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AddressSanitizerAlgorithm
The run-time library replaces the malloc
and free
functions.
The memory around malloc-ed regions (red zones) is poisoned.
The free
-ed memory is placed in quarantine and also poisoned.
Every memory access in the program is transformed by the compiler in the following way:
Before:
*address = ...; // or: ... = *address;
After:
if (IsPoisoned(address)) {
ReportError(address, kAccessSize, kIsWrite);
}
*address = ...; // or: ... = *address;
The tricky part is how to implement IsPoisoned
very fast and ReportError
very compact.
Also, instrumenting some of the accesses may be proven redundant.
The virtual address space is divided into 2 disjoint classes:
- Main application memory (
Mem
): this memory is used by the regular application code. - Shadow memory (
Shadow
): this memory contains the shadow values (or metadata). There is a correspondence between the shadow and the main application memory. Poisoning a byte in the main memory means writing some special value into the corresponding shadow memory.
These 2 classes of memory should be organized in such a way that computing the shadow memory
(MemToShadow
) is fast.
The instrumentation performed by the compiler:
shadow_address = MemToShadow(address);
if (ShadowIsPoisoned(shadow_address)) {
ReportError(address, kAccessSize, kIsWrite);
}
AddressSanitizer maps 8 bytes of the application memory into 1 byte of the shadow memory.
There are only 9 different values for any aligned 8 bytes of the application memory:
- All 8 bytes in qword are unpoisoned (i.e. addressible). The shadow value is 0.
- All 8 bytes in qword are poisoned (i.e. not addressible). The shadow value is negative.
- First
k
bytes are unpoisoned, the rest8-k
are poisoned. The shadow value isk
. This is guaranteed by the fact thatmalloc
returns 8-byte aligned chunks of memory. The only case where different bytes of an aligned qword have different state is the tail of a malloc-ed region. For example, if we callmalloc(13)
, we will have one full unpoisoned qword and one qword where 5 first bytes are unpoisoned.
The instrumentation looks like this:
byte *shadow_address = MemToShadow(address);
byte shadow_value = *shadow_address;
if (shadow_value) {
if (SlowPathCheck(shadow_value, address, kAccessSize)) {
ReportError(address, kAccessSize, kIsWrite);
}
}
// Check the cases where we access first k bytes of the qword
// and these k bytes are unpoisoned.
bool SlowPathCheck(shadow_value, address, kAccessSize) {
last_accessed_byte = (address & 7) + kAccessSize - 1;
return (last_accessed_byte >= shadow_value);
}
MemToShadow(ShadowAddr)
falls into the ShadowGap
region
which is unaddressible. So, if the program tries to directly access a memory location
in the shadow region, it will crash.
Shadow = (Mem >> 3) + 0x7fff8000;
[0x10007fff8000, 0x7fffffffffff] |
HighMem |
---|---|
[0x02008fff7000, 0x10007fff7fff] |
HighShadow |
[0x00008fff7000, 0x02008fff6fff] |
ShadowGap |
[0x00007fff8000, 0x00008fff6fff] |
LowShadow |
[0x000000000000, 0x00007fff7fff] |
LowMem |
Shadow = (Mem >> 3) + 0x20000000;
[0x40000000, 0xffffffff] |
HighMem |
---|---|
[0x28000000, 0x3fffffff] |
HighShadow |
[0x24000000, 0x27ffffff] |
ShadowGap |
[0x20000000, 0x23ffffff] |
LowShadow |
[0x00000000, 0x1fffffff] |
LowMem |
It is possible to use even more compact shadow memory, e.g.
Shadow = (Mem >> 7) | kOffset;
Experiments are in flight.
The ReportError
could be implemented as a call (this is the default now),
but there are some other, slightly more efficient and/or more compact solutions.
At some point the default behaviour was:
- copy the failure address to
%rax
(%eax
). - execute
ud2
(generates SIGILL) - Encode access type and size in a one-byte instruction which follows
ud2
. Overal these 3 instructions require 5-6 bytes of machine code.
It is possible to use just a single instruction (e.g. ud2
), but this will require
to have a full disassembler in the run-time library (or some other hacks).
In order to catch stack buffer overflow, AddressSanitizer instruments the code like this:
Original code:
void foo() {
char a[8];
...
return;
}
Instrumented code:
void foo() {
char redzone1[32]; // 32-byte aligned
char a[8]; // 32-byte aligned
char redzone2[24];
char redzone3[32]; // 32-byte aligned
int *shadow_base = MemToShadow(redzone1);
shadow_base[0] = 0xffffffff; // poison redzone1
shadow_base[1] = 0xffffff00; // poison redzone2, unpoison 'a'
shadow_base[2] = 0xffffffff; // poison redzone3
...
shadow_base[0] = shadow_base[1] = shadow_base[2] = 0; // unpoison all
return;
}
# long load8(long *a) { return *a; }
0000000000000030 <load8>:
30: 48 89 f8 mov %rdi,%rax
33: 48 c1 e8 03 shr $0x3,%rax
37: 80 b8 00 80 ff 7f 00 cmpb $0x0,0x7fff8000(%rax)
3e: 75 04 jne 44 <load8+0x14>
40: 48 8b 07 mov (%rdi),%rax <<<<<< original load
43: c3 retq
44: 52 push %rdx
45: e8 00 00 00 00 callq __asan_report_load8
# int load4(int *a) { return *a; }
0000000000000000 <load4>:
0: 48 89 f8 mov %rdi,%rax
3: 48 89 fa mov %rdi,%rdx
6: 48 c1 e8 03 shr $0x3,%rax
a: 83 e2 07 and $0x7,%edx
d: 0f b6 80 00 80 ff 7f movzbl 0x7fff8000(%rax),%eax
14: 83 c2 03 add $0x3,%edx
17: 38 c2 cmp %al,%dl
19: 7d 03 jge 1e <load4+0x1e>
1b: 8b 07 mov (%rdi),%eax <<<<<< original load
1d: c3 retq
1e: 84 c0 test %al,%al
20: 74 f9 je 1b <load4+0x1b>
22: 50 push %rax
23: e8 00 00 00 00 callq __asan_report_load4
The current compact mapping will not catch unaligned partially out-of-bound accesses:
int *x = new int[2]; // 8 bytes: [0,7].
int *u = (int*)((char*)x + 6);
*u = 1; // Access to range [6-9]
A viable solution is described in http://code.google.com/p/address-sanitizer/issues/detail?id=100 but it comes at a performance cost.
The run-time library replaces malloc
/free
and provides error reporting functions like __asan_report_load8
.
malloc
allocates the requested amount of memory with redzones around it.
The shadow values corresponding to the redzones are poisoned
and the shadow values for the main memory region are cleared.
free
poisons shadow values for the entire region and puts the chunk of memory
into a quarantine queue (such that this chunk
will not be returned again by malloc during some period of time).
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