| // Copyright 2021 The Go Authors. All rights reserved. | |
| // Use of this source code is governed by a BSD-style | |
| // license that can be found in the LICENSE file. | |
| package bigmod | |
| import ( | |
| _ "crypto/internal/fips140/check" | |
| "crypto/internal/fips140deps/byteorder" | |
| "errors" | |
| "math/bits" | |
| ) | |
| const ( | |
| // _W is the size in bits of our limbs. | |
| _W = bits.UintSize | |
| // _S is the size in bytes of our limbs. | |
| _S = _W / 8 | |
| ) | |
| // Note: These functions make many loops over all the words in a Nat. | |
| // These loops used to be in assembly, invisible to -race, -asan, and -msan, | |
| // but now they are in Go and incur significant overhead in those modes. | |
| // To bring the old performance back, we mark all functions that loop | |
| // over Nat words with //go:norace. Because //go:norace does not | |
| // propagate across inlining, we must also mark functions that inline | |
| // //go:norace functions - specifically, those that inline add, addMulVVW, | |
| // assign, cmpGeq, rshift1, and sub. | |
| // choice represents a constant-time boolean. The value of choice is always | |
| // either 1 or 0. We use an int instead of bool in order to make decisions in | |
| // constant time by turning it into a mask. | |
| type choice uint | |
| func not(c choice) choice { return 1 ^ c } | |
| const yes = choice(1) | |
| const no = choice(0) | |
| // ctMask is all 1s if on is yes, and all 0s otherwise. | |
| func ctMask(on choice) uint { return -uint(on) } | |
| // ctEq returns 1 if x == y, and 0 otherwise. The execution time of this | |
| // function does not depend on its inputs. | |
| func ctEq(x, y uint) choice { | |
| // If x != y, then either x - y or y - x will generate a carry. | |
| _, c1 := bits.Sub(x, y, 0) | |
| _, c2 := bits.Sub(y, x, 0) | |
| return not(choice(c1 | c2)) | |
| } | |
| // Nat represents an arbitrary natural number | |
| // | |
| // Each Nat has an announced length, which is the number of limbs it has stored. | |
| // Operations on this number are allowed to leak this length, but will not leak | |
| // any information about the values contained in those limbs. | |
| type Nat struct { | |
| // limbs is little-endian in base 2^W with W = bits.UintSize. | |
| limbs []uint | |
| } | |
| // preallocTarget is the size in bits of the numbers used to implement the most | |
| // common and most performant RSA key size. It's also enough to cover some of | |
| // the operations of key sizes up to 4096. | |
| const preallocTarget = 2048 | |
| const preallocLimbs = (preallocTarget + _W - 1) / _W | |
| // NewNat returns a new nat with a size of zero, just like new(Nat), but with | |
| // the preallocated capacity to hold a number of up to preallocTarget bits. | |
| // NewNat inlines, so the allocation can live on the stack. | |
| func NewNat() *Nat { | |
| limbs := make([]uint, 0, preallocLimbs) | |
| return &Nat{limbs} | |
| } | |
| // expand expands x to n limbs, leaving its value unchanged. | |
| func (x *Nat) expand(n int) *Nat { | |
| if len(x.limbs) > n { | |
| panic("bigmod: internal error: shrinking nat") | |
| } | |
| if cap(x.limbs) < n { | |
| newLimbs := make([]uint, n) | |
| copy(newLimbs, x.limbs) | |
| x.limbs = newLimbs | |
| return x | |
| } | |
| extraLimbs := x.limbs[len(x.limbs):n] | |
| clear(extraLimbs) | |
| x.limbs = x.limbs[:n] | |
| return x | |
| } | |
| // reset returns a zero nat of n limbs, reusing x's storage if n <= cap(x.limbs). | |
| func (x *Nat) reset(n int) *Nat { | |
| if cap(x.limbs) < n { | |
| x.limbs = make([]uint, n) | |
| return x | |
| } | |
| // Clear both the returned limbs and the previously used ones. | |
| clear(x.limbs[:max(n, len(x.limbs))]) | |
| x.limbs = x.limbs[:n] | |
| return x | |
| } | |
