// Tests shadow memory correctness for 16-byte/32-byte/etc. vector
// loads/stores. Requires vector_copy() and VECTOR_BYTES to be
// specified somehow.
#ifndef VECTOR_BYTES
#error "VECTOR_BYTES must be defined"
#endif
#include <assert.h>
#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#include "tests/malloc.h"
#include "memcheck/memcheck.h"
// What we're actually testing
// .. is vector_copy, which should be defined before this point
// All the sizes here are in *bytes*, not bits.
typedef unsigned char U1;
typedef unsigned short U2;
typedef unsigned int U4;
typedef unsigned long long U8;
typedef unsigned long int UWord;
typedef unsigned char Bool;
#define True ((Bool)1)
#define False ((Bool)0)
#define CFENCE __asm__ __volatile__("":::"cc","memory")
static __attribute__((noinline)) const char* get_endianness ( void )
{
volatile U4 w32 = 0x88776655;
volatile U1* p = (U1*)&w32;
if (p[0] == 0x55) {
assert(p[3] == 0x88);
return "little";
}
if (p[0] == 0x88) {
assert(p[3] == 0x55);
return "big";
}
assert(0);
}
static inline U4 randomU4 ( void )
{
static U4 n = 0;
/* From "Numerical Recipes in C" 2nd Edition */
n = 1664525UL * n + 1013904223UL;
return n;
}
static inline U1 randomU1 ( void )
{
return 0xFF & (randomU4() >> 13);
}
#define N_BYTES 80000
#define N_EVENTS (N_BYTES * 2)
// Return x, but with its definedness bits set to be its own value bits
static inline U1 self_shadow ( U1 x )
{
U1 res = 0xFF;
(void) VALGRIND_MAKE_MEM_UNDEFINED(&res, 1);
res &= x;
return res;
}
static inline U1 get_shadow ( U1 x )
{
U1 res = 0;
U4 r = VALGRIND_GET_VBITS(&x, &res, 1);
assert(r == 1 || r == 0);
return res;
}
static inline U1 make_def ( U1 x )
{
U1 y = x;
(void) VALGRIND_MAKE_MEM_DEFINED(&y, 1);
return y;
}
static inline U1 make_undef ( U1 x )
{
U1 y = x;
(void) VALGRIND_MAKE_MEM_UNDEFINED(&y, 1);
return y;
}
static void make_noaccess ( U1* dst )
{
(void) VALGRIND_MAKE_MEM_NOACCESS(dst, 1);
}
static void apply ( void(*fn)(U4,Bool), U4 arg1, Bool arg2 )
{
switch (arg1 & (32-1)) {
case 0: CFENCE; fn(arg1, arg2); CFENCE; break;
case 1: CFENCE; fn(arg1, arg2); CFENCE; break;
case 2: CFENCE; fn(arg1, arg2); CFENCE; break;
case 3: CFENCE; fn(arg1, arg2); CFENCE; break;
case 4: CFENCE; fn(arg1, arg2); CFENCE; break;
case 5: CFENCE; fn(arg1, arg2); CFENCE; break;
case 6: CFENCE; fn(arg1, arg2); CFENCE; break;
case 7: CFENCE; fn(arg1, arg2); CFENCE; break;
case 8: CFENCE; fn(arg1, arg2); CFENCE; break;
case 9: CFENCE; fn(arg1, arg2); CFENCE; break;
case 10: CFENCE; fn(arg1, arg2); CFENCE; break;
case 11: CFENCE; fn(arg1, arg2); CFENCE; break;
case 12: CFENCE; fn(arg1, arg2); CFENCE; break;
case 13: CFENCE; fn(arg1, arg2); CFENCE; break;
case 14: CFENCE; fn(arg1, arg2); CFENCE; break;
case 15: CFENCE; fn(arg1, arg2); CFENCE; break;
case 16: CFENCE; fn(arg1, arg2); CFENCE; break;
case 17: CFENCE; fn(arg1, arg2); CFENCE; break;
case 18: CFENCE; fn(arg1, arg2); CFENCE; break;
case 19: CFENCE; fn(arg1, arg2); CFENCE; break;
case 20: CFENCE; fn(arg1, arg2); CFENCE; break;
case 21: CFENCE; fn(arg1, arg2); CFENCE; break;
case 22: CFENCE; fn(arg1, arg2); CFENCE; break;
case 23: CFENCE; fn(arg1, arg2); CFENCE; break;
case 24: CFENCE; fn(arg1, arg2); CFENCE; break;
case 25: CFENCE; fn(arg1, arg2); CFENCE; break;
case 26: CFENCE; fn(arg1, arg2); CFENCE; break;
case 27: CFENCE; fn(arg1, arg2); CFENCE; break;
case 28: CFENCE; fn(arg1, arg2); CFENCE; break;
case 29: CFENCE; fn(arg1, arg2); CFENCE; break;
case 30: CFENCE; fn(arg1, arg2); CFENCE; break;
case 31: CFENCE; fn(arg1, arg2); CFENCE; break;
default: CFENCE; fn(arg1, arg2); CFENCE; break;
}
}
// Try doing some partial-loads-ok/not-ok testing.
