/* * ccn.h * corecrypto * * Created by Michael Brouwer on 7/25/10. * Copyright 2010,2011 Apple Inc. All rights reserved. * */ #ifndef _CORECRYPTO_CCN_H_ #define _CORECRYPTO_CCN_H_ #include #include /* TODO: Get rid of this include in this header. */ #include typedef uint8_t cc_byte; typedef size_t cc_size; #if CCN_UNIT_SIZE == 8 typedef uint64_t cc_unit; // 64 bit unit //typedef uint128_t cc_dunit; // 128 bit double width unit #define CCN_LOG2_BITS_PER_UNIT 6 // 2^6 = 64 bits #define CC_UNIT_C(x) UINT64_C(x) #elif CCN_UNIT_SIZE == 4 typedef uint32_t cc_unit; // 32 bit unit typedef uint64_t cc_dunit; // 64 bit double width unit #define CCN_LOG2_BITS_PER_UNIT 5 // 2^5 = 32 bits #define CC_UNIT_C(x) UINT32_C(x) #elif CCN_UNIT_SIZE == 2 typedef uint16_t cc_unit; // 16 bit unit typedef uint32_t cc_dunit; // 32 bit double width unit #define CCN_LOG2_BITS_PER_UNIT 4 // 2^4 = 16 bits #define CC_UNIT_C(x) UINT16_C(x) #elif CCN_UNIT_SIZE == 1 typedef uint8_t cc_unit; // 8 bit unit typedef uint16_t cc_dunit; // 16 bit double width unit #define CCN_LOG2_BITS_PER_UNIT 3 // 2^3 = 8 bits #define CC_UNIT_C(x) UINT8_C(x) #else #error invalid CCN_UNIT_SIZE #endif // All mp types have units in little endian unit order. typedef cc_unit *ccn_t; // n unit long mp typedef cc_unit *ccnp1_t; // n + 1 unit long mp typedef cc_unit *cc2n_t; // 2 * n unit long mp typedef cc_unit *cc2np2_t; // 2 * n + 2 unit long mp typedef const cc_unit *ccn_in_t; // n unit long mp typedef const cc_unit *ccnp1_in_t; // n + 1 unit long mp typedef const cc_unit *cc2n_in_t; // 2 * n unit long mp typedef const cc_unit *cc2np2_in_t; // 2 * n + 2 unit long mp #define CCN_UNIT_BITS (sizeof(cc_unit) * 8) #define CCN_UNIT_MASK ((cc_unit)~0) /* Conversions between n sizeof and bits */ /* Returns the sizeof a ccn vector of length _n_ units. */ #define ccn_sizeof_n(_n_) (sizeof(cc_unit) * (_n_)) /* Returns the count (n) of a ccn vector that can represent _bits_. */ #define ccn_nof(_bits_) (((_bits_) + CCN_UNIT_BITS - 1) / CCN_UNIT_BITS) /* Returns the sizeof a ccn vector that can represent _bits_. */ #define ccn_sizeof(_bits_) (ccn_sizeof_n(ccn_nof(_bits_))) /* Returns the count (n) of a ccn vector that can represent _size_ bytes. */ #define ccn_nof_size(_size_) (((_size_) + CCN_UNIT_SIZE - 1) / CCN_UNIT_SIZE) /* Return the max number of bits a ccn vector of _n_ units can hold. */ #define ccn_bitsof_n(_n_) ((_n_) * CCN_UNIT_BITS) /* Return the max number of bits a ccn vector of _size_ bytes can hold. */ #define ccn_bitsof_size(_size_) ((_size_) * 8) /* Return the size of a ccn of size bytes in bytes. */ #define ccn_sizeof_size(_size_) ccn_sizeof_n(ccn_nof_size(_size_)) /* Returns the value of bit _k_ of _ccn_, both are only evaluated once. */ #define ccn_bit(_ccn_, _k_) ({__typeof__ (_k_) __k = (_k_); \ 1 & ((_ccn_)[__k / CCN_UNIT_BITS] >> (__k & (CCN_UNIT_BITS - 1)));}) #define ccn_set_bit(_ccn_, _k_, _v_) ({__typeof__ (_k_) __k = (_k_); \ if (_v_) \ (_ccn_)[__k/CCN_UNIT_BITS] |= CC_UNIT_C(1) << (__k & (CCN_UNIT_BITS - 1)); \ else \ (_ccn_)[__k/CCN_UNIT_BITS] &= ~(CC_UNIT_C(1) << (__k & (CCN_UNIT_BITS - 1))); \ }) /* Macros for making ccn constants. You must use list of CCN64_C() instances separated by commas, with an optional smaller sized CCN32_C, CCN16_C, or CCN8_C() instance at the end of the list, when making macros to declare larger sized constants. */ #define CCN8_C(a0) CC_UNIT_C(0x##a0) #if CCN_UNIT_SIZE >= 2 #define CCN16_C(a1,a0) CC_UNIT_C(0x##a1##a0) #define ccn16_v(a0) (a0) #elif CCN_UNIT_SIZE == 1 #define CCN16_C(a1,a0) CCN8_C(a0),CCN8_C(a1) #define ccn16_v(a0) (a0 & UINT8_C(0xff)),(a0 >> 8) #endif #if CCN_UNIT_SIZE >= 4 #define CCN32_C(a3,a2,a1,a0) CC_UNIT_C(0x##a3##a2##a1##a0) #define ccn32_v(a0) (a0) #else #define CCN32_C(a3,a2,a1,a0) CCN16_C(a1,a0),CCN16_C(a3,a2) #define ccn32_v(a0) ccn16_v(a0 & UINT16_C(0xffff)),ccn16_v(a0 >> 16) #endif #if CCN_UNIT_SIZE == 8 #define CCN64_C(a7,a6,a5,a4,a3,a2,a1,a0) CC_UNIT_C(0x##a7##a6##a5##a4##a3##a2##a1##a0) #define CCN40_C(a4,a3,a2,a1,a0) CC_UNIT_C(0x##a4##a3##a2##a1##a0) #define ccn64_v(a0) (a0) //#define ccn64_32(a1,a0) ((a1 << 32) | a0) //#define ccn_uint64(a,i) (a[i]) #else #define CCN64_C(a7,a6,a5,a4,a3,a2,a1,a0) CCN32_C(a3,a2,a1,a0),CCN32_C(a7,a6,a5,a4) #define CCN40_C(a4,a3,a2,a1,a0) CCN32_C(a3,a2,a1,a0),CCN8_C(a4) #define ccn64_v(a0) ccn32_v((uint64_t)a0 & UINT32_C(0xffffffff)),ccn32_v((uint64_t)a0 >> 32) //#define ccn64_32(a1,a0) ccn32_v(a0),ccn32_v(a1) //#define ccn_uint64(a,i) ((uint64_t)ccn_uint32(a, i << 1 + 1) << 32 | (uint64_t)ccn_uint32(a, i << 1)) #endif /* Macro's for reading uint32_t and uint64_t from ccns, the index is in 32 or 64 bit units respectively. */ #if CCN_UNIT_SIZE == 8 //#define ccn_uint16(a,i) ((i & 3) == 3 ? ((uint16_t)(a[i >> 2] >> 48)) : \ // (i & 3) == 2 ? ((uint16_t)(a[i >> 2] >> 32) & UINT16_C(0xffff)) : \ // (i & 3) == 1 ? ((uint16_t)(a[i >> 2] >> 16) & UINT16_C(0xffff)) : \ // ((uint16_t)(a[i >> 1] & UINT16_C(0xffff)))) //#define ccn_uint32(a,i) (i & 1 ? ((uint32_t)(a[i >> 1] >> 32)) : ((uint32_t)(a[i >> 1] & UINT32_C(0xffffffff)))) #elif CCN_UNIT_SIZE == 4 //#define ccn16_v(a0) (a0) //#define ccn32_v(a0) (a0) //#define ccn_uint16(a,i) (i & 1 ? ((uint16_t)(a[i >> 1] >> 16)) : ((uint16_t)(a[i >> 1] & UINT16_C(0xffff)))) //#define ccn_uint32(a,i) (a[i]) #elif CCN_UNIT_SIZE == 2 //#define ccn16_v(a0) (a0) //#define ccn32_v(a0,a1) (a1,a0) //#define ccn_uint16(a,i) (a[i]) //#define