/* Copyright 2013 The Chromium OS Authors. All rights reserved. * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. * * Test common utilities. */ #include "common.h" #include "console.h" #include "shared_mem.h" #include "system.h" #include "test_util.h" #include "timer.h" #include "util.h" #include "watchdog.h" static int test_memmove(void) { int i; timestamp_t t0, t1, t2, t3; char *buf; const int buf_size = 1000; const int len = 400; const int iteration = 1000; TEST_ASSERT(shared_mem_acquire(buf_size, &buf) == EC_SUCCESS); for (i = 0; i < len; ++i) buf[i] = i & 0x7f; for (i = len; i < buf_size; ++i) buf[i] = 0; t0 = get_time(); for (i = 0; i < iteration; ++i) memmove(buf + 101, buf, len); /* unaligned */ t1 = get_time(); TEST_ASSERT_ARRAY_EQ(buf + 101, buf, len); ccprintf(" (speed gain: %d ->", t1.val-t0.val); t2 = get_time(); for (i = 0; i < iteration; ++i) memmove(buf + 100, buf, len); /* aligned */ t3 = get_time(); ccprintf(" %d us) ", t3.val-t2.val); TEST_ASSERT_ARRAY_EQ(buf + 100, buf, len); /* Expected about 4x speed gain. Use 3x because it fluctuates */ #ifndef EMU_BUILD /* * The speed gain is too unpredictable on host, especially on * buildbots. Skip it if we are running in the emulator. */ TEST_ASSERT((t1.val-t0.val) > (unsigned)(t3.val-t2.val) * 3); #endif /* Test small moves */ memmove(buf + 1, buf, 1); TEST_ASSERT_ARRAY_EQ(buf + 1, buf, 1); memmove(buf + 5, buf, 4); memmove(buf + 1, buf, 4); TEST_ASSERT_ARRAY_EQ(buf + 1, buf + 5, 4); shared_mem_release(buf); return EC_SUCCESS; } static int test_memcpy(void) { int i; timestamp_t t0, t1, t2, t3; char *buf; const int buf_size = 1000; const int len = 400; const int dest_offset = 500; const int iteration = 1000; TEST_ASSERT(shared_mem_acquire(buf_size, &buf) == EC_SUCCESS); for (i = 0; i < len; ++i) buf[i] = i & 0x7f; for (i = len; i < buf_size; ++i) buf[i] = 0; t0 = get_time(); for (i = 0; i < iteration; ++i) memcpy(buf + dest_offset + 1, buf, len); /* unaligned */ t1 = get_time(); TEST_ASSERT_ARRAY_EQ(buf + dest_offset + 1, buf, len); ccprintf(" (speed gain: %d ->", t1.val-t0.val); t2 = get_time(); for (i = 0; i < iteration; ++i) memcpy(buf + dest_offset, buf, len); /* aligned */ t3 = get_time(); ccprintf(" %d us) ", t3.val-t2.val); TEST_ASSERT_ARRAY_EQ(buf + dest_offset, buf, len); /* Expected about 4x speed gain. Use 3x because it fluctuates */ #ifndef EMU_BUILD /* * The speed gain is too unpredictable on host, especially on * buildbots. Skip it if we are running in the emulator. */ TEST_ASSERT((t1.val-t0.val) > (unsigned)(t3.val-t2.val) * 3); #endif memcpy(buf + dest_offset + 1, buf + 1, len - 1); TEST_ASSERT_ARRAY_EQ(buf + dest_offset + 1, buf + 1, len - 1); /* Test small copies */ memcpy(buf + dest_offset, buf, 1); TEST_ASSERT_ARRAY_EQ(buf + dest_offset, buf, 1); memcpy(buf + dest_offset, buf, 4); TEST_ASSERT_ARRAY_EQ(buf + dest_offset, buf, 4); memcpy(buf + dest_offset + 1, buf, 1); TEST_ASSERT_ARRAY_EQ(buf + dest_offset + 1, buf, 1); memcpy(buf + dest_offset + 1, buf, 4); TEST_ASSERT_ARRAY_EQ(buf + dest_offset + 1, buf, 4); shared_mem_release(buf); return EC_SUCCESS; } /* Plain memset, used as a reference to measure speed gain */ static void *dumb_memset(void *dest, int c, int len) { char *d = (char *)dest; while (len > 