test/core/util/histogram.cc - platform/external/grpc-grpc - Git at Google

 /*
  *
  * Copyright 2015 gRPC authors.
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *     http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  *
  */

 #include "test/core/util/histogram.h"

 #include <math.h>
 #include <stddef.h>
 #include <string.h>

 #include <grpc/support/alloc.h>
 #include <grpc/support/log.h>
 #include <grpc/support/port_platform.h>

 #include "src/core/lib/gpr/useful.h"

 /* Histograms are stored with exponentially increasing bucket sizes.
    The first bucket is [0, m) where m = 1 + resolution
    Bucket n (n>=1) contains [m**n, m**(n+1))
    There are sufficient buckets to reach max_bucket_start */

 struct grpc_histogram {
   /* Sum of all values seen so far */
   double sum;
   /* Sum of squares of all values seen so far */
   double sum_of_squares;
   /* number of values seen so far */
   double count;
   /* m in the description */
   double multiplier;
   double one_on_log_multiplier;
   /* minimum value seen */
   double min_seen;
   /* maximum value seen */
   double max_seen;
   /* maximum representable value */
   double max_possible;
   /* number of buckets */
   size_t num_buckets;
   /* the buckets themselves */
   uint32_t* buckets;
 };

 /* determine a bucket index given a value - does no bounds checking */
 static size_t bucket_for_unchecked(grpc_histogram* h, double x) {
   return static_cast<size_t>(log(x) * h->one_on_log_multiplier);
 }

 /* bounds checked version of the above */
 static size_t bucket_for(grpc_histogram* h, double x) {
   size_t bucket = bucket_for_unchecked(h, GPR_CLAMP(x, 1.0, h->max_possible));
   GPR_ASSERT(bucket < h->num_buckets);
   return bucket;
 }

 /* at what value does a bucket start? */
 static double bucket_start(grpc_histogram* h, double x) {
   return pow(h->multiplier, x);
 }

 grpc_histogram* grpc_histogram_create(double resolution,
                                       double max_bucket_start) {
   grpc_histogram* h =
       static_cast<grpc_histogram*>(gpr_malloc(sizeof(grpc_histogram)));
   GPR_ASSERT(resolution > 0.0);
   GPR_ASSERT(max_bucket_start > resolution);
   h->sum = 0.0;
   h->sum_of_squares = 0.0;
   h->multiplier = 1.0 + resolution;
   h->one_on_log_multiplier = 1.0 / log(1.0 + resolution);
   h->max_possible = max_bucket_start;
   h->count = 0.0;
   h->min_seen = max_bucket_start;
   h->max_seen = 0.0;
   h->num_buckets = bucket_for_unchecked(h, max_bucket_start) + 1;
   GPR_ASSERT(h->num_buckets > 1);
   GPR_ASSERT(h->num_buckets < 100000000);
   h->buckets =
       static_cast<uint32_t*>(gpr_zalloc(sizeof(uint32_t) * h->num_buckets));
   return h;
 }

 void grpc_histogram_destroy(grpc_histogram* h) {
   gpr_free(h->buckets);
   gpr_free(h);
 }

 void grpc_histogram_add(grpc_histogram* h, double x) {
   h->sum += x;
   h->sum_of_squares += x * x;
   h->count++;
   if (x < h->min_seen) {
     h->min_seen = x;
   }
   if (x > h->max_seen) {
     h->max_seen = x;
   }
   h->buckets[bucket_for(h, x)]++;
 }

 int grpc_histogram_merge(grpc_histogram* dst, const grpc_histogram* src) {
   if ((dst->num_buckets != src->num_buckets) ||
       (dst->multiplier != src->multiplier)) {
     /* Fail because these histograms don't match */
     return 0;
   }
   grpc_histogram_merge_contents(dst, src->buckets, src->num_buckets,
                                 src->min_seen, src->max_seen, src->sum,
                                 src->sum_of_squares, src->count);
   return 1;
 }

 void grpc_histogram_merge_contents(grpc_histogram* dst, const uint32_t* data,
                                    size_t data_count, double min_seen,
                                    double max_seen, double sum,
                                    double sum_of_squares, double count) {
   size_t i;
   GPR_ASSERT(dst->num_buckets == data_count);
   dst->sum += sum;
   dst->sum_of_squares += sum_of_squares;
   dst->count += count;
   if (min_seen < dst->min_seen) {
     dst->min_seen = min_seen;
   }
   if (max_seen > dst->max_seen) {
     dst->max_seen = max_seen;
   }
   for (i = 0; i < dst->num_buckets; i++) {
     dst->buckets[i] += data[i];
   }
 }

 static double threshold_for_count_below(grpc_histogram* h, double count_below) {
   double count_so_far;
   double lower_bound;
   double upper_bound;
   size_t lower_idx;
   size_t upper_idx;

   if (h->count == 0) {
     return 0.0;
   }

   if (count_below <= 0) {
     return h->min_seen;
   }
   if (count_below >= h->count) {
     return h->max_seen;
   }

