Upgrade to Digest::SHA 5.46

[p5sagit/p5-mst-13.2.git] / ext / Digest / SHA / src / sha.c

/*
 * sha.c: routines to compute SHA-1/224/256/384/512 digests
 *
 * Ref: NIST FIPS PUB 180-2 Secure Hash Standard
 *
 * Copyright (C) 2003-2007 Mark Shelor, All Rights Reserved
 *
 * Version: 5.46
 * Wed Apr  9 05:04:00 MST 2008
 *
 */

#include <stdio.h>
#include <stdlib.h>
#include <stddef.h>
#include <string.h>
#include <ctype.h>
#include "sha.h"
#include "sha64bit.h"

#define W32     SHA32                   /* useful abbreviations */
#define C32     SHA32_CONST
#define SR32    SHA32_SHR
#define SL32    SHA32_SHL
#define LO32    SHA_LO32
#define UCHR    unsigned char
#define UINT    unsigned int
#define ULNG    unsigned long
#define VP      void *

#define ROTR(x, n)      (SR32(x, n) | SL32(x, 32-(n)))
#define ROTL(x, n)      (SL32(x, n) | SR32(x, 32-(n)))

#define Ch(x, y, z)     ((z) ^ ((x) & ((y) ^ (z))))
#define Pa(x, y, z)     ((x) ^ (y) ^ (z))
#define Ma(x, y, z)     (((x) & (y)) | ((z) & ((x) | (y))))

#define SIGMA0(x)       (ROTR(x,  2) ^ ROTR(x, 13) ^ ROTR(x, 22))
#define SIGMA1(x)       (ROTR(x,  6) ^ ROTR(x, 11) ^ ROTR(x, 25))
#define sigma0(x)       (ROTR(x,  7) ^ ROTR(x, 18) ^ SR32(x,  3))
#define sigma1(x)       (ROTR(x, 17) ^ ROTR(x, 19) ^ SR32(x, 10))

#define K1      C32(0x5a827999)         /* SHA-1 constants */
#define K2      C32(0x6ed9eba1)
#define K3      C32(0x8f1bbcdc)
#define K4      C32(0xca62c1d6)

static W32 K256[64] =                   /* SHA-224/256 constants */
{
        C32(0x428a2f98), C32(0x71374491), C32(0xb5c0fbcf), C32(0xe9b5dba5),
        C32(0x3956c25b), C32(0x59f111f1), C32(0x923f82a4), C32(0xab1c5ed5),
        C32(0xd807aa98), C32(0x12835b01), C32(0x243185be), C32(0x550c7dc3),
        C32(0x72be5d74), C32(0x80deb1fe), C32(0x9bdc06a7), C32(0xc19bf174),
        C32(0xe49b69c1), C32(0xefbe4786), C32(0x0fc19dc6), C32(0x240ca1cc),
        C32(0x2de92c6f), C32(0x4a7484aa), C32(0x5cb0a9dc), C32(0x76f988da),
        C32(0x983e5152), C32(0xa831c66d), C32(0xb00327c8), C32(0xbf597fc7),
        C32(0xc6e00bf3), C32(0xd5a79147), C32(0x06ca6351), C32(0x14292967),
        C32(0x27b70a85), C32(0x2e1b2138), C32(0x4d2c6dfc), C32(0x53380d13),
        C32(0x650a7354), C32(0x766a0abb), C32(0x81c2c92e), C32(0x92722c85),
        C32(0xa2bfe8a1), C32(0xa81a664b), C32(0xc24b8b70), C32(0xc76c51a3),
        C32(0xd192e819), C32(0xd6990624), C32(0xf40e3585), C32(0x106aa070),
        C32(0x19a4c116), C32(0x1e376c08), C32(0x2748774c), C32(0x34b0bcb5),
        C32(0x391c0cb3), C32(0x4ed8aa4a), C32(0x5b9cca4f), C32(0x682e6ff3),
        C32(0x748f82ee), C32(0x78a5636f), C32(0x84c87814), C32(0x8cc70208),
        C32(0x90befffa), C32(0xa4506ceb), C32(0xbef9a3f7), C32(0xc67178f2)
};

