#include "config.h"
#include "bearssl.h"
+/*
+ * On MSVC, disable the warning about applying unary minus on an
+ * unsigned type: it is standard, we do it all the time, and for
+ * good reasons.
+ */
+#if _MSC_VER
+#pragma warning( disable : 4146 )
+#endif
+
/*
* Maximum size for a RSA modulus (in bits). Allocated stack buffers
* depend on that size, so this value should be kept small. Currently,
#endif
#endif
+/*
+ * Set BR_LOMUL on platforms where it makes sense.
+ */
+#ifndef BR_LOMUL
+#if BR_ARMEL_CORTEX_GCC
+#define BR_LOMUL 1
+#endif
+#endif
+
+/*
+ * Determine whether x86 AES instructions are understood by the compiler.
+ */
+#ifndef BR_AES_X86NI
+#if (__i386__ || __x86_64__) \
+ && ((__GNUC__ > 4 || (__GNUC__ == 4 && __GNUC_MINOR__ >= 8)) \
+ || (__clang_major__ > 3 \
+ || (__clang_major__ == 3 && __clang_minor__ >= 7)))
+#define BR_AES_X86NI 1
+#elif (_M_IX86 || _M_X64) && (_MSC_VER >= 1700)
+#define BR_AES_X86NI 1
+#endif
+#endif
+
+/*
+ * If we use x86 AES instruction, determine the compiler brand.
+ */
+#if BR_AES_X86NI
+#ifndef BR_AES_X86NI_GCC
+#if __GNUC__
+#define BR_AES_X86NI_GCC 1
+#endif
+#endif
+#ifndef BR_AES_X86NI_MSC
+#if _MSC_VER >= 1700
+#define BR_AES_X86NI_MSC 1
+#endif
+#endif
+#endif
+
+/*
+ * A macro to tag a function with a "target" attribute (for GCC and Clang).
+ */
+#if BR_AES_X86NI_GCC
+#define BR_TARGET(x) __attribute__((target(x)))
+#else
+#define BR_TARGET(x)
+#endif
+
+/*
+ * GCC versions from 4.4 to 4.8 (inclusive) must use a special #pragma
+ * to activate extra opcodes before including the relevant intrinsic
+ * headers. But these don't work with Clang (which does not need them
+ * either).
+ */
+#if BR_AES_X86NI_GCC && !defined BR_AES_X86NI_GCC_OLD
+#if __GNUC__ == 4 && __GNUC_MINOR__ >= 4 && __GNUC_MINOR__ <= 8 && !__clang__
+#define BR_AES_X86NI_GCC_OLD 1
+#endif
+#endif
+
+/*
+ * POWER8 crypto support. We rely on compiler macros for the
+ * architecture, since we do not have a reliable, simple way to detect
+ * the required support at runtime (we could try running an opcode, and
+ * trapping the exception or signal on illegal instruction, but this
+ * induces some non-trivial OS dependencies that we would prefer to
+ * avoid if possible).
+ */
+#ifndef BR_POWER8
+#if __GNUC__ && ((_ARCH_PWR8 || _ARCH_PPC) && __CRYPTO__)
+#define BR_POWER8 1
+#endif
+#endif
+
+/*
+ * Detect endinanness on POWER8.
+ */
+#if BR_POWER8
+#if defined BR_POWER8_LE
+#undef BR_POWER8_BE
+#if BR_POWER8_LE
+#define BR_POWER8_BE 0
+#else
+#define BR_POWER8_BE 1
+#endif
+#elif defined BR_POWER8_BE
+#undef BR_POWER8_LE
+#if BR_POWER8_BE
+#define BR_POWER8_LE 0
+#else
+#define BR_POWER8_LE 1
+#endif
+#else
+#if __LITTLE_ENDIAN__
+#define BR_POWER8_LE 1
+#define BR_POWER8_BE 0
+#else
+#define BR_POWER8_LE 0
+#define BR_POWER8_BE 1
+#endif
+#endif
+#endif
+
+/*
+ * Detect support for 128-bit integers.
+ */
+#if !defined BR_INT128 && !defined BR_UMUL128
+#ifdef __SIZEOF_INT128__
+#define BR_INT128 1
+#elif _M_X64
+#define BR_UMUL128 1
+#endif
+#endif
+
+/*
+ * Detect support for unaligned accesses with known endianness.
+ *
+ * x86 (both 32-bit and 64-bit) is little-endian and allows unaligned
+ * accesses.
+ *
+ * POWER/PowerPC allows unaligned accesses when big-endian. POWER8 and
+ * later also allow unaligned accesses when little-endian.