   /* find the lowest bucket that gets us above count_below */
   count_so_far = 0.0;
   for (lower_idx = 0; lower_idx < h->num_buckets; lower_idx++) {
     count_so_far += h->buckets[lower_idx];
     if (count_so_far >= count_below) {
       break;
     }
   }
   if (count_so_far == count_below) {
     /* this bucket hits the threshold exactly... we should be midway through
        any run of zero values following the bucket */
     for (upper_idx = lower_idx + 1; upper_idx < h->num_buckets; upper_idx++) {
       if (h->buckets[upper_idx]) {
         break;
       }
     }
     return (bucket_start(h, static_cast<double>(lower_idx)) +
             bucket_start(h, static_cast<double>(upper_idx))) /
            2.0;
   } else {
     /* treat values as uniform throughout the bucket, and find where this value
        should lie */
     lower_bound = bucket_start(h, static_cast<double>(lower_idx));
     upper_bound = bucket_start(h, static_cast<double>(lower_idx + 1));
     return GPR_CLAMP(upper_bound - (upper_bound - lower_bound) *
                                        (count_so_far - count_below) /
                                        h->buckets[lower_idx],
                      h->min_seen, h->max_seen);
   }
 }

 double grpc_histogram_percentile(grpc_histogram* h, double percentile) {
   return threshold_for_count_below(h, h->count * percentile / 100.0);
 }

 double grpc_histogram_mean(grpc_histogram* h) {
   GPR_ASSERT(h->count != 0);
   return h->sum / h->count;
 }

 double grpc_histogram_stddev(grpc_histogram* h) {
   return sqrt(grpc_histogram_variance(h));
 }

 double grpc_histogram_variance(grpc_histogram* h) {
   if (h->count == 0) return 0.0;
   return (h->sum_of_squares * h->count - h->sum * h->sum) /
          (h->count * h->count);
 }

 double grpc_histogram_maximum(grpc_histogram* h) { return h->max_seen; }

 double grpc_histogram_minimum(grpc_histogram* h) { return h->min_seen; }

 double grpc_histogram_count(grpc_histogram* h) { return h->count; }

 double grpc_histogram_sum(grpc_histogram* h) { return h->sum; }

 double grpc_histogram_sum_of_squares(grpc_histogram* h) {
   return h->sum_of_squares;
 }

 const uint32_t* grpc_histogram_get_contents(grpc_histogram* h, size_t* size) {
   *size = h->num_buckets;
   return h->buckets;
 }
	/*
	*
	* Copyright 2015 gRPC authors.
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*
	*/

	#include "test/core/util/histogram.h"

	#include <math.h>
	#include <stddef.h>
	#include <string.h>

	#include <grpc/support/alloc.h>
	#include <grpc/support/log.h>
	#include <grpc/support/port_platform.h>

	#include "src/core/lib/gpr/useful.h"

	/* Histograms are stored with exponentially increasing bucket sizes.
	The first bucket is [0, m) where m = 1 + resolution
	Bucket n (n>=1) contains [mn, m(n+1))
	There are sufficient buckets to reach max_bucket_start */

	struct grpc_histogram {
	/* Sum of all values seen so far */
	double sum;
	/* Sum of squares of all values seen so far */
	double sum_of_squares;
	/* number of values seen so far */
	double count;
	/* m in the description */
	double multiplier;
	double one_on_log_multiplier;
	/* minimum value seen */
	double min_seen;
	/* maximum value seen */
	double max_seen;
	/* maximum representable value */
	double max_possible;
	/* number of buckets */
	size_t num_buckets;
	/* the buckets themselves */
	uint32_t* buckets;
	};

	/* determine a bucket index given a value - does no bounds checking */
	static size_t bucket_for_unchecked(grpc_histogram* h, double x) {
	return static_cast<size_t>(log(x) * h->one_on_log_multiplier);
	}

	/* bounds checked version of the above */
	static size_t bucket_for(grpc_histogram* h, double x) {
	size_t bucket = bucket_for_unchecked(h, GPR_CLAMP(x, 1.0, h->max_possible));
	GPR_ASSERT(bucket < h->num_buckets);
	return bucket;
	}