/* Test cases:
- load, aligned, all no-access
==> addr err
- load, aligned, 1 to VECTOR_BYTES-1 initial bytes accessible,
then at least one unaccessible byte,
then remaining bytes in any state.
==> if PLO then no error, but returned V bits are undefined
for unaccessible bytes
else
error; and V bits are defined for unaccessible bytes
All of the above, but non-aligned:
-- all return an addressing error
*/
static void do_partial_load_case ( U4 nInitialValid, Bool aligned )
{
fprintf(stderr,
"------ PL %s case with %u leading acc+def bytes ------\n\n",
aligned ? "Aligned" : "Unaligned", nInitialValid);
void *temp;
if (posix_memalign(&temp, VECTOR_BYTES, 64) != 0)
abort();
U1* block = temp;
U4 j;
for (j = 0; j < 64; j++) block[j] = 0;
if (!aligned) block++;
// Make the block have this pattern:
// block[0 .. i-1] accessible and defined
// block[i .. VECTOR_BYTES-1] repeating NOACCESS, UNDEF, DEF
// hence block[i], at the very least, is always NOACCESS
U4 i = nInitialValid;
for (j = i; j < VECTOR_BYTES; j++) {
switch ((j-i) % 3) {
case 0: make_noaccess(&block[j]); break;
case 1: block[j] = make_undef(block[j]); break;
case 2: /* already acc and def */ break;
}
}
// Do the access, possibly generating an error, and show the
// resulting V bits
U1 dst[VECTOR_BYTES];
vector_copy(&dst[0], block);
U1 dst_vbits[VECTOR_BYTES];
U4 r = VALGRIND_GET_VBITS(&dst[0], &dst_vbits[0], VECTOR_BYTES);
assert(r == 1 || r == 0);
fprintf(stderr, "\n");
for (j = 0; j < VECTOR_BYTES; j++) {
fprintf(stderr, "%c", dst_vbits[j] == 0 ? 'd'
: dst_vbits[j] == 0xFF ? 'U' : '?');
}
fprintf(stderr, "\n\n");
// Also let's use the resulting value, to check we get an undef
// error
U1 sum = 0;
for (j = 0; j < VECTOR_BYTES; j++)
sum ^= dst[j];
if (sum == 42) {
CFENCE; fprintf(stderr, "%s", ""); CFENCE;
} else {
CFENCE; fprintf(stderr, "%s", ""); CFENCE;
}
fprintf(stderr, "\n");
if (!aligned) block--;
free(block);
}
int main ( void )
{
fprintf(stderr, "sh-mem-vec%d: config: %s-endian, %d-bit word size\n",
VECTOR_BYTES * 8, get_endianness(), (int)(8 * sizeof(void*)));
U4 i;
void *temp;
if (posix_memalign(&temp, VECTOR_BYTES, N_BYTES) != 0)
abort();
U1* buf = temp;
// Fill |buf| with bytes, so that zero bits have a zero shadow
// (are defined) and one bits have a one shadow (are undefined)
for (i = 0; i < N_BYTES/2; i++) {
buf[i] = self_shadow( (i & (1<<5)) ? 0x00 : 0xFF );
}
for ( ; i < N_BYTES; i++) {
buf[i] = self_shadow( randomU1() );
}
// Randomly copy the data around. Once every 8 srcs/dsts, force
// the src or dst to be aligned. Once every 64, force both to be
// aligned. So as to give the fast (aligned) paths some checking.
