blob: df224b1b2437e8e8e47c15478f916d8c79183014 [file] [log] [blame]
/*
* haproxy log statistics reporter
*
* Copyright 2000-2010 Willy Tarreau <w@1wt.eu>
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version
* 2 of the License, or (at your option) any later version.
*
*/
#include <errno.h>
#include <fcntl.h>
#include <stdio.h>
#include <stdlib.h>
#include <syslog.h>
#include <string.h>
#include <unistd.h>
#include <ctype.h>
#include <eb32tree.h>
#include <eb64tree.h>
#include <ebistree.h>
#include <ebsttree.h>
#define SOURCE_FIELD 5
#define ACCEPT_FIELD 6
#define SERVER_FIELD 8
#define TIME_FIELD 9
#define STATUS_FIELD 10
#define TERM_CODES_FIELD 14
#define CONN_FIELD 15
#define QUEUE_LEN_FIELD 16
#define METH_FIELD 17
#define URL_FIELD 18
#define MAXLINE 16384
#define QBITS 4
#define SEP(c) ((unsigned char)(c) <= ' ')
#define SKIP_CHAR(p,c) do { while (1) { int __c = (unsigned char)*p++; if (__c == c) break; if (__c <= ' ') { p--; break; } } } while (0)
/* [0] = err/date, [1] = req, [2] = conn, [3] = resp, [4] = data */
static struct eb_root timers[5] = {
EB_ROOT_UNIQUE, EB_ROOT_UNIQUE, EB_ROOT_UNIQUE,
EB_ROOT_UNIQUE, EB_ROOT_UNIQUE,
};
struct timer {
struct eb32_node node;
unsigned int count;
};
struct srv_st {
unsigned int st_cnt[6]; /* 0xx to 5xx */
unsigned int nb_ct, nb_rt, nb_ok;
unsigned long long cum_ct, cum_rt;
struct ebmb_node node;
/* don't put anything else here, the server name will be there */
};
struct url_stat {
union {
struct ebpt_node url;
struct eb64_node val;
} node;
char *url;
unsigned long long total_time; /* sum(all reqs' times) */
unsigned long long total_time_ok; /* sum(all OK reqs' times) */
unsigned int nb_err, nb_req;
};
#define FILT_COUNT_ONLY 0x01
#define FILT_INVERT 0x02
#define FILT_QUIET 0x04
#define FILT_ERRORS_ONLY 0x08
#define FILT_ACC_DELAY 0x10
#define FILT_ACC_COUNT 0x20
#define FILT_GRAPH_TIMERS 0x40
#define FILT_PERCENTILE 0x80
#define FILT_TIME_RESP 0x100
#define FILT_INVERT_ERRORS 0x200
#define FILT_INVERT_TIME_RESP 0x400
#define FILT_COUNT_STATUS 0x800
#define FILT_COUNT_SRV_STATUS 0x1000
#define FILT_COUNT_TERM_CODES 0x2000
#define FILT_COUNT_URL_ONLY 0x004000
#define FILT_COUNT_URL_COUNT 0x008000
#define FILT_COUNT_URL_ERR 0x010000
#define FILT_COUNT_URL_TTOT 0x020000
#define FILT_COUNT_URL_TAVG 0x040000
#define FILT_COUNT_URL_TTOTO 0x080000
#define FILT_COUNT_URL_TAVGO 0x100000
#define FILT_COUNT_URL_ANY (FILT_COUNT_URL_ONLY|FILT_COUNT_URL_COUNT|FILT_COUNT_URL_ERR| \
FILT_COUNT_URL_TTOT|FILT_COUNT_URL_TAVG|FILT_COUNT_URL_TTOTO|FILT_COUNT_URL_TAVGO)
#define FILT_HTTP_ONLY 0x200000
#define FILT_TERM_CODE_NAME 0x400000
#define FILT_INVERT_TERM_CODE_NAME 0x800000
#define FILT_HTTP_STATUS 0x1000000
#define FILT_INVERT_HTTP_STATUS 0x2000000
#define FILT_QUEUE_ONLY 0x4000000
#define FILT_QUEUE_SRV_ONLY 0x8000000
unsigned int filter = 0;
unsigned int filter_invert = 0;
const char *line;
int linenum = 0;
int parse_err = 0;
int lines_out = 0;
const char *fgets2(FILE *stream);
void filter_count_url(const char *accept_field, const char *time_field, struct timer **tptr);
void filter_count_srv_status(const char *accept_field, const char *time_field, struct timer **tptr);
void filter_count_term_codes(const char *accept_field, const char *time_field, struct timer **tptr);
void filter_count_status(const char *accept_field, const char *time_field, struct timer **tptr);
void filter_graphs(const char *accept_field, const char *time_field, struct timer **tptr);
void filter_output_line(const char *accept_field, const char *time_field, struct timer **tptr);
void filter_accept_holes(const char *accept_field, const char *time_field, struct timer **tptr);
void die(const char *msg)
{
fprintf(stderr,
"%s"
"Usage: halog [-q] [-c] [-v] {-gt|-pct|-st|-tc|-srv|-u|-uc|-ue|-ua|-ut|-uao|-uto}\n"
" [-s <skip>] [-e|-E] [-H] [-rt|-RT <time>] [-ad <delay>] [-ac <count>]\n"
" [-Q|-QS] [-tcn|-TCN <termcode>] [ -hs|-HS [min][:[max]] ] < log\n"
"\n",
msg ? msg : ""
);
exit(1);
}
/* return pointer to first char not part of current field starting at <p>. */
#if defined(__i386__)
/* this one is always faster on 32-bits */
static inline const char *field_stop(const char *p)
{
asm(
/* Look for spaces */
"4: \n\t"
"inc %0 \n\t"
"cmpb $0x20, -1(%0) \n\t"
"ja 4b \n\t"
"jz 3f \n\t"
/* we only get there for control chars 0..31. Leave if we find '\0' */
"cmpb $0x0, -1(%0) \n\t"
"jnz 4b \n\t"
/* return %0-1 = position of the last char we checked */
"3: \n\t"
"dec %0 \n\t"
: "=r" (p)
: "0" (p)
);
return p;
}
#else
const char *field_stop(const char *p)
{
unsigned char c;
while (1) {
c = *(p++);
if (c > ' ')
continue;
if (c == ' ' || c == 0)
break;
}
return p - 1;
}
#endif
/* return field <field> (starting from 1) in string <p>. Only consider
* contiguous spaces (or tabs) as one delimiter. May return pointer to
* last char if field is not found. Equivalent to awk '{print $field}'.
