/* * Copyright 2001-2017 The OpenSSL Project Authors. All Rights Reserved. * * Licensed under the Apache License 2.0 (the "License"). You may not use * this file except in compliance with the License. You can obtain a copy * in the file LICENSE in the source distribution or at * https://www.openssl.org/source/license.html */ #include "e_os.h" #include #include #include "crypto/ctype.h" #include #include #include #include #include /* Stateful OCSP request code, supporting non-blocking I/O */ /* Opaque OCSP request status structure */ struct ocsp_req_ctx_st { int state; /* Current I/O state */ unsigned char *iobuf; /* Line buffer */ int iobuflen; /* Line buffer length */ BIO *io; /* BIO to perform I/O with */ BIO *mem; /* Memory BIO response is built into */ unsigned long asn1_len; /* ASN1 length of response */ unsigned long max_resp_len; /* Maximum length of response */ }; #define OCSP_MAX_RESP_LENGTH (100 * 1024) #define OCSP_MAX_LINE_LEN 4096; /* OCSP states */ /* If set no reading should be performed */ #define OHS_NOREAD 0x1000 /* Error condition */ #define OHS_ERROR (0 | OHS_NOREAD) /* First line being read */ #define OHS_FIRSTLINE 1 /* MIME headers being read */ #define OHS_HEADERS 2 /* OCSP initial header (tag + length) being read */ #define OHS_ASN1_HEADER 3 /* OCSP content octets being read */ #define OHS_ASN1_CONTENT 4 /* First call: ready to start I/O */ #define OHS_ASN1_WRITE_INIT (5 | OHS_NOREAD) /* Request being sent */ #define OHS_ASN1_WRITE (6 | OHS_NOREAD) /* Request being flushed */ #define OHS_ASN1_FLUSH (7 | OHS_NOREAD) /* Completed */ #define OHS_DONE (8 | OHS_NOREAD) /* Headers set, no final \r\n included */ #define OHS_HTTP_HEADER (9 | OHS_NOREAD) static int parse_http_line1(char *line); OCSP_REQ_CTX *OCSP_REQ_CTX_new(BIO *io, int maxline) { OCSP_REQ_CTX *rctx = OPENSSL_zalloc(sizeof(*rctx)); if (rctx == NULL) return NULL; rctx->state = OHS_ERROR; rctx->max_resp_len = OCSP_MAX_RESP_LENGTH; rctx->mem = BIO_new(BIO_s_mem()); rctx->io = io; if (maxline > 0) rctx->iobuflen = maxline; else rctx->iobuflen = OCSP_MAX_LINE_LEN; rctx->iobuf = OPENSSL_malloc(rctx->iobuflen); if (rctx->iobuf == NULL || rctx->mem == NULL) { OCSP_REQ_CTX_free(rctx); return NULL; } return rctx; } void OCSP_REQ_CTX_free(OCSP_REQ_CTX *rctx) { if (!rctx) return; BIO_free(rctx->mem); OPENSSL_free(rctx->iobuf); OPENSSL_free(rctx); } BIO *OCSP_REQ_CTX_get0_mem_bio(OCSP_REQ_CTX *rctx) { return rctx->mem; } void OCSP_set_max_response_length(OCSP_REQ_CTX *rctx, unsigned long len) { if (len == 0) rctx->max_resp_len = OCSP_MAX_RESP_LENGTH; else rctx->max_resp_len = len; } int OCSP_REQ_CTX_i2d(OCSP_REQ_CTX *rctx, const ASN1_ITEM *it, ASN1_VALUE *val) { static const char req_hdr[] = "Content-Type: application/ocsp-request\r\n" "Content-Length: %d\r\n\r\n"; int reqlen = ASN1_item_i2d(val, NULL, it); if (BIO_printf(rctx->mem, req_hdr, reqlen) <= 0) return 0; if (ASN1_item_i2d_bio(it, rctx->mem, val) <= 0) return 0; rctx->state = OHS_ASN1_WRITE_INIT; return 1; } int OCSP_REQ_CTX_nbio_d2i(OCSP_REQ_CTX *rctx, ASN1_VALUE **pval, const ASN1_ITEM *it) { int rv, len; const unsigned char *p; rv = OCSP_REQ_CTX_nbio(rctx); if (rv != 1) return rv; len = BIO_get_mem_data(rctx->mem, &p); *pval = ASN1_item_d2i(NULL, &p, len, it); if (*pval == NULL) { rctx->state = OHS_ERROR; return 0; } return 1; } int