/* crypto/evp/bio_ok.c */ /* Copyright (C) 1995-1998 Eric Young (eay@cryptsoft.com) * All rights reserved. * * This package is an SSL implementation written * by Eric Young (eay@cryptsoft.com). * The implementation was written so as to conform with Netscapes SSL. * * This library is free for commercial and non-commercial use as long as * the following conditions are aheared to. The following conditions * apply to all code found in this distribution, be it the RC4, RSA, * lhash, DES, etc., code; not just the SSL code. The SSL documentation * included with this distribution is covered by the same copyright terms * except that the holder is Tim Hudson (tjh@cryptsoft.com). * * Copyright remains Eric Young's, and as such any Copyright notices in * the code are not to be removed. * If this package is used in a product, Eric Young should be given attribution * as the author of the parts of the library used. * This can be in the form of a textual message at program startup or * in documentation (online or textual) provided with the package. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * "This product includes cryptographic software written by * Eric Young (eay@cryptsoft.com)" * The word 'cryptographic' can be left out if the rouines from the library * being used are not cryptographic related :-). * 4. If you include any Windows specific code (or a derivative thereof) from * the apps directory (application code) you must include an acknowledgement: * "This product includes software written by Tim Hudson (tjh@cryptsoft.com)" * * THIS SOFTWARE IS PROVIDED BY ERIC YOUNG ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * The licence and distribution terms for any publically available version or * derivative of this code cannot be changed. i.e. this code cannot simply be * copied and put under another distribution licence * [including the GNU Public Licence.] */ /* From: Arne Ansper Why BIO_f_reliable? I wrote function which took BIO* as argument, read data from it and processed it. Then I wanted to store the input file in encrypted form. OK I pushed BIO_f_cipher to the BIO stack and everything was OK. BUT if user types wrong password BIO_f_cipher outputs only garbage and my function crashes. Yes I can and I should fix my function, but BIO_f_cipher is easy way to add encryption support to many exisiting applications and it's hard to debug and fix them all. So I wanted another BIO which would catch the incorrect passwords and file damages which cause garbage on BIO_f_cipher's output. The easy way is to push the BIO_f_md and save the checksum at the end of the file. However there are several problems with this approach: 1) you must somehow separate checksum from actual data. 2) you need lot's of memory when reading the file, because you must read to the end of the file and verify the checksum before leting the application to read the data. BIO_f_reliable tries to solve both problems, so that you can read and write arbitraly long streams using only fixed amount of memory. BIO_f_reliable splits data stream into blocks. Each block is prefixed with it's length and suffixed with it's digest. So you need only several Kbytes of memory to buffer single block before