0) { *(d++) = c; len--; } return dest; } static int test_memset(void) { int i; timestamp_t t0, t1, t2, t3; char *buf; const int buf_size = 1000; const int len = 400; const int iteration = 1000; TEST_ASSERT(shared_mem_acquire(buf_size, &buf) == EC_SUCCESS); t0 = get_time(); for (i = 0; i < iteration; ++i) dumb_memset(buf, 1, len); t1 = get_time(); TEST_ASSERT_MEMSET(buf, (char)1, len); ccprintf(" (speed gain: %d ->", t1.val-t0.val); t2 = get_time(); for (i = 0; i < iteration; ++i) memset(buf, 1, len); t3 = get_time(); TEST_ASSERT_MEMSET(buf, (char)1, len); ccprintf(" %d us) ", t3.val-t2.val); /* Expected about 4x speed gain. Use 3x because it fluctuates */ #ifndef EMU_BUILD /* * The speed gain is too unpredictable on host, especially on * buildbots. Skip it if we are running in the emulator. */ TEST_ASSERT((t1.val-t0.val) > (unsigned)(t3.val-t2.val) * 3); #endif memset(buf, 128, len); TEST_ASSERT_MEMSET(buf, (char)128, len); memset(buf, -2, len); TEST_ASSERT_MEMSET(buf, (char)-2, len); memset(buf + 1, 1, len - 2); TEST_ASSERT_MEMSET(buf + 1, (char)1, len - 2); shared_mem_release(buf); return EC_SUCCESS; } static int test_memchr(void) { char *buf = "1234"; TEST_ASSERT(memchr("123567890", '4', 8) == NULL); TEST_ASSERT(memchr("123", '3', 2) == NULL); TEST_ASSERT(memchr(buf, '3', 4) == buf + 2); TEST_ASSERT(memchr(buf, '4', 4) == buf + 3); return EC_SUCCESS; } static int test_uint64divmod_0(void) { uint64_t n = 8567106442584750ULL; int d = 54870071; int r = uint64divmod(&n, d); TEST_CHECK(r == 5991285 && n == 156134415ULL); } static int test_uint64divmod_1(void) { uint64_t n = 8567106442584750ULL; int d = 2; int r = uint64divmod(&n, d); TEST_CHECK(r == 0 && n == 4283553221292375ULL); } static int test_uint64divmod_2(void) { uint64_t n = 8567106442584750ULL; int d = 0; int r = uint64divmod(&n, d); TEST_CHECK(r == 0 && n == 0ULL); } static int test_get_next_bit(void) { uint32_t mask = 0x10001010; TEST_ASSERT(get_next_bit(&mask) == 28); TEST_ASSERT(mask == 0x1010); TEST_ASSERT(get_next_bit(&mask) == 12); TEST_ASSERT(mask == 0x10); TEST_ASSERT(get_next_bit(&mask) == 4); TEST_ASSERT(mask == 0x0); return EC_SUCCESS; } static int test_shared_mem(void) { int i; int sz = shared_mem_size(); char *mem; TEST_ASSERT(shared_mem_acquire(sz, &mem) == EC_SUCCESS); TEST_ASSERT(shared_mem_acquire(sz, &mem) == EC_ERROR_BUSY); for (i = 0; i < 256; ++i) { memset(mem, i, sz); TEST_ASSERT_MEMSET(mem, (char)i, sz); if ((i & 0xf) == 0) msleep(20); /* Yield to other tasks */ } shared_mem_release(mem); return EC_SUCCESS; } static int test_scratchpad(void) { system_set_scratchpad(0xfeed); TEST_ASSERT(system_get_scratchpad() == 0xfeed); return EC_SUCCESS; } static int test_cond_t(void) { cond_t c; /* one-shot? */ cond_init_false(&c); cond_set_true(&c); TEST_ASSERT(cond_went_true(&c)); TEST_ASSERT(!cond_went_true(&c)); TEST_ASSERT(!cond_went_true(&c)); cond_set_false(&c); TEST_ASSERT(cond_went_false(&c)); TEST_ASSERT(!cond_went_false(&c)); TEST_ASSERT(!cond_went_false(&c)); /* one-shot when initially true? */ cond_init_true(&c); cond_set_false(&c); TEST_ASSERT(cond_went_false(&c)); TEST_ASSERT(!cond_went_false(&c)); TEST_ASSERT(!cond_went_false(&c)); cond_set_true(&c); TEST_ASSERT(cond_went_true(&c)); TEST_ASSERT(!cond_went_true(&c)); TEST_ASSERT(!cond_went_true(&c)); /* still