static W32 H01[5] =                     /* SHA-1 initial hash value */
{
        C32(0x67452301), C32(0xefcdab89), C32(0x98badcfe),
        C32(0x10325476), C32(0xc3d2e1f0)
};

static W32 H0224[8] =                   /* SHA-224 initial hash value */
{
        C32(0xc1059ed8), C32(0x367cd507), C32(0x3070dd17), C32(0xf70e5939),
        C32(0xffc00b31), C32(0x68581511), C32(0x64f98fa7), C32(0xbefa4fa4)
};

static W32 H0256[8] =                   /* SHA-256 initial hash value */
{
        C32(0x6a09e667), C32(0xbb67ae85), C32(0x3c6ef372), C32(0xa54ff53a),
        C32(0x510e527f), C32(0x9b05688c), C32(0x1f83d9ab), C32(0x5be0cd19)
};

static void sha1(SHA *s, UCHR *block)           /* SHA-1 transform */
{
        W32 a, b, c, d, e;
        SHA_STO_CLASS W32 W[16];
        W32 *wp = W;
        W32 *H = (W32 *) s->H;

        SHA32_SCHED(W, block);

/*
 * Use SHA-1 alternate method from FIPS PUB 180-2 (ref. 6.1.3)
 *
 * To improve performance, unroll the loop and consolidate assignments
 * by changing the roles of variables "a" through "e" at each step.
 * Note that the variable "T" is no longer needed.
 */

#define M1(a, b, c, d, e, f, k, w)              \
        e += ROTL(a, 5) + f(b, c, d) + k + w;   \
        b =  ROTL(b, 30)

#define M11(f, k, w)    M1(a, b, c, d, e, f, k, w);
#define M12(f, k, w)    M1(e, a, b, c, d, f, k, w);
#define M13(f, k, w)    M1(d, e, a, b, c, f, k, w);
#define M14(f, k, w)    M1(c, d, e, a, b, f, k, w);
#define M15(f, k, w)    M1(b, c, d, e, a, f, k, w);

#define W11(s)  W[(s+ 0) & 0xf]
#define W12(s)  W[(s+13) & 0xf]
#define W13(s)  W[(s+ 8) & 0xf]
#define W14(s)  W[(s+ 2) & 0xf]

#define A1(s)   (W11(s) = ROTL(W11(s) ^ W12(s) ^ W13(s) ^ W14(s), 1))

        a = H[0]; b = H[1]; c = H[2]; d = H[3]; e = H[4];

        M11(Ch, K1,  *wp++); M12(Ch, K1,  *wp++); M13(Ch, K1,  *wp++);
        M14(Ch, K1,  *wp++); M15(Ch, K1,  *wp++); M11(Ch, K1,  *wp++);
        M12(Ch, K1,  *wp++); M13(Ch, K1,  *wp++); M14(Ch, K1,  *wp++);
        M15(Ch, K1,  *wp++); M11(Ch, K1,  *wp++); M12(Ch, K1,  *wp++);
        M13(Ch, K1,  *wp++); M14(Ch, K1,  *wp++); M15(Ch, K1,  *wp++);
        M11(Ch, K1,  *wp  ); M12(Ch, K1, A1( 0)); M13(Ch, K1, A1( 1));
        M14(Ch, K1, A1( 2)); M15(Ch, K1, A1( 3)); M11(Pa, K2, A1( 4));
        M12(Pa, K2, A1( 5)); M13(Pa, K2, A1( 6)); M14(Pa, K2, A1( 7));
        M15(Pa, K2, A1( 8)); M11(Pa, K2, A1( 9)); M12(Pa, K2, A1(10));
        M13(Pa, K2, A1(11)); M14(Pa, K2, A1(12)); M15(Pa, K2, A1(13));
        M11(Pa, K2, A1(14)); M12(Pa, K2, A1(15)); M13(Pa, K2, A1( 0));
        M14(Pa, K2, A1( 1)); M15(Pa, K2, A1( 2)); M11(Pa, K2, A1( 3));
        M12(Pa, K2, A1( 4)); M13(Pa, K2, A1( 5)); M14(Pa, K2, A1( 6));
        M15(Pa, K2, A1( 7)); M11(Ma, K3, A1( 8)); M12(Ma, K3, A1( 9));
        M13(Ma, K3, A1(10)); M14(Ma, K3, A1(11)); M15(Ma, K3, A1(12));
        M11(Ma, K3, A1(13)); M12(Ma, K3, A1(14)); M13(Ma, K3, A1(15));
        M14(Ma, K3, A1( 0)); M15(Ma, K3, A1( 1)); M11(Ma, K3, A1( 2));
        M12(Ma, K3, A1( 3)); M13(Ma, K3, A1( 4)); M14(Ma, K3, A1( 5));
        M15(Ma, K3, A1( 6)); M11(Ma, K3, A1( 7)); M12(Ma, K3, A1( 8));
        M13(Ma, K3, A1( 9)); M14(Ma, K3, A1(10)); M15(Ma, K3, A1(11));
        M11(Pa, K4, A1(12)); M12(Pa, K4, A1(13)); M13(Pa, K4, A1(14));
        M14(Pa, K4, A1(15)); M15(Pa, K4, A1( 0)); M11(Pa, K4, A1( 1));
        M12(Pa, K4, A1( 2)); M13(Pa, K4, A1( 3)); M14(Pa, K4, A1( 4));
        M15(Pa, K4, A1( 5)); M11(Pa, K4, A1( 6)); M12(Pa, K4, A1( 7));
        M13(Pa, K4, A1( 8)); M14(Pa, K4, A1( 9)); M15(Pa, K4, A1(10));
        M11(Pa, K4, A1(11)); M12(Pa, K4, A1(12)); M13(Pa, K4, A1(13));
        M14(Pa, K4, A1(14)); M15(Pa, K4, A1(15));