*/
const char *field_start(const char *p, int field)
{
#ifndef PREFER_ASM
unsigned char c;
while (1) {
/* skip spaces */
while (1) {
c = *(p++);
if (c > ' ')
break;
if (c == ' ')
continue;
if (!c) /* end of line */
return p-1;
/* other char => new field */
break;
}
/* start of field */
field--;
if (!field)
return p-1;
/* skip this field */
while (1) {
c = *(p++);
if (c == ' ')
break;
if (c > ' ')
continue;
if (c == '\0')
return p - 1;
}
}
#else
/* This version works optimally on i386 and x86_64 but the code above
* shows similar performance. However, depending on the version of GCC
* used, inlining rules change and it may have difficulties to make
* efficient use of this code at other locations and could result in
* worse performance (eg: gcc 4.4). You may want to experience.
*/
asm(
/* skip spaces */
"1: \n\t"
"inc %0 \n\t"
"cmpb $0x20, -1(%0) \n\t"
"ja 2f \n\t"
"jz 1b \n\t"
/* we only get there for control chars 0..31. Leave if we find '\0' */
"cmpb $0x0, -1(%0) \n\t"
"jz 3f \n\t"
/* start of field at [%0-1]. Check if we need to skip more fields */
"2: \n\t"
"dec %1 \n\t"
"jz 3f \n\t"
/* Look for spaces */
"4: \n\t"
"inc %0 \n\t"
"cmpb $0x20, -1(%0) \n\t"
"jz 1b \n\t"
"ja 4b \n\t"
/* we only get there for control chars 0..31. Leave if we find '\0' */
"cmpb $0x0, -1(%0) \n\t"
"jnz 4b \n\t"
/* return %0-1 = position of the last char we checked */
"3: \n\t"
"dec %0 \n\t"
: "=r" (p)
: "r" (field), "0" (p)
);
return p;
#endif
}
/* keep only the <bits> higher bits of <i> */
static inline unsigned int quantify_u32(unsigned int i, int bits)
{
int high;
if (!bits)
return 0;
if (i)
high = fls_auto(i); // 1 to 32
else
high = 0;
if (high <= bits)
return i;
return i & ~((1 << (high - bits)) - 1);
}
/* keep only the <bits> higher bits of the absolute value of <i>, as well as
* its sign. */
static inline int quantify(int i, int bits)
{
if (i >= 0)
return quantify_u32(i, bits);
else
return -quantify_u32(-i, bits);
}
/* Insert timer value <v> into tree <r>. A pre-allocated node must be passed
* in <alloc>. It may be NULL, in which case the function will allocate it
* itself. It will be reset to NULL once consumed. The caller is responsible
* for freeing the node once not used anymore. The node where the value was
* inserted is returned.
*/
struct timer *insert_timer(struct eb_root *r, struct timer **alloc, int v)
{
struct timer *t = *alloc;
struct eb32_node *n;
if (!t) {
t = calloc(sizeof(*t), 1);
if (unlikely(!t)) {
fprintf(stderr, "%s: not enough memory\n", __FUNCTION__);
exit(1);
}
}
t->node.key = quantify(v, QBITS); // keep only the higher QBITS bits
n = eb32i_insert(r, &t->node);
if (n == &t->node)
t = NULL; /* node inserted, will malloc next time */
*alloc = t;
return container_of(n, struct timer, node);
}
/* Insert value value <v> into tree <r>. A pre-allocated node must be passed
* in <alloc>. It may be NULL, in which case the function will allocate it
* itself. It will be reset to NULL once consumed. The caller is responsible
* for freeing the node once not used anymore. The node where the value was
* inserted is returned.
