verifier.c:opt_subreg_zext_lo32_rnd_hi32() */ 840 __flag(BPF_F_TEST_RND_HI32) 841 __success 842 /* This test was added because of a bug in verifier.c:sync_linked_regs(), 843 * upon range propagation it destroyed subreg_def marks for registers. 844 * The subreg_def mark is used to decide whether zero extension instructions 845 * are needed when register is read. When BPF_F_TEST_RND_HI32 is set it 846 * also causes generation of statements to randomize upper halves of 847 * read registers. 848 * 849 * The test is written in a way to return an upper half of a register 850 * that is affected by range propagation and must have it's subreg_def 851 * preserved. This gives a return value of 0 and leads to undefined 852 * return value if subreg_def mark is not preserved. 853 */ 854 __retval(0) 855 /* Check that verifier believes r1/r0 are zero at exit */ 856 __log_level(2) 857 __msg("4: (77) r1 >>= 32 ; R1=0") 858 __msg("5: (bf) r0 = r1 ; R0=0 R1=0") 859 __msg("6: (95) exit") 860 __msg("from 3 to 4") 861 __msg("4: (77) r1 >>= 32 ; R1=0") 862 __msg("5: (bf) r0 = r1 ; R0=0 R1=0") 863 __msg("6: (95) exit") 864 /* Verify that statements to randomize upper half of r1 had not been 865 * generated. 866 */ 867 __xlated("call unknown") 868 __xlated("r0 &= 2147483647") 869 __xlated("w1 = w0") 870 /* This is how disasm.c prints BPF_ZEXT_REG at the moment, x86 and arm 871 * are the only CI archs that do not need zero extension for subregs. 872 */ 873 #if !defined(__TARGET_ARCH_x86) && !defined(__TARGET_ARCH_arm64) 874 __xlated("w1 = w1") 875 #endif 876 __xlated("if w0 < 0xa goto pc+0") 877 __xlated("r1 >>= 32") 878 __xlated("r0 = r1") 879 __xlated("exit") 880 __naked void linked_regs_and_subreg_def(void) 881 { 882 asm volatile ( 883 "call %[bpf_ktime_get_ns];" 884 /* make sure r0 is in 32-bit range, otherwise w1 = w0 won't 885 * assign same IDs to registers. 886 */ 887 "r0 &= 0x7fffffff;" 888 /* link w1 and w0 via ID */ 889 "w1 = w0;" 890 /* 'if' statement propagates range info from w0 to w1, 891 * but should not affect w1->subreg_def property. 892 */ 893 "if w0 < 10 goto +0;" 894 /* r1 is read here, on archs that require subreg zero 895 * extension this would cause zext patch generation. 896 */ 897 "r1 >>= 32;" 898 "r0 = r1;" 899 "exit;" 900 : 901 : __imm(bpf_ktime_get_ns) 902 : __clobber_all); 903 } 904 905 char _license[] SEC("license") = "GPL"; 906