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view src/core/ngx_crypt.c @ 6250:0256738454dc

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Increased the default number of output buffers. Since an output buffer can only be used for either reading or sending, small amounts of data left from the previous operation (due to some limits) must be sent before nginx will be able to read further into the buffer. Using only one output buffer can result in suboptimal behavior that manifests itself in forming and sending too small chunks of data. This is particularly painful with SPDY (or HTTP/2) where each such chunk needs to be prefixed with some header. The default flow-control window in HTTP/2 is 64k minus one bytes. With one 32k output buffer this results is one byte left after exhausting the window. With two 32k buffers the data will be read into the second free buffer before sending, thus the minimum output is increased to 32k + 1 bytes which is much better.
author Valentin Bartenev <vbart@nginx.com>
date Tue, 15 Sep 2015 17:49:15 +0300
parents 58956c644ad0
children 2cd019520210
line wrap: on
line source


/*
 * Copyright (C) Maxim Dounin
 */


#include <ngx_config.h>
#include <ngx_core.h>
#include <ngx_crypt.h>
#include <ngx_md5.h>
#if (NGX_HAVE_SHA1)
#include <ngx_sha1.h>
#endif


#if (NGX_CRYPT)

static ngx_int_t ngx_crypt_apr1(ngx_pool_t *pool, u_char *key, u_char *salt,
    u_char **encrypted);
static ngx_int_t ngx_crypt_plain(ngx_pool_t *pool, u_char *key, u_char *salt,
    u_char **encrypted);

#if (NGX_HAVE_SHA1)

static ngx_int_t ngx_crypt_ssha(ngx_pool_t *pool, u_char *key, u_char *salt,
    u_char **encrypted);
static ngx_int_t ngx_crypt_sha(ngx_pool_t *pool, u_char *key, u_char *salt,
    u_char **encrypted);

#endif


static u_char *ngx_crypt_to64(u_char *p, uint32_t v, size_t n);


ngx_int_t
ngx_crypt(ngx_pool_t *pool, u_char *key, u_char *salt, u_char **encrypted)
{
    if (ngx_strncmp(salt, "$apr1$", sizeof("$apr1$") - 1) == 0) {
        return ngx_crypt_apr1(pool, key, salt, encrypted);

    } else if (ngx_strncmp(salt, "{PLAIN}", sizeof("{PLAIN}") - 1) == 0) {
        return ngx_crypt_plain(pool, key, salt, encrypted);

#if (NGX_HAVE_SHA1)
    } else if (ngx_strncmp(salt, "{SSHA}", sizeof("{SSHA}") - 1) == 0) {
        return ngx_crypt_ssha(pool, key, salt, encrypted);

    } else if (ngx_strncmp(salt, "{SHA}", sizeof("{SHA}") - 1) == 0) {
        return ngx_crypt_sha(pool, key, salt, encrypted);
#endif
    }

    /* fallback to libc crypt() */

    return ngx_libc_crypt(pool, key, salt, encrypted);
}


static ngx_int_t
ngx_crypt_apr1(ngx_pool_t *pool, u_char *key, u_char *salt, u_char **encrypted)
{
    ngx_int_t          n;
    ngx_uint_t         i;
    u_char            *p, *last, final[16];
    size_t             saltlen, keylen;
    ngx_md5_t          md5, ctx1;

    /* Apache's apr1 crypt is Poul-Henning Kamp's md5 crypt with $apr1$ magic */

    keylen = ngx_strlen(key);

    /* true salt: no magic, max 8 chars, stop at first $ */

    salt += sizeof("$apr1$") - 1;
    last = salt + 8;
    for (p = salt; *p && *p != '$' && p < last; p++) { /* void */ }
    saltlen = p - salt;

    /* hash key and salt */

    ngx_md5_init(&md5);
    ngx_md5_update(&md5, key, keylen);
    ngx_md5_update(&md5, (u_char *) "$apr1$", sizeof("$apr1$") - 1);
    ngx_md5_update(&md5, salt, saltlen);

    ngx_md5_init(&ctx1);
    ngx_md5_update(&ctx1, key, keylen);
    ngx_md5_update(&ctx1, salt, saltlen);
    ngx_md5_update(&ctx1, key, keylen);
    ngx_md5_final(final, &ctx1);

    for (n = keylen; n > 0; n -= 16) {
        ngx_md5_update(&md5, final, n > 16 ? 16 : n);
    }

    ngx_memzero(final, sizeof(final));

    for (i = keylen; i; i >>= 1) {
        if (i & 1) {
            ngx_md5_update(&md5, final, 1);

        } else {
            ngx_md5_update(&md5, key, 1);
        }
    }

    ngx_md5_final(final, &md5);

    for (i = 0; i < 1000; i++) {
        ngx_md5_init(&ctx1);

        if (i & 1) {
            ngx_md5_update(&ctx1, key, keylen);

        } else {
            ngx_md5_update(&ctx1, final, 16);
        }

        if (i % 3) {
            ngx_md5_update(&ctx1, salt, saltlen);
        }

        if (i % 7) {
            ngx_md5_update(&ctx1, key, keylen);
        }

        if (i & 1) {
            ngx_md5_update(&ctx1, final, 16);