*/
struct timer *insert_value(struct eb_root *r, struct timer **alloc, int v)
{
struct timer *t = *alloc;
struct eb32_node *n;
if (!t) {
t = calloc(sizeof(*t), 1);
if (unlikely(!t)) {
fprintf(stderr, "%s: not enough memory\n", __FUNCTION__);
exit(1);
}
}
t->node.key = v;
n = eb32i_insert(r, &t->node);
if (n == &t->node)
t = NULL; /* node inserted, will malloc next time */
*alloc = t;
return container_of(n, struct timer, node);
}
int str2ic(const char *s)
{
int i = 0;
int j, k;
if (*s != '-') {
/* positive number */
while (1) {
j = (*s++) - '0';
k = i * 10;
if ((unsigned)j > 9)
break;
i = k + j;
}
} else {
/* negative number */
s++;
while (1) {
j = (*s++) - '0';
k = i * 10;
if ((unsigned)j > 9)
break;
i = k - j;
}
}
return i;
}
/* Equivalent to strtoul with a length. */
static inline unsigned int __strl2ui(const char *s, int len)
{
unsigned int i = 0;
while (len-- > 0) {
i = i * 10 - '0';
i += (unsigned char)*s++;
}
return i;
}
unsigned int strl2ui(const char *s, int len)
{
return __strl2ui(s, len);
}
/* Convert "[04/Dec/2008:09:49:40.555]" to an integer equivalent to the time of
* the day in milliseconds. It returns -1 for all unparsable values. The parser
* looks ugly but gcc emits far better code that way.
*/
int convert_date(const char *field)
{
unsigned int h, m, s, ms;
unsigned char c;
const char *b, *e;
h = m = s = ms = 0;
e = field;
/* skip the date */
while (1) {
c = *(e++);
if (c == ':')
break;
if (!c)
goto out_err;
}
/* hour + ':' */
b = e;
while (1) {
c = *(e++) - '0';
if (c > 9)
break;
h = h * 10 + c;
}
if (c == (unsigned char)(0 - '0'))
goto out_err;
/* minute + ':' */
b = e;
while (1) {
c = *(e++) - '0';
if (c > 9)
break;
m = m * 10 + c;
}
if (c == (unsigned char)(0 - '0'))
goto out_err;
/* second + '.' or ']' */
b = e;
while (1) {
c = *(e++) - '0';
if (c > 9)
break;
s = s * 10 + c;
}
if (c == (unsigned char)(0 - '0'))
goto out_err;
/* if there's a '.', we have milliseconds */
if (c == (unsigned char)('.' - '0')) {
/* millisecond second + ']' */
b = e;
while (1) {
c = *(e++) - '0';
if (c > 9)
break;
ms = ms * 10 + c;
}
if (c == (unsigned char)(0 - '0'))
goto out_err;
}
return (((h * 60) + m) * 60 + s) * 1000 + ms;
out_err:
return -1;
}
void truncated_line(int linenum, const char *line)
{
if (!(filter & FILT_QUIET))
fprintf(stderr, "Truncated line %d: %s\n", linenum, line);
}
int main(int argc, char **argv)
{
const char *b, *e, *p, *time_field, *accept_field;
const char *filter_term_code_name = NULL;
const char *output_file = NULL;
int f, last, err;
struct timer *t = NULL;
struct eb32_node *n;
struct url_stat *ustat = NULL;
int val, test;
int filter_acc_delay = 0, filter_acc_count = 0;
int filter_time_resp = 0;
int filt_http_status_low = 0, filt_http_status_high = 0;
int skip_fields = 1;
void (*line_filter)(const char *accept_field, const char *time_field, struct timer **tptr) = NULL;
argc--; argv++;
while (argc > 0) {
if (*argv[0] != '-')
break;
if (strcmp(argv[0], "-ad") == 0) {
if (argc < 2) die("missing option for -ad");
argc--; argv++;
filter |= FILT_ACC_DELAY;
filter_acc_delay = atol(*argv);
}
else if (strcmp(argv[0], "-ac") == 0) {
if (argc < 2) die("missing option for -ac");
argc--; argv++;
filter |= FILT_ACC_COUNT;
filter_acc_count = atol(*argv);
}
else if (strcmp(argv[0], "-rt") == 0) {
if (argc < 2) die("missing option for -rt");
argc--; argv++;
filter |= FILT_TIME_RESP;
filter_time_resp = atol(*argv);
}
else if (strcmp(argv[0], "-RT") == 0) {
if (argc < 2) die("missing option for -RT");
argc--; argv++;
filter |= FILT_TIME_RESP | FILT_INVERT_TIME_RESP;
filter_time_resp = atol(*argv);