+ */
+#if !defined BR_LE_UNALIGNED && !defined BR_BE_UNALIGNED
+
+#if __i386 || __i386__ || __x86_64__ || _M_IX86 || _M_X64
+#define BR_LE_UNALIGNED 1
+#elif BR_POWER8_BE
+#define BR_BE_UNALIGNED 1
+#elif BR_POWER8_LE
+#define BR_LE_UNALIGNED 1
+#elif (__powerpc__ || __powerpc64__ || _M_PPC || _ARCH_PPC || _ARCH_PPC64) \
+ && __BIG_ENDIAN__
+#define BR_BE_UNALIGNED 1
+#endif
+
+#endif
+
/* ==================================================================== */
/*
* Encoding/decoding functions.
*
* 32-bit and 64-bit decoding, both little-endian and big-endian, is
- * implemented with the inline functions below. These functions are
- * generic: they don't depend on the architecture natural endianness,
- * and they can handle unaligned accesses. Optimized versions for some
- * specific architectures may be implemented at a later time.
- */
+ * implemented with the inline functions below.
+ *
+ * When allowed by some compile-time options (autodetected or provided),
+ * optimised code is used, to perform direct memory access when the
+ * underlying architecture supports it, both for endianness and
+ * alignment. This, however, may trigger strict aliasing issues; the
+ * code below uses unions to perform (supposedly) safe type punning.
+ * Since the C aliasing rules are relatively complex and were amended,
+ * or at least re-explained with different phrasing, in all successive
+ * versions of the C standard, it is always a bit risky to bet that any
+ * specific version of a C compiler got it right, for some notion of
+ * "right".
+ */
+
+typedef union {
+ uint16_t u;
+ unsigned char b[sizeof(uint16_t)];
+} br_union_u16;
+
+typedef union {
+ uint32_t u;
+ unsigned char b[sizeof(uint32_t)];
+} br_union_u32;
+
+typedef union {
+ uint64_t u;
+ unsigned char b[sizeof(uint64_t)];
+} br_union_u64;
static inline void
br_enc16le(void *dst, unsigned x)
{
+#if BR_LE_UNALIGNED
+ ((br_union_u16 *)dst)->u = x;
+#else
unsigned char *buf;
buf = dst;
buf[0] = (unsigned char)x;
buf[1] = (unsigned char)(x >> 8);
+#endif
}
static inline void
br_enc16be(void *dst, unsigned x)
{
+#if BR_BE_UNALIGNED
+ ((br_union_u16 *)dst)->u = x;
+#else
unsigned char *buf;
buf = dst;
buf[0] = (unsigned char)(x >> 8);
buf[1] = (unsigned char)x;
+#endif
}
static inline unsigned
br_dec16le(const void *src)
{
+#if BR_LE_UNALIGNED
+ return ((const br_union_u16 *)src)->u;
+#else
const unsigned char *buf;
buf = src;
return (unsigned)buf[0] | ((unsigned)buf[1] << 8);
+#endif
}
static inline unsigned
br_dec16be(const void *src)
{
+#if BR_BE_UNALIGNED
+ return ((const br_union_u16 *)src)->u;
+#else
const unsigned char *buf;
buf = src;
return ((unsigned)buf[0] << 8) | (unsigned)buf[1];
+#endif
}
static inline void
br_enc32le(void *dst, uint32_t x)
{
+#if BR_LE_UNALIGNED
+ ((br_union_u32 *)dst)->u = x;
+#else
unsigned char *buf;
buf = dst;
buf[1] = (unsigned char)(x >> 8);
buf[2] = (unsigned char)(x >> 16);
buf[3] = (unsigned char)(x >> 24);
+#endif
}
static inline void
br_enc32be(void *dst, uint32_t x)
{
+#if BR_BE_UNALIGNED
+ ((br_union_u32 *)dst)->u = x;
+#else
unsigned char *buf;
buf = dst;
buf[1] = (unsigned char)(x >> 16);
buf[2] = (unsigned char)(x >> 8);
buf[3] = (unsigned char)x;
+#endif
}
static inline uint32_t
br_dec32le(const void *src)
{
+#if BR_LE_UNALIGNED
+ return ((const br_union_u32 *)src)->u;
+#else
const unsigned char *buf;
buf = src;
| ((uint32_t)buf[1] << 8)
| ((uint32_t)buf[2] << 16)
| ((uint32_t)buf[3] << 24);
+#endif
}
static inline uint32_t
br_dec32be(const void *src)
{
+#if BR_BE_UNALIGNED
+ return ((const br_union_u32 *)src)->u;
+#else
const unsigned char *buf;