ccn_uint32(a,i) (((uint32_t)a[i << 1 + 1]) << 16 | (uint32_t)a[i << 1])) #elif CCN_UNIT_SIZE == 1 //#define ccn16_v(a0) (a0 & UINT8_C(0xff)),(a0 >> 8) //#define ccn_uint16(a,i) ((uint16_t)((a[i << 1 + 1] << 8) | a[i << 1])) //#define ccn_uint32(a,i) ((uint32_t)ccn_uint16(a, i << 1 + 1) << 16 | (uint32_t)ccn_uint16(a, i << 1)) #endif /* Macro's for reading uint32_t and uint64_t from ccns, the index is in 32 or 64 bit units respectively. */ #if CCN_UNIT_SIZE == 8 #define ccn64_32(a1,a0) (((cc_unit)a1) << 32 | ((cc_unit)a0)) #define ccn32_32(a0) a0 #if __LITTLE_ENDIAN__ #define ccn32_32_parse(p,i) (((uint32_t *)p)[i]) #else #define ccn32_32_parse(p,i) (((uint32_t *)p)[i^1]) #endif #define ccn32_32_null 0 #define ccn64_64(a0) a0 #define ccn64_64_parse(p,i) p[i] #define ccn64_64_null 0 #elif CCN_UNIT_SIZE == 4 #define ccn32_32(a0) a0 #define ccn32_32_parse(p,i) p[i] #define ccn32_32_null 0 #define ccn64_32(a1,a0) ccn32_32(a0),ccn32_32(a1) #define ccn64_64(a1,a0) a0,a1 #define ccn64_64_parse(p,i) p[1+(i<<1)],p[i<<1] #define ccn64_64_null 0,0 #elif CCN_UNIT_SIZE == 2 #define ccn32_32(a1,a0) a0,a1 #define ccn32_32_parse(p,i) p[1+(i<<1)],p[i<<1] #define ccn32_32_null 0,0 #define ccn64_32(a3,a2,a1,a0) ccn32_32(a1,a0),ccn32_32(a3,a2) #define ccn64_64(a3,a2,a1,a0) a0,a1,a2,a3 #define ccn64_64_parse(p,i) p[3+(i<<2)],p[2+(i<<2)],p[1+(i<<2)],p[i<<2] #define ccn64_64_null 0,0,0,0 #elif CCN_UNIT_SIZE == 1 #define ccn32_32(a3,a2,a1,a0) a0,a1,a2,a3 #define ccn32_32_parse(p,i) p[3+(i<<2)],p[2+(i<<2)],p[1+(i<<2)],p[i<<2] #define ccn32_32_null 0,0,0,0 #define ccn64_32(a7,a6,a5,a4,a3,a2,a1,a0) ccn32_32(a3,a2,a1,a0),ccn32_32(a7,a6,a5,a4) #define ccn64_64(a7,a6,a5,a4,a3,a2,a1,a0) a0,a1,a2,a3,a4,a5,a6,a7 #define ccn64_64_parse(p,i) p[7+(i<<3)],p[6+(i<<3)],p[5+(i<<3)],p[4+(i<<3)],p[3+(i<<3)],p[2+(i<<3)],p[1+(i<<3)],p[i<<3] #define ccn64_64_null 0,0,0,0,0,0,0,0 #endif /* Macros to construct fixed size ccn arrays from 64 or 32 bit quantities. */ #define ccn192_64(a2,a1,a0) ccn64_64(a0),ccn64_64(a1),ccn64_64(a2) #define ccn224_32(a6,a5,a4,a3,a2,a1,a0) ccn64_32(a1,a0),ccn64_32(a3,a2),ccn64_32(a5,a4),ccn32_32(a6) #define ccn256_32(a7,a6,a5,a4,a3,a2,a1,a0) ccn64_32(a1,a0),ccn64_32(a3,a2),ccn64_32(a5,a4),ccn64_32(a7,a6) #define ccn384_32(a11,a10,a9,a8,a7,a6,a5,a4,a3,a2,a1,a0) ccn64_32(a1,a0),ccn64_32(a3,a2),ccn64_32(a5,a4),ccn64_32(a7,a6),ccn64_32(a9,a8),ccn64_32(a11,a10) #define CCN192_C(c7,c6,c5,c4,c3,c2,c1,c0,b7,b6,b5,b4,b3,b2,b1,b0,a7,a6,a5,a4,a3,a2,a1,a0) \ CCN64_C(a7,a6,a5,a4,a3,a2,a1,a0),\ CCN64_C(b7,b6,b5,b4,b3,b2,b1,b0),\ CCN64_C(c7,c6,c5,c4,c3,c2,c1,c0) #define CCN200_C(d0,c7,c6,c5,c4,c3,c2,c1,c0,b7,b6,b5,b4,b3,b2,b1,b0,a7,a6,a5,a4,a3,a2,a1,a0) \ CCN192_C(c7,c6,c5,c4,c3,c2,c1,c0,b7,b6,b5,b4,b3,b2,b1,b0,a7,a6,a5,a4,a3,a2,a1,a0),\ CCN8_C(d0) #define CCN224_C(d3,d2,d1,d0,c7,c6,c5,c4,c3,c2,c1,c0,b7,b6,b5,b4,b3,b2,b1,b0,a7,a6,a5,a4,a3,a2,a1,a0) \ CCN192_C(c7,c6,c5,c4,c3,c2,c1,c0,b7,b6,b5,b4,b3,b2,b1,b0,a7,a6,a5,a4,a3,a2,a1,a0),\ CCN32_C(d3,d2,d1,d0) #define CCN232_C(d4,d3,d2,d1,d0,c7,c6,c5,c4,c3,c2,c1,c0,b7,b6,b5,b4,b3,b2,b1,b0,a7,a6,a5,a4,a3,a2,a1,a0) \ CCN192_C(c7,c6,c5,c4,c3,c2,c1,c0,b7,b6,b5,b4,b3,b2,b1,b0,a7,a6,a5,a4,a3,a2,a1,a0),\ CCN40_C(d4,d3,d2,d1,d0) #define CCN256_C(d7,d6,d5,d4,d3,d2,d1,d0,c7,c6,c5,c4,c3,c2,c1,c0,b7,b6,b5,b4,b3,b2,b1,b0,a7,a6,a5,a4,a3,a2,a1,a0) \ CCN192_C(c7,c6,c5,c4,c3,c2,c1,c0,b7,b6,b5,b4,b3,b2,b1,b0,a7,a6,a5,a4,a3,a2,a1,a0),\ CCN64_C(d7,d6,d5,d4,d3,d2,d1,d0) #define CCN264_C(e0,d7,d6,d5,d4,d3,d2,d1,d0,c7,c6,c5,c4,c3,c2,c1,c0,b7,b6,b5,b4,b3,b2,b1,b0,a7,a6,a5,a4,a3,a2,a1,a0) \ CCN256_C(d7,d6,d5,d4,d3,d2,d1,d0,c7,c6,c5,c4,c3,c2,c1,c0,b7,b6,b5,b4,b3,b2,b1,b0,a7,a6,a5,a4,a3,a2,a1,a0),\ CCN8_C(e0) #define CCN384_C(f7,f6,f5,f4,f3,f2,f1,f0,e7,e6,e5,e4,e3,e2,e1,e0,d7,d6,d5,d4,d3,d2,d1,d0,c7,c6,c5,c4,c3,c2,c1,c0,b7,b6,b5,b4,b3,b2,b1,b0,a7,a6,a5,a4,a3,a2,a1,a0) \ CCN256_C(d7,d6,d5,d4,d3,d2,d1,d0,c7,c6,c5,c4,c3,c2,c1,c0,b7,b6,b5,b4,b3,b2,b1,b0,a7,a6,a5,a4,a3,a2,a1,a0),\ CCN64_C(e7,e6,e5,e4,e3,e2,e1,e0),\ CCN64_C(f7,f6,f5,f4,f3,f2,f1,f0) #define CCN392_C(g0,f7,f6,f5,f4,f3,f2,f1,f0,e7,e6,e5,e4,e3,e2,e1,e0,d7,d6,d5,d4,d3,d2,d1,d0,c7,c6,c5,c4,c3,c2,c1,c0,b7,b6,b5,b4,b3,b2,b1,b0,a7,a6,a5,a4,a3,a2,a1,a0) \ CCN384_C(f7,f6,f5,f4,f3,f2,f1,f0,e7,e6,e5,e4,e3,e2,e1,e0,d7,d6,d5,d4,d3,d2,d1,d0,c7,c6,c5,c4,c3,c2,c1,c0,b7,b6,b5,b4,b3,b2,b1,b0,a7,a6,a5,a4,a3,a2,a1,a0),\ CCN8_C(g0) #define CCN528_C(i1,i0,h7,h6,h5,h4,h3,h2,h1,h0,g7,g6,g5,g4,g3,g2,g1,g0,f7,f6,f5,f4,f3,f2,f1,f0,e7,e6,e5,e4,e3,e2,e1,e0,d7,d6,d5,d4,d3,d2,d1,d0,c7,c6,c5,c4,c3,c2,c1,c0,b7,b6,b5,b4,b3,b2,b1,b0,a7,a6,a5,a4,a3,a2,a1,a0) \ CCN256_C(d7,d6,d5,d4,d3,d2,d1,d0,c7,c6,c5,c4,c3,c2,c1,c0,b7,b6,b5,b4,b3,b2,b1,b0,a7,a6,a5,a4,a3,a2,a1,a0),\ CCN256_C(h7,h6,h5,h4,h3,h2,h1,h0,g7,g6,g5,g4,g3,g2,g1,g0,f7,f6,f5,f4,f3,f2,f1,f0,e7,e6,e5,e4,e3,e2,e1,e0),\ CCN16_C(i1,i0) #define CCN192_N ccn_nof(192) #define CCN224_N ccn_nof(224) #define CCN256_N ccn_nof(256) #define CCN384_N ccn_nof(384) #define CCN521_N ccn_nof(521) #if defined(_ARM_ARCH_6) || defined(_ARM_ARCH_7) #if CCN_USE_BUILTIN_CLZ CC_INLINE CC_CONST cc_unit cc_clz(cc_unit data) { return __builtin_clzl(data); } #else CC_INLINE CC_CONST cc_unit cc_clz(cc_unit data) { __asm__ ("clz %0, %1\n" : "=l" (data) : "l" (data)); return data; } #endif /* CCN_USE_BUILTIN_CLZ */ #endif /* !defined(_ARM_ARCH_6) && !defined(_ARM_ARCH_7) */ #if CCN_N_INLINE /* Return the number of used units after stripping leading 0 