Clean up SFMT test.
Refactor array declarations to remove some dubious casts. Reduce array size to what is actually used. Extract magic numbers into cpp macro definitions.
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6edc97db15
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19609724f9
@ -35,9 +35,10 @@
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*/
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*/
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#include "test/jemalloc_test.h"
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#include "test/jemalloc_test.h"
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#define BLOCK_SIZE 100000
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#define BLOCK_SIZE 10000
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#define BLOCK_SIZE64 50000
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#define BLOCK_SIZE64 (BLOCK_SIZE / 2)
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#define COUNT 1000
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#define COUNT_1 1000
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#define COUNT_2 700
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static const uint32_t init_gen_rand_32_expected[] = {
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static const uint32_t init_gen_rand_32_expected[] = {
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3440181298U, 1564997079U, 1510669302U, 2930277156U, 1452439940U,
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3440181298U, 1564997079U, 1510669302U, 2930277156U, 1452439940U,
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@ -1450,23 +1451,22 @@ static const uint64_t init_by_array_64_expected[] = {
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TEST_BEGIN(test_gen_rand_32)
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TEST_BEGIN(test_gen_rand_32)
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{
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{
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uint64_t array1[BLOCK_SIZE / 4][2] JEMALLOC_ATTR(aligned(16));
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uint32_t array32[BLOCK_SIZE] JEMALLOC_ATTR(aligned(16));
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uint64_t array2[10000 / 4][2] JEMALLOC_ATTR(aligned(16));
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uint32_t array32_2[BLOCK_SIZE] JEMALLOC_ATTR(aligned(16));
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int i;
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int i;
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uint32_t *array32 = (uint32_t *)array1;
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uint32_t *array32_2 = (uint32_t *)array2;
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uint32_t r32;
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uint32_t r32;
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sfmt_t *ctx;
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sfmt_t *ctx;
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assert_d_le(get_min_array_size32(), 10000, "Array size too small");
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assert_d_le(get_min_array_size32(), BLOCK_SIZE,
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"Array size too small");
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ctx = init_gen_rand(1234);
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ctx = init_gen_rand(1234);
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fill_array32(ctx, array32, 10000);
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fill_array32(ctx, array32, BLOCK_SIZE);
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fill_array32(ctx, array32_2, 10000);
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fill_array32(ctx, array32_2, BLOCK_SIZE);
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fini_gen_rand(ctx);
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fini_gen_rand(ctx);
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ctx = init_gen_rand(1234);
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ctx = init_gen_rand(1234);
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for (i = 0; i < 10000; i++) {
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for (i = 0; i < BLOCK_SIZE; i++) {
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if (i < 1000) {
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if (i < COUNT_1) {
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assert_u32_eq(array32[i], init_gen_rand_32_expected[i],
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assert_u32_eq(array32[i], init_gen_rand_32_expected[i],
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"Output mismatch for i=%d", i);
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"Output mismatch for i=%d", i);
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}
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}
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@ -1474,7 +1474,7 @@ TEST_BEGIN(test_gen_rand_32)
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assert_u32_eq(r32, array32[i],
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assert_u32_eq(r32, array32[i],
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"Mismatch at array32[%d]=%x, gen=%x", i, array32[i], r32);
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"Mismatch at array32[%d]=%x, gen=%x", i, array32[i], r32);
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}
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}
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for (i = 0; i < 700; i++) {
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for (i = 0; i < COUNT_2; i++) {
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r32 = gen_rand32(ctx);
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r32 = gen_rand32(ctx);
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assert_u32_eq(r32, array32_2[i],
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assert_u32_eq(r32, array32_2[i],
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"Mismatch at array32_2[%d]=%x, gen=%x", i, array32_2[i],
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"Mismatch at array32_2[%d]=%x, gen=%x", i, array32_2[i],
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@ -1486,24 +1486,23 @@ TEST_END
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TEST_BEGIN(test_by_array_32)
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TEST_BEGIN(test_by_array_32)
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{
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{
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uint64_t array1[BLOCK_SIZE / 4][2] JEMALLOC_ATTR(aligned(16));
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uint32_t array32[BLOCK_SIZE] JEMALLOC_ATTR(aligned(16));