buf = src;
| ((uint32_t)buf[1] << 16)
| ((uint32_t)buf[2] << 8)
| (uint32_t)buf[3];
+#endif
}
static inline void
br_enc64le(void *dst, uint64_t x)
{
+#if BR_LE_UNALIGNED
+ ((br_union_u64 *)dst)->u = x;
+#else
unsigned char *buf;
buf = dst;
br_enc32le(buf, (uint32_t)x);
br_enc32le(buf + 4, (uint32_t)(x >> 32));
+#endif
}
static inline void
br_enc64be(void *dst, uint64_t x)
{
+#if BR_BE_UNALIGNED
+ ((br_union_u64 *)dst)->u = x;
+#else
unsigned char *buf;
buf = dst;
br_enc32be(buf, (uint32_t)(x >> 32));
br_enc32be(buf + 4, (uint32_t)x);
+#endif
}
static inline uint64_t
br_dec64le(const void *src)
{
+#if BR_LE_UNALIGNED
+ return ((const br_union_u64 *)src)->u;
+#else
const unsigned char *buf;
buf = src;
return (uint64_t)br_dec32le(buf)
| ((uint64_t)br_dec32le(buf + 4) << 32);
+#endif
}
static inline uint64_t
br_dec64be(const void *src)
{
+#if BR_BE_UNALIGNED
+ return ((const br_union_u64 *)src)->u;
+#else
const unsigned char *buf;
buf = src;
return ((uint64_t)br_dec32be(buf) << 32)
| (uint64_t)br_dec32be(buf + 4);
+#endif
}
/*
br_multihash_copyimpl(br_multihash_context *dst,
const br_multihash_context *src)
{
- memcpy(dst->impl, src->impl, sizeof src->impl);
+ memcpy((void *)dst->impl, src->impl, sizeof src->impl);
}
/* ==================================================================== */
void br_i31_modpow(uint32_t *x, const unsigned char *e, size_t elen,
const uint32_t *m, uint32_t m0i, uint32_t *t1, uint32_t *t2);
+/*
+ * Compute a modular exponentiation. x[] MUST be an integer modulo m[]
+ * (same announced bit length, lower value). m[] MUST be odd. The
+ * exponent is in big-endian unsigned notation, over 'elen' bytes. The
+ * "m0i" parameter is equal to -(1/m0) mod 2^31, where m0 is the least
+ * significant value word of m[] (this works only if m[] is an odd
+ * integer). The tmp[] array is used for temporaries, and has size
+ * 'twlen' words; it must be large enough to accommodate at least two
+ * temporary values with the same size as m[] (including the leading
+ * "bit length" word). If there is room for more temporaries, then this
+ * function may use the extra room for window-based optimisation,
+ * resulting in faster computations.
+ *
+ * Returned value is 1 on success, 0 on error. An error is reported if
+ * the provided tmp[] array is too short.
+ */
+uint32_t br_i31_modpow_opt(uint32_t *x, const unsigned char *e, size_t elen,
+ const uint32_t *m, uint32_t m0i, uint32_t *tmp, size_t twlen);
+
/*
* Compute d+a*b, result in d. The initial announced bit length of d[]
* MUST match that of a[]. The d[] array MUST be large enough to
/* ==================================================================== */
+/*
+ * FIXME: document "i15" functions.
+ */
+
static inline void
br_i15_zero(uint16_t *x, uint16_t bit_len)
{
void br_i15_modpow(uint16_t *x, const unsigned char *e, size_t elen,
const uint16_t *m, uint16_t m0i, uint16_t *t1, uint16_t *t2);
+uint32_t br_i15_modpow_opt(uint16_t *x, const unsigned char *e, size_t elen,
+ const uint16_t *m, uint16_t m0i, uint16_t *tmp, size_t twlen);
+
void br_i15_encode(void *dst, size_t len, const uint16_t *x);
uint32_t br_i15_decode_mod(uint16_t *x,
void br_i15_mulacc(uint16_t *d, const uint16_t *a, const uint16_t *b);
+uint32_t br_i62_modpow_opt(uint32_t *x31, const unsigned char *e, size_t elen,
+ const uint32_t *m31, uint32_t m0i31, uint64_t *tmp, size_t twlen);
+
/* ==================================================================== */
static inline size_t
void br_aes_ct64_skey_expand(uint64_t *skey,
unsigned num_rounds, const uint64_t *comp_skey);
+/*
+ * Test support for AES-NI opcodes.