verifying it's digest. BIO_f_reliable goes futher and adds several important capabilities: 1) the digest of the block is computed over the whole stream -- so nobody can rearrange the blocks or remove or replace them. 2) to detect invalid passwords right at the start BIO_f_reliable adds special prefix to the stream. In order to avoid known plain-text attacks this prefix is generated as follows: *) digest is initialized with random seed instead of standardized one. *) same seed is written to ouput *) well-known text is then hashed and the output of the digest is also written to output. reader can now read the seed from stream, hash the same string and then compare the digest output. Bad things: BIO_f_reliable knows what's going on in EVP_Digest. I initialy wrote and tested this code on x86 machine and wrote the digests out in machine-dependent order :( There are people using this code and I cannot change this easily without making existing data files unreadable. */ #include #include #include "cryptlib.h" #include "buffer.h" #include "bio.h" #include "evp.h" #include "rand.h" #ifndef NOPROTO static int ok_write(BIO *h,char *buf,int num); static int ok_read(BIO *h,char *buf,int size); static long ok_ctrl(BIO *h,int cmd,long arg1,char *arg2); static int ok_new(BIO *h); static int ok_free(BIO *data); static void sig_out(BIO* b); static void sig_in(BIO* b); static void block_out(BIO* b); static void block_in(BIO* b); #else static int ok_write(); static int ok_read(); static long ok_ctrl(); static int ok_new(); static int ok_free(); static void sig_out(); static void sig_in(); static void block_out(); static void block_in(); #endif #define OK_BLOCK_SIZE (1024*4) #define OK_BLOCK_BLOCK 4 #define IOBS (OK_BLOCK_SIZE+ OK_BLOCK_BLOCK+ 3*EVP_MAX_MD_SIZE) #define WELLKNOWN "The quick brown fox jumped over the lazy dog's back." #ifndef L_ENDIAN #define swapem(x) \ ((unsigned long int)((((unsigned long int)(x) & 0x000000ffU) << 24) | \ (((unsigned long int)(x) & 0x0000ff00U) << 8) | \ (((unsigned long int)(x) & 0x00ff0000U) >> 8) | \ (((unsigned long int)(x) & 0xff000000U) >> 24))) #else #define swapem(x) (x) #endif typedef struct ok_struct { int buf_len; int buf_off; int buf_len_save; int buf_off_save; int cont; /* <= 0 when finished */ int finished; EVP_MD_CTX md; int blockout; /* output block is ready */ int sigio; /* must process signature */ char buf[IOBS]; } BIO_OK_CTX; static BIO_METHOD methods_ok= { BIO_TYPE_CIPHER,"reliable", ok_write, ok_read, NULL, /* ok_puts, */ NULL, /* ok_gets, */ ok_ctrl, ok_new, ok_free, }; BIO_METHOD *BIO_f_reliable(void) { return(&methods_ok); } static int ok_new(BIO *bi) { BIO_OK_CTX *ctx; ctx=(BIO_OK_CTX *)Malloc(sizeof(BIO_OK_CTX)); if (ctx == NULL) return(0); ctx->buf_len=0; ctx->buf_off=0; ctx->buf_len_save=0; ctx->buf_off_save=0; ctx->cont=1; ctx->finished=0; ctx->blockout= 0; ctx->sigio=1; bi->init=0; bi->ptr=(char *)ctx; bi->flags=0; return(1); } static int ok_free(BIO *a) { if (a == NULL) return(0); memset(a->ptr,0,sizeof(BIO_OK_CTX)); Free(a->ptr); a->ptr=NULL; a->init=0; a->flags=0; return(1); } static int ok_read(BIO *b, char *out, int outl) { int ret=0,i,n; BIO_OK_CTX *ctx; if (out == NULL) return(0); ctx=(BIO_OK_CTX *)b->ptr; if ((ctx == NULL) || (b->next_bio == NULL) || (b->init == 0)) return(0); while(outl > 0) { /* copy clean bytes to output buffer */ if (ctx->blockout) { i=ctx->buf_len-ctx->buf_off; if (i > outl) i=outl; memcpy(out,&(ctx->buf[ctx->buf_off]),i); ret+=i; out+=i; outl-=i; ctx->buf_off+=i; /* all clean bytes are out */ if (ctx->buf_len == ctx->buf_off) { ctx->buf_off=0; /* copy start of the next block into proper place */ if(ctx->buf_len_save- ctx->buf_off_save > 0) { ctx->buf_len= ctx->buf_len_save- ctx->buf_off_save; memmove(ctx->buf, &(ctx->buf[ctx->buf_off_save]), ctx->buf_len); } else { ctx->buf_len=0; } ctx->blockout= 0; } } /* output buffer full -- cancel */ if (outl == 0) break; /* no clean bytes in buffer -- fill it */ n=IOBS- ctx->buf_len; i=BIO_read(b->next_bio,&(ctx->buf[ctx->buf_len]),n); if (i <= 0) break; /* nothing new */ ctx->buf_len+= i; /* no signature yet -- check if we got one */ if (ctx->sigio == 1) sig_in(b); /* signature ok -- check if we got block */ if (ctx->sigio == 0) block_in(b); /* invalid block -- cancel */ if (ctx->cont <= 0) break; } BIO_clear_retry_flags(b); BIO_copy_next_retry(b); return(ret); } static int ok_write(BIO *b, char *in, int inl) { int ret=0,n,i; BIO_OK_CTX *ctx; ctx=(BIO_OK_CTX *)b->ptr; ret=inl; if ((ctx == NULL) || (b->next_bio == NULL) || (b->init == 0)) return(0); if(ctx->sigio) sig_out(b); do{ BIO_clear_retry_flags(b); n=ctx->buf_len-ctx->buf_off; while (ctx->blockout && n > 0) { i=BIO_write(b->next_bio,&(ctx->buf[ctx->buf_off]),n); if (i <= 0) { BIO_copy_next_retry(b); if(!BIO_should_retry(b)) ctx->cont= 0; return(i); } ctx->buf_off+=i; n-=i; } /* at this point all pending data has been written */ ctx->blockout= 0; if (ctx->buf_len == ctx->buf_off) { ctx->buf_len=OK_BLOCK_BLOCK; ctx->buf_off=0; } if ((in == NULL) || (inl <= 0)) return(0); n= (inl+ ctx->buf_len > OK_BLOCK_SIZE+ OK_BLOCK_BLOCK) ? OK_BLOCK_SIZE+ OK_BLOCK_BLOCK- ctx->buf_len : inl; memcpy((unsigned char *)(&(ctx->buf[ctx->buf_len])),(unsigned char *)in,n); ctx->buf_len+= n; inl-=n; in+=n; if(ctx->buf_len >= OK_BLOCK_SIZE+ OK_BLOCK_BLOCK) { block_out(b); } }while(inl > 0); BIO_clear_retry_flags(b); BIO_copy_next_retry(b); return(ret); } static long ok_ctrl(BIO *b, int cmd, long num, char *ptr) { BIO_OK_CTX *ctx; EVP_MD *md; const EVP_MD **ppmd; long ret=1; int i; ctx=(BIO_OK_CTX *)b->ptr; switch (cmd) { case BIO_CTRL_RESET: ctx->buf_len=0; ctx->buf_off=0; ctx->buf_len_save=0; ctx->buf_off_save=0; ctx->cont=1; ctx->finished=0; ctx->blockout= 0; ctx->sigio=1; ret=BIO_ctrl(b->next_bio,cmd,num,ptr); break; case BIO_CTRL_EOF: /* More to read */ if (ctx->cont <= 0) ret=1; else ret=BIO_ctrl(b->next_bio,cmd,num,ptr); break; case BIO_CTRL_PENDING: /* More to read in buffer */ case BIO_CTRL_WPENDING: /* More to read in buffer */ ret=ctx->blockout ? ctx->buf_len-ctx->buf_off : 0; if (ret <= 0) ret=BIO_ctrl(b->next_bio,cmd,num,ptr); break; case BIO_CTRL_FLUSH: /* do a final write */ if(ctx->blockout == 0) block_out(b); while (ctx->blockout) { i=ok_write(b,NULL,0); if (i < 0) { ret=i; break; } } ctx->finished=1; ctx->buf_off=ctx->buf_len=0; ctx->cont=(int)ret; /* Finally flush the underlying BIO */ ret=BIO_ctrl(b->next_bio,cmd,num,ptr); break; case