        } else {
            ngx_md5_update(&ctx1, key, keylen);
        }

        ngx_md5_final(final, &ctx1);
    }

    /* output */

    *encrypted = ngx_pnalloc(pool, sizeof("$apr1$") - 1 + saltlen + 1 + 22 + 1);
    if (*encrypted == NULL) {
        return NGX_ERROR;
    }

    p = ngx_cpymem(*encrypted, "$apr1$", sizeof("$apr1$") - 1);
    p = ngx_copy(p, salt, saltlen);
    *p++ = '$';

    p = ngx_crypt_to64(p, (final[ 0]<<16) | (final[ 6]<<8) | final[12], 4);
    p = ngx_crypt_to64(p, (final[ 1]<<16) | (final[ 7]<<8) | final[13], 4);
    p = ngx_crypt_to64(p, (final[ 2]<<16) | (final[ 8]<<8) | final[14], 4);
    p = ngx_crypt_to64(p, (final[ 3]<<16) | (final[ 9]<<8) | final[15], 4);
    p = ngx_crypt_to64(p, (final[ 4]<<16) | (final[10]<<8) | final[ 5], 4);
    p = ngx_crypt_to64(p, final[11], 2);
    *p = '\0';

    return NGX_OK;
}


static u_char *
ngx_crypt_to64(u_char *p, uint32_t v, size_t n)
{
    static u_char   itoa64[] =
        "./0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz";

    while (n--) {
       *p++ = itoa64[v & 0x3f];
       v >>= 6;
    }

    return p;
}


static ngx_int_t
ngx_crypt_plain(ngx_pool_t *pool, u_char *key, u_char *salt, u_char **encrypted)
{
    size_t   len;
    u_char  *p;

    len = ngx_strlen(key);

    *encrypted = ngx_pnalloc(pool, sizeof("{PLAIN}") - 1 + len + 1);
    if (*encrypted == NULL) {
        return NGX_ERROR;
    }

    p = ngx_cpymem(*encrypted, "{PLAIN}", sizeof("{PLAIN}") - 1);
    ngx_memcpy(p, key, len + 1);

    return NGX_OK;
}


#if (NGX_HAVE_SHA1)

static ngx_int_t
ngx_crypt_ssha(ngx_pool_t *pool, u_char *key, u_char *salt, u_char **encrypted)
{
    size_t       len;
    ngx_int_t    rc;
    ngx_str_t    encoded, decoded;
    ngx_sha1_t   sha1;

    /* "{SSHA}" base64(SHA1(key salt) salt) */

    /* decode base64 salt to find out true salt */

    encoded.data = salt + sizeof("{SSHA}") - 1;
    encoded.len = ngx_strlen(encoded.data);

    len = ngx_max(ngx_base64_decoded_length(encoded.len), 20);

    decoded.data = ngx_pnalloc(pool, len);
    if (decoded.data == NULL) {
        return NGX_ERROR;
    }

    rc = ngx_decode_base64(&decoded, &encoded);

    if (rc != NGX_OK || decoded.len < 20) {
        decoded.len = 20;
    }

    /* update SHA1 from key and salt */

    ngx_sha1_init(&sha1);
    ngx_sha1_update(&sha1, key, ngx_strlen(key));
    ngx_sha1_update(&sha1, decoded.data + 20, decoded.len - 20);
    ngx_sha1_final(decoded.data, &sha1);

    /* encode it back to base64 */

    len = sizeof("{SSHA}") - 1 + ngx_base64_encoded_length(decoded.len) + 1;

    *encrypted = ngx_pnalloc(pool, len);
    if (*encrypted == NULL) {
        return NGX_ERROR;
    }

    encoded.data = ngx_cpymem(*encrypted, "{SSHA}", sizeof("{SSHA}") - 1);
    ngx_encode_base64(&encoded, &decoded);
    encoded.data[encoded.len] = '\0';

    return NGX_OK;
}


static ngx_int_t
ngx_crypt_sha(ngx_pool_t *pool, u_char *key, u_char *salt, u_char **encrypted)
{
    size_t      len;
    ngx_str_t   encoded, decoded;
    ngx_sha1_t  sha1;
    u_char      digest[20];

    /* "{SHA}" base64(SHA1(key)) */

    decoded.len = sizeof(digest);
    decoded.data = digest;

    ngx_sha1_init(&sha1);
    ngx_sha1_update(&sha1, key, ngx_strlen(key));
    ngx_sha1_final(digest, &sha1);

    len = sizeof("{SHA}") - 1 + ngx_base64_encoded_length(decoded.len) + 1;

    *encrypted = ngx_pnalloc(pool, len);
    if (*encrypted == NULL) {
        return NGX_ERROR;
    }

    encoded.data = ngx_cpymem(*encrypted, "{SHA}", sizeof("{SHA}") - 1);
    ngx_encode_base64(&encoded, &decoded);
    encoded.data[encoded.len] = '\0';

    return NGX_OK;
}

#endif /* NGX_HAVE_SHA1 */

#endif /* NGX_CRYPT */