+ */
+int br_aes_x86ni_supported(void);
+
+/*
+ * AES key schedule, using x86 AES-NI instructions. This yields the
+ * subkeys in the encryption direction. Number of rounds is returned.
+ * Key size MUST be 16, 24 or 32 bytes; otherwise, 0 is returned.
+ */
+unsigned br_aes_x86ni_keysched_enc(unsigned char *skni,
+ const void *key, size_t len);
+
+/*
+ * AES key schedule, using x86 AES-NI instructions. This yields the
+ * subkeys in the decryption direction. Number of rounds is returned.
+ * Key size MUST be 16, 24 or 32 bytes; otherwise, 0 is returned.
+ */
+unsigned br_aes_x86ni_keysched_dec(unsigned char *skni,
+ const void *key, size_t len);
+
+/*
+ * Test support for AES POWER8 opcodes.
+ */
+int br_aes_pwr8_supported(void);
+
+/*
+ * AES key schedule, using POWER8 instructions. This yields the
+ * subkeys in the encryption direction. Number of rounds is returned.
+ * Key size MUST be 16, 24 or 32 bytes; otherwise, 0 is returned.
+ */
+unsigned br_aes_pwr8_keysched(unsigned char *skni,
+ const void *key, size_t len);
+
/* ==================================================================== */
/*
* RSA.
extern const br_ec_curve_def br_secp384r1;
extern const br_ec_curve_def br_secp521r1;
-#if 0
-/* obsolete */
/*
- * Type for the parameters for a "prime curve":
- * coordinates are in GF(p), with p prime
- * curve equation is Y^2 = X^3 - 3*X + b
- * b is in Montgomery representation
- * curve order is n and is prime
- * base point is G (encoded) and has order n
+ * For Curve25519, the advertised "order" really is 2^255-1, since the
+ * point multipliction function really works over arbitrary 255-bit
+ * scalars. This value is only meant as a hint for ECDH key generation;
+ * only ECDSA uses the exact curve order, and ECDSA is not used with
+ * that specific curve.
*/
-typedef struct {
- const uint32_t *p;
- const uint32_t *b;
- const uint32_t p0i;
-} br_ec_prime_i31_curve;
-
-extern const br_ec_prime_i31_curve br_ec_prime_i31_secp256r1;
-extern const br_ec_prime_i31_curve br_ec_prime_i31_secp384r1;
-extern const br_ec_prime_i31_curve br_ec_prime_i31_secp521r1;
-
-#define BR_EC_I31_LEN ((BR_MAX_EC_SIZE + 61) / 31)
-#endif
+extern const br_ec_curve_def br_curve25519;
/*
* Decode some bytes as an i31 integer, with truncation (corresponding
/* ==================================================================== */
+/*
+ * PowerPC / POWER assembly stuff. The special BR_POWER_ASM_MACROS macro
+ * must be defined before including this file; this is done by source
+ * files that use some inline assembly for PowerPC / POWER machines.
+ */
+
+#if BR_POWER_ASM_MACROS
+
+#define lxvw4x(xt, ra, rb) lxvw4x_(xt, ra, rb)
+#define stxvw4x(xt, ra, rb) stxvw4x_(xt, ra, rb)
+
+#define bdnz(foo) bdnz_(foo)
+#define beq(foo) beq_(foo)
+
+#define li(rx, value) li_(rx, value)
+#define addi(rx, ra, imm) addi_(rx, ra, imm)
+#define cmpldi(rx, imm) cmpldi_(rx, imm)
+#define mtctr(rx) mtctr_(rx)
+#define vspltb(vrt, vrb, uim) vspltb_(vrt, vrb, uim)
+#define vspltw(vrt, vrb, uim) vspltw_(vrt, vrb, uim)
+#define vspltisb(vrt, imm) vspltisb_(vrt, imm)
+#define vspltisw(vrt, imm) vspltisw_(vrt, imm)
+#define vrlw(vrt, vra, vrb) vrlw_(vrt, vra, vrb)