        H[0] += a; H[1] += b; H[2] += c; H[3] += d; H[4] += e;
}

static void sha256(SHA *s, UCHR *block)         /* SHA-224/256 transform */
{
        W32 a, b, c, d, e, f, g, h, T1;
        SHA_STO_CLASS W32 W[16];
        W32 *kp = K256;
        W32 *wp = W;
        W32 *H = (W32 *) s->H;

        SHA32_SCHED(W, block);

/*
 * Use same technique as in sha1()
 *
 * To improve performance, unroll the loop and consolidate assignments
 * by changing the roles of variables "a" through "h" at each step.
 * Note that the variable "T2" is no longer needed.
 */

#define M2(a, b, c, d, e, f, g, h, w)                           \
        T1 = h  + SIGMA1(e) + Ch(e, f, g) + (*kp++) + w;        \
        h  = T1 + SIGMA0(a) + Ma(a, b, c); d += T1;

#define W21(s)  W[(s+ 0) & 0xf]
#define W22(s)  W[(s+14) & 0xf]
#define W23(s)  W[(s+ 9) & 0xf]
#define W24(s)  W[(s+ 1) & 0xf]

#define A2(s)   (W21(s) += sigma1(W22(s)) + W23(s) + sigma0(W24(s)))

#define M21(w)  M2(a, b, c, d, e, f, g, h, w)
#define M22(w)  M2(h, a, b, c, d, e, f, g, w)
#define M23(w)  M2(g, h, a, b, c, d, e, f, w)
#define M24(w)  M2(f, g, h, a, b, c, d, e, w)
#define M25(w)  M2(e, f, g, h, a, b, c, d, w)
#define M26(w)  M2(d, e, f, g, h, a, b, c, w)
#define M27(w)  M2(c, d, e, f, g, h, a, b, w)
#define M28(w)  M2(b, c, d, e, f, g, h, a, w)

        a = H[0]; b = H[1]; c = H[2]; d = H[3];
        e = H[4]; f = H[5]; g = H[6]; h = H[7];

        M21( *wp++); M22( *wp++); M23( *wp++); M24( *wp++);
        M25( *wp++); M26( *wp++); M27( *wp++); M28( *wp++);
        M21( *wp++); M22( *wp++); M23( *wp++); M24( *wp++);
        M25( *wp++); M26( *wp++); M27( *wp++); M28( *wp  );
        M21(A2( 0)); M22(A2( 1)); M23(A2( 2)); M24(A2( 3));
        M25(A2( 4)); M26(A2( 5)); M27(A2( 6)); M28(A2( 7));
        M21(A2( 8)); M22(A2( 9)); M23(A2(10)); M24(A2(11));
        M25(A2(12)); M26(A2(13)); M27(A2(14)); M28(A2(15));
        M21(A2( 0)); M22(A2( 1)); M23(A2( 2)); M24(A2( 3));
        M25(A2( 4)); M26(A2( 5)); M27(A2( 6)); M28(A2( 7));
        M21(A2( 8)); M22(A2( 9)); M23(A2(10)); M24(A2(11));
        M25(A2(12)); M26(A2(13)); M27(A2(14)); M28(A2(15));
        M21(A2( 0)); M22(A2( 1)); M23(A2( 2)); M24(A2( 3));
        M25(A2( 4)); M26(A2( 5)); M27(A2( 6)); M28(A2( 7));
        M21(A2( 8)); M22(A2( 9)); M23(A2(10)); M24(A2(11));
        M25(A2(12)); M26(A2(13)); M27(A2(14)); M28(A2(15));

        H[0] += a; H[1] += b; H[2] += c; H[3] += d;
        H[4] += e; H[5] += f; H[6] += g; H[7] += h;
}

#include "sha64bit.c"

#define SETBIT(s, pos)  s[(pos) >> 3] |=  (0x01 << (7 - (pos) % 8))
#define CLRBIT(s, pos)  s[(pos) >> 3] &= ~(0x01 << (7 - (pos) % 8))
#define NBYTES(nbits)   ((nbits) > 0 ? 1 + (((nbits) - 1) >> 3) : 0)
#define HEXLEN(nbytes)  ((nbytes) << 1)
#define B64LEN(nbytes)  (((nbytes) % 3 == 0) ? ((nbytes) / 3) * 4 \
                        : ((nbytes) / 3) * 4 + ((nbytes) % 3) + 1)

/* w32mem: writes 32-bit word to memory in big-endian order */
static void w32mem(UCHR *mem, W32 w32)
{
        int i;

        for (i = 0; i < 4; i++)
                *mem++ = (UCHR) (SR32(w32, 24-i*8) & 0xff);
}

/* digcpy: writes current state to digest buffer */
static void digcpy(SHA *s)
{
        UINT i;
        UCHR *d = s->digest;
        W32 *p32 = (W32 *) s->H;
        W64 *p64 = (W64 *) s->H;

        if (s->alg <= SHA256)
                for (i = 0; i < 8; i++, d += 4)
                        w32mem(d, *p32++);
        else
                for (i = 0; i < 8; i++, d += 8) {
                        w32mem(d, (W32) ((*p64 >> 16) >> 16));
                        w32mem(d+4, (W32) (*p64++ & SHA32_MAX));
                }
}

#define SHA_INIT(algo, transform)                                       \
        do {                                                            \
                memset(s, 0, sizeof(SHA));                              \
                s->alg = algo; s->sha = sha ## transform;               \
                memcpy(s->H, H0 ## algo, sizeof(H0 ## algo));           \
                s->blocksize = SHA ## algo ## _BLOCK_BITS;              \
                s->digestlen = SHA ## algo ## _DIGEST_BITS >> 3;        \
        } while (0)

/* sharewind: re-initializes the digest object */
void sharewind(SHA *s)
{
        if      (s->alg == SHA1)   SHA_INIT(1, 1);
        else if (s->alg == SHA224) SHA_INIT(224, 256);
        else if (s->alg == SHA256) SHA_INIT(256, 256);
        else if (s->alg == SHA384) SHA_INIT(384, 512);
        else if (s->alg == SHA512) SHA_INIT(512, 512);
}

/* shaopen: creates a new digest object */
SHA *shaopen(int alg)
{
        SHA *s;

        if (alg != SHA1 && alg != SHA224 && alg != SHA256 &&
                alg != SHA384 && alg != SHA512)
                return(NULL);
        if (alg >= SHA384 && !sha_384_512)
                return(NULL);
        SHA_newz(0, s, 1, SHA);
        if (s == NULL)
                return(NULL);
        s->alg = alg;
        sharewind(s);
        return(s);
}

/* shadirect: updates state directly (w/o going through s->block) */
static ULNG shadirect(UCHR *bitstr, ULNG bitcnt, SHA *s)
{
        ULNG savecnt = bitcnt;

        while (bitcnt >= s->blocksize) {
                s->sha(s, bitstr);
                bitstr += (s->blocksize >> 3);
                bitcnt -= s->blocksize;
        }
        if (bitcnt > 0) {
                memcpy(s->block, bitstr, NBYTES(bitcnt));
                s->blockcnt = bitcnt;
        }
        return(savecnt);
}

/* shabytes: updates state for byte-aligned input data */
static ULNG shabytes(UCHR *bitstr, ULNG bitcnt, SHA *s)
{
        UINT offset;
        UINT nbits;
        ULNG savecnt = bitcnt;

        offset = s->blockcnt >> 3;
        if (s->blockcnt + bitcnt >= s->blocksize) {
                nbits = s->blocksize - s->blockcnt;
                memcpy(s->block+offset, bitstr, nbits>>3);
                bitcnt -= nbits;
                bitstr += (nbits >> 3);
                s->sha(s, s->block), s->blockcnt = 0;
                shadirect(bitstr, bitcnt, s);
        }
        else {
                memcpy(s->block+offset, bitstr, NBYTES(bitcnt));
                s->blockcnt += bitcnt;
        }
        return(savecnt);
}

/* shabits: updates state for bit-aligned input data */
static ULNG shabits(UCHR *bitstr, ULNG bitcnt, SHA *s)
{
        UINT i;
        UINT gap;
        ULNG nbits;
        UCHR buf[1<<9];
        UINT bufsize = sizeof(buf);
        ULNG bufbits = (ULNG) bufsize << 3;
        UINT nbytes = NBYTES(bitcnt);
        ULNG savecnt = bitcnt;

        gap = 8 - s->blockcnt % 8;
        s->block[s->blockcnt>>3] &= ~0 << gap;
        s->block[s->blockcnt>>3] |= *bitstr >> (8 - gap);
        s->blockcnt += bitcnt < gap ? bitcnt : gap;
        if (bitcnt < gap)
                return(savecnt);
        if (s->blockcnt == s->blocksize)
                s->sha(s, s->block), s->blockcnt = 0;
        if ((bitcnt -= gap) == 0)
                return(savecnt);
        while (nbytes > bufsize) {
                for (i = 0; i < bufsize; i++)
                        buf[i] = bitstr[i] << gap | bitstr[i+1] >> (8-gap);
                nbits = bitcnt < bufbits ? bitcnt : bufbits;
                shabytes(buf, nbits, s);
                bitcnt -= nbits, bitstr += bufsize, nbytes -= bufsize;
        }
        for (i = 0; i < nbytes - 1; i++)
                buf[i] = bitstr[i] << gap | bitstr[i+1] >> (8-gap);
        buf[nbytes-1] = bitstr[nbytes-1] << gap;
        shabytes(buf, bitcnt, s);
        return(savecnt);
}

/* shawrite: triggers a state update using data in bitstr/bitcnt */
ULNG shawrite(UCHR *bitstr, ULNG bitcnt, SHA *s)
{
        if (bitcnt < 1)
                return(0);
        if (SHA_LO32(s->lenll += bitcnt) < bitcnt)
                if (SHA_LO32(++s->lenlh) == 0)
                        if (SHA_LO32(++s->lenhl) == 0)
                                s->lenhh++;
        if (s->blockcnt == 0)
                return(shadirect(bitstr, bitcnt, s));
        else if (s->blockcnt % 8 == 0)
                return(shabytes(bitstr, bitcnt, s));
        else
                return(shabits(bitstr, bitcnt, s));
}

/* shafinish: pads remaining block(s) and computes final digest state */
void shafinish(SHA *s)
{
        UINT lenpos, lhpos, llpos;

        lenpos = s->blocksize == SHA1_BLOCK_BITS ? 448 : 896;
        lhpos  = s->blocksize == SHA1_BLOCK_BITS ?  56 : 120;
        llpos  = s->blocksize == SHA1_BLOCK_BITS ?  60 : 124;
        SETBIT(s->block, s->blockcnt), s->blockcnt++;
        while (s->blockcnt > lenpos)
                if (s->blockcnt < s->blocksize)
                        CLRBIT(s->block, s->blockcnt), s->blockcnt++;
                else
                        s->sha(s, s->block), s->blockcnt = 0;
        while (s->blockcnt < lenpos)
                CLRBIT(s->block, s->blockcnt), s->blockcnt++;
        if (s->blocksize > SHA1_BLOCK_BITS) {
                w32mem(s->block + 112, s->lenhh);
                w32mem(s->block + 116, s->lenhl);
        }
        w32mem(s->block + lhpos, s->lenlh);
        w32mem(s->block + llpos, s->lenll);
        s->sha(s, s->block);
}

/* shadigest: returns pointer to current digest (binary) */
UCHR *shadigest(SHA *s)
{
        digcpy(s);
        return(s->digest);
}

/* shahex: returns pointer to current digest (hexadecimal) */
char *shahex(SHA *s)
{
        int i;

        digcpy(s);
        s->hex[0] = '\0';
        if (HEXLEN((size_t) s->digestlen) >= sizeof(s->hex))
                return(s->hex);
        for (i = 0; i < s->digestlen; i++)
                sprintf(s->hex+i*2, "%02x", s->digest[i]);
        return(s->hex);
}

/* map: translation map for Base 64 encoding */
static char map[] =
        "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789+/";

/* encbase64: encodes input (0 to 3 bytes) into Base 64 */
static void encbase64(UCHR *in, int n, char *out)
{
        UCHR byte[3] = {0, 0, 0};

        out[0] = '\0';
        if (n < 1 || n > 3)
                return;
        memcpy(byte, in, n);
        out[0] = map[byte[0] >> 2];
        out[1] = map[((byte[0] & 0x03) << 4) | (byte[1] >> 4)];
        out[2] = map[((byte[1] & 0x0f) << 2) | (byte[2] >> 6)];
        out[3] = map[byte[2] & 0x3f];
        out[n+1] = '\0';
}

/* shabase64: returns pointer to current digest (Base 64) */
char *shabase64(SHA *s)
{
        int n;
        UCHR *q;
        char out[5];

        digcpy(s);
        s->base64[0] = '\0';
        if (B64LEN(s->digestlen) >= sizeof(s->base64))
                return(s->base64);
        for (n = s->digestlen, q = s->digest; n > 3; n -= 3, q += 3) {
                encbase64(q, 3, out);
                strcat(s->base64, out);
        }
        encbase64(q, n, out);
        strcat(s->base64, out);
        return(s->base64);
}

/* shadsize: returns length of digest in bytes */
int shadsize(SHA *s)
{
        return(s->digestlen);
}

/* shadup: duplicates current digest object */
SHA *shadup(SHA *s)
{
        SHA *p;

        SHA_new(0, p, 1, SHA);
        if (p == NULL)
                return(NULL);
        memcpy(p, s, sizeof(SHA));
        return(p);
}

/* shadump: dumps digest object to a human-readable ASCII file */
int shadump(char *file, SHA *s)
{
        int i, j;
        SHA_FILE *f;
        UCHR *p = shadigest(s);

        if (file == NULL || strlen(file) == 0)
                f = SHA_stdout();
        else if ((f = SHA_open(file, "w")) == NULL)
                return(0);
        SHA_fprintf(f, "alg:%d\nH", s->alg);
        for (i = 0; i < 8; i++)
                for (j = 0; j < (s->alg <= 256 ? 4 : 8); j++)
                        SHA_fprintf(f, "%s%02x", j==0 ? ":" : "", *p++);
        SHA_fprintf(f, "\nblock");
        for (i = 0; i < (int) (s->blocksize >> 3); i++)
                SHA_fprintf(f, ":%02x", s->block[i]);
        SHA_fprintf(f, "\nblockcnt:%u\n", s->blockcnt);
        SHA_fprintf(f, "lenhh:%lu\nlenhl:%lu\nlenlh:%lu\nlenll:%lu\n",
                (ULNG) LO32(s->lenhh), (ULNG) LO32(s->lenhl),
                (ULNG) LO32(s->lenlh), (ULNG) LO32(s->lenll));
        if (f != SHA_stdout())
                SHA_close(f);
        return(1);
}

/* fgetstr: reads (and returns pointer to) next line of file */
static char *fgetstr(char *line, UINT maxsize, SHA_FILE *f)
{
        char *p;

        if (SHA_feof(f) || maxsize == 0)
                return(NULL);
        for (p = line; !SHA_feof(f) && maxsize > 1; maxsize--)
                if ((*p++ = SHA_getc(f)) == '\n')
                        break;
        *p = '\0';
        return(line);
}

/* empty: returns true if line contains only whitespace characters */
static int empty(char *line)
{
        char *p;

        for (p = line; *p; p++)
                if (!isspace(*p))
                        return(0);
        return(1);
}

/* getval: null-terminates field value, and sets pointer to rest of line */
static char *getval(char *line, char **pprest)
{
        char *p, *v;

        for (v = line; *v == ':' || isspace(*v); v++)
                ;
        for (p = v; *p; p++) {
                if (*p == ':' || isspace(*p)) {
                        *p++ = '\0';
                        break;
                }
        }
        *pprest = p;
        return(p == v ? NULL : v);
}

/* types of values present in dump file */
#define T_C 1                   /* character */
#define T_I 2                   /* normal integer */
#define T_L 3                   /* 32-bit value */
#define T_Q 4                   /* 64-bit value */

/* ldvals: checks next line in dump file against tag, and loads values */
static int ldvals(
        SHA_FILE *f,
        const char *tag,
        int type,
        void *pval,
        int reps,
        int base)
{
        char *p, *pr, line[512];
        UCHR *pc = (UCHR *) pval; UINT *pi = (UINT *) pval;
        W32  *pl = (W32  *) pval; W64  *pq = (W64  *) pval;

        while ((p = fgetstr(line, sizeof(line), f)) != NULL)
                if (line[0] != '#' && !empty(line))
                        break;
        if (p == NULL || strcmp(getval(line, &pr), tag) != 0)
                return(0);
        while (reps-- > 0) {
                if ((p = getval(pr, &pr)) == NULL)
                        return(1);
                switch (type) {
                case T_C: *pc++ = (UCHR) strtoul(p, NULL, base); break;
                case T_I: *pi++ = (UINT) strtoul(p, NULL, base); break;
                case T_L: *pl++ = (W32 ) strtoul(p, NULL, base); break;
                case T_Q: *pq++ = (W64 ) strto64(p            ); break;
                }
        }
        return(1);
}

/* closeall: closes dump file and de-allocates digest object */
static SHA *closeall(SHA_FILE *f, SHA *s)
{
        if (f != NULL && f != SHA_stdin())
                SHA_close(f);
        if (s != NULL)
                shaclose(s);
        return(NULL);
}

/* shaload: creates digest object corresponding to contents of dump file */
SHA *shaload(char *file)
{
        int alg;
        SHA *s = NULL;
        SHA_FILE *f;

        if (file == NULL || strlen(file) == 0)
                f = SHA_stdin();
        else if ((f = SHA_open(file, "r")) == NULL)
                return(NULL);
        if (
                /* avoid parens by exploiting precedence of (type)&-> */
                !ldvals(f,"alg",T_I,(VP)&alg,1,10)                      ||
                ((s = shaopen(alg)) == NULL)                            ||
                !ldvals(f,"H",alg<=SHA256?T_L:T_Q,(VP)s->H,8,16)        ||
                !ldvals(f,"block",T_C,(VP)s->block,s->blocksize/8,16)   ||
                !ldvals(f,"blockcnt",T_I,(VP)&s->blockcnt,1,10)         ||
                (alg <= SHA256 && s->blockcnt >= SHA1_BLOCK_BITS)       ||
                (alg >= SHA384 && s->blockcnt >= SHA384_BLOCK_BITS)     ||
                !ldvals(f,"lenhh",T_L,(VP)&s->lenhh,1,10)               ||
                !ldvals(f,"lenhl",T_L,(VP)&s->lenhl,1,10)               ||
                !ldvals(f,"lenlh",T_L,(VP)&s->lenlh,1,10)               ||
                !ldvals(f,"lenll",T_L,(VP)&s->lenll,1,10)
        )
                return(closeall(f, s));
        if (f != SHA_stdin())
                SHA_close(f);
        return(s);
}

/* shaclose: de-allocates digest object */
int shaclose(SHA *s)
{
        if (s != NULL) {
                memset(s, 0, sizeof(SHA));
                SHA_free(s);
        }
        return(0);
}