}
else if (strcmp(argv[0], "-s") == 0) {
if (argc < 2) die("missing option for -s");
argc--; argv++;
skip_fields = atol(*argv);
}
else if (strcmp(argv[0], "-e") == 0)
filter |= FILT_ERRORS_ONLY;
else if (strcmp(argv[0], "-E") == 0)
filter |= FILT_ERRORS_ONLY | FILT_INVERT_ERRORS;
else if (strcmp(argv[0], "-H") == 0)
filter |= FILT_HTTP_ONLY;
else if (strcmp(argv[0], "-Q") == 0)
filter |= FILT_QUEUE_ONLY;
else if (strcmp(argv[0], "-QS") == 0)
filter |= FILT_QUEUE_SRV_ONLY;
else if (strcmp(argv[0], "-c") == 0)
filter |= FILT_COUNT_ONLY;
else if (strcmp(argv[0], "-q") == 0)
filter |= FILT_QUIET;
else if (strcmp(argv[0], "-v") == 0)
filter_invert = !filter_invert;
else if (strcmp(argv[0], "-gt") == 0)
filter |= FILT_GRAPH_TIMERS;
else if (strcmp(argv[0], "-pct") == 0)
filter |= FILT_PERCENTILE;
else if (strcmp(argv[0], "-st") == 0)
filter |= FILT_COUNT_STATUS;
else if (strcmp(argv[0], "-srv") == 0)
filter |= FILT_COUNT_SRV_STATUS;
else if (strcmp(argv[0], "-tc") == 0)
filter |= FILT_COUNT_TERM_CODES;
else if (strcmp(argv[0], "-tcn") == 0) {
if (argc < 2) die("missing option for -tcn");
argc--; argv++;
filter |= FILT_TERM_CODE_NAME;
filter_term_code_name = *argv;
}
else if (strcmp(argv[0], "-TCN") == 0) {
if (argc < 2) die("missing option for -TCN");
argc--; argv++;
filter |= FILT_TERM_CODE_NAME | FILT_INVERT_TERM_CODE_NAME;
filter_term_code_name = *argv;
}
else if (strcmp(argv[0], "-hs") == 0 || strcmp(argv[0], "-HS") == 0) {
char *sep, *str;
if (argc < 2) die("missing option for -hs/-HS ([min]:[max])");
filter |= FILT_HTTP_STATUS;
if (argv[0][1] == 'H')
filter |= FILT_INVERT_HTTP_STATUS;
argc--; argv++;
str = *argv;
sep = strchr(str, ':'); /* [min]:[max] */
if (!sep)
sep = str; /* make max point to min */
else
*sep++ = 0;
filt_http_status_low = *str ? atol(str) : 0;
filt_http_status_high = *sep ? atol(sep) : 65535;
}
else if (strcmp(argv[0], "-u") == 0)
filter |= FILT_COUNT_URL_ONLY;
else if (strcmp(argv[0], "-uc") == 0)
filter |= FILT_COUNT_URL_COUNT;
else if (strcmp(argv[0], "-ue") == 0)
filter |= FILT_COUNT_URL_ERR;
else if (strcmp(argv[0], "-ua") == 0)
filter |= FILT_COUNT_URL_TAVG;
else if (strcmp(argv[0], "-ut") == 0)
filter |= FILT_COUNT_URL_TTOT;
else if (strcmp(argv[0], "-uao") == 0)
filter |= FILT_COUNT_URL_TAVGO;
else if (strcmp(argv[0], "-uto") == 0)
filter |= FILT_COUNT_URL_TTOTO;
else if (strcmp(argv[0], "-o") == 0) {
if (output_file)
die("Fatal: output file name already specified.\n");
if (argc < 2)
die("Fatal: missing output file name.\n");
output_file = argv[1];
}
argc--;
argv++;
}
if (!filter)
die("No action specified.\n");
if (filter & FILT_ACC_COUNT && !filter_acc_count)
filter_acc_count=1;
if (filter & FILT_ACC_DELAY && !filter_acc_delay)
filter_acc_delay = 1;
/* by default, all lines are printed */
line_filter = filter_output_line;
if (filter & (FILT_ACC_COUNT|FILT_ACC_DELAY))
line_filter = filter_accept_holes;
else if (filter & (FILT_GRAPH_TIMERS|FILT_PERCENTILE))
line_filter = filter_graphs;
else if (filter & FILT_COUNT_STATUS)
line_filter = filter_count_status;
else if (filter & FILT_COUNT_TERM_CODES)
line_filter = filter_count_term_codes;
else if (filter & FILT_COUNT_SRV_STATUS)
line_filter = filter_count_srv_status;
else if (filter & FILT_COUNT_URL_ANY)
line_filter = filter_count_url;
else if (filter & FILT_COUNT_ONLY)
line_filter = NULL;
while ((line = fgets2(stdin)) != NULL) {
linenum++;
time_field = NULL; accept_field = NULL;
test = 1;
/* for any line we process, we first ensure that there is a field
* looking like the accept date field (beginning with a '[').