| // resetToBytes assigns x = b, where b is a slice of big-endian bytes, resizing | |
| // n to the appropriate size. | |
| // | |
| // The announced length of x is set based on the actual bit size of the input, | |
| // ignoring leading zeroes. | |
| func (x *Nat) resetToBytes(b []byte) *Nat { | |
| x.reset((len(b) + _S - 1) / _S) | |
| if err := x.setBytes(b); err != nil { | |
| panic("bigmod: internal error: bad arithmetic") | |
| } | |
| return x.trim() | |
| } | |
| // trim reduces the size of x to match its value. | |
| func (x *Nat) trim() *Nat { | |
| // Trim most significant (trailing in little-endian) zero limbs. | |
| // We assume comparison with zero (but not the branch) is constant time. | |
| for i := len(x.limbs) - 1; i >= 0; i-- { | |
| if x.limbs[i] != 0 { | |
| break | |
| } | |
| x.limbs = x.limbs[:i] | |
| } | |
| return x | |
| } | |
| // set assigns x = y, optionally resizing x to the appropriate size. | |
| func (x *Nat) set(y *Nat) *Nat { | |
| x.reset(len(y.limbs)) | |
| copy(x.limbs, y.limbs) | |
| return x | |
| } | |
| // Bits returns x as a little-endian slice of uint. The length of the slice | |
| // matches the announced length of x. The result and x share the same underlying | |
| // array. | |
| func (x *Nat) Bits() []uint { | |
| return x.limbs | |
| } | |
| // Bytes returns x as a zero-extended big-endian byte slice. The size of the | |
| // slice will match the size of m. | |
| // | |
| // x must have the same size as m and it must be less than or equal to m. | |
| func (x *Nat) Bytes(m *Modulus) []byte { | |
| i := m.Size() | |
| bytes := make([]byte, i) | |
| for _, limb := range x.limbs { | |
| for j := 0; j < _S; j++ { | |
| i-- | |
| if i < 0 { | |
| if limb == 0 { | |
| break | |
| } | |
| panic("bigmod: modulus is smaller than nat") | |
| } | |
| bytes[i] = byte(limb) | |
| limb >>= 8 | |
| } | |
| } | |
| return bytes | |
| } | |
| // SetBytes assigns x = b, where b is a slice of big-endian bytes. | |
| // SetBytes returns an error if b >= m. | |
| // | |
| // The output will be resized to the size of m and overwritten. | |
| // | |
| //go:norace | |
| func (x *Nat) SetBytes(b []byte, m *Modulus) (*Nat, error) { | |
| x.resetFor(m) | |
| if err := x.setBytes(b); err != nil { | |
| return nil, err | |
| } | |
| if x.cmpGeq(m.nat) == yes { | |
| return nil, errors.New("input overflows the modulus") | |
| } | |
| return x, nil | |
| } | |
| // SetOverflowingBytes assigns x = b, where b is a slice of big-endian bytes. | |
| // SetOverflowingBytes returns an error if b has a longer bit length than m, but | |
| // reduces overflowing values up to 2^⌈log2(m)⌉ - 1. | |
| // | |
| // The output will be resized to the size of m and overwritten. | |
| func (x *Nat) SetOverflowingBytes(b []byte, m *Modulus) (*Nat, error) { | |
| x.resetFor(m) | |
| if err := x.setBytes(b); err != nil { | |
| return nil, err | |
| } | |
| // setBytes would have returned an error if the input overflowed the limb | |
| // size of the modulus, so now we only need to check if the most significant | |
| // limb of x has more bits than the most significant limb of the modulus. | |
| if bitLen(x.limbs[len(x.limbs)-1]) > bitLen(m.nat.limbs[len(m.nat.limbs)-1]) { | |
| return nil, errors.New("input overflows the modulus size") | |
| } | |
| x.maybeSubtractModulus(no, m) | |
| return x, nil | |
| } | |
| // bigEndianUint returns the contents of buf interpreted as a | |
| // big-endian encoded uint value. | |
| func bigEndianUint(buf []byte) uint { | |
| if _W == 64 { | |
| return uint(byteorder.BEUint64(buf)) | |
| } | |
| return uint(byteorder.BEUint32(buf)) | |
| } | |
| func (x *Nat) setBytes(b []byte) error { | |
| i, k := len(b), 0 | |
| for k < len(x.limbs) && i >= _S { | |
| x.limbs[k] = bigEndianUint(b[i-_S : i]) | |
| i -= _S | |
| k++ | |