one-shot even if set multiple times? */ cond_init_false(&c); cond_set_true(&c); cond_set_true(&c); cond_set_true(&c); cond_set_true(&c); cond_set_true(&c); cond_set_true(&c); TEST_ASSERT(cond_went_true(&c)); TEST_ASSERT(!cond_went_true(&c)); TEST_ASSERT(!cond_went_true(&c)); cond_set_true(&c); cond_set_false(&c); cond_set_false(&c); cond_set_false(&c); cond_set_false(&c); cond_set_false(&c); TEST_ASSERT(cond_went_false(&c)); TEST_ASSERT(!cond_went_false(&c)); TEST_ASSERT(!cond_went_false(&c)); /* only the detected transition direction resets it */ cond_set_true(&c); TEST_ASSERT(!cond_went_false(&c)); TEST_ASSERT(cond_went_true(&c)); TEST_ASSERT(!cond_went_false(&c)); TEST_ASSERT(!cond_went_true(&c)); cond_set_false(&c); TEST_ASSERT(!cond_went_true(&c)); TEST_ASSERT(!cond_went_true(&c)); TEST_ASSERT(cond_went_false(&c)); TEST_ASSERT(!cond_went_false(&c)); TEST_ASSERT(!cond_went_false(&c)); TEST_ASSERT(!cond_went_true(&c)); TEST_ASSERT(!cond_went_true(&c)); /* multiple transitions between checks should notice both edges */ cond_set_true(&c); cond_set_false(&c); cond_set_true(&c); cond_set_false(&c); cond_set_true(&c); cond_set_false(&c); TEST_ASSERT(cond_went_true(&c)); TEST_ASSERT(!cond_went_true(&c)); TEST_ASSERT(!cond_went_true(&c)); TEST_ASSERT(!cond_went_true(&c)); TEST_ASSERT(cond_went_false(&c)); TEST_ASSERT(!cond_went_false(&c)); TEST_ASSERT(!cond_went_false(&c)); TEST_ASSERT(!cond_went_false(&c)); TEST_ASSERT(!cond_went_true(&c)); TEST_ASSERT(!cond_went_true(&c)); TEST_ASSERT(!cond_went_false(&c)); /* Still has last value? */ cond_set_true(&c); cond_set_false(&c); cond_set_true(&c); cond_set_false(&c); TEST_ASSERT(cond_is_false(&c)); cond_set_false(&c); cond_set_true(&c); cond_set_false(&c); cond_set_true(&c); TEST_ASSERT(cond_is_true(&c)); /* well okay then */ return EC_SUCCESS; } static int test_mula32(void) { uint64_t r = 0x0; uint64_t r2 = 0x0; uint32_t b = 0x1; uint32_t c = 0x1; uint32_t i; timestamp_t t0, t1; t0 = get_time(); for (i = 0; i < 5000000; i++) { r = mula32(b, c, r + (r >> 32)); r2 = mulaa32(b, c, r2 >> 32, r2); b = (b << 13) ^ (b >> 2) ^ i; c = (c << 16) ^ (c >> 7) ^ i; watchdog_reload(); } t1 = get_time(); ccprintf("After %d iterations, r=%08x%08x, r2=%08x%08x (time: %d)\n", i, (uint32_t)(r >> 32), (uint32_t)r, (uint32_t)(r2 >> 32), (uint32_t)r2, t1.le.lo-t0.le.lo); TEST_ASSERT(r == 0x9df59b9fb0ab9d96L); TEST_ASSERT(r2 == 0x9df59b9fb0beabd6L); /* well okay then */ return EC_SUCCESS; } #define SWAP_TEST_HARNESS(t, x, y) \ do { \ t a = x, b = y; \ swap(a, b); \ TEST_ASSERT(a == y); \ TEST_ASSERT(b == x); \ } while (0) static int test_swap(void) { SWAP_TEST_HARNESS(uint8_t, UINT8_MAX, 0); SWAP_TEST_HARNESS(uint16_t, UINT16_MAX, 0); SWAP_TEST_HARNESS(uint32_t, UINT32_MAX, 0); SWAP_TEST_HARNESS(float, 1, 0); SWAP_TEST_HARNESS(double, 1, 0); return EC_SUCCESS; } void run_test(void) { test_reset(); RUN_TEST(test_memmove); RUN_TEST(test_memcpy); RUN_TEST(test_memset); RUN_TEST(test_memchr); RUN_TEST(test_uint64divmod_0); RUN_TEST(test_uint64divmod_1); RUN_TEST(test_uint64divmod_2); RUN_TEST(test_get_next_bit); RUN_TEST(test_shared_mem); RUN_TEST(test_scratchpad); RUN_TEST(test_cond_t); RUN_TEST(test_mula32); RUN_TEST(test_swap); test_print_result(); }