*/
accept_field = field_start(line, ACCEPT_FIELD + skip_fields);
if (unlikely(*accept_field != '[')) {
parse_err++;
continue;
}
/* the day of month field is begin 01 and 31 */
if (accept_field[1] < '0' || accept_field[1] > '3') {
parse_err++;
continue;
}
if (filter & FILT_HTTP_ONLY) {
/* only report lines with at least 4 timers */
if (!time_field) {
time_field = field_start(accept_field, TIME_FIELD - ACCEPT_FIELD + 1);
if (unlikely(!*time_field)) {
truncated_line(linenum, line);
continue;
}
}
e = field_stop(time_field + 1);
/* we have field TIME_FIELD in [time_field]..[e-1] */
p = time_field;
f = 0;
while (!SEP(*p)) {
if (++f == 4)
break;
SKIP_CHAR(p, '/');
}
test &= (f >= 4);
}
if (filter & FILT_TIME_RESP) {
int tps;
/* only report lines with response times larger than filter_time_resp */
if (!time_field) {
time_field = field_start(accept_field, TIME_FIELD - ACCEPT_FIELD + 1);
if (unlikely(!*time_field)) {
truncated_line(linenum, line);
continue;
}
}
e = field_stop(time_field + 1);
/* we have field TIME_FIELD in [time_field]..[e-1], let's check only the response time */
p = time_field;
err = 0;
f = 0;
while (!SEP(*p)) {
tps = str2ic(p);
if (tps < 0) {
tps = -1;
err = 1;
}
if (++f == 4)
break;
SKIP_CHAR(p, '/');
}
if (unlikely(f < 4)) {
parse_err++;
continue;
}
test &= (tps >= filter_time_resp) ^ !!(filter & FILT_INVERT_TIME_RESP);
}
if (filter & (FILT_ERRORS_ONLY | FILT_HTTP_STATUS)) {
/* Check both error codes (-1, 5xx) and status code ranges */
if (time_field)
b = field_start(time_field, STATUS_FIELD - TIME_FIELD + 1);
else
b = field_start(accept_field, STATUS_FIELD - ACCEPT_FIELD + 1);
if (unlikely(!*b)) {
truncated_line(linenum, line);
continue;
}
val = str2ic(b);
if (filter & FILT_ERRORS_ONLY)
test &= (val < 0 || (val >= 500 && val <= 599)) ^ !!(filter & FILT_INVERT_ERRORS);
if (filter & FILT_HTTP_STATUS)
test &= (val >= filt_http_status_low && val <= filt_http_status_high) ^ !!(filter & FILT_INVERT_HTTP_STATUS);
}
if (filter & (FILT_QUEUE_ONLY|FILT_QUEUE_SRV_ONLY)) {
/* Check if the server's queue is non-nul */
if (time_field)
b = field_start(time_field, QUEUE_LEN_FIELD - TIME_FIELD + 1);
else
b = field_start(accept_field, QUEUE_LEN_FIELD - ACCEPT_FIELD + 1);
if (unlikely(!*b)) {
truncated_line(linenum, line);
continue;
}
if (*b == '0') {
if (filter & FILT_QUEUE_SRV_ONLY) {
test = 0;
}
else {
do {
b++;
if (*b == '/') {
b++;
break;
}
} while (*b);
test &= ((unsigned char)(*b - '1') < 9);
}
}
}
if (filter & FILT_TERM_CODE_NAME) {
/* only report corresponding termination code name */
if (time_field)
b = field_start(time_field, TERM_CODES_FIELD - TIME_FIELD + 1);
else
b = field_start(accept_field, TERM_CODES_FIELD - ACCEPT_FIELD + 1);
if (unlikely(!*b)) {
truncated_line(linenum, line);
continue;
}
test &= (b[0] == filter_term_code_name[0] && b[1] == filter_term_code_name[1]) ^ !!(filter & FILT_INVERT_TERM_CODE_NAME);
}
test ^= filter_invert;
if (!test)
continue;
/************** here we process inputs *******************/
if (line_filter)
line_filter(accept_field, time_field, &t);
else
lines_out++; /* we're just counting lines */
}
/*****************************************************
* Here we've finished reading all input. Depending on the
* filters, we may still have some analysis to run on the
* collected data and to output data in a new format.
*************************************************** */
if (t)
free(t);
if (filter & FILT_COUNT_ONLY) {
printf("%d\n", lines_out);
exit(0);
}
if (filter & (FILT_ACC_COUNT|FILT_ACC_DELAY)) {
/* sort and count all timers. Output will look like this :
* <accept_date> <delta_ms from previous one> <nb entries>
*/
n = eb32_first(&timers[0]);
if (n)
last = n->key;
while (n) {
unsigned int d, h, m, s, ms;
t = container_of(n, struct timer, node);
h = n->key;
d = h - last;
last = h;
if (d >= filter_acc_delay && t->count >= filter_acc_count) {
ms = h % 1000; h = h / 1000;
s = h % 60; h = h / 60;
m = h % 60; h = h / 60;
lines_out++;
printf("%02d:%02d:%02d.%03d %d %d %d\n", h, m, s, ms, last, d, t->count);
}
n = eb32_next(n);
}
}
else if (filter & FILT_GRAPH_TIMERS) {
/* sort all timers */
for (f = 0; f < 5; f++) {
struct eb32_node *n;
int val;
val = 0;
n = eb32_first(&timers[f]);
while (n) {
int i;
double d;
t = container_of(n, struct timer, node);
last = n->key;
val = t->count;
i = (last < 0) ? -last : last;
i = fls_auto(i) - QBITS;
if (i > 0)
d = val / (double)(1 << i);
else
d = val;
if (d > 0.0) {
printf("%d %d %f\n", f, last, d+1.0);
lines_out++;
}
n = eb32_next(n);
}
}
}
else if (filter & FILT_PERCENTILE) {
/* report timers by percentile :
* <percent> <total> <max_req_time> <max_conn_time> <max_resp_time> <max_data_time>
* We don't count errs.