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uint64_t array2[10000 / 4][2] JEMALLOC_ATTR(aligned(16));
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uint32_t array32_2[BLOCK_SIZE] JEMALLOC_ATTR(aligned(16));
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int i;
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int i;
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uint32_t *array32 = (uint32_t *)array1;
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uint32_t *array32_2 = (uint32_t *)array2;
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uint32_t ini[4] = {0x1234, 0x5678, 0x9abc, 0xdef0};
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uint32_t ini[4] = {0x1234, 0x5678, 0x9abc, 0xdef0};
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uint32_t r32;
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uint32_t r32;
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sfmt_t *ctx;
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sfmt_t *ctx;
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assert_d_le(get_min_array_size32(), 10000, "Array size too small");
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assert_d_le(get_min_array_size32(), BLOCK_SIZE,
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"Array size too small");
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ctx = init_by_array(ini, 4);
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ctx = init_by_array(ini, 4);
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fill_array32(ctx, array32, 10000);
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fill_array32(ctx, array32, BLOCK_SIZE);
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fill_array32(ctx, array32_2, 10000);
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fill_array32(ctx, array32_2, BLOCK_SIZE);
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fini_gen_rand(ctx);
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fini_gen_rand(ctx);
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ctx = init_by_array(ini, 4);
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ctx = init_by_array(ini, 4);
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for (i = 0; i < 10000; i++) {
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for (i = 0; i < BLOCK_SIZE; i++) {
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if (i < 1000) {
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if (i < COUNT_1) {
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assert_u32_eq(array32[i], init_by_array_32_expected[i],
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assert_u32_eq(array32[i], init_by_array_32_expected[i],
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"Output mismatch for i=%d", i);
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"Output mismatch for i=%d", i);
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}
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}
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@ -1511,7 +1510,7 @@ TEST_BEGIN(test_by_array_32)
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assert_u32_eq(r32, array32[i],
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assert_u32_eq(r32, array32[i],
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"Mismatch at array32[%d]=%x, gen=%x", i, array32[i], r32);
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"Mismatch at array32[%d]=%x, gen=%x", i, array32[i], r32);
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}
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}
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for (i = 0; i < 700; i++) {
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for (i = 0; i < COUNT_2; i++) {
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r32 = gen_rand32(ctx);
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r32 = gen_rand32(ctx);
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assert_u32_eq(r32, array32_2[i],
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assert_u32_eq(r32, array32_2[i],
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"Mismatch at array32_2[%d]=%x, gen=%x", i, array32_2[i],
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"Mismatch at array32_2[%d]=%x, gen=%x", i, array32_2[i],
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@ -1523,23 +1522,22 @@ TEST_END
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TEST_BEGIN(test_gen_rand_64)
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TEST_BEGIN(test_gen_rand_64)
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{
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{
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uint64_t array1[BLOCK_SIZE / 4][2] JEMALLOC_ATTR(aligned(16));
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uint64_t array64[BLOCK_SIZE64] JEMALLOC_ATTR(aligned(16));
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uint64_t array2[10000 / 4][2] JEMALLOC_ATTR(aligned(16));
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uint64_t array64_2[BLOCK_SIZE64] JEMALLOC_ATTR(aligned(16));
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int i;
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int i;
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uint64_t *array64 = (uint64_t *)array1;
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uint64_t *array64_2 = (uint64_t *)array2;
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uint64_t r;
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uint64_t r;
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sfmt_t *ctx;
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sfmt_t *ctx;
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assert_d_le(get_min_array_size64(), 5000, "Array size too small");
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assert_d_le(get_min_array_size64(), BLOCK_SIZE64,
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"Array size too small");
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ctx = init_gen_rand(4321);
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ctx = init_gen_rand(4321);
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fill_array64(ctx, array64, 5000);
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fill_array64(ctx, array64, BLOCK_SIZE64);
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fill_array64(ctx, array64_2, 5000);
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fill_array64(ctx, array64_2, BLOCK_SIZE64);
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fini_gen_rand(ctx);
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fini_gen_rand(ctx);
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ctx = init_gen_rand(4321);
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ctx = init_gen_rand(4321);