+#define vsbox(vrt, vra) vsbox_(vrt, vra)
+#define vxor(vrt, vra, vrb) vxor_(vrt, vra, vrb)
+#define vand(vrt, vra, vrb) vand_(vrt, vra, vrb)
+#define vsro(vrt, vra, vrb) vsro_(vrt, vra, vrb)
+#define vsl(vrt, vra, vrb) vsl_(vrt, vra, vrb)
+#define vsldoi(vt, va, vb, sh) vsldoi_(vt, va, vb, sh)
+#define vsr(vrt, vra, vrb) vsr_(vrt, vra, vrb)
+#define vadduwm(vrt, vra, vrb) vadduwm_(vrt, vra, vrb)
+#define vsububm(vrt, vra, vrb) vsububm_(vrt, vra, vrb)
+#define vsubuwm(vrt, vra, vrb) vsubuwm_(vrt, vra, vrb)
+#define vsrw(vrt, vra, vrb) vsrw_(vrt, vra, vrb)
+#define vcipher(vt, va, vb) vcipher_(vt, va, vb)
+#define vcipherlast(vt, va, vb) vcipherlast_(vt, va, vb)
+#define vncipher(vt, va, vb) vncipher_(vt, va, vb)
+#define vncipherlast(vt, va, vb) vncipherlast_(vt, va, vb)
+#define vperm(vt, va, vb, vc) vperm_(vt, va, vb, vc)
+#define vpmsumd(vt, va, vb) vpmsumd_(vt, va, vb)
+#define xxpermdi(vt, va, vb, d) xxpermdi_(vt, va, vb, d)
+
+#define lxvw4x_(xt, ra, rb) "\tlxvw4x\t" #xt "," #ra "," #rb "\n"
+#define stxvw4x_(xt, ra, rb) "\tstxvw4x\t" #xt "," #ra "," #rb "\n"
+
+#define label(foo) #foo "%=:\n"
+#define bdnz_(foo) "\tbdnz\t" #foo "%=\n"
+#define beq_(foo) "\tbeq\t" #foo "%=\n"
+
+#define li_(rx, value) "\tli\t" #rx "," #value "\n"
+#define addi_(rx, ra, imm) "\taddi\t" #rx "," #ra "," #imm "\n"
+#define cmpldi_(rx, imm) "\tcmpldi\t" #rx "," #imm "\n"
+#define mtctr_(rx) "\tmtctr\t" #rx "\n"
+#define vspltb_(vrt, vrb, uim) "\tvspltb\t" #vrt "," #vrb "," #uim "\n"
+#define vspltw_(vrt, vrb, uim) "\tvspltw\t" #vrt "," #vrb "," #uim "\n"
+#define vspltisb_(vrt, imm) "\tvspltisb\t" #vrt "," #imm "\n"
+#define vspltisw_(vrt, imm) "\tvspltisw\t" #vrt "," #imm "\n"
+#define vrlw_(vrt, vra, vrb) "\tvrlw\t" #vrt "," #vra "," #vrb "\n"
+#define vsbox_(vrt, vra) "\tvsbox\t" #vrt "," #vra "\n"
+#define vxor_(vrt, vra, vrb) "\tvxor\t" #vrt "," #vra "," #vrb "\n"
+#define vand_(vrt, vra, vrb) "\tvand\t" #vrt "," #vra "," #vrb "\n"
+#define vsro_(vrt, vra, vrb) "\tvsro\t" #vrt "," #vra "," #vrb "\n"
+#define vsl_(vrt, vra, vrb) "\tvsl\t" #vrt "," #vra "," #vrb "\n"
+#define vsldoi_(vt, va, vb, sh) "\tvsldoi\t" #vt "," #va "," #vb "," #sh "\n"
+#define vsr_(vrt, vra, vrb) "\tvsr\t" #vrt "," #vra "," #vrb "\n"
+#define vadduwm_(vrt, vra, vrb) "\tvadduwm\t" #vrt "," #vra "," #vrb "\n"
+#define vsububm_(vrt, vra, vrb) "\tvsububm\t" #vrt "," #vra "," #vrb "\n"
+#define vsubuwm_(vrt, vra, vrb) "\tvsubuwm\t" #vrt "," #vra "," #vrb "\n"
+#define vsrw_(vrt, vra, vrb) "\tvsrw\t" #vrt "," #vra "," #vrb "\n"
+#define vcipher_(vt, va, vb) "\tvcipher\t" #vt "," #va "," #vb "\n"
+#define vcipherlast_(vt, va, vb) "\tvcipherlast\t" #vt "," #va "," #vb "\n"
+#define vncipher_(vt, va, vb) "\tvncipher\t" #vt "," #va "," #vb "\n"
+#define vncipherlast_(vt, va, vb) "\tvncipherlast\t" #vt "," #va "," #vb "\n"
+#define vperm_(vt, va, vb, vc) "\tvperm\t" #vt "," #va "," #vb "," #vc "\n"
+#define vpmsumd_(vt, va, vb) "\tvpmsumd\t" #vt "," #va "," #vb "\n"
+#define xxpermdi_(vt, va, vb, d) "\txxpermdi\t" #vt "," #va "," #vb "," #d "\n"
+
+#endif
+
+/* ==================================================================== */
+
#endif