BIO_C_DO_STATE_MACHINE: BIO_clear_retry_flags(b); ret=BIO_ctrl(b->next_bio,cmd,num,ptr); BIO_copy_next_retry(b); break; case BIO_CTRL_INFO: ret=(long)ctx->cont; break; case BIO_C_SET_MD: md=(EVP_MD *)ptr; EVP_DigestInit(&(ctx->md),md); b->init=1; break; case BIO_C_GET_MD: if (b->init) { ppmd=(const EVP_MD **)ptr; *ppmd=ctx->md.digest; } else ret=0; break; default: ret=BIO_ctrl(b->next_bio,cmd,num,ptr); break; } return(ret); } static void longswap(char* ptr, int len) { #ifndef L_ENDIAN int i; for(i= 0;i < len;i+= 4){ *((unsigned long *)&(ptr[i]))= swapem(*((unsigned long *)&(ptr[i]))); } #endif } static void sig_out(BIO* b) { BIO_OK_CTX *ctx; EVP_MD_CTX *md; ctx=(BIO_OK_CTX *)b->ptr; md= &(ctx->md); if(ctx->buf_len+ 2* md->digest->md_size > OK_BLOCK_SIZE) return; EVP_DigestInit(md, md->digest); RAND_bytes(&(md->md.base[0]), md->digest->md_size); memcpy(&(ctx->buf[ctx->buf_len]), &(md->md.base[0]), md->digest->md_size); longswap(&(ctx->buf[ctx->buf_len]), md->digest->md_size); ctx->buf_len+= md->digest->md_size; EVP_DigestUpdate(md, (unsigned char*)WELLKNOWN, strlen(WELLKNOWN)); md->digest->final(&(ctx->buf[ctx->buf_len]), &(md->md.base[0])); ctx->buf_len+= md->digest->md_size; ctx->blockout= 1; ctx->sigio= 0; } static void sig_in(BIO* b) { BIO_OK_CTX *ctx; EVP_MD_CTX *md; unsigned char tmp[EVP_MAX_MD_SIZE]; int ret= 0; ctx=(BIO_OK_CTX *)b->ptr; md= &(ctx->md); if(ctx->buf_len- ctx->buf_off < 2* md->digest->md_size) return; EVP_DigestInit(md, md->digest); memcpy(&(md->md.base[0]), &(ctx->buf[ctx->buf_off]), md->digest->md_size); longswap(&(md->md.base[0]), md->digest->md_size); ctx->buf_off+= md->digest->md_size; EVP_DigestUpdate(md, (unsigned char*)WELLKNOWN, strlen(WELLKNOWN)); md->digest->final(tmp, &(md->md.base[0])); ret= memcmp(&(ctx->buf[ctx->buf_off]), tmp, md->digest->md_size) == 0; ctx->buf_off+= md->digest->md_size; if(ret == 1) { ctx->sigio= 0; if(ctx->buf_len != ctx->buf_off) { memmove(ctx->buf, &(ctx->buf[ctx->buf_off]), ctx->buf_len- ctx->buf_off); } ctx->buf_len-= ctx->buf_off; ctx->buf_off= 0; } else { ctx->cont= 0; } } static void block_out(BIO* b) { BIO_OK_CTX *ctx; EVP_MD_CTX *md; unsigned long tl; ctx=(BIO_OK_CTX *)b->ptr; md= &(ctx->md); tl= ctx->buf_len- OK_BLOCK_BLOCK; tl= swapem(tl); memcpy(ctx->buf, &tl, OK_BLOCK_BLOCK); tl= swapem(tl); EVP_DigestUpdate(md, (unsigned char*) &(ctx->buf[OK_BLOCK_BLOCK]), tl); md->digest->final(&(ctx->buf[ctx->buf_len]), &(md->md.base[0])); ctx->buf_len+= md->digest->md_size; ctx->blockout= 1; } static void block_in(BIO* b) { BIO_OK_CTX *ctx; EVP_MD_CTX *md; long tl= 0; unsigned char tmp[EVP_MAX_MD_SIZE]; ctx=(BIO_OK_CTX *)b->ptr; md= &(ctx->md); memcpy(&tl, ctx->buf, OK_BLOCK_BLOCK); tl= swapem(tl); if (ctx->buf_len < tl+ OK_BLOCK_BLOCK+ md->digest->md_size) return; EVP_DigestUpdate(md, (unsigned char*) &(ctx->buf[OK_BLOCK_BLOCK]), tl); md->digest->final(tmp, &(md->md.base[0])); if(memcmp(&(ctx->buf[tl+ OK_BLOCK_BLOCK]), tmp, md->digest->md_size) == 0) { /* there might be parts from next block lurking around ! */ ctx->buf_off_save= tl+ OK_BLOCK_BLOCK+ md->digest->md_size; ctx->buf_len_save= ctx->buf_len; ctx->buf_off= OK_BLOCK_BLOCK; ctx->buf_len= tl+ OK_BLOCK_BLOCK; ctx->blockout= 1; } else { ctx->cont= 0; } }