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for (i = 0; i < 5000; i++) {
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for (i = 0; i < BLOCK_SIZE64; i++) {
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if (i < 1000) {
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if (i < COUNT_1) {
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assert_u64_eq(array64[i], init_gen_rand_64_expected[i],
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assert_u64_eq(array64[i], init_gen_rand_64_expected[i],
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"Output mismatch for i=%d", i);
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"Output mismatch for i=%d", i);
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}
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}
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@ -1548,7 +1546,7 @@ TEST_BEGIN(test_gen_rand_64)
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"Mismatch at array64[%d]=%"PRIx64", gen=%"PRIx64, i,
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"Mismatch at array64[%d]=%"PRIx64", gen=%"PRIx64, i,
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array64[i], r);
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array64[i], r);
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}
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}
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for (i = 0; i < 700; i++) {
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for (i = 0; i < COUNT_2; i++) {
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r = gen_rand64(ctx);
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r = gen_rand64(ctx);
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assert_u64_eq(r, array64_2[i],
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assert_u64_eq(r, array64_2[i],
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"Mismatch at array64_2[%d]=%"PRIx64" gen=%"PRIx64"", i,
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"Mismatch at array64_2[%d]=%"PRIx64" gen=%"PRIx64"", i,
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@ -1560,24 +1558,23 @@ TEST_END
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TEST_BEGIN(test_by_array_64)
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TEST_BEGIN(test_by_array_64)
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{
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{
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uint64_t array1[BLOCK_SIZE / 4][2] JEMALLOC_ATTR(aligned(16));
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uint64_t array64[BLOCK_SIZE64] JEMALLOC_ATTR(aligned(16));
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uint64_t array2[10000 / 4][2] JEMALLOC_ATTR(aligned(16));
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uint64_t array64_2[BLOCK_SIZE64] JEMALLOC_ATTR(aligned(16));
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int i;
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int i;
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uint64_t *array64 = (uint64_t *)array1;
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uint64_t *array64_2 = (uint64_t *)array2;
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uint64_t r;
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uint64_t r;
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uint32_t ini[] = {5, 4, 3, 2, 1};
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uint32_t ini[] = {5, 4, 3, 2, 1};
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sfmt_t *ctx;
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sfmt_t *ctx;
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assert_d_le(get_min_array_size64(), 5000, "Array size too small");
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assert_d_le(get_min_array_size64(), BLOCK_SIZE64,
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"Array size too small");
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ctx = init_by_array(ini, 5);
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ctx = init_by_array(ini, 5);
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fill_array64(ctx, array64, 5000);
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fill_array64(ctx, array64, BLOCK_SIZE64);
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fill_array64(ctx, array64_2, 5000);
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fill_array64(ctx, array64_2, BLOCK_SIZE64);
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fini_gen_rand(ctx);
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fini_gen_rand(ctx);
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ctx = init_by_array(ini, 5);
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ctx = init_by_array(ini, 5);
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for (i = 0; i < 5000; i++) {
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for (i = 0; i < BLOCK_SIZE64; i++) {
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if (i < 1000) {
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if (i < COUNT_1) {
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assert_u64_eq(array64[i], init_by_array_64_expected[i],
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assert_u64_eq(array64[i], init_by_array_64_expected[i],
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"Output mismatch for i=%d");
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"Output mismatch for i=%d");
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}
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}
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@ -1586,7 +1583,7 @@ TEST_BEGIN(test_by_array_64)
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"Mismatch at array64[%d]=%"PRIx64" gen=%"PRIx64, i,
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"Mismatch at array64[%d]=%"PRIx64" gen=%"PRIx64, i,
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array64[i], r);
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array64[i], r);
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}
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}
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for (i = 0; i < 700; i++) {
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for (i = 0; i < COUNT_2; i++) {
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r = gen_rand64(ctx);
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r = gen_rand64(ctx);
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assert_u64_eq(r, array64_2[i],
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assert_u64_eq(r, array64_2[i],
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"Mismatch at array64_2[%d]=%"PRIx64" gen=%"PRIx64, i,
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"Mismatch at array64_2[%d]=%"PRIx64" gen=%"PRIx64, i,
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