Mercurial > hg > nginx
view src/core/ngx_crypt.c @ 6806:75dbab4ea930
Events: improved error event handling for UDP sockets.
Normally, the epoll module calls the read and write handlers depending
on whether EPOLLIN and EPOLLOUT are reported by epoll_wait(). No error
processing is done in the module, the handlers are expected to get an
error when doing I/O.
If an error event is reported without EPOLLIN and EPOLLOUT, the module
set both EPOLLIN and EPOLLOUT to ensure the error event is handled at
least in one active handler.
This works well unless the error is delivered along with only one of
EPOLLIN or EPOLLOUT, and the corresponding handler does not do any I/O.
For example, it happened when getting EPOLLERR|EPOLLOUT from
epoll_wait() upon receiving "ICMP port unreachable" while proxying UDP.
As the write handler had nothing to send it was not able to detect and
log an error, and did not switch to the next upstream.
The fix is to unconditionally set EPOLLIN and EPOLLOUT in case of an
error event. In the aforementioned case, this causes the read handler
to be called which does recv() and detects an error.
In addition to the epoll module, analogous changes were made in
devpoll/eventport/poll.
| author | Dmitry Volyntsev <xeioex@nginx.com> |
|---|---|
| date | Mon, 21 Nov 2016 16:03:42 +0300 |
| parents | 1064ea81ed3a |
| children |
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> #include <ngx_sha1.h> #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); 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); 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); } 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); } /* 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; } 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_CRYPT */