ref: 09cf3c0ae6c0fed01e32a149f4668b7a7d52944b
dir: /libinterp/crypt.c/
#include "lib9.h" #include "kernel.h" #include <isa.h> #include "interp.h" #include "runt.h" #include "cryptmod.h" #include <mp.h> #include <libsec.h> #include "pool.h" #include "raise.h" #include "ipint.h" #define MPX(x) checkIPint((void*)(x)) static Type* TDigestState; static Type* TAESstate; static Type* TDESstate; static Type* TIDEAstate; static Type* TBFstate; static Type* TRC4state; static Type* TSKdsa; static Type* TPKdsa; static Type* TPKsigdsa; static Type* TSKeg; static Type* TPKeg; static Type* TPKsigeg; static Type* TSKrsa; static Type* TPKrsa; static Type* TPKsigrsa; static uchar DigestStatemap[] = Crypt_DigestState_map; static uchar AESstatemap[] = Crypt_AESstate_map; static uchar DESstatemap[] = Crypt_DESstate_map; static uchar IDEAstatemap[] = Crypt_IDEAstate_map; static uchar BFstatemap[] = Crypt_BFstate_map; static uchar RC4statemap[] = Crypt_RC4state_map; static uchar DSAskmap[] = Crypt_SK_DSA_map; static uchar DSApkmap[] = Crypt_PK_DSA_map; static uchar DSAsigmap[] = Crypt_PKsig_DSA_map; static uchar EGskmap[] = Crypt_SK_Elgamal_map; static uchar EGpkmap[] = Crypt_PK_Elgamal_map; static uchar EGsigmap[] = Crypt_PKsig_Elgamal_map; static uchar RSAskmap[] = Crypt_SK_RSA_map; static uchar RSApkmap[] = Crypt_PK_RSA_map; static uchar RSAsigmap[] = Crypt_PKsig_RSA_map; static char exBadBsize[] = "data not multiple of block size"; static char exBadKey[] = "bad encryption key"; static char exBadDigest[] = "bad digest value"; static char exBadIvec[] = "bad ivec"; static char exBadState[] = "bad encryption state"; /* * these structures reveal the C state of Limbo adts in crypt.m */ typedef struct XDigestState XDigestState; typedef struct XAESstate XAESstate; typedef struct XDESstate XDESstate; typedef struct XIDEAstate XIDEAstate; typedef struct XBFstate XBFstate; typedef struct XRC4state XRC4state; /* digest state */ struct XDigestState { Crypt_DigestState x; DigestState state; }; /* AES state */ struct XAESstate { Crypt_AESstate x; AESstate state; }; /* DES state */ struct XDESstate { Crypt_DESstate x; DESstate state; }; /* IDEA state */ struct XIDEAstate { Crypt_IDEAstate x; IDEAstate state; }; /* BF state */ struct XBFstate { Crypt_BFstate x; BFstate state; }; /* RC4 state */ struct XRC4state { Crypt_RC4state x; RC4state state; }; static Crypt_PK* newPK(Type *t, int pick) { Heap *h; Crypt_PK *sk; h = heap(t); sk = H2D(Crypt_PK*, h); sk->pick = pick; return sk; } static Crypt_SK* newSK(Crypt_SK** ret, Type *t, int pick) { Heap *h; Crypt_SK *sk; h = heap(t); sk = H2D(Crypt_SK*, h); sk->pick = pick; if(ret != nil) *ret = sk; switch(pick){ case Crypt_PK_RSA: sk->u.RSA.pk = newPK(TPKrsa, Crypt_PK_RSA); break; case Crypt_PK_Elgamal: sk->u.Elgamal.pk = newPK(TPKeg, Crypt_PK_Elgamal); break; case Crypt_PK_DSA: sk->u.DSA.pk = newPK(TPKdsa, Crypt_PK_DSA); break; default: error(exType); } return sk; } static Crypt_PKsig* newPKsig(Type *t, int pick) { Heap *h; Crypt_PKsig *s; h = heap(t); s = H2D(Crypt_PKsig*, h); s->pick = pick; return s; } static IPints_IPint* ipcopymp(mpint* b) { if(b == nil) return H; return newIPint(mpcopy(b)); } /* * digests */ void DigestState_copy(void *fp) { F_DigestState_copy *f; Heap *h; XDigestState *ds, *ods; void *r; f = fp; r = *f->ret; *f->ret = H; destroy(r); if(f->d != H){ ods = checktype(f->d, TDigestState, "DigestState", 0); h = heap(TDigestState); ds = H2D(XDigestState*, h); memmove(&ds->state, &ods->state, sizeof(ds->state)); *f->ret = (Crypt_DigestState*)ds; } } static Crypt_DigestState* crypt_digest_x(Array *buf, int n, Array *digest, int dlen, Crypt_DigestState *state, DigestState* (*fn)(uchar*, ulong, uchar*, DigestState*)) { Heap *h; XDigestState *ds; uchar *cbuf, *cdigest; if(buf != H){ if(n > buf->len) n = buf->len; cbuf = buf->data; }else{ if(n != 0) error(exInval); cbuf = nil; } if(digest != H){ if(digest->len < dlen) error(exBadDigest); cdigest = digest->data; } else cdigest = nil; if(state == H){ h = heap(TDigestState); ds = H2D(XDigestState*, h); memset(&ds->state, 0, sizeof(ds->state)); } else ds = checktype(state, TDigestState, "DigestState", 1); (*fn)(cbuf, n, cdigest, &ds->state); return (Crypt_DigestState*)ds; } void Crypt_sha1(void *fp) { F_Crypt_sha1 *f; void *r; f = fp; r = *f->ret; *f->ret = H; destroy(r); *f->ret = crypt_digest_x(f->buf, f->n, f->digest, SHA1dlen, f->state, sha1); } void Crypt_sha224(void *fp) { F_Crypt_sha224 *f; void *r; f = fp; r = *f->ret; *f->ret = H; destroy(r); *f->ret = crypt_digest_x(f->buf, f->n, f->digest, SHA224dlen, f->state, sha224); } void Crypt_sha256(void *fp) { F_Crypt_sha256 *f; void *r; f = fp; r = *f->ret; *f->ret = H; destroy(r); *f->ret = crypt_digest_x(f->buf, f->n, f->digest, SHA256dlen, f->state, sha256); } void Crypt_sha384(void *fp) { F_Crypt_sha384 *f; void *r; f = fp; r = *f->ret; *f->ret = H; destroy(r); *f->ret = crypt_digest_x(f->buf, f->n, f->digest, SHA384dlen, f->state, sha384); } void Crypt_sha512(void *fp) { F_Crypt_sha512 *f; void *r; f = fp; r = *f->ret; *f->ret = H; destroy(r); *f->ret = crypt_digest_x(f->buf, f->n, f->digest, SHA512dlen, f->state, sha512); } void Crypt_md5(void *fp) { F_Crypt_md5 *f; void *r; f = fp; r = *f->ret; *f->ret = H; destroy(r); *f->ret = crypt_digest_x(f->buf, f->n, f->digest, MD5dlen, f->state, md5); } void Crypt_md4(void *fp) { F_Crypt_md4 *f; void *r; f = fp; r = *f->ret; *f->ret = H; destroy(r); *f->ret = crypt_digest_x(f->buf, f->n, f->digest, MD4dlen, f->state, md4); } static Crypt_DigestState* crypt_hmac_x(Array *data, int n, Array *key, Array *digest, int dlen, Crypt_DigestState *state, DigestState* (*fn)(uchar*, ulong, uchar*, ulong, uchar*, DigestState*)) { Heap *h; XDigestState *ds; uchar *cdata, *cdigest; if(data != H){ if(n > data->len) n = data->len; cdata = data->data; }else{ if(n != 0) error(exInval); cdata = nil; } if(key == H || key->len > 64) error(exBadKey); if(digest != H){ if(digest->len < dlen) error(exBadDigest); cdigest = digest->data; } else cdigest = nil; if(state == H){ h = heap(TDigestState); ds = H2D(XDigestState*, h); memset(&ds->state, 0, sizeof(ds->state)); } else ds = checktype(state, TDigestState, "DigestState", 1); (*fn)(cdata, n, key->data, key->len, cdigest, &ds->state); return (Crypt_DigestState*)ds; } void Crypt_hmac_sha1(void *fp) { F_Crypt_hmac_sha1 *f; void *r; f = fp; r = *f->ret; *f->ret = H; destroy(r); *f->ret = crypt_hmac_x(f->data, f->n, f->key, f->digest, SHA1dlen, f->state, hmac_sha1); } void Crypt_hmac_md5(void *fp) { F_Crypt_hmac_md5 *f; void *r; f = fp; r = *f->ret; *f->ret = H; destroy(r); *f->ret = crypt_hmac_x(f->data, f->n, f->key, f->digest, MD5dlen, f->state, hmac_md5); } void Crypt_dhparams(void *fp) { F_Crypt_dhparams *f; mpint *p, *alpha; void *v; f = fp; v = f->ret->t0; f->ret->t0 = H; destroy(v); v = f->ret->t1; f->ret->t1 = H; destroy(v); p = mpnew(0); alpha = mpnew(0); release(); if(f->nbits == 1024) DSAprimes(alpha, p, nil); else gensafeprime(p, alpha, f->nbits, 0); acquire(); f->ret->t0 = newIPint(alpha); f->ret->t1 = newIPint(p); } void cryptmodinit(void) { ipintsmodinit(); /* TIPint */ TDigestState = dtype(freeheap, sizeof(XDigestState), DigestStatemap, sizeof(DigestStatemap)); TAESstate = dtype(freeheap, sizeof(XAESstate), AESstatemap, sizeof(AESstatemap)); TDESstate = dtype(freeheap, sizeof(XDESstate), DESstatemap, sizeof(DESstatemap)); TIDEAstate = dtype(freeheap, sizeof(XIDEAstate), IDEAstatemap, sizeof(IDEAstatemap)); TBFstate = dtype(freeheap, sizeof(XBFstate), BFstatemap, sizeof(BFstatemap)); TRC4state = dtype(freeheap, sizeof(XRC4state), RC4statemap, sizeof(RC4statemap)); TSKdsa = dtype(freeheap, Crypt_SK_DSA_size, DSAskmap, sizeof(DSAskmap)); TPKdsa = dtype(freeheap, Crypt_PK_DSA_size, DSApkmap, sizeof(DSApkmap)); TPKsigdsa = dtype(freeheap, Crypt_PKsig_DSA_size, DSAsigmap, sizeof(DSAsigmap)); TSKeg = dtype(freeheap, Crypt_SK_Elgamal_size, EGskmap, sizeof(EGskmap)); TPKeg = dtype(freeheap, Crypt_PK_Elgamal_size, EGpkmap, sizeof(EGpkmap)); TPKsigeg = dtype(freeheap, Crypt_PKsig_Elgamal_size, EGsigmap, sizeof(EGsigmap)); TSKrsa = dtype(freeheap, Crypt_SK_RSA_size, RSAskmap, sizeof(RSAskmap)); TPKrsa = dtype(freeheap, Crypt_PK_RSA_size, RSApkmap, sizeof(RSApkmap)); TPKsigrsa = dtype(freeheap, Crypt_PKsig_RSA_size, RSAsigmap, sizeof(RSAsigmap)); builtinmod("$Crypt", Cryptmodtab, Cryptmodlen); } void Crypt_dessetup(void *fp) { F_Crypt_dessetup *f; Heap *h; XDESstate *ds; uchar *ivec; void *v; f = fp; v = *f->ret; *f->ret = H; destroy(v); if(f->key == H) error(exNilref); if(f->key->len < 8) error(exBadKey); if(f->ivec != H){ if(f->ivec->len < 8) error(exBadIvec); ivec = f->ivec->data; }else ivec = nil; h = heap(TDESstate); ds = H2D(XDESstate*, h); setupDESstate(&ds->state, f->key->data, ivec); *f->ret = (Crypt_DESstate*)ds; } void Crypt_desecb(void *fp) { F_Crypt_desecb *f; XDESstate *ds; int i; uchar *p; f = fp; if(f->buf == H) return; if(f->n < 0 || f->n > f->buf->len) error(exBounds); if(f->n & 7) error(exBadBsize); ds = checktype(f->state, TDESstate, exBadState, 0); p = f->buf->data; for(i = 8; i <= f->n; i += 8, p += 8) block_cipher(ds->state.expanded, p, f->direction); } void Crypt_descbc(void *fp) { F_Crypt_descbc *f; XDESstate *ds; uchar *p, *ep, *ip, *p2, *eip; uchar tmp[8]; f = fp; if(f->buf == H) return; if(f->n < 0 || f->n > f->buf->len) error(exBounds); if(f->n & 7) error(exBadBsize); ds = checktype(f->state, TDESstate, exBadState, 0); p = f->buf->data; if(f->direction == 0){ for(ep = p + f->n; p < ep; p += 8){ p2 = p; ip = ds->state.ivec; for(eip = ip+8; ip < eip; ) *p2++ ^= *ip++; block_cipher(ds->state.expanded, p, 0); memmove(ds->state.ivec, p, 8); } } else { for(ep = p + f->n; p < ep; ){ memmove(tmp, p, 8); block_cipher(ds->state.expanded, p, 1); p2 = tmp; ip = ds->state.ivec; for(eip = ip+8; ip < eip; ){ *p++ ^= *ip; *ip++ = *p2++; } } } } void Crypt_ideasetup(void *fp) { F_Crypt_ideasetup *f; Heap *h; XIDEAstate *is; uchar *ivec; void *v; f = fp; v = *f->ret; *f->ret = H; destroy(v); if(f->key == H) error(exNilref); if(f->key->len < 16) error(exBadKey); if(f->ivec != H){ if(f->ivec->len < 8) error(exBadIvec); ivec = f->ivec->data; }else ivec = nil; h = heap(TIDEAstate); is = H2D(XIDEAstate*, h); setupIDEAstate(&is->state, f->key->data, ivec); *f->ret = (Crypt_IDEAstate*)is; } void Crypt_ideaecb(void *fp) { F_Crypt_ideaecb *f; XIDEAstate *is; int i; uchar *p; f = fp; if(f->buf == H) return; if(f->n < 0 || f->n > f->buf->len) error(exBounds); if(f->n & 7) error(exBadBsize); is = checktype(f->state, TIDEAstate, exBadState, 0); p = f->buf->data; for(i = 8; i <= f->n; i += 8, p += 8) idea_cipher(is->state.edkey, p, f->direction); } void Crypt_ideacbc(void *fp) { F_Crypt_ideacbc *f; XIDEAstate *is; uchar *p, *ep, *ip, *p2, *eip; uchar tmp[8]; f = fp; if(f->buf == H) return; if(f->n < 0 || f->n > f->buf->len) error(exBounds); if(f->n & 7) error(exBadBsize); is = checktype(f->state, TIDEAstate, exBadState, 0); p = f->buf->data; if(f->direction == 0){ for(ep = p + f->n; p < ep; p += 8){ p2 = p; ip = is->state.ivec; for(eip = ip+8; ip < eip; ) *p2++ ^= *ip++; idea_cipher(is->state.edkey, p, 0); memmove(is->state.ivec, p, 8); } } else { for(ep = p + f->n; p < ep; ){ memmove(tmp, p, 8); idea_cipher(is->state.edkey, p, 1); p2 = tmp; ip = is->state.ivec; for(eip = ip+8; ip < eip; ){ *p++ ^= *ip; *ip++ = *p2++; } } } } void Crypt_aessetup(void *fp) { F_Crypt_aessetup *f; Heap *h; XAESstate *is; uchar *ivec; void *v; f = fp; v = *f->ret; *f->ret = H; destroy(v); if(f->key == H) error(exNilref); if(f->key->len != 16 && f->key->len != 24 && f->key->len != 32) error(exBadKey); if(f->ivec != H){ if(f->ivec->len < AESbsize) error(exBadIvec); ivec = f->ivec->data; }else ivec = nil; h = heap(TAESstate); is = H2D(XAESstate*, h); setupAESstate(&is->state, f->key->data, f->key->len, ivec); *f->ret = (Crypt_AESstate*)is; } void Crypt_aescbc(void *fp) { F_Crypt_aescbc *f; XAESstate *is; uchar *p; f = fp; if(f->buf == H) return; if(f->n < 0 || f->n > f->buf->len) error(exBounds); is = checktype(f->state, TAESstate, exBadState, 0); p = f->buf->data; if(f->direction == 0) aesCBCencrypt(p, f->n, &is->state); else aesCBCdecrypt(p, f->n, &is->state); } void Crypt_blowfishsetup(void *fp) { F_Crypt_blowfishsetup *f; Heap *h; XBFstate *is; uchar *ivec; void *v; f = fp; v = *f->ret; *f->ret = H; destroy(v); if(f->key == H) error(exNilref); if(f->key->len <= 0) error(exBadKey); if(f->ivec != H){ if(f->ivec->len != BFbsize) error(exBadIvec); ivec = f->ivec->data; }else ivec = nil; h = heap(TBFstate); is = H2D(XBFstate*, h); setupBFstate(&is->state, f->key->data, f->key->len, ivec); *f->ret = (Crypt_BFstate*)is; } void Crypt_blowfishcbc(void *fp) { F_Crypt_blowfishcbc *f; XBFstate *is; uchar *p; f = fp; if(f->state == H) return; if(f->n < 0 || f->n > f->buf->len) error(exBounds); if(f->n & 7) error(exBadBsize); is = checktype(f->state, TBFstate, exBadState, 0); p = f->buf->data; if(f->direction == 0) bfCBCencrypt(p, f->n, &is->state); else bfCBCdecrypt(p, f->n, &is->state); } void Crypt_rc4setup(void *fp) { F_Crypt_rc4setup *f; Heap *h; XRC4state *is; void *v; f = fp; v = *f->ret; *f->ret = H; destroy(v); if(f->seed == H) error(exNilref); h = heap(TRC4state); is = H2D(XRC4state*, h); setupRC4state(&is->state, f->seed->data, f->seed->len); *f->ret = (Crypt_RC4state*)is; } void Crypt_rc4(void *fp) { F_Crypt_rc4 *f; XRC4state *is; uchar *p; f = fp; if(f->buf == H) return; if(f->n < 0 || f->n > f->buf->len) error(exBounds); is = checktype(f->state, TRC4state, exBadState, 0); p = f->buf->data; rc4(&is->state, p, f->n); } void Crypt_rc4skip(void *fp) { F_Crypt_rc4skip *f; XRC4state *is; f = fp; is = checktype(f->state, TRC4state, exBadState, 0); rc4skip(&is->state, f->n); } void Crypt_rc4back(void *fp) { F_Crypt_rc4back *f; XRC4state *is; f = fp; is = checktype(f->state, TRC4state, exBadState, 0); rc4back(&is->state, f->n); } /* * public/secret keys, signing and verifying */ /* * DSA */ static void dsapk2pub(DSApub* p, Crypt_PK* pk) { if(pk == H) error(exNilref); if(pk->pick != Crypt_PK_DSA) error(exType); p->p = MPX(pk->u.DSA.p); p->q = MPX(pk->u.DSA.q); p->alpha = MPX(pk->u.DSA.alpha); p->key = MPX(pk->u.DSA.key); } static void dsask2priv(DSApriv* p, Crypt_SK* sk) { if(sk == H) error(exNilref); if(sk->pick != Crypt_SK_DSA) error(exType); dsapk2pub(&p->pub, sk->u.DSA.pk); p->secret = MPX(sk->u.DSA.secret); } static void dsapriv2sk(Crypt_SK* sk, DSApriv* p) { Crypt_PK *pk; pk = sk->u.DSA.pk; pk->u.DSA.p = ipcopymp(p->pub.p); pk->u.DSA.q = ipcopymp(p->pub.q); pk->u.DSA.alpha = ipcopymp(p->pub.alpha); pk->u.DSA.key = ipcopymp(p->pub.key); sk->u.DSA.secret = ipcopymp(p->secret); } static void dsaxgen(Crypt_SK* sk, DSApub* oldpk) { DSApriv *p; release(); p = dsagen(oldpk); acquire(); dsapriv2sk(sk, p); dsaprivfree(p); } void Crypt_dsagen(void *fp) { F_Crypt_dsagen *f; Crypt_SK *sk; DSApub pub, *oldpk; void *v; f = fp; v = *f->ret; *f->ret = H; destroy(v); sk = newSK(f->ret, TSKdsa, Crypt_SK_DSA); oldpk = nil; if(f->oldpk != H && f->oldpk->pick == Crypt_PK_DSA){ dsapk2pub(&pub, f->oldpk); oldpk = &pub; } dsaxgen(sk, oldpk); } /* * Elgamal */ static void egpk2pub(EGpub* p, Crypt_PK* pk) { if(pk == H) error(exNilref); if(pk->pick != Crypt_PK_Elgamal) error(exType); p->p = MPX(pk->u.Elgamal.p); p->alpha = MPX(pk->u.Elgamal.alpha); p->key = MPX(pk->u.Elgamal.key); } static void egsk2priv(EGpriv* p, Crypt_SK* sk) { if(sk == H) error(exNilref); if(sk->pick != Crypt_SK_Elgamal) error(exType); egpk2pub(&p->pub, sk->u.Elgamal.pk); p->secret = MPX(sk->u.Elgamal.secret); } static void egpriv2sk(Crypt_SK* sk, EGpriv* p) { Crypt_PK* pk; pk = sk->u.Elgamal.pk; pk->u.Elgamal.p = ipcopymp(p->pub.p); pk->u.Elgamal.alpha = ipcopymp(p->pub.alpha); pk->u.Elgamal.key = ipcopymp(p->pub.key); sk->u.Elgamal.secret = ipcopymp(p->secret); } static void egxgen(Crypt_SK* sk, int nlen, int nrep) { EGpriv *p; release(); for(;;){ p = eggen(nlen, nrep); if(mpsignif(p->pub.p) == nlen) break; egprivfree(p); } acquire(); egpriv2sk(sk, p); egprivfree(p); } void Crypt_eggen(void *fp) { F_Crypt_eggen *f; Crypt_SK *sk; void *v; f = fp; v = *f->ret; *f->ret = H; destroy(v); sk = newSK(f->ret, TSKeg, Crypt_SK_Elgamal); egxgen(sk, f->nlen, f->nrep); } /* * RSA */ static void rsapk2pub(RSApub* p, Crypt_PK* pk) { if(pk == H) error(exNilref); if(pk->pick != Crypt_PK_RSA) error(exType); p->n = MPX(pk->u.RSA.n); p->ek = MPX(pk->u.RSA.ek); } static void rsask2priv(RSApriv* p, Crypt_SK* sk) { if(sk == H) error(exNilref); if(sk->pick != Crypt_SK_RSA) error(exType); rsapk2pub(&p->pub, sk->u.RSA.pk); p->dk = MPX(sk->u.RSA.dk); p->p = MPX(sk->u.RSA.p); p->q = MPX(sk->u.RSA.q); p->kp = MPX(sk->u.RSA.kp); p->kq = MPX(sk->u.RSA.kq); p->c2 = MPX(sk->u.RSA.c2); } static void rsapriv2sk(Crypt_SK* sk, RSApriv* p) { Crypt_PK *pk; pk = sk->u.RSA.pk; pk->u.RSA.n = ipcopymp(p->pub.n); pk->u.RSA.ek = ipcopymp(p->pub.ek); sk->u.RSA.dk = ipcopymp(p->dk); sk->u.RSA.p = ipcopymp(p->p); sk->u.RSA.q = ipcopymp(p->q); sk->u.RSA.kp = ipcopymp(p->kp); sk->u.RSA.kq = ipcopymp(p->kq); sk->u.RSA.c2 = ipcopymp(p->c2); } static void rsaxgen(Crypt_SK *sk, int nlen, int elen, int nrep) { RSApriv *p; release(); for(;;){ p = rsagen(nlen, elen, nrep); if(mpsignif(p->pub.n) == nlen) break; rsaprivfree(p); } acquire(); rsapriv2sk(sk, p); rsaprivfree(p); } void Crypt_rsagen(void *fp) { F_Crypt_rsagen *f; Crypt_SK *sk; void *v; f = fp; v = *f->ret; *f->ret = H; destroy(v); sk = newSK(f->ret, TSKrsa, Crypt_SK_RSA); rsaxgen(sk, f->nlen, f->elen, f->nrep); } void Crypt_rsafill(void *fp) { F_Crypt_rsafill *f; Crypt_SK *sk; RSApriv *p; void *v; f = fp; v = *f->ret; *f->ret = H; destroy(v); sk = newSK(f->ret, TSKrsa, Crypt_SK_RSA); release(); p = rsafill(MPX(f->n), MPX(f->ek), MPX(f->dk), MPX(f->p), MPX(f->q)); acquire(); if(p == nil) { *f->ret = H; destroy(sk); }else{ rsapriv2sk(sk, p); rsaprivfree(p); } } void Crypt_rsaencrypt(void *fp) { F_Crypt_rsaencrypt *f; RSApub p; mpint *m, *o; void *v; f = fp; v = *f->ret; *f->ret = H; destroy(v); rsapk2pub(&p, f->k); m = MPX(f->m); release(); o = rsaencrypt(&p, m, nil); acquire(); *f->ret = newIPint(o); } void Crypt_rsadecrypt(void *fp) { F_Crypt_rsadecrypt *f; RSApriv p; mpint *m, *o; void *v; f = fp; v = *f->ret; *f->ret = H; destroy(v); rsask2priv(&p, f->k); m = MPX(f->m); release(); o = rsadecrypt(&p, m, nil); acquire(); *f->ret = newIPint(o); } /* * generic key functions */ void Crypt_genSK(void *fp) { F_Crypt_genSK *f; Crypt_SK *sk; char *sa; void *v; f = fp; v = *f->ret; *f->ret = H; destroy(v); sa = string2c(f->algname); if(strcmp(sa, "rsa") == 0){ sk = newSK(f->ret, TSKrsa, Crypt_SK_RSA); rsaxgen(sk, f->length, 6, 0); }else if(strcmp(sa, "dsa") == 0){ sk = newSK(f->ret, TSKdsa, Crypt_SK_DSA); dsaxgen(sk, nil); }else if(strcmp(sa, "elgamal") == 0){ sk = newSK(f->ret, TSKeg, Crypt_SK_Elgamal); egxgen(sk, f->length, 0); } /* genSK returns nil for unknown algorithm */ } void Crypt_genSKfromPK(void *fp) { F_Crypt_genSKfromPK *f; Crypt_SK *sk; void *v; f = fp; v = *f->ret; *f->ret = H; destroy(v); if(f->pk == H) error(exNilref); switch(f->pk->pick){ case Crypt_PK_RSA: { RSApub p; rsapk2pub(&p, f->pk); sk = newSK(f->ret, TSKrsa, Crypt_SK_RSA); rsaxgen(sk, mpsignif(p.n), mpsignif(p.ek), 0); } break; case Crypt_PK_Elgamal: { EGpub p; egpk2pub(&p, f->pk); sk = newSK(f->ret, TSKeg, Crypt_SK_Elgamal); egxgen(sk, mpsignif(p.p), 0); } break; case Crypt_PK_DSA: { DSApub p; dsapk2pub(&p, f->pk); sk = newSK(f->ret, TSKdsa, Crypt_SK_DSA); dsaxgen(sk, &p); } break; default: /* shouldn't happen */ error(exType); } } void Crypt_sktopk(void *fp) { F_Crypt_sktopk *f; Crypt_PK *pk; void *v; f = fp; v = *f->ret; *f->ret = H; destroy(v); if(f->sk == H) error(exNilref); switch(f->sk->pick){ case Crypt_PK_RSA: pk = f->sk->u.RSA.pk; break; case Crypt_PK_Elgamal: pk = f->sk->u.Elgamal.pk; break; case Crypt_PK_DSA: pk = f->sk->u.DSA.pk; break; default: pk = H; error(exType); } if(pk == H) return; D2H(pk)->ref++; *f->ret = pk; } void Crypt_sign(void *fp) { F_Crypt_sign *f; Crypt_PKsig *sig; mpint *m; void *v; f = fp; v = *f->ret; *f->ret = H; destroy(v); if(f->m == H || f->sk == H) error(exNilref); m = MPX(f->m); switch(f->sk->pick){ case Crypt_SK_RSA: { RSApriv p; mpint *s; rsask2priv(&p, f->sk); release(); s = rsadecrypt(&p, m, nil); acquire(); sig = newPKsig(TPKsigrsa, Crypt_PKsig_RSA); sig->u.RSA.n = newIPint(s); } break; case Crypt_SK_Elgamal: { EGpriv p; EGsig *s; egsk2priv(&p, f->sk); release(); s = egsign(&p, m); acquire(); sig = newPKsig(TPKsigeg, Crypt_PKsig_Elgamal); sig->u.Elgamal.r = ipcopymp(s->r); sig->u.Elgamal.s = ipcopymp(s->s); egsigfree(s); } break; case Crypt_SK_DSA: { DSApriv p; DSAsig *s; dsask2priv(&p, f->sk); m = MPX(f->m); release(); s = dsasign(&p, m); acquire(); sig = newPKsig(TPKsigdsa, Crypt_PKsig_DSA); sig->u.DSA.r = ipcopymp(s->r); sig->u.DSA.s = ipcopymp(s->s); dsasigfree(s); } break; default: sig = H; error(exType); } *f->ret = sig; } void Crypt_verify(void *fp) { F_Crypt_verify *f; mpint *m; f = fp; *f->ret = 0; if(f->sig == H || f->pk == H) error(exNilref); if(f->sig->pick != f->pk->pick) return; /* key type and signature mismatch, doesn't validate */ m = MPX(f->m); switch(f->pk->pick){ case Crypt_PK_RSA: { RSApub p; mpint *sig, *t; rsapk2pub(&p, f->pk); sig = MPX(f->sig->u.RSA.n); release(); t = rsaencrypt(&p, sig, nil); *f->ret = mpcmp(t, m) == 0; mpfree(t); acquire(); } break; case Crypt_PK_Elgamal: { EGpub p; EGsig sig; egpk2pub(&p, f->pk); sig.r = MPX(f->sig->u.Elgamal.r); sig.s = MPX(f->sig->u.Elgamal.s); release(); *f->ret = egverify(&p, &sig, m) == 0; acquire(); } break; case Crypt_PK_DSA: { DSApub p; DSAsig sig; dsapk2pub(&p, f->pk); sig.r = MPX(f->sig->u.DSA.r); sig.s = MPX(f->sig->u.DSA.s); release(); *f->ret = dsaverify(&p, &sig, m) == 0; acquire(); } break; default: error(exType); } }