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HTTP/2: always use temporary pool for processing headers. This is required for implementing per request timeouts. Previously, the temporary pool was used only during skipping of headers and the request pool was used otherwise. That required switching of pools if the request was closed while parsing. It wasn't a problem since the request could be closed only after the validation of the fully parsed header. With the per request timeouts, the request can be closed at any moment, and switching of pools in the middle of parsing header name or value becomes a problem. To overcome this, the temporary pool is now always created and used. Special checks are added to keep it when either the stream is being processed or until header block is fully parsed.
author Valentin Bartenev <vbart@nginx.com>
date Wed, 24 Feb 2016 16:05:47 +0300
parents 4fef8ed52389
children
line wrap: on
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/*
 * Copyright (C) Igor Sysoev
 * Copyright (C) Nginx, Inc.
 */


#include <ngx_config.h>
#include <ngx_core.h>


ngx_array_t *
ngx_array_create(ngx_pool_t *p, ngx_uint_t n, size_t size)
{
    ngx_array_t *a;

    a = ngx_palloc(p, sizeof(ngx_array_t));
    if (a == NULL) {
        return NULL;
    }

    if (ngx_array_init(a, p, n, size) != NGX_OK) {
        return NULL;
    }

    return a;
}


void
ngx_array_destroy(ngx_array_t *a)
{
    ngx_pool_t  *p;

    p = a->pool;

    if ((u_char *) a->elts + a->size * a->nalloc == p->d.last) {
        p->d.last -= a->size * a->nalloc;
    }

    if ((u_char *) a + sizeof(ngx_array_t) == p->d.last) {
        p->d.last = (u_char *) a;
    }
}


void *
ngx_array_push(ngx_array_t *a)
{
    void        *elt, *new;
    size_t       size;
    ngx_pool_t  *p;

    if (a->nelts == a->nalloc) {

        /* the array is full */

        size = a->size * a->nalloc;

        p = a->pool;

        if ((u_char *) a->elts + size == p->d.last
            && p->d.last + a->size <= p->d.end)
        {
            /*
             * the array allocation is the last in the pool
             * and there is space for new allocation
             */

            p->d.last += a->size;
            a->nalloc++;

        } else {
            /* allocate a new array */

            new = ngx_palloc(p, 2 * size);
            if (new == NULL) {
                return NULL;
            }

            ngx_memcpy(new, a->elts, size);
            a->elts = new;
            a->nalloc *= 2;
        }
    }

    elt = (u_char *) a->elts + a->size * a->nelts;
    a->nelts++;

    return elt;
}


void *
ngx_array_push_n(ngx_array_t *a, ngx_uint_t n)
{
    void        *elt, *new;
    size_t       size;
    ngx_uint_t   nalloc;
    ngx_pool_t  *p;

    size = n * a->size;

    if (a->nelts + n > a->nalloc) {

        /* the array is full */

        p = a->pool;

        if ((u_char *) a->elts + a->size * a->nalloc == p->d.last
            && p->d.last + size <= p->d.end)
        {
            /*
             * the array allocation is the last in the pool
             * and there is space for new allocation
             */

            p->d.last += size;
            a->nalloc += n;

        } else {
            /* allocate a new array */

            nalloc = 2 * ((n >= a->nalloc) ? n : a->nalloc);

            new = ngx_palloc(p, nalloc * a->size);
            if (new == NULL) {
                return NULL;
            }

            ngx_memcpy(new, a->elts, a->nelts * a->size);
            a->elts = new;
            a->nalloc = nalloc;
        }
    }

    elt = (u_char *) a->elts + a->size * a->nelts;
    a->nelts += n;

    return elt;
}