blob: e3aa9d4fcf3a56c67acb8f084079cc418ec65fd5 [file] [log] [blame]
// SPDX-License-Identifier: GPL-2.0
#include "util/cputopo.h"
#include "util/debug.h"
#include "util/expr.h"
#include "util/hashmap.h"
#include "util/header.h"
#include "util/smt.h"
#include "tests.h"
#include <math.h>
#include <stdlib.h>
#include <string.h>
#include <string2.h>
#include <linux/zalloc.h>
static int test_ids_union(void)
{
struct hashmap *ids1, *ids2;
/* Empty union. */
ids1 = ids__new();
TEST_ASSERT_VAL("ids__new", ids1);
ids2 = ids__new();
TEST_ASSERT_VAL("ids__new", ids2);
ids1 = ids__union(ids1, ids2);
TEST_ASSERT_EQUAL("union", (int)hashmap__size(ids1), 0);
/* Union {foo, bar} against {}. */
ids2 = ids__new();
TEST_ASSERT_VAL("ids__new", ids2);
TEST_ASSERT_EQUAL("ids__insert", ids__insert(ids1, strdup("foo")), 0);
TEST_ASSERT_EQUAL("ids__insert", ids__insert(ids1, strdup("bar")), 0);
ids1 = ids__union(ids1, ids2);
TEST_ASSERT_EQUAL("union", (int)hashmap__size(ids1), 2);
/* Union {foo, bar} against {foo}. */
ids2 = ids__new();
TEST_ASSERT_VAL("ids__new", ids2);
TEST_ASSERT_EQUAL("ids__insert", ids__insert(ids2, strdup("foo")), 0);
ids1 = ids__union(ids1, ids2);
TEST_ASSERT_EQUAL("union", (int)hashmap__size(ids1), 2);
/* Union {foo, bar} against {bar,baz}. */
ids2 = ids__new();
TEST_ASSERT_VAL("ids__new", ids2);
TEST_ASSERT_EQUAL("ids__insert", ids__insert(ids2, strdup("bar")), 0);
TEST_ASSERT_EQUAL("ids__insert", ids__insert(ids2, strdup("baz")), 0);
ids1 = ids__union(ids1, ids2);
TEST_ASSERT_EQUAL("union", (int)hashmap__size(ids1), 3);
ids__free(ids1);
return 0;
}
static int test(struct expr_parse_ctx *ctx, const char *e, double val2)
{
double val;
if (expr__parse(&val, ctx, e))
TEST_ASSERT_VAL("parse test failed", 0);
TEST_ASSERT_VAL("unexpected value", val == val2);
return 0;
}
static int test__expr(struct test_suite *t __maybe_unused, int subtest __maybe_unused)
{
struct expr_id_data *val_ptr;
const char *p;
double val, num_cpus_online, num_cpus, num_cores, num_dies, num_packages;
int ret;
struct expr_parse_ctx *ctx;
bool is_intel = false;
char strcmp_cpuid_buf[256];
struct perf_pmu *pmu = perf_pmus__find_core_pmu();
char *cpuid = perf_pmu__getcpuid(pmu);
char *escaped_cpuid1, *escaped_cpuid2;
TEST_ASSERT_VAL("get_cpuid", cpuid);
is_intel = strstr(cpuid, "Intel") != NULL;
TEST_ASSERT_EQUAL("ids_union", test_ids_union(), 0);
ctx = expr__ctx_new();
TEST_ASSERT_VAL("expr__ctx_new", ctx);
expr__add_id_val(ctx, strdup("FOO"), 1);
expr__add_id_val(ctx, strdup("BAR"), 2);
ret = test(ctx, "1+1", 2);
ret |= test(ctx, "FOO+BAR", 3);
ret |= test(ctx, "(BAR/2)%2", 1);
ret |= test(ctx, "1 - -4", 5);
ret |= test(ctx, "(FOO-1)*2 + (BAR/2)%2 - -4", 5);
ret |= test(ctx, "1-1 | 1", 1);
ret |= test(ctx, "1-1 & 1", 0);
ret |= test(ctx, "min(1,2) + 1", 2);
ret |= test(ctx, "max(1,2) + 1", 3);
ret |= test(ctx, "1+1 if 3*4 else 0", 2);
ret |= test(ctx, "100 if 1 else 200 if 1 else 300", 100);
ret |= test(ctx, "100 if 0 else 200 if 1 else 300", 200);
ret |= test(ctx, "100 if 1 else 200 if 0 else 300", 100);
ret |= test(ctx, "100 if 0 else 200 if 0 else 300", 300);
ret |= test(ctx, "1.1 + 2.1", 3.2);
ret |= test(ctx, ".1 + 2.", 2.1);
ret |= test(ctx, "d_ratio(1, 2)", 0.5);
ret |= test(ctx, "d_ratio(2.5, 0)", 0);
ret |= test(ctx, "1.1 < 2.2", 1);