units. */ CC_INLINE CC_PURE CC_NONNULL2 cc_size ccn_n(cc_size n, const cc_unit *s) { #if 1 while (n-- && s[n] == 0) {} return n + 1; #elif 0 while (n && s[n - 1] == 0) { n -= 1; } return n; #else if (n & 1) { if (s[n - 1]) return n; n &= ~1; } if (n & 2) { cc_unit a[2] = { s[n - 1], s[n - 2] }; if (a[0]) return n - 1; if (a[1]) return n - 2; n &= ~2; } while (n) { cc_unit a[4] = { s[n - 1], s[n - 2], s[n - 3], s[n - 4] }; if (a[0]) return n - 1; if (a[1]) return n - 2; if (a[2]) return n - 3; if (a[3]) return n - 4; n -= 4; } return n; #endif } #else /* Return the number of used units after stripping leading 0 units. */ CC_PURE CC_NONNULL2 cc_size ccn_n(cc_size n, const cc_unit *s); #endif /* s >> k -> r return bits shifted out of least significant word in bits [0, n> { N bit, scalar -> N bit } N = n * sizeof(cc_unit) * 8 the _multi version doesn't return the shifted bits, but does support multiple word shifts. */ CC_NONNULL((2,3)) cc_unit ccn_shift_right(cc_size n, cc_unit *r, const cc_unit *s, size_t k); CC_NONNULL((2,3)) void ccn_shift_right_multi(cc_size n, cc_unit *r,const cc_unit *s, size_t k); /* s << k -> r return bits shifted out of most significant word in bits [0, n> { N bit, scalar -> N bit } N = n * sizeof(cc_unit) * 8 the _multi version doesn't return the shifted bits, but does support multiple word shifts */ CC_NONNULL((2,3)) cc_unit ccn_shift_left(cc_size n, cc_unit *r, const cc_unit *s, size_t k); CC_NONNULL((2,3)) void ccn_shift_left_multi(cc_size n, cc_unit *r, const cc_unit *s, size_t k); /* s == 0 -> return 0 | s > 0 -> return index (starting at 1) of most significant bit that is 1. { N bit } N = n * sizeof(cc_unit) * 8 */ CC_NONNULL2 size_t ccn_bitlen(cc_size n, const cc_unit *s); /* Returns the number of bits which are zero before the first one bit counting from least to most significant bit. */ size_t ccn_trailing_zeros(cc_size n, const cc_unit *s); /* s == 0 -> return true | s != 0 -> return false { N bit } N = n * sizeof(cc_unit) * 8 */ #define ccn_is_zero(_n_, _s_) (!ccn_n(_n_, _s_)) /* s == 1 -> return true | s != 1 -> return false { N bit } N = n * sizeof(cc_unit) * 8 */ #define ccn_is_one(_n_, _s_) (ccn_n(_n_, _s_) == 1 && _s_[0] == 1) #if CCN_CMP_INLINE CC_INLINE CC_PURE CC_NONNULL((2,3)) int ccn_cmp(cc_size n, const cc_unit *s, const cc_unit *t) { while (n) { n--; cc_unit si = s[n]; cc_unit ti = t[n]; if (si != ti) return si > ti ? 