*/
struct eb32_node *n[5];
unsigned long cum[5];
double step;
if (!lines_out)
goto empty;
for (f = 1; f < 5; f++) {
n[f] = eb32_first(&timers[f]);
cum[f] = container_of(n[f], struct timer, node)->count;
}
for (step = 1; step <= 1000;) {
unsigned int thres = lines_out * (step / 1000.0);
printf("%3.1f %d ", step/10.0, thres);
for (f = 1; f < 5; f++) {
struct eb32_node *next;
while (cum[f] < thres) {
/* need to find other keys */
next = eb32_next(n[f]);
if (!next)
break;
n[f] = next;
cum[f] += container_of(next, struct timer, node)->count;
}
/* value still within $step % of total */
printf("%d ", n[f]->key);
}
putchar('\n');
if (step >= 100 && step < 900)
step += 50; // jump 5% by 5% between those steps.
else if (step >= 20 && step < 980)
step += 10;
else
step += 1;
}
}
else if (filter & FILT_COUNT_STATUS) {
/* output all statuses in the form of <status> <occurrences> */
n = eb32_first(&timers[0]);
while (n) {
t = container_of(n, struct timer, node);
printf("%d %d\n", n->key, t->count);
lines_out++;
n = eb32_next(n);
}
}
else if (filter & FILT_COUNT_SRV_STATUS) {
struct ebmb_node *srv_node;
struct srv_st *srv;
printf("#srv_name 1xx 2xx 3xx 4xx 5xx other tot_req req_ok pct_ok avg_ct avg_rt\n");
srv_node = ebmb_first(&timers[0]);
while (srv_node) {
int tot_rq;
srv = container_of(srv_node, struct srv_st, node);
tot_rq = 0;
for (f = 0; f <= 5; f++)
tot_rq += srv->st_cnt[f];
printf("%s %d %d %d %d %d %d %d %d %.1f %d %d\n",
srv_node->key, srv->st_cnt[1], srv->st_cnt[2],
srv->st_cnt[3], srv->st_cnt[4], srv->st_cnt[5], srv->st_cnt[0],
tot_rq,
srv->nb_ok, (double)srv->nb_ok * 100.0 / (tot_rq?tot_rq:1),
(int)(srv->cum_ct / (srv->nb_ct?srv->nb_ct:1)), (int)(srv->cum_rt / (srv->nb_rt?srv->nb_rt:1)));
srv_node = ebmb_next(srv_node);
lines_out++;
}
}
else if (filter & FILT_COUNT_TERM_CODES) {
/* output all statuses in the form of <code> <occurrences> */
n = eb32_first(&timers[0]);
while (n) {
t = container_of(n, struct timer, node);
printf("%c%c %d\n", (n->key >> 8), (n->key) & 255, t->count);
lines_out++;
n = eb32_next(n);
}
}
else if (filter & FILT_COUNT_URL_ANY) {
struct eb_node *node, *next;
if (!(filter & FILT_COUNT_URL_ONLY)) {
/* we have to sort on another criterion. We'll use timers[1] for the
* destination tree.
*/
timers[1] = EB_ROOT; /* reconfigure to accept duplicates */
for (node = eb_first(&timers[0]); node; node = next) {
next = eb_next(node);
eb_delete(node);
ustat = container_of(node, struct url_stat, node.url.node);
if (filter & FILT_COUNT_URL_COUNT)
ustat->node.val.key = ustat->nb_req;
else if (filter & FILT_COUNT_URL_ERR)
ustat->node.val.key = ustat->nb_err;
else if (filter & FILT_COUNT_URL_TTOT)
ustat->node.val.key = ustat->total_time;
else if (filter & FILT_COUNT_URL_TAVG)
ustat->node.val.key = ustat->nb_req ? ustat->total_time / ustat->nb_req : 0;
else if (filter & FILT_COUNT_URL_TTOTO)
ustat->node.val.key = ustat->total_time_ok;
else if (filter & FILT_COUNT_URL_TAVGO)
ustat->node.val.key = (ustat->nb_req - ustat->nb_err) ? ustat->total_time_ok / (ustat->nb_req - ustat->nb_err) : 0;
else
ustat->node.val.key = 0;
eb64_insert(&timers[1], &ustat->node.val);
}
/* switch trees */
timers[0] = timers[1];
}
printf("#req err ttot tavg oktot okavg url\n");
/* scan the tree in its reverse sorting order */
node = eb_last(&timers[0]);
while (node) {
ustat = container_of(node, struct url_stat, node.url.node);
printf("%d %d %Ld %Ld %Ld %Ld %s\n",
ustat->nb_req,
ustat->nb_err,
ustat->total_time,
ustat->nb_req ? ustat->total_time / ustat->nb_req : 0,
ustat->total_time_ok,
(ustat->nb_req - ustat->nb_err) ? ustat->total_time_ok / (ustat->nb_req - ustat->nb_err) : 0,
ustat->url);
node = eb_prev(node);
lines_out++;
}
}
empty:
if (!(filter & FILT_QUIET))
fprintf(stderr, "%d lines in, %d lines out, %d parsing errors\n",
linenum, lines_out, parse_err);
exit(0);
}
void filter_output_line(const char *accept_field, const char *time_field, struct timer **tptr)
{
puts(line);
lines_out++;
}