ret |= test(ctx, "2.2 > 1.1", 1);
ret |= test(ctx, "1.1 < 1.1", 0);
ret |= test(ctx, "2.2 > 2.2", 0);
ret |= test(ctx, "2.2 < 1.1", 0);
ret |= test(ctx, "1.1 > 2.2", 0);
ret |= test(ctx, "1.1e10 < 1.1e100", 1);
ret |= test(ctx, "1.1e2 > 1.1e-2", 1);
if (ret) {
expr__ctx_free(ctx);
return ret;
}
p = "FOO/0";
ret = expr__parse(&val, ctx, p);
TEST_ASSERT_VAL("division by zero", ret == 0);
TEST_ASSERT_VAL("division by zero", isnan(val));
p = "BAR/";
ret = expr__parse(&val, ctx, p);
TEST_ASSERT_VAL("missing operand", ret == -1);
expr__ctx_clear(ctx);
TEST_ASSERT_VAL("find ids",
expr__find_ids("FOO + BAR + BAZ + BOZO", "FOO",
ctx) == 0);
TEST_ASSERT_VAL("find ids", hashmap__size(ctx->ids) == 3);
TEST_ASSERT_VAL("find ids", hashmap__find(ctx->ids, "BAR", &val_ptr));
TEST_ASSERT_VAL("find ids", hashmap__find(ctx->ids, "BAZ", &val_ptr));
TEST_ASSERT_VAL("find ids", hashmap__find(ctx->ids, "BOZO", &val_ptr));
expr__ctx_clear(ctx);
ctx->sctx.runtime = 3;
TEST_ASSERT_VAL("find ids",
expr__find_ids("EVENT1\\,param\\=?@ + EVENT2\\,param\\=?@",
NULL, ctx) == 0);
TEST_ASSERT_VAL("find ids", hashmap__size(ctx->ids) == 2);
TEST_ASSERT_VAL("find ids", hashmap__find(ctx->ids, "EVENT1,param=3@", &val_ptr));
TEST_ASSERT_VAL("find ids", hashmap__find(ctx->ids, "EVENT2,param=3@", &val_ptr));
expr__ctx_clear(ctx);
TEST_ASSERT_VAL("find ids",
expr__find_ids("dash\\-event1 - dash\\-event2",
NULL, ctx) == 0);
TEST_ASSERT_VAL("find ids", hashmap__size(ctx->ids) == 2);
TEST_ASSERT_VAL("find ids", hashmap__find(ctx->ids, "dash-event1", &val_ptr));
TEST_ASSERT_VAL("find ids", hashmap__find(ctx->ids, "dash-event2", &val_ptr));
/* Only EVENT1 or EVENT2 need be measured depending on the value of smt_on. */
{
bool smton = smt_on();
bool corewide = core_wide(/*system_wide=*/false,
/*user_requested_cpus=*/false);
expr__ctx_clear(ctx);
TEST_ASSERT_VAL("find ids",
expr__find_ids("EVENT1 if #smt_on else EVENT2",
NULL, ctx) == 0);
TEST_ASSERT_VAL("find ids", hashmap__size(ctx->ids) == 1);
TEST_ASSERT_VAL("find ids", hashmap__find(ctx->ids,
smton ? "EVENT1" : "EVENT2",
&val_ptr));
expr__ctx_clear(ctx);
TEST_ASSERT_VAL("find ids",
expr__find_ids("EVENT1 if #core_wide else EVENT2",
NULL, ctx) == 0);
TEST_ASSERT_VAL("find ids", hashmap__size(ctx->ids) == 1);
TEST_ASSERT_VAL("find ids", hashmap__find(ctx->ids,
corewide ? "EVENT1" : "EVENT2",
&val_ptr));
}
/* The expression is a constant 1.0 without needing to evaluate EVENT1. */
expr__ctx_clear(ctx);
TEST_ASSERT_VAL("find ids",
expr__find_ids("1.0 if EVENT1 > 100.0 else 1.0",
NULL, ctx) == 0);
TEST_ASSERT_VAL("find ids", hashmap__size(ctx->ids) == 0);
/* The expression is a constant 0.0 without needing to evaluate EVENT1. */
expr__ctx_clear(ctx);
TEST_ASSERT_VAL("find ids",
expr__find_ids("0 & EVENT1 > 0", NULL, ctx) == 0);
TEST_ASSERT_VAL("find ids", hashmap__size(ctx->ids) == 0);
expr__ctx_clear(ctx);
TEST_ASSERT_VAL("find ids",
expr__find_ids("EVENT1 > 0 & 0", NULL, ctx) == 0);
TEST_ASSERT_VAL("find ids", hashmap__size(ctx->ids) == 0);
expr__ctx_clear(ctx);
TEST_ASSERT_VAL("find ids",
expr__find_ids("1 & EVENT1 > 0", NULL, ctx) == 0);
TEST_ASSERT_VAL("find ids", hashmap__size(ctx->ids) == 1);
TEST_ASSERT_VAL("find ids", hashmap__find(ctx->ids, "EVENT1", &val_ptr));
expr__ctx_clear(ctx);
TEST_ASSERT_VAL("find ids",