1 : -1; } return n; } #else /* s < t -> return - 1 | s == t -> return 0 | s > t -> return 1 { N bit, N bit -> int } N = n * sizeof(cc_unit) * 8 */ CC_PURE CC_NONNULL((2,3)) int ccn_cmp(cc_size n, const cc_unit *s, const cc_unit *t); #endif /* s < t -> return - 1 | s == t -> return 0 | s > t -> return 1 { N bit, M bit -> int } N = ns * sizeof(cc_unit) * 8 M = nt * sizeof(cc_unit) * 8 */ CC_INLINE int ccn_cmpn(cc_size ns, const cc_unit *s, cc_size nt, const cc_unit *t) { if (ns > nt) { return 1; } else if (ns < nt) { return -1; } return ccn_cmp(ns, s, t); } /* s - t -> r return 1 iff t > s { N bit, N bit -> N bit } N = n * sizeof(cc_unit) * 8 */ CC_NONNULL((2,3,4)) cc_unit ccn_sub(cc_size n, cc_unit *r, const cc_unit *s, const cc_unit *t); /* s - v -> r return 1 iff v > s return 0 otherwise. { N bit, sizeof(cc_unit) * 8 bit -> N bit } N = n * sizeof(cc_unit) * 8 */ CC_NONNULL((2,3)) cc_unit ccn_sub1(cc_size n, cc_unit *r, const cc_unit *s, cc_unit v); /* s - t -> r return 1 iff t > s { N bit, NT bit -> N bit NT <= N} N = n * sizeof(cc_unit) * 8 */ CC_INLINE CC_NONNULL((2,3,5)) cc_unit ccn_subn(cc_size n, cc_unit *r,const cc_unit *s, cc_size nt, const cc_unit *t) { return ccn_sub1(n - nt, r + nt, s + nt, ccn_sub(nt, r, s, t)); } /* s + t -> r return carry if result doesn't fit in n bits. { N bit, N bit -> N bit } N = n * sizeof(cc_unit) * 8 */ CC_NONNULL((2,3,4)) cc_unit ccn_add(cc_size n, cc_unit *r, const cc_unit *s, const cc_unit *t); /* s + v -> r return carry if result doesn't fit in n bits. { N bit, sizeof(cc_unit) * 8 bit -> N bit } N = n * sizeof(cc_unit) * 8 */ CC_NONNULL((2,3)) cc_unit ccn_add1(cc_size n, cc_unit *r, const cc_unit *s, cc_unit v); /* s + t -> r return carry if result doesn't fit in n bits { N bit, NT bit -> N bit NT <= N} N = n * sizeof(cc_unit) * 8 */ CC_INLINE CC_NONNULL((2,3,5)) cc_unit ccn_addn(cc_size n, cc_unit *r, const cc_unit *s, cc_size nt, const cc_unit *t) { return ccn_add1(n - nt, r + nt, s + nt, ccn_add(nt, r, s, t)); } CC_NONNULL((4,5)) void ccn_divmod(cc_size n, cc_unit *q, cc_unit *r, const cc_unit *s, const cc_unit *t); CC_NONNULL((2,3,4)) void ccn_lcm(cc_size n, cc_unit *r2n, const cc_unit *s, const cc_unit *t); /* s * t -> r { n bit, n bit -> 2 * n bit } n = count * sizeof(cc_unit) * 8 */ CC_NONNULL((2,3,4)) void ccn_mul(cc_size n, cc_unit *r_2n, const cc_unit *s, const cc_unit *t); CC_NONNULL((2,3)) cc_unit ccn_mul1(cc_size n, cc_unit *r, const cc_unit *s, const cc_unit v); CC_NONNULL((2,3)) cc_unit ccn_addmul1(cc_size n, cc_unit *r, const cc_unit *s, const cc_unit v); #if 0 /* a % d -> n {2 * n bit, n bit -> n bit } n = count * sizeof(cc_unit) * 8 */ CC_NONNULL((2,3,4)) void ccn_mod(cc_size n, cc_unit *r, const cc_unit *a_2n, const cc_unit *d); #endif /* r = gcd(s, t). N bit, N bit -> N bit */ CC_NONNULL((2,3,4)) void ccn_gcd(cc_size n, cc_unit *r, const cc_unit *s, const cc_unit *t); /* r = gcd(s, t). N bit, N bit -> O bit */ CC_NONNULL((2,4,6)) void ccn_gcdn(cc_size rn, cc_unit *r, cc_size sn, const