ref: b7af62b250e5dff30320a181ca9d53ab5a7c276d
dir: /module/keyring.m/
# # security routines implemented in C # Keyring: module { PATH: con "$Keyring"; # infinite precision integers IPint: adt { x: int; # dummy for C compiler for runt.h # conversions iptob64: fn(i: self ref IPint): string; iptob64z: fn(i: self ref IPint): string; b64toip: fn(str: string): ref IPint; iptobytes: fn(i: self ref IPint): array of byte; iptobebytes: fn(i: self ref IPint): array of byte; bytestoip: fn(buf: array of byte): ref IPint; bebytestoip: fn(mag: array of byte): ref IPint; inttoip: fn(i: int): ref IPint; iptoint: fn(i: self ref IPint): int; iptostr: fn(i: self ref IPint, base: int): string; strtoip: fn(str: string, base: int): ref IPint; # create a random large integer using the accelerated generator random: fn(minbits, maxbits: int): ref IPint; # operations bits: fn(i: self ref IPint): int; expmod: fn(base: self ref IPint, exp, mod: ref IPint): ref IPint; invert: fn(base: self ref IPint, mod: ref IPint): ref IPint; add: fn(i1: self ref IPint, i2: ref IPint): ref IPint; sub: fn(i1: self ref IPint, i2: ref IPint): ref IPint; neg: fn(i: self ref IPint): ref IPint; mul: fn(i1: self ref IPint, i2: ref IPint): ref IPint; div: fn(i1: self ref IPint, i2: ref IPint): (ref IPint, ref IPint); mod: fn(i1: self ref IPint, i2: ref IPint): ref IPint; eq: fn(i1: self ref IPint, i2: ref IPint): int; cmp: fn(i1: self ref IPint, i2: ref IPint): int; copy: fn(i: self ref IPint): ref IPint; # shifts shl: fn(i: self ref IPint, n: int): ref IPint; shr: fn(i: self ref IPint, n: int): ref IPint; # bitwise and: fn(i1: self ref IPint, i2: ref IPint): ref IPint; ori: fn(i1: self ref IPint, i2: ref IPint): ref IPint; xor: fn(i1: self ref IPint, i2: ref IPint): ref IPint; not: fn(i1: self ref IPint): ref IPint; }; # signature algorithm SigAlg: adt { name: string; # C function pointers are hidden }; # generic public key PK: adt { sa: ref SigAlg; # signature algorithm owner: string; # owner's name # key and system parameters are hidden }; # generic secret key SK: adt { sa: ref SigAlg; # signature algorithm owner: string; # owner's name # key and system parameters are hidden }; # generic certificate Certificate: adt { sa: ref SigAlg; # signature algorithm ha: string; # hash algorithm signer: string; # name of signer exp: int; # expiration date # actual signature is hidden }; # state held while creating digests DigestState: adt { x: int; # dummy for C compiler for runt.h # all the state is hidden copy: fn(d: self ref DigestState): ref DigestState; }; # expanded AES key + state for chaining AESstate: adt { x: int; # dummy for C compiler for runt.h # all the state is hidden }; # expanded DES key + state for chaining DESstate: adt { x: int; # dummy for C compiler for runt.h # all the state is hidden }; # expanded IDEA key + state for chaining IDEAstate: adt { x: int; # dummy for C compiler for runt.h # all the state is hidden }; # expanded RC4 key + encryption state RC4state: adt { x: int; # dummy for C compiler for runt.h # all the state is hidden }; # expanded Blowfish key + state for chaining BFstate: adt { x: int; # dummy for C compiler for runt.h # all the state is hidden }; # authentication info Authinfo: adt { mysk: ref SK; # my private key mypk: ref PK; # my public key cert: ref Certificate; # signature of my public key spk: ref PK; # signers public key alpha: ref IPint; # diffie helman parameters p: ref IPint; }; # convert types to byte strings certtostr: fn (c: ref Certificate): string; pktostr: fn (pk: ref PK): string; sktostr: fn (sk: ref SK): string; # parse byte strings into types strtocert: fn (s: string): ref Certificate; strtopk: fn (s: string): ref PK; strtosk: fn (s: string): ref SK; # convert types to attr/value pairs certtoattr: fn (c: ref Certificate): string; pktoattr: fn (pk: ref PK): string; sktoattr: fn (sk: ref SK): string; # parse a/v pairs into types # attrtocert: fn (s: string): ref Certificate; # attrtopk: fn (s: string): ref PK; # attrtosk: fn (s: string): ref SK; # create and verify signatures sign: fn (sk: ref SK, exp: int, state: ref DigestState, ha: string): ref Certificate; verify: fn (pk: ref PK, cert: ref Certificate, state: ref DigestState): int; signm: fn (sk: ref SK, m: ref IPint, ha: string): ref Certificate; verifym: fn (pk: ref PK, cert: ref Certificate, m: ref IPint): int; # generate keys genSK: fn (algname, owner: string, length: int): ref SK; genSKfromPK: fn (pk: ref PK, owner: string): ref SK; sktopk: fn (sk: ref SK): ref PK; # digests md4: fn(buf: array of byte, n: int, digest: array of byte, state: ref DigestState): ref DigestState; md5: fn(buf: array of byte, n: int, digest: array of byte, state: ref DigestState): ref DigestState; sha1: fn(buf: array of byte, n: int, digest: array of byte, state: ref DigestState): ref DigestState; sha224: fn(buf: array of byte, n: int, digest: array of byte, state: ref DigestState): ref DigestState; sha256: fn(buf: array of byte, n: int, digest: array of byte, state: ref DigestState): ref DigestState; sha384: fn(buf: array of byte, n: int, digest: array of byte, state: ref DigestState): ref DigestState; sha512: fn(buf: array of byte, n: int, digest: array of byte, state: ref DigestState): ref DigestState; hmac_sha1: fn(data: array of byte, n: int, key: array of byte, digest: array of byte, state: ref DigestState): ref DigestState; hmac_md5: fn(data: array of byte, n: int, key: array of byte, digest: array of byte, state: ref DigestState): ref DigestState; SHA1dlen: con 20; SHA224dlen: con 28; SHA256dlen: con 32; SHA384dlen: con 48; SHA512dlen: con 64; MD5dlen: con 16; MD4dlen: con 16; # encryption interfaces Encrypt: con 0; Decrypt: con 1; AESbsize: con 16; aessetup: fn(key: array of byte, ivec: array of byte): ref AESstate; aescbc: fn(state: ref AESstate, buf: array of byte, n: int, direction: int); DESbsize: con 8; dessetup: fn(key: array of byte, ivec: array of byte): ref DESstate; desecb: fn(state: ref DESstate, buf: array of byte, n: int, direction: int); descbc: fn(state: ref DESstate, buf: array of byte, n: int, direction: int); IDEAbsize: con 8; ideasetup: fn(key: array of byte, ivec: array of byte): ref IDEAstate; ideaecb: fn(state: ref IDEAstate, buf: array of byte, n: int, direction: int); ideacbc: fn(state: ref IDEAstate, buf: array of byte, n: int, direction: int); BFbsize: con 8; blowfishsetup: fn(key: array of byte, ivec: array of byte): ref BFstate; # blowfishecb: fn(state: ref BFstate, buf: array of byte, n: int, direction: int); blowfishcbc: fn(state: ref BFstate, buf: array of byte, n: int, direction: int); rc4setup: fn(seed: array of byte): ref RC4state; rc4: fn(state: ref RC4state, buf: array of byte, n: int); rc4skip: fn(state: ref RC4state, n: int); rc4back: fn(state: ref RC4state, n: int); # create an alpha and p for diffie helman exchanges dhparams: fn(nbits: int): (ref IPint, ref IPint); # comm link authentication is symmetric auth: fn(fd: ref Sys->FD, info: ref Authinfo, setid: int): (string, array of byte); # auth io readauthinfo: fn(filename: string): ref Authinfo; writeauthinfo: fn(filename: string, info: ref Authinfo): int; # message io on a delimited connection (ssl for example) # messages > 4096 bytes are truncated # errors > 64 bytes are truncated # getstring and getbytearray return (result, error). getstring: fn(fd: ref Sys->FD): (string, string); putstring: fn(fd: ref Sys->FD, s: string): int; getbytearray: fn(fd: ref Sys->FD): (array of byte, string); putbytearray: fn(fd: ref Sys->FD, a: array of byte, n: int): int; puterror: fn(fd: ref Sys->FD, s: string): int; # to send and receive messages when ssl isn't pushed getmsg: fn(fd: ref Sys->FD): array of byte; sendmsg: fn(fd: ref Sys->FD, buf: array of byte, n: int): int; senderrmsg: fn(fd: ref Sys->FD, s: string): int; RSApk: adt { n: ref IPint; # modulus ek: ref IPint; # exp (encryption key) encrypt: fn(k: self ref RSApk, m: ref IPint): ref IPint; verify: fn(k: self ref RSApk, sig: ref RSAsig, m: ref IPint): int; }; RSAsk: adt { pk: ref RSApk; dk: ref IPint; # exp (decryption key) p: ref IPint; # q in pkcs q: ref IPint; # p in pkcs # precomputed crt values kp: ref IPint; # k mod p-1 kq: ref IPint; # k mod q-1 c2: ref IPint; # for converting residues to number gen: fn(nlen: int, elen: int, nrep: int): ref RSAsk; fill: fn(n: ref IPint, e: ref IPint, d: ref IPint, p: ref IPint, q: ref IPint): ref RSAsk; decrypt: fn(k: self ref RSAsk, m: ref IPint): ref IPint; sign: fn(k: self ref RSAsk, m: ref IPint): ref RSAsig; }; RSAsig: adt { n: ref IPint; }; DSApk: adt { p: ref IPint; # modulus q: ref IPint; # group order, q divides p-1 alpha: ref IPint; # group generator key: ref IPint; # encryption key (alpha**secret mod p) verify: fn(k: self ref DSApk, sig: ref DSAsig, m: ref IPint): int; }; DSAsk: adt { pk: ref DSApk; secret: ref IPint; # decryption key gen: fn(oldpk: ref DSApk): ref DSAsk; sign: fn(k: self ref DSAsk, m: ref IPint): ref DSAsig; }; DSAsig: adt { r: ref IPint; s: ref IPint; }; EGpk: adt { p: ref IPint; # modulus alpha: ref IPint; # generator key: ref IPint; # encryption key (alpha**secret mod p) verify: fn(k: self ref EGpk, sig: ref EGsig, m: ref IPint): int; }; EGsk: adt { pk: ref EGpk; secret: ref IPint; # decryption key gen: fn(nlen: int, nrep: int): ref EGsk; sign: fn(k: self ref EGsk, m: ref IPint): ref EGsig; }; EGsig: adt { r: ref IPint; s: ref IPint; }; };