OCSP_REQ_CTX_http(OCSP_REQ_CTX *rctx, const char *op, const char *path) { static const char http_hdr[] = "%s %s HTTP/1.0\r\n"; if (path == NULL) path = "/"; if (BIO_printf(rctx->mem, http_hdr, op, path) <= 0) return 0; rctx->state = OHS_HTTP_HEADER; return 1; } int OCSP_REQ_CTX_set1_req(OCSP_REQ_CTX *rctx, OCSP_REQUEST *req) { return OCSP_REQ_CTX_i2d(rctx, ASN1_ITEM_rptr(OCSP_REQUEST), (ASN1_VALUE *)req); } int OCSP_REQ_CTX_add1_header(OCSP_REQ_CTX *rctx, const char *name, const char *value) { if (!name) return 0; if (BIO_puts(rctx->mem, name) <= 0) return 0; if (value) { if (BIO_write(rctx->mem, ": ", 2) != 2) return 0; if (BIO_puts(rctx->mem, value) <= 0) return 0; } if (BIO_write(rctx->mem, "\r\n", 2) != 2) return 0; rctx->state = OHS_HTTP_HEADER; return 1; } OCSP_REQ_CTX *OCSP_sendreq_new(BIO *io, const char *path, OCSP_REQUEST *req, int maxline) { OCSP_REQ_CTX *rctx = NULL; rctx = OCSP_REQ_CTX_new(io, maxline); if (rctx == NULL) return NULL; if (!OCSP_REQ_CTX_http(rctx, "POST", path)) goto err; if (req && !OCSP_REQ_CTX_set1_req(rctx, req)) goto err; return rctx; err: OCSP_REQ_CTX_free(rctx); return NULL; } /* * Parse the HTTP response. This will look like this: "HTTP/1.0 200 OK". We * need to obtain the numeric code and (optional) informational message. */ static int parse_http_line1(char *line) { int retcode; char *p, *q, *r; /* Skip to first white space (passed protocol info) */ for (p = line; *p && !ossl_isspace(*p); p++) continue; if (*p == '\0') { OCSPerr(OCSP_F_PARSE_HTTP_LINE1, OCSP_R_SERVER_RESPONSE_PARSE_ERROR); return 0; } /* Skip past white space to start of response code */ while (*p && ossl_isspace(*p)) p++; if (*p == '\0') { OCSPerr(OCSP_F_PARSE_HTTP_LINE1, OCSP_R_SERVER_RESPONSE_PARSE_ERROR); return 0; } /* Find end of response code: first whitespace after start of code */ for (q = p; *q && !ossl_isspace(*q); q++) continue; if (*q == '\0') { OCSPerr(OCSP_F_PARSE_HTTP_LINE1, OCSP_R_SERVER_RESPONSE_PARSE_ERROR); return 0; } /* Set end of response code and start of message */ *q++ = 0; /* Attempt to parse numeric code */ retcode = strtoul(p, &r, 10); if (*r) return 0; /* Skip over any leading white space in message */ while (*q && ossl_isspace(*q)) q++; if (*q) { /* * Finally zap any trailing white space in message (include CRLF) */ /* We know q has a non white space character so this is OK */ for (r = q + strlen(q) - 1; ossl_isspace(*r); r--) *r = 0; } if (retcode != 200) { OCSPerr(OCSP_F_PARSE_HTTP_LINE1, OCSP_R_SERVER_RESPONSE_ERROR); if (*q == '\0') ERR_add_error_data(2, "Code=", p); else ERR_add_error_data(4, "Code=", p, ",Reason=", q); return 0; } return 1; } int OCSP_REQ_CTX_nbio(OCSP_REQ_CTX *rctx) { int i, n; const unsigned char *p; next_io: if (!(rctx->state & OHS_NOREAD)) { n = BIO_read(rctx->io, rctx->iobuf, rctx->iobuflen); if (n <= 0) { if (BIO_should_retry(rctx->io)) return -1; return 0; } /* Write data to memory BIO */ if (BIO_write(rctx->mem, rctx->iobuf, n) != n) return 0; } switch (rctx->state) { case OHS_HTTP_HEADER: /* Last operation was adding headers: need a final \r\n */ if (BIO_write(rctx->mem, "\r\n", 2) != 2) { rctx->state = OHS_ERROR; return 0; } rctx->state = OHS_ASN1_WRITE_INIT; /* fall thru */ case OHS_ASN1_WRITE_INIT: rctx->asn1_len = BIO_get_mem_data(rctx->mem, NULL); rctx->state = OHS_ASN1_WRITE; /* fall thru */ case OHS_ASN1_WRITE: n = BIO_get_mem_data(rctx->mem, &p); i = BIO_write(rctx->io, p + (n - rctx->asn1_len), rctx->asn1_len); if (i <= 0) { if (BIO_should_retry(rctx->io)) return -1; rctx->state = OHS_ERROR; return 0; } rctx->asn1_len -= i; if (rctx->asn1_len > 0) goto next_io; rctx->state = OHS_ASN1_FLUSH; (void)BIO_reset(rctx->mem); /* fall thru */ case OHS_ASN1_FLUSH: i = BIO_flush(rctx->io); if (i > 0) { rctx->state = OHS_FIRSTLINE; goto next_io; } if (BIO_should_retry(rctx->io)) return -1; rctx->state = OHS_ERROR; return 0; case OHS_ERROR: return 0; case OHS_FIRSTLINE: case OHS_HEADERS: /* Attempt to read a line in */ next_line: /* * Due to &%^*$" memory BIO behaviour with BIO_gets we have to check * there's a complete line in there before calling BIO_gets or we'll * just get a partial read. */ n = BIO_get_mem_data(rctx->mem, &p); if ((n <= 0) || !memchr(p, '\n', n)) { if (n >= rctx->iobuflen) { rctx->state = OHS_ERROR; return 0; } goto next_io; } n = BIO_gets(rctx->mem, (char *)rctx->iobuf, rctx->iobuflen); if (n <= 0) { if (BIO_should_retry(rctx->mem)) goto next_io; rctx->state = OHS_ERROR; return 0; } /* Don't allow excessive lines */ if (n == rctx->iobuflen) { rctx->state = OHS_ERROR; return 0; } /* First line */ if (rctx->state == OHS_FIRSTLINE) { if (parse_http_line1((char *)rctx->iobuf)) { rctx->state = OHS_HEADERS; goto next_line; } else { rctx->state = OHS_ERROR; return 0; } } else { /* Look for blank line: end of headers */ for (p = rctx->iobuf; *p; p++) { if ((*p != '\r') && (*p != '\n')) break; } if (*p) goto next_line; rctx->state = OHS_ASN1_HEADER; } /* Fall thru */ case OHS_ASN1_HEADER: /* * Now reading ASN1 header: can read at least 2 bytes which is enough * for ASN1 SEQUENCE header and either length field or at least the * length of the length field. */ n = BIO_get_mem_data(rctx->mem, &p); if (n < 2) goto next_io; /* Check it is an ASN1 SEQUENCE */ if (*p++ != (V_ASN1_SEQUENCE | V_ASN1_CONSTRUCTED)) { rctx->state = OHS_ERROR; return 0; } /* Check out length field */ if (*p & 0x80) { /* * If MSB set on initial length octet we can now always read 6 * octets: make sure we have them. */ if (n < 6) goto next_io; n = *p & 0x7F; /* Not NDEF or excessive length */ if (!n || (n > 4)) { rctx->state = OHS_ERROR; return 0; } p++; rctx->asn1_len = 0; for (i = 0; i < n; i++) { rctx->asn1_len <<= 8; rctx->asn1_len |= *p++; } if (rctx->asn1_len > rctx->max_resp_len) { rctx->state = OHS_ERROR; return 0; } rctx->asn1_len += n + 2; } else rctx->asn1_len = *p + 2; rctx->state = OHS_ASN1_CONTENT; /* Fall thru */ case OHS_ASN1_CONTENT: n = BIO_get_mem_data(rctx->mem, NULL); if (n < (int)rctx->asn1_len) goto next_io; rctx->state = OHS_DONE; return 1; case OHS_DONE: return 1; } return 0; } int OCSP_sendreq_nbio(OCSP_RESPONSE **presp, OCSP_REQ_CTX *rctx) { return OCSP_REQ_CTX_nbio_d2i(rctx, (ASN1_VALUE **)presp, ASN1_ITEM_rptr(OCSP_RESPONSE)); } /* Blocking OCSP request handler: now a special case of non-blocking I/O */ OCSP_RESPONSE *OCSP_sendreq_bio(BIO *b, const char *path, OCSP_REQUEST *req) { OCSP_RESPONSE *resp = NULL; OCSP_REQ_CTX *ctx; int rv; ctx = OCSP_sendreq_new(b, path, req, -1); if (ctx == NULL) return NULL; do { rv = OCSP_sendreq_nbio(&resp, ctx); } while ((rv == -1) && BIO_should_retry(b)); OCSP_REQ_CTX_free(ctx); if (rv) return resp; return NULL; }