void filter_accept_holes(const char *accept_field, const char *time_field, struct timer **tptr)
{
struct timer *t2;
int val;
val = convert_date(accept_field);
if (unlikely(val < 0)) {
truncated_line(linenum, line);
return;
}
t2 = insert_value(&timers[0], tptr, val);
t2->count++;
lines_out++;
return;
}
void filter_count_status(const char *accept_field, const char *time_field, struct timer **tptr)
{
struct timer *t2;
const char *b;
int val;
if (time_field)
b = field_start(time_field, STATUS_FIELD - TIME_FIELD + 1);
else
b = field_start(accept_field, STATUS_FIELD - ACCEPT_FIELD + 1);
if (unlikely(!*b)) {
truncated_line(linenum, line);
return;
}
val = str2ic(b);
t2 = insert_value(&timers[0], tptr, val);
t2->count++;
}
void filter_count_term_codes(const char *accept_field, const char *time_field, struct timer **tptr)
{
struct timer *t2;
const char *b;
int val;
if (time_field)
b = field_start(time_field, TERM_CODES_FIELD - TIME_FIELD + 1);
else
b = field_start(accept_field, TERM_CODES_FIELD - ACCEPT_FIELD + 1);
if (unlikely(!*b)) {
truncated_line(linenum, line);
return;
}
val = 256 * b[0] + b[1];
t2 = insert_value(&timers[0], tptr, val);
t2->count++;
}
void filter_count_srv_status(const char *accept_field, const char *time_field, struct timer **tptr)
{
const char *b, *e, *p;
int f, err, array[5];
struct ebmb_node *srv_node;
struct srv_st *srv;
int val;
/* the server field is before the status field, so let's
* parse them in the proper order.
*/
b = field_start(accept_field, SERVER_FIELD - ACCEPT_FIELD + 1);
if (unlikely(!*b)) {
truncated_line(linenum, line);
return;
}
e = field_stop(b + 1); /* we have the server name in [b]..[e-1] */
/* the chance that a server name already exists is extremely high,
* so let's perform a normal lookup first.
*/
srv_node = ebst_lookup_len(&timers[0], b, e - b);
srv = container_of(srv_node, struct srv_st, node);
if (!srv_node) {
/* server not yet in the tree, let's create it */
srv = (void *)calloc(1, sizeof(struct srv_st) + e - b + 1);
srv_node = &srv->node;
memcpy(&srv_node->key, b, e - b);
srv_node->key[e - b] = '\0';
ebst_insert(&timers[0], srv_node);
}
/* let's collect the connect and response times */
if (!time_field) {
time_field = field_start(e, TIME_FIELD - SERVER_FIELD);
if (unlikely(!*time_field)) {
truncated_line(linenum, line);
return;
}
}
e = field_stop(time_field + 1);
/* we have field TIME_FIELD in [time_field]..[e-1] */
p = time_field;
err = 0;
f = 0;
while (!SEP(*p)) {
array[f] = str2ic(p);
if (array[f] < 0) {
array[f] = -1;
err = 1;
}
if (++f == 5)
break;
SKIP_CHAR(p, '/');
}
if (unlikely(f < 5)){
parse_err++;
return;
}
/* OK we have our timers in array[2,3] */
if (!err)
srv->nb_ok++;
if (array[2] >= 0) {
srv->cum_ct += array[2];
srv->nb_ct++;
}
if (array[3] >= 0) {
srv->cum_rt += array[3];
srv->nb_rt++;
}
/* we're interested in the 5 HTTP status classes (1xx ... 5xx), and
* the invalid ones which will be reported as 0.
*/
b = field_start(e, STATUS_FIELD - TIME_FIELD);
if (unlikely(!*b)) {
truncated_line(linenum, line);
return;
}
val = 0;
if (*b >= '1' && *b <= '5')
val = *b - '0';
srv->st_cnt[val]++;
}
void filter_count_url(const char *accept_field, const char *time_field, struct timer **tptr)
{
struct url_stat *ustat = NULL;
struct ebpt_node *ebpt_old;
const char *b, *e;
int f, err, array[5];
/* let's collect the response time */
if (!time_field) {
time_field = field_start(accept_field, TIME_FIELD - ACCEPT_FIELD + 1); // avg 115 ns per line
if (unlikely(!*time_field)) {
truncated_line(linenum, line);
return;
}
}
/* we have the field TIME_FIELD starting at <time_field>. We'll
* parse the 5 timers to detect errors, it takes avg 55 ns per line.
*/
e = time_field; err = 0; f = 0;
while (!SEP(*e)) {
array[f] = str2ic(e);
if (array[f] < 0) {
array[f] = -1;
err = 1;
}
if (++f == 5)
break;
SKIP_CHAR(e, '/');
}
if (f < 5) {
parse_err++;
return;
}
/* OK we have our timers in array[3], and err is >0 if at
* least one -1 was seen. <e> points to the first char of
* the last timer. Let's prepare a new node with that.