cc_unit *s, cc_size tn, const cc_unit *t); /* r = (data, len) treated as a big endian byte array, return -1 if data doesn't fit in r, return 0 otherwise. */ CC_NONNULL((2,4)) int ccn_read_uint(cc_size n, cc_unit *r, size_t data_size, const uint8_t *data); /* r = (data, len) treated as a big endian byte array, return -1 if data doesn't fit in r, return 0 otherwise. ccn_read_uint strips leading zeroes and doesn't care about sign. */ #define ccn_read_int(n, r, data_size, data) ccn_read_uint(n, r, data_size, data) /* Return actual size in bytes needed to serialize s. */ CC_PURE CC_NONNULL2 size_t ccn_write_uint_size(cc_size n, const cc_unit *s); /* Serialize s, to out. First byte of byte stream is the m.s. byte of s, regardless of the size of cc_unit. No assumption is made about the alignment of out. The out_size argument should be the value returned from ccn_write_uint_size, and is also the exact number of bytes this function will write to out. If out_size if less than the value returned by ccn_write_uint_size, only the first out_size non-zero most significant octects of s will be written. */ CC_NONNULL((2,4)) void ccn_write_uint(cc_size n, const cc_unit *s, size_t out_size, void *out); CC_INLINE CC_NONNULL((2,4)) cc_size ccn_write_uint_padded(cc_size n, const cc_unit* s, size_t out_size, uint8_t* to) { size_t bytesInKey = ccn_write_uint_size(n, s); cc_size offset = (out_size > bytesInKey) ? out_size - bytesInKey : 0; cc_zero(offset, to); ccn_write_uint(n, s, out_size - offset, to + offset); return offset; } /* Return actual size in bytes needed to serialize s as int (adding leading zero if high bit is set). */ CC_PURE CC_NONNULL2 size_t ccn_write_int_size(cc_size n, const cc_unit *s); /* Serialize s, to out. First byte of byte stream is the m.s. byte of s, regardless of the size of cc_unit. No assumption is made about the alignment of out. The out_size argument should be the value returned from ccn_write_int_size, and is also the exact number of bytes this function will write to out. If out_size if less than the value returned by ccn_write_int_size, only the first out_size non-zero most significant octects of s will be written. */ CC_NONNULL((2,4)) void ccn_write_int(cc_size n, const cc_unit *s, size_t out_size, void *out); /* s^2 -> r { n bit -> 2 * n bit } */ CC_INLINE CC_NONNULL((2,3)) void ccn_sqr(cc_size n, cc_unit *r, const cc_unit *s) { ccn_mul(n, r, s, s); } /* s -> r { n bit -> n bit } */ CC_NONNULL((2,3)) void ccn_set(cc_size n, cc_unit *r, const cc_unit *s); CC_INLINE CC_NONNULL2 void ccn_zero(cc_size n, cc_unit *r) { CC_BZERO(r, ccn_sizeof_n(n)); } /* Burn (zero fill or otherwise overwrite) n cc_units of stack space. */ void ccn_burn_stack(cc_size