| } | |
| for s := 0; s < _W && k < len(x.limbs) && i > 0; s += 8 { | |
| x.limbs[k] |= uint(b[i-1]) << s | |
| i-- | |
| } | |
| if i > 0 { | |
| return errors.New("input overflows the modulus size") | |
| } | |
| return nil | |
| } | |
| // SetUint assigns x = y. | |
| // | |
| // The output will be resized to a single limb and overwritten. | |
| func (x *Nat) SetUint(y uint) *Nat { | |
| x.reset(1) | |
| x.limbs[0] = y | |
| return x | |
| } | |
| // Equal returns 1 if x == y, and 0 otherwise. | |
| // | |
| // Both operands must have the same announced length. | |
| // | |
| //go:norace | |
| func (x *Nat) Equal(y *Nat) choice { | |
| // Eliminate bounds checks in the loop. | |
| size := len(x.limbs) | |
| xLimbs := x.limbs[:size] | |
| yLimbs := y.limbs[:size] | |
| equal := yes | |
| for i := 0; i < size; i++ { | |
| equal &= ctEq(xLimbs[i], yLimbs[i]) | |
| } | |
| return equal | |
| } | |
| // IsZero returns 1 if x == 0, and 0 otherwise. | |
| // | |
| //go:norace | |
| func (x *Nat) IsZero() choice { | |
| // Eliminate bounds checks in the loop. | |
| size := len(x.limbs) | |
| xLimbs := x.limbs[:size] | |
| zero := yes | |
| for i := 0; i < size; i++ { | |
| zero &= ctEq(xLimbs[i], 0) | |
| } | |
| return zero | |
| } | |
| // IsOne returns 1 if x == 1, and 0 otherwise. | |
| // | |
| //go:norace | |
| func (x *Nat) IsOne() choice { | |
| // Eliminate bounds checks in the loop. | |
| size := len(x.limbs) | |
| xLimbs := x.limbs[:size] | |
| if len(xLimbs) == 0 { | |
| return no | |
| } | |
| one := ctEq(xLimbs[0], 1) | |
| for i := 1; i < size; i++ { | |
| one &= ctEq(xLimbs[i], 0) | |
| } | |
| return one | |
| } | |
| // IsMinusOne returns 1 if x == -1 mod m, and 0 otherwise. | |
| // | |
| // The length of x must be the same as the modulus. x must already be reduced | |
| // modulo m. | |
| // | |
| //go:norace | |
| func (x *Nat) IsMinusOne(m *Modulus) choice { | |
| minusOne := m.Nat() | |
| minusOne.SubOne(m) | |
| return x.Equal(minusOne) | |
| } | |
| // IsOdd returns 1 if x is odd, and 0 otherwise. | |
| func (x *Nat) IsOdd() choice { | |
| if len(x.limbs) == 0 { | |
| return no | |
| } | |
| return choice(x.limbs[0] & 1) | |
| } | |
| // TrailingZeroBitsVarTime returns the number of trailing zero bits in x. | |
| func (x *Nat) TrailingZeroBitsVarTime() uint { | |
| var t uint | |
| limbs := x.limbs | |
| for _, l := range limbs { | |
| if l == 0 { | |
| t += _W | |
| continue | |
| } | |
| t += uint(bits.TrailingZeros(l)) | |
| break | |
| } | |
| return t | |
| } | |
| // cmpGeq returns 1 if x >= y, and 0 otherwise. | |
| // | |
| // Both operands must have the same announced length. | |
| // | |
| //go:norace | |
| func (x *Nat) cmpGeq(y *Nat) choice { | |
| // Eliminate bounds checks in the loop. | |
| size := len(x.limbs) | |
| xLimbs := x.limbs[:size] | |
| yLimbs := y.limbs[:size] | |
| var c uint | |
| for i := 0; i < size; i++ { | |
| _, c = bits.Sub(xLimbs[i], yLimbs[i], c) | |
| } | |
| // If there was a carry, then subtracting y underflowed, so | |
| // x is not greater than or equal to y. | |
| return not(choice(c)) | |
| } | |
| // assign sets x <- y if on == 1, and does nothing otherwise. | |
| // | |
| // Both operands must have the same announced length. | |
| // | |
| //go:norace | |
| func (x *Nat) assign(on choice, y *Nat) *Nat { | |
| // Eliminate bounds checks in the loop. | |
| size := len(x.limbs) | |
| xLimbs := x.limbs[:size] | |
| yLimbs := y.limbs[:size] | |
| mask := ctMask(on) | |
| for i := 0; i < size; i++ { | |
| xLimbs[i] ^= mask & (xLimbs[i] ^ yLimbs[i]) | |
| } | |
| return x | |
| } | |
| // add computes x += y and returns the carry. | |
| // | |
| // Both operands must have the same announced length. | |
| // | |
| //go:norace | |
| func (x *Nat) add(y *Nat) (c uint) { | |
| // Eliminate bounds checks in the loop. | |
| size := len(x.limbs) | |
| xLimbs := x.limbs[:size] | |
| yLimbs := y.limbs[:size] | |
| for i := 0; i < size; i++ { | |
| xLimbs[i], c = bits.Add(xLimbs[i], yLimbs[i], c) | |
| } | |
| return | |
| } | |
| // sub computes x -= y. It returns the borrow of the subtraction. | |
| // | |
| // Both operands must have the same announced length. | |
| // | |
| //go:norace | |
| func (x *Nat) sub(y *Nat) (c uint) { | |
| // Eliminate bounds checks in the loop. | |
| size := len(x.limbs) | |
| xLimbs := x.limbs[:size] | |
| yLimbs := y.limbs[:size] | |
| for i := 0; i < size; i++ { | |
| xLimbs[i], c = bits.Sub(xLimbs[i], yLimbs[i], c) | |
| } | |
| return | |
| } | |
| // ShiftRightVarTime sets x = x >> n. | |
| // | |
| // The announced length of x is unchanged. | |
| // | |
| //go:norace | |
| func (x *Nat) ShiftRightVarTime(n uint) *Nat { | |
| // Eliminate bounds checks in the loop. | |
| size := len(x.limbs) | |
| xLimbs := x.limbs[:size] | |
| shift := int(n % _W) | |
| shiftLimbs := int(n / _W) | |
| var shiftedLimbs []uint | |
| if shiftLimbs < size { | |
| shiftedLimbs = xLimbs[shiftLimbs:] | |
| } | |
| for i := range xLimbs { | |
| if i >= len(shiftedLimbs) { | |
| xLimbs[i] = 0 | |
| continue | |
| } | |
| xLimbs[i] = shiftedLimbs[i] >> shift | |
| if i+1 < len(shiftedLimbs) { | |
| xLimbs[i] |= shiftedLimbs[i+1] << (_W - shift) | |
| } | |
| } | |
| return x | |
| } | |
| // BitLenVarTime returns the actual size of x in bits. | |
| // | |
| // The actual size of x (but nothing more) leaks through timing side-channels. | |
| // Note that this is ordinarily secret, as opposed to the announced size of x. | |
| func (x *Nat) BitLenVarTime() int { | |
| // Eliminate bounds checks in the loop. | |
| size := len(x.limbs) | |
| xLimbs := x.limbs[:size] | |
| for i := size - 1; i >= 0; i-- { | |
| if xLimbs[i] != 0 { | |
| return i*_W + bitLen(xLimbs[i]) | |
| } | |
| } | |
| return 0 | |
| } | |
| // bitLen is a version of bits.Len that only leaks the bit length of n, but not | |
| // its value. bits.Len and bits.LeadingZeros use a lookup table for the | |
| // low-order bits on some architectures. | |
| func bitLen(n uint) int { | |
| len := 0 | |
| // We assume, here and elsewhere, that comparison to zero is constant time | |
| // with respect to different non-zero values. | |
| for n != 0 { | |
| len++ | |
| n >>= 1 | |
| } | |
| return len | |
| } | |
| // Modulus is used for modular arithmetic, precomputing relevant constants. | |
| // | |
| // A Modulus can leak the exact number of bits needed to store its value | |
| // and is stored without padding. Its actual value is still kept secret. | |
| type Modulus struct { | |
| // The underlying natural number for this modulus. | |
| // | |
| // This will be stored without any padding, and shouldn't alias with any | |
| // other natural number being used. | |
| nat *Nat | |
| // If m is even, the following fields are not set. | |
| odd bool | |
| m0inv uint // -nat.limbs[0]⁻¹ mod _W | |
| rr *Nat // R*R for montgomeryRepresentation | |
| } | |
| // rr returns R*R with R = 2^(_W * n) and n = len(m.nat.limbs). | |
| func rr(m *Modulus) *Nat { | |
| rr := NewNat().ExpandFor(m) | |
| n := uint(len(rr.limbs)) | |
| mLen := uint(m.BitLen()) | |
| logR := _W * n | |
| // We start by computing R = 2^(_W * n) mod m. We can get pretty close, to | |
| // 2^⌊log₂m⌋, by setting the highest bit we can without having to reduce. | |
| rr.limbs[n-1] = 1 << ((mLen - 1) % _W) | |
| // Then we double until we reach 2^(_W * n). | |
| for i := mLen - 1; i < logR; i++ { | |
| rr.Add(rr, m) | |
| } | |
| // Next we need to get from R to 2^(_W * n) R mod m (aka from one to R in | |
| // the Montgomery domain, meaning we can use Montgomery multiplication now). | |
| // We could do that by doubling _W * n times, or with a square-and-double | |
| // chain log2(_W * n) long. Turns out the fastest thing is to start out with | |
| // doublings, and switch to square-and-double once the exponent is large | |
| // enough to justify the cost of the multiplications. | |
| // The threshold is selected experimentally as a linear function of n. | |
| threshold := n / 4 | |
| // We calculate how many of the most-significant bits of the exponent we can | |
| // compute before crossing the threshold, and we do it with doublings. | |
| i := bits.UintSize | |
| for logR>>i <= threshold { | |
| i-- | |
| } | |
| for k := uint(0); k < logR>>i; k++ { | |
| rr.Add(rr, m) | |
| } | |
| // Then we process the remaining bits of the exponent with a | |
| // square-and-double chain. | |
| for i > 0 { | |
| rr.montgomeryMul(rr, rr, m) | |
| i-- | |
| if logR>>i&1 != 0 { | |
| rr.Add(rr, m) | |
| } | |
| } | |
| return rr | |
| } | |
| // minusInverseModW computes -x⁻¹ mod _W with x odd. | |
| // | |
| // This operation is used to precompute a constant involved in Montgomery | |
| // multiplication. | |
| func minusInverseModW(x uint) uint { | |
| // Every iteration of this loop doubles the least-significant bits of | |
| // correct inverse in y. The first three bits are already correct (1⁻¹ = 1, | |
| // 3⁻¹ = 3, 5⁻¹ = 5, and 7⁻¹ = 7 mod 8), so doubling five times is enough | |
| // for 64 bits (and wastes only one iteration for 32 bits). | |
| // | |
| // See https://crypto.stackexchange.com/a/47496. | |
| y := x | |
| for i := 0; i < 5; i++ { | |
| y = y * (2 - x*y) | |
| } | |
| return -y | |
| } | |
| // NewModulus creates a new Modulus from a slice of big-endian bytes. The | |
| // modulus must be greater than one. | |
| // | |
| // The number of significant bits and whether the modulus is even is leaked | |
| // through timing side-channels. | |
| func NewModulus(b []byte) (*Modulus, error) { | |
| n := NewNat().resetToBytes(b) | |
| return newModulus(n) | |
| } | |
| // NewModulusProduct creates a new Modulus from the product of two numbers | |
| // represented as big-endian byte slices. The result must be greater than one. | |
| // | |
| //go:norace | |
| func NewModulusProduct(a, b []byte) (*Modulus, error) { | |
| x := NewNat().resetToBytes(a) | |
| y := NewNat().resetToBytes(b) | |
| n := NewNat().reset(len(x.limbs) + len(y.limbs)) | |
| for i := range y.limbs { | |
| n.limbs[i+len(x.limbs)] = addMulVVW(n.limbs[i:i+len(x.limbs)], x.limbs, y.limbs[i]) | |
| } | |
| return newModulus(n.trim()) | |
| } | |
| func newModulus(n *Nat) (*Modulus, error) { | |
| m := &Modulus{nat: n} | |
| if m.nat.IsZero() == yes || m.nat.IsOne() == yes { | |
| return nil, errors.New("modulus must be > 1") | |
| } | |
| if m.nat.IsOdd() == 1 { | |
| m.odd = true | |
| m.m0inv = minusInverseModW(m.nat.limbs[0]) | |
| m.rr = rr(m) | |
| } | |
| return m, nil | |
| } | |
| // Size returns the size of m in bytes. | |
| func (m *Modulus) Size() int { | |
| return (m.BitLen() + 7) / 8 | |
| } | |
| // BitLen returns the size of m in bits. | |
| func (m *Modulus) BitLen() int { | |
| return m.nat.BitLenVarTime() | |
| } | |
| // Nat returns m as a Nat. | |
| func (m *Modulus) Nat() *Nat { | |
| // Make a copy so that the caller can't modify m.nat or alias it with | |
| // another Nat in a modulus operation. | |
| n := NewNat() | |
| n.set(m.nat) | |
| return n | |
| } | |
| // shiftIn calculates x = x << _W + y mod m. | |
| // | |
| // This assumes that x is already reduced mod m. | |
| // | |
| //go:norace | |
| func (x *Nat) shiftIn(y uint, m *Modulus) *Nat { | |
| d := NewNat().resetFor(m) | |
| // Eliminate bounds checks in the loop. | |
| size := len(m.nat.limbs) | |
| xLimbs := x.limbs[:size] | |
| dLimbs := d.limbs[:size] | |
| mLimbs := m.nat.limbs[:size] | |
| // Each iteration of this loop computes x = 2x + b mod m, where b is a bit | |
| // from y. Effectively, it left-shifts x and adds y one bit at a time, | |
| // reducing it every time. | |
| // | |
| // To do the reduction, each iteration computes both 2x + b and 2x + b - m. | |
| // The next iteration (and finally the return line) will use either result | |
| // based on whether 2x + b overflows m. | |
| needSubtraction := no | |
| for i := _W - 1; i >= 0; i-- { | |
| carry := (y >> i) & 1 | |
| var borrow uint | |
| mask := ctMask(needSubtraction) | |
| for i := 0; i < size; i++ { | |
| l := xLimbs[i] ^ (mask & (xLimbs[i] ^ dLimbs[i])) | |
| xLimbs[i], carry = bits.Add(l, l, carry) | |
| dLimbs[i], borrow = bits.Sub(xLimbs[i], mLimbs[i], borrow) | |
| } | |
| // Like in maybeSubtractModulus, we need the subtraction if either it | |
| // didn't underflow (meaning 2x + b > m) or if computing 2x + b | |
| // overflowed (meaning 2x + b > 2^_W*n > m). | |
| needSubtraction = not(choice(borrow)) | choice(carry) | |
| } | |
| return x.assign(needSubtraction, d) | |
| } | |
| // Mod calculates out = x mod m. | |
| // | |
| // This works regardless how large the value of x is. | |
| // | |
| // The output will be resized to the size of m and overwritten. | |
| // | |
| //go:norace | |
| func (out *Nat) Mod(x *Nat, m *Modulus) *Nat { | |
| out.resetFor(m) | |
| // Working our way from the most significant to the least significant limb, | |
| // we can insert each limb at the least significant position, shifting all | |
| // previous limbs left by _W. This way each limb will get shifted by the | |
| // correct number of bits. We can insert at least N - 1 limbs without | |
| // overflowing m. After that, we need to reduce every time we shift. | |
| i := len(x.limbs) - 1 | |
| // For the first N - 1 limbs we can skip the actual shifting and position | |
| // them at the shifted position, which starts at min(N - 2, i). | |
| start := len(m.nat.limbs) - 2 | |
| if i < start { | |
| start = i | |
| } | |
| for j := start; j >= 0; j-- { | |
| out.limbs[j] = x.limbs[i] | |
| i-- | |
| } | |
| // We shift in the remaining limbs, reducing modulo m each time. | |
| for i >= 0 { | |
| out.shiftIn(x.limbs[i], m) | |
| i-- | |
| } | |
| return out | |
| } | |
| // ExpandFor ensures x has the right size to work with operations modulo m. | |
| // | |
| // The announced size of x must be smaller than or equal to that of m. | |
| func (x *Nat) ExpandFor(m *Modulus) *Nat { | |
| return x.expand(len(m.nat.limbs)) | |
| } | |
| // resetFor ensures out has the right size to work with operations modulo m. | |
| // | |
| // out is zeroed and may start at any size. | |
| func (out *Nat) resetFor(m *Modulus) *Nat { | |
| return out.reset(len(m.nat.limbs)) | |
| } | |
| // maybeSubtractModulus computes x -= m if and only if x >= m or if "always" is yes. | |
| // | |
| // It can be used to reduce modulo m a value up to 2m - 1, which is a common | |
| // range for results computed by higher level operations. | |
| // | |
| // always is usually a carry that indicates that the operation that produced x | |
| // overflowed its size, meaning abstractly x > 2^_W*n > m even if x < m. | |
| // | |
| // x and m operands must have the same announced length. | |
| // | |
| //go:norace | |
| func (x *Nat) maybeSubtractModulus(always choice, m *Modulus) { | |
| t := NewNat().set(x) | |
| underflow := t.sub(m.nat) | |
| // We keep the result if x - m didn't underflow (meaning x >= m) | |
| // or if always was set. | |
| keep := not(choice(underflow)) | choice(always) | |
| x.assign(keep, t) | |
| } | |
| // Sub computes x = x - y mod m. | |
| // | |
| // The length of both operands must be the same as the modulus. Both operands | |
| // must already be reduced modulo m. | |
| // | |
| //go:norace | |
| func (x *Nat) Sub(y *Nat, m *Modulus) *Nat { | |
| underflow := x.sub(y) | |
| // If the subtraction underflowed, add m. | |
| t := NewNat().set(x) | |
| t.add(m.nat) | |
| x.assign(choice(underflow), t) | |
| return x | |
| } | |
| // SubOne computes x = x - 1 mod m. | |
| // | |
| // The length of x must be the same as the modulus. | |
| func (x *Nat) SubOne(m *Modulus) *Nat { | |
| one := NewNat().ExpandFor(m) | |
| one.limbs[0] = 1 | |
| // Sub asks for x to be reduced modulo m, while SubOne doesn't, but when | |
| // y = 1, it works, and this is an internal use. | |
| return x.Sub(one, m) | |
| } | |
| // Add computes x = x + y mod m. | |
| // | |
| // The length of both operands must be the same as the modulus. Both operands | |
| // must already be reduced modulo m. | |
| // | |
| //go:norace | |
| func (x *Nat) Add(y *Nat, m *Modulus) *Nat { | |
| overflow := x.add(y) | |
| x.maybeSubtractModulus(choice(overflow), m) | |
| return x | |
| } | |
| // montgomeryRepresentation calculates x = x * R mod m, with R = 2^(_W * n) and | |
| // n = len(m.nat.limbs). | |
| // | |
| // Faster Montgomery multiplication replaces standard modular multiplication for | |
| // numbers in this representation. | |
| // | |
| // This assumes that x is already reduced mod m. | |
| func (x *Nat) montgomeryRepresentation(m *Modulus) *Nat { | |
| // A Montgomery multiplication (which computes a * b / R) by R * R works out | |
| // to a multiplication by R, which takes the value out of the Montgomery domain. | |
| return x.montgomeryMul(x, m.rr, m) | |
| } | |
| // montgomeryReduction calculates x = x / R mod m, with R = 2^(_W * n) and | |
| // n = len(m.nat.limbs). | |
| // | |
| // This assumes that x is already reduced mod m. | |
| func (x *Nat) montgomeryReduction(m *Modulus) *Nat { | |
| // By Montgomery multiplying with 1 not in Montgomery representation, we | |
| // convert out back from Montgomery representation, because it works out to | |
| // dividing by R. | |
| one := NewNat().ExpandFor(m) | |
| one.limbs[0] = 1 | |
| return x.montgomeryMul(x, one, m) | |
| } | |
| // montgomeryMul calculates x = a * b / R mod m, with R = 2^(_W * n) and | |
| // n = len(m.nat.limbs), also known as a Montgomery multiplication. | |
| // | |
| // All inputs should be the same length and already reduced modulo m. | |
| // x will be resized to the size of m and overwritten. | |
| // | |
| //go:norace | |
| func (x *Nat) montgomeryMul(a *Nat, b *Nat, m *Modulus) *Nat { | |
| n := len(m.nat.limbs) | |
| mLimbs := m.nat.limbs[:n] | |
| aLimbs := a.limbs[:n] | |
| bLimbs := b.limbs[:n] | |
| switch n { | |
| default: | |
| // Attempt to use a stack-allocated backing array. | |
| T := make([]uint, 0, preallocLimbs*2) | |
| if cap(T) < n*2 { | |
| T = make([]uint, 0, n*2) | |
| } | |
| T = T[:n*2] | |
| // This loop implements Word-by-Word Montgomery Multiplication, as | |
| // described in Algorithm 4 (Fig. 3) of "Efficient Software | |
| // Implementations of Modular Exponentiation" by Shay Gueron | |
| // [https://eprint.iacr.org/2011/239.pdf]. | |
| var c uint | |
| for i := 0; i < n; i++ { | |
| _ = T[n+i] // bounds check elimination hint | |
| // Step 1 (T = a × b) is computed as a large pen-and-paper column | |
| // multiplication of two numbers with n base-2^_W digits. If we just | |
| // wanted to produce 2n-wide T, we would do | |
| // | |
| // for i := 0; i < n; i++ { | |
| // d := bLimbs[i] | |
| // T[n+i] = addMulVVW(T[i:n+i], aLimbs, d) | |
| // } | |
| // | |
| // where d is a digit of the multiplier, T[i:n+i] is the shifted | |
| // position of the product of that digit, and T[n+i] is the final carry. | |
| // Note that T[i] isn't modified after processing the i-th digit. | |
| // | |
| // Instead of running two loops, one for Step 1 and one for Steps 2–6, | |
| // the result of Step 1 is computed during the next loop. This is | |
| // possible because each iteration only uses T[i] in Step 2 and then | |
| // discards it in Step 6. | |
| d := bLimbs[i] | |
| c1 := addMulVVW(T[i:n+i], aLimbs, d) | |
| // Step 6 is replaced by shifting the virtual window we operate | |
| // over: T of the algorithm is T[i:] for us. That means that T1 in | |
| // Step 2 (T mod 2^_W) is simply T[i]. k0 in Step 3 is our m0inv. | |
| Y := T[i] * m.m0inv | |
| // Step 4 and 5 add Y × m to T, which as mentioned above is stored | |
| // at T[i:]. The two carries (from a × d and Y × m) are added up in | |
| // the next word T[n+i], and the carry bit from that addition is | |
| // brought forward to the next iteration. | |
| c2 := addMulVVW(T[i:n+i], mLimbs, Y) | |
| T[n+i], c = bits.Add(c1, c2, c) | |
| } | |
| // Finally for Step 7 we copy the final T window into x, and subtract m | |
| // if necessary (which as explained in maybeSubtractModulus can be the | |
| // case both if x >= m, or if x overflowed). | |
| // | |
| // The paper suggests in Section 4 that we can do an "Almost Montgomery | |
| // Multiplication" by subtracting only in the overflow case, but the | |
| // cost is very similar since the constant time subtraction tells us if | |
| // x >= m as a side effect, and taking care of the broken invariant is | |
| // highly undesirable (see https://go.dev/issue/13907). | |
| copy(x.reset(n).limbs, T[n:]) | |
| x.maybeSubtractModulus(choice(c), m) | |
| // The following specialized cases follow the exact same algorithm, but | |
| // optimized for the sizes most used in RSA. addMulVVW is implemented in | |
| // assembly with loop unrolling depending on the architecture and bounds | |
| // checks are removed by the compiler thanks to the constant size. | |
| case 1024 / _W: | |
| const n = 1024 / _W // compiler hint | |
| T := make([]uint, n*2) | |
| var c uint | |
| for i := 0; i < n; i++ { | |
| d := bLimbs[i] | |
| c1 := addMulVVW1024(&T[i], &aLimbs[0], d) | |
| Y := T[i] * m.m0inv | |
| c2 := addMulVVW1024(&T[i], &mLimbs[0], Y) | |
| T[n+i], c = bits.Add(c1, c2, c) | |
| } | |
| copy(x.reset(n).limbs, T[n:]) | |
| x.maybeSubtractModulus(choice(c), m) | |
| case 1536 / _W: | |
| const n = 1536 / _W // compiler hint | |
| T := make([]uint, n*2) | |
| var c uint | |
| for i := 0; i < n; i++ { | |
| d := bLimbs[i] | |
| c1 := addMulVVW1536(&T[i], &aLimbs[0], d) | |
| Y := T[i] * m.m0inv | |
| c2 := addMulVVW1536(&T[i], &mLimbs[0], Y) | |
| T[n+i], c = bits.Add(c1, c2, c) | |
| } | |
| copy(x.reset(n).limbs, T[n:]) | |
| x.maybeSubtractModulus(choice(c), m) | |
| case 2048 / _W: | |
| const n = 2048 / _W // compiler hint | |
| T := make([]uint, n*2) | |
| var c uint | |
| for i := 0; i < n; i++ { | |
| d := bLimbs[i] | |
| c1 := addMulVVW2048(&T[i], &aLimbs[0], d) | |
| Y := T[i] * m.m0inv | |
| c2 := addMulVVW2048(&T[i], &mLimbs[0], Y) | |
| T[n+i], c = bits.Add(c1, c2, c) | |
| } | |
| copy(x.reset(n).limbs, T[n:]) | |
| x.maybeSubtractModulus(choice(c), m) | |
| } | |
| return x | |
| } | |
| // addMulVVW multiplies the multi-word value x by the single-word value y, | |
| // adding the result to the multi-word value z and returning the final carry. | |
| // It can be thought of as one row of a pen-and-paper column multiplication. | |
| // | |
| //go:norace | |
| func addMulVVW(z, x []uint, y uint) (carry uint) { | |
| _ = x[len(z)-1] // bounds check elimination hint | |
| for i := range z { | |
| hi, lo := bits.Mul(x[i], y) | |
| lo, c := bits.Add(lo, z[i], 0) | |
| // We use bits.Add with zero to get an add-with-carry instruction that | |
| // absorbs the carry from the previous bits.Add. | |
| hi, _ = bits.Add(hi, 0, c) | |
| lo, c = bits.Add(lo, carry, 0