const U4 n_copies = N_EVENTS;
U4 n_d_aligned = 0;
U4 n_s_aligned = 0;
U4 n_both_aligned = 0;
U4 n_fails = 0;
for (i = 0; i < n_copies; i++) {
U4 si = randomU4() % (N_BYTES-VECTOR_BYTES);
U4 di = randomU4() % (N_BYTES-VECTOR_BYTES);
if (0 == (randomU1() & 7)) si &= ~(VECTOR_BYTES-1);
if (0 == (randomU1() & 7)) di &= ~(VECTOR_BYTES-1);
if (0 == (randomU1() & 63)) { di &= ~(VECTOR_BYTES-1); si &= ~(VECTOR_BYTES-1); }
void* dst = &buf[di];
void* src = &buf[si];
if (0 == (((UWord)src) & (VECTOR_BYTES-1))) n_s_aligned++;
if (0 == (((UWord)dst) & (VECTOR_BYTES-1))) n_d_aligned++;
if (0 == (((UWord)src) & (VECTOR_BYTES-1)) && 0 == (((UWord)dst) & (VECTOR_BYTES-1)))
n_both_aligned++;
vector_copy(dst, src);
}
U4 freq[256];
for (i = 0; i < 256; i++)
freq[i] = 0;
for (i = 0; i < N_BYTES; i++) {
//if (i > 0 && 0 == (i & 0x0F)) fprintf(stderr, "\n");
U1 v_actual = make_def(buf[i]);
U1 v_shadow = get_shadow(buf[i]);
if (v_actual != v_shadow) n_fails++;
//fprintf(stderr, "%02x:%02x ", (U4)v_actual, (U4)v_shadow);
freq[(U4)v_actual]++;
}
fprintf(stderr, "\n");
U4 totFreq = 0;
for (i = 0; i < 256; i++) {
totFreq += freq[i];
if (i > 0 && (0 == (i % 16))) fprintf(stderr, "\n");
fprintf(stderr, "%5u ", freq[i]);
}
assert(totFreq == N_BYTES);
fprintf(stderr, "\n\n");
fprintf(stderr, "%u copies, %u d_aligned, %u s_aligned, %u both_aligned\n",
n_copies, n_d_aligned, n_s_aligned, n_both_aligned);
fprintf(stderr, "%u %s\n", n_fails, n_fails == 0 ? "failures" : "FAILURES");
// Check that we can detect underruns of the block.
fprintf(stderr, "\nExpect 2 x no error\n" );
vector_copy( &buf[100], &buf[0] );
vector_copy( &buf[0], &buf[100] );
fprintf(stderr, "\nExpect 2 x error\n\n" );
vector_copy( &buf[100], &buf[-1] ); // invalid rd
vector_copy( &buf[-1], &buf[100] ); // invalid wr
// and overruns ..
fprintf(stderr, "\nExpect 2 x no error\n" );
vector_copy( &buf[200], &buf[N_BYTES-VECTOR_BYTES + 0] );
vector_copy( &buf[N_BYTES-VECTOR_BYTES + 0], &buf[200] );
fprintf(stderr, "\nExpect 2 x error\n\n" );
vector_copy( &buf[200], &buf[N_BYTES-VECTOR_BYTES + 1] );
vector_copy( &buf[N_BYTES-VECTOR_BYTES + 1], &buf[200] );
free(buf);
fprintf(stderr, "\n");
for (i = 0; i < VECTOR_BYTES; i++)
apply( do_partial_load_case, i, True/*aligned*/ );
for (i = 0; i < VECTOR_BYTES; i++)
apply( do_partial_load_case, i, False/*not aligned*/ );
return 0;
}