expr__find_ids("EVENT1 > 0 & 1", NULL, ctx) == 0);
TEST_ASSERT_VAL("find ids", hashmap__size(ctx->ids) == 1);
TEST_ASSERT_VAL("find ids", hashmap__find(ctx->ids, "EVENT1", &val_ptr));
/* The expression is a constant 1.0 without needing to evaluate EVENT1. */
expr__ctx_clear(ctx);
TEST_ASSERT_VAL("find ids",
expr__find_ids("1 | EVENT1 > 0", NULL, ctx) == 0);
TEST_ASSERT_VAL("find ids", hashmap__size(ctx->ids) == 0);
expr__ctx_clear(ctx);
TEST_ASSERT_VAL("find ids",
expr__find_ids("EVENT1 > 0 | 1", NULL, ctx) == 0);
TEST_ASSERT_VAL("find ids", hashmap__size(ctx->ids) == 0);
expr__ctx_clear(ctx);
TEST_ASSERT_VAL("find ids",
expr__find_ids("0 | EVENT1 > 0", NULL, ctx) == 0);
TEST_ASSERT_VAL("find ids", hashmap__size(ctx->ids) == 1);
TEST_ASSERT_VAL("find ids", hashmap__find(ctx->ids, "EVENT1", &val_ptr));
expr__ctx_clear(ctx);
TEST_ASSERT_VAL("find ids",
expr__find_ids("EVENT1 > 0 | 0", NULL, ctx) == 0);
TEST_ASSERT_VAL("find ids", hashmap__size(ctx->ids) == 1);
TEST_ASSERT_VAL("find ids", hashmap__find(ctx->ids, "EVENT1", &val_ptr));
/* Test toplogy constants appear well ordered. */
expr__ctx_clear(ctx);
TEST_ASSERT_VAL("#num_cpus_online",
expr__parse(&num_cpus_online, ctx, "#num_cpus_online") == 0);
TEST_ASSERT_VAL("#num_cpus", expr__parse(&num_cpus, ctx, "#num_cpus") == 0);
TEST_ASSERT_VAL("#num_cpus >= #num_cpus_online", num_cpus >= num_cpus_online);
TEST_ASSERT_VAL("#num_cores", expr__parse(&num_cores, ctx, "#num_cores") == 0);
TEST_ASSERT_VAL("#num_cpus >= #num_cores", num_cpus >= num_cores);
TEST_ASSERT_VAL("#num_dies", expr__parse(&num_dies, ctx, "#num_dies") == 0);
TEST_ASSERT_VAL("#num_cores >= #num_dies", num_cores >= num_dies);
TEST_ASSERT_VAL("#num_packages", expr__parse(&num_packages, ctx, "#num_packages") == 0);
if (num_dies) // Some platforms do not have CPU die support, for example s390
TEST_ASSERT_VAL("#num_dies >= #num_packages", num_dies >= num_packages);
TEST_ASSERT_VAL("#system_tsc_freq", expr__parse(&val, ctx, "#system_tsc_freq") == 0);
if (is_intel)
TEST_ASSERT_VAL("#system_tsc_freq > 0", val > 0);
else
TEST_ASSERT_VAL("#system_tsc_freq == 0", fpclassify(val) == FP_ZERO);
/*
* Source count returns the number of events aggregating in a leader
* event including the leader. Check parsing yields an id.
*/
expr__ctx_clear(ctx);
TEST_ASSERT_VAL("source count",
expr__find_ids("source_count(EVENT1)",
NULL, ctx) == 0);
TEST_ASSERT_VAL("source count", hashmap__size(ctx->ids) == 1);
TEST_ASSERT_VAL("source count", hashmap__find(ctx->ids, "EVENT1", &val_ptr));
/* Test no cpuid match */
ret = test(ctx, "strcmp_cpuid_str(0x0)", 0);
/*
* Test cpuid match with current cpuid. Special chars have to be
* escaped.
*/
escaped_cpuid1 = strreplace_chars('-', cpuid, "\\-");
free(cpuid);
escaped_cpuid2 = strreplace_chars(',', escaped_cpuid1, "\\,");
free(escaped_cpuid1);
escaped_cpuid1 = strreplace_chars('=', escaped_cpuid2, "\\=");
free(escaped_cpuid2);
scnprintf(strcmp_cpuid_buf, sizeof(strcmp_cpuid_buf),
"strcmp_cpuid_str(%s)", escaped_cpuid1);
free(escaped_cpuid1);
ret |= test(ctx, strcmp_cpuid_buf, 1);
/* has_event returns 1 when an event exists. */
expr__add_id_val(ctx, strdup("cycles"), 2);
ret |= test(ctx, "has_event(cycles)", 1);
expr__ctx_free(ctx);
return ret;
}
DEFINE_SUITE("Simple expression parser", expr);