	/* at what value does a bucket start? */
	static double bucket_start(grpc_histogram* h, double x) {
	return pow(h->multiplier, x);
	}

	grpc_histogram* grpc_histogram_create(double resolution,
	double max_bucket_start) {
	grpc_histogram* h =
	static_cast<grpc_histogram*>(gpr_malloc(sizeof(grpc_histogram)));
	GPR_ASSERT(resolution > 0.0);
	GPR_ASSERT(max_bucket_start > resolution);
	h->sum = 0.0;
	h->sum_of_squares = 0.0;
	h->multiplier = 1.0 + resolution;
	h->one_on_log_multiplier = 1.0 / log(1.0 + resolution);
	h->max_possible = max_bucket_start;
	h->count = 0.0;
	h->min_seen = max_bucket_start;
	h->max_seen = 0.0;
	h->num_buckets = bucket_for_unchecked(h, max_bucket_start) + 1;
	GPR_ASSERT(h->num_buckets > 1);
	GPR_ASSERT(h->num_buckets < 100000000);
	h->buckets =
	static_cast<uint32_t>(gpr_zalloc(sizeof(uint32_t) h->num_buckets));
	return h;
	}

	void grpc_histogram_destroy(grpc_histogram* h) {
	gpr_free(h->buckets);
	gpr_free(h);
	}

	void grpc_histogram_add(grpc_histogram* h, double x) {
	h->sum += x;
	h->sum_of_squares += x * x;
	h->count++;
	if (x < h->min_seen) {
	h->min_seen = x;
	}
	if (x > h->max_seen) {
	h->max_seen = x;
	}
	h->buckets[bucket_for(h, x)]++;
	}

	int grpc_histogram_merge(grpc_histogram* dst, const grpc_histogram* src) {
	if ((dst->num_buckets != src->num_buckets) \|\|
	(dst->multiplier != src->multiplier)) {
	/* Fail because these histograms don't match */
	return 0;
	}
	grpc_histogram_merge_contents(dst, src->buckets, src->num_buckets,
	src->min_seen, src->max_seen, src->sum,
	src->sum_of_squares, src->count);
	return 1;
	}

	void grpc_histogram_merge_contents(grpc_histogram* dst, const uint32_t* data,
	size_t data_count, double min_seen,
	double max_seen, double sum,
	double sum_of_squares, double count) {
	size_t i;
	GPR_ASSERT(dst->num_buckets == data_count);
	dst->sum += sum;
	dst->sum_of_squares += sum_of_squares;
	dst->count += count;
	if (min_seen < dst->min_seen) {
	dst->min_seen = min_seen;
	}
	if (max_seen > dst->max_seen) {
	dst->max_seen = max_seen;
	}
	for (i = 0; i < dst->num_buckets; i++) {
	dst->buckets[i] += data[i];
	}
	}

	static double threshold_for_count_below(grpc_histogram* h, double count_below) {
	double count_so_far;
	double lower_bound;
	double upper_bound;
	size_t lower_idx;
	size_t upper_idx;

	if (h->count == 0) {
	return 0.0;
	}

	if (count_below <= 0) {
	return h->min_seen;
	}
	if (count_below >= h->count) {
	return h->max_seen;
	}

	/* find the lowest bucket that gets us above count_below */
	count_so_far = 0.0;
	for (lower_idx = 0; lower_idx < h->num_buckets; lower_idx++) {
	count_so_far += h->buckets[lower_idx];
	if (count_so_far >= count_below) {
	break;
	}
	}
	if (count_so_far == count_below) {
	/* this bucket hits the threshold exactly... we should be midway through
	any run of zero values following the bucket */
	for (upper_idx = lower_idx + 1; upper_idx < h->num_buckets; upper_idx++) {
	if (h->buckets[upper_idx]) {
	break;
	}
	}
	return (bucket_start(h, static_cast<double>(lower_idx)) +
	bucket_start(h, static_cast<double>(upper_idx))) /
	2.0;
	} else {
	/* treat values as uniform throughout the bucket, and find where this value
	should lie */
	lower_bound = bucket_start(h, static_cast<double>(lower_idx));
	upper_bound = bucket_start(h, static_cast<double>(lower_idx + 1));
	return GPR_CLAMP(upper_bound - (upper_bound - lower_bound) *
	(count_so_far - count_below) /
	h->buckets[lower_idx],
	h->min_seen, h->max_seen);
	}
	}

	double grpc_histogram_percentile(grpc_histogram* h, double percentile) {
	return threshold_for_count_below(h, h->count * percentile / 100.0);
	}

	double grpc_histogram_mean(grpc_histogram* h) {
	GPR_ASSERT(h->count != 0);
	return h->sum / h->count;
	}

	double grpc_histogram_stddev(grpc_histogram* h) {
	return sqrt(grpc_histogram_variance(h));
	}

	double grpc_histogram_variance(grpc_histogram* h) {
	if (h->count == 0) return 0.0;
	return (h->sum_of_squares * h->count - h->sum * h->sum) /
	(h->count * h->count);
	}

	double grpc_histogram_maximum(grpc_histogram* h) { return h->max_seen; }

	double grpc_histogram_minimum(grpc_histogram* h) { return h->min_seen; }

	double grpc_histogram_count(grpc_histogram* h) { return h->count; }

	double grpc_histogram_sum(grpc_histogram* h) { return h->sum; }

	double grpc_histogram_sum_of_squares(grpc_histogram* h) {
	return h->sum_of_squares;
	}

	const uint32_t* grpc_histogram_get_contents(grpc_histogram* h, size_t* size) {
	*size = h->num_buckets;
	return h->buckets;
	}