*/
if (unlikely(!ustat))
ustat = calloc(1, sizeof(*ustat));
ustat->nb_err = err;
ustat->nb_req = 1;
/* use array[4] = total time in case of error */
ustat->total_time = (array[3] >= 0) ? array[3] : array[4];
ustat->total_time_ok = (array[3] >= 0) ? array[3] : 0;
/* the line may be truncated because of a bad request or anything like this,
* without a method. Also, if it does not begin with an quote, let's skip to
* the next field because it's a capture. Let's fall back to the "method" itself
* if there's nothing else.
*/
e = field_start(e, METH_FIELD - TIME_FIELD + 1); // avg 100 ns per line
while (*e != '"' && *e) {
/* Note: some syslog servers escape quotes ! */
if (*e == '\\' && e[1] == '"')
break;
e = field_start(e, 2);
}
if (unlikely(!*e)) {
truncated_line(linenum, line);
return;
}
b = field_start(e, URL_FIELD - METH_FIELD + 1); // avg 40 ns per line
if (!*b)
b = e;
/* stop at end of field or first ';' or '?', takes avg 64 ns per line */
e = b;
do {
if (*e == ' ' || *e == '?' || *e == ';') {
*(char *)e = 0;
break;
}
e++;
} while (*e);
/* now instead of copying the URL for a simple lookup, we'll link
* to it from the node we're trying to insert. If it returns a
* different value, it was already there. Otherwise we just have
* to dynamically realloc an entry using strdup().
*/
ustat->node.url.key = (char *)b;
ebpt_old = ebis_insert(&timers[0], &ustat->node.url);
if (ebpt_old != &ustat->node.url) {
struct url_stat *ustat_old;
/* node was already there, let's update previous one */
ustat_old = container_of(ebpt_old, struct url_stat, node.url);
ustat_old->nb_req ++;
ustat_old->nb_err += ustat->nb_err;
ustat_old->total_time += ustat->total_time;
ustat_old->total_time_ok += ustat->total_time_ok;
} else {
ustat->url = ustat->node.url.key = strdup(ustat->node.url.key);
ustat = NULL; /* node was used */
}
}
void filter_graphs(const char *accept_field, const char *time_field, struct timer **tptr)
{
struct timer *t2;
const char *e, *p;
int f, err, array[5];
if (!time_field) {
time_field = field_start(accept_field, TIME_FIELD - ACCEPT_FIELD + 1);
if (unlikely(!*time_field)) {
truncated_line(linenum, line);
return;
}
}
e = field_stop(time_field + 1);
/* we have field TIME_FIELD in [time_field]..[e-1] */
p = time_field;
err = 0;
f = 0;
while (!SEP(*p)) {
array[f] = str2ic(p);
if (array[f] < 0) {
array[f] = -1;
err = 1;
}
if (++f == 5)
break;
SKIP_CHAR(p, '/');
}
if (unlikely(f < 5)) {
parse_err++;
return;
}
/* if we find at least one negative time, we count one error
* with a time equal to the total session time. This will
* emphasize quantum timing effects associated to known
* timeouts. Note that on some buggy machines, it is possible
* that the total time is negative, hence the reason to reset
* it.
*/
if (filter & FILT_GRAPH_TIMERS) {
if (err) {
if (array[4] < 0)
array[4] = -1;
t2 = insert_timer(&timers[0], tptr, array[4]); // total time
t2->count++;
} else {
int v;
t2 = insert_timer(&timers[1], tptr, array[0]); t2->count++; // req
t2 = insert_timer(&timers[2], tptr, array[2]); t2->count++; // conn
t2 = insert_timer(&timers[3], tptr, array[3]); t2->count++; // resp
v = array[4] - array[0] - array[1] - array[2] - array[3]; // data time
if (v < 0 && !(filter & FILT_QUIET))
fprintf(stderr, "ERR: %s (%d %d %d %d %d => %d)\n",
line, array[0], array[1], array[2], array[3], array[4], v);
t2 = insert_timer(&timers[4], tptr, v); t2->count++;
lines_out++;
}
} else { /* percentile */
if (err) {
if (array[4] < 0)
array[4] = -1;
t2 = insert_value(&timers[0], tptr, array[4]); // total time
t2->count++;
} else {
int v;
t2 = insert_value(&timers[1], tptr, array[0]); t2->count++; // req
t2 = insert_value(&timers[2], tptr, array[2]); t2->count++; // conn
t2 = insert_value(&timers[3], tptr, array[3]); t2->count++; // resp
v = array[4] - array[0] - array[1] - array[2] - array[3]; // data time
if (v < 0 && !(filter & FILT_QUIET))
fprintf(stderr, "ERR: %s (%d %d %d %d %d => %d)\n",
line, array[0], array[1], array[2], array[3], array[4], v);
t2 = insert_value(&timers[4], tptr, v); t2->count++;
lines_out++;
}
}
}
/*
* Local variables:
* c-indent-level: 8
* c-basic-offset: 8
* End:
*/