n); CC_INLINE CC_NONNULL2 void ccn_seti(cc_size n, cc_unit *r, cc_unit v) { /* assert(n > 0); */ r[0] = v; ccn_zero(n - 1, r + 1); } CC_INLINE CC_NONNULL((2,4)) void ccn_setn(cc_size n, cc_unit *r, CC_UNUSED const cc_size s_size, const cc_unit *s) { /* FIXME: assert not available in kernel. assert(n > 0); assert(s_size > 0); assert(s_size <= n); */ ccn_set(s_size, r, s); ccn_zero(n - s_size, r + s_size); } #define CC_SWAP_HOST_BIG_64(x) \ ((uint64_t)((((uint64_t)(x) & 0xff00000000000000ULL) >> 56) | \ (((uint64_t)(x) & 0x00ff000000000000ULL) >> 40) | \ (((uint64_t)(x) & 0x0000ff0000000000ULL) >> 24) | \ (((uint64_t)(x) & 0x000000ff00000000ULL) >> 8) | \ (((uint64_t)(x) & 0x00000000ff000000ULL) << 8) | \ (((uint64_t)(x) & 0x0000000000ff0000ULL) << 24) | \ (((uint64_t)(x) & 0x000000000000ff00ULL) << 40) | \ (((uint64_t)(x) & 0x00000000000000ffULL) << 56))) #define CC_SWAP_HOST_BIG_32(x) \ ((((x) & 0xff000000) >> 24) | \ (((x) & 0x00ff0000) >> 8) | \ (((x) & 0x0000ff00) << 8) | \ (((x) & 0x000000ff) << 24) ) #define CC_SWAP_HOST_BIG_16(x) \ (((x) & 0xff00) >> 8) | \ (((x) & 0x00ff) << 8) | \ /* This should probably move if we move ccn_swap out of line. */ #if CCN_UNIT_SIZE == 8 #define CC_UNIT_TO_BIG(x) CC_SWAP_HOST_BIG_64(x) #elif CCN_UNIT_SIZE == 4 #define CC_UNIT_TO_BIG(x) CC_SWAP_HOST_BIG_32(x) #elif CCN_UNIT_SIZE == 2 #define CC_UNIT_TO_BIG(x) CC_SWAP_HOST_BIG_16(x) #elif CCN_UNIT_SIZE == 1 #define CC_UNIT_TO_BIG(x) (x) #else #error unsupported CCN_UNIT_SIZE #endif /* Swap units in r in place from cc_unit vector byte order to big endian byte order (or back). */ CC_INLINE CC_NONNULL2 void ccn_swap(cc_size n, cc_unit *r) { cc_unit *e; for (e = r + n - 1; r < e; ++r, --e) { cc_unit t = CC_UNIT_TO_BIG(*r); *r = CC_UNIT_TO_BIG(*e); *e = t; } if (n & 1) *r = CC_UNIT_TO_BIG(*r); } CC_INLINE CC_NONNULL2 CC_NONNULL3 CC_NONNULL4 void ccn_xor(cc_size n, cc_unit *r, const cc_unit *s, const cc_unit *t) { while (n--) { r[n] = s[n] ^ t[n]; } } /* Debugging */ CC_NONNULL2 void ccn_print(cc_size n, const cc_unit *s); CC_NONNULL3 void ccn_lprint(cc_size n, const char *label, const cc_unit *s); /* Forward declaration so we don't depend on ccrng.h. */ struct ccrng_state; #if 0 CC_INLINE CC_NONNULL((2,3)) int ccn_random(cc_size n, cc_unit *r, struct ccrng_state *rng) { return (RNG)->generate((RNG), ccn_sizeof_n(n), (unsigned char *)r); } #else #define ccn_random(_n_,_r_,_ccrng_ctx_) \ ccrng_generate(_ccrng_ctx_, ccn_sizeof_n(_n_), (unsigned char *)_r_); #endif /* Make a ccn of size ccn_nof(nbits) units with up to nbits sized random value. */ CC_NONNULL((2,3)) int ccn_random_bits(cc_size nbits, cc_unit *r, struct ccrng_state *rng); #endif /* _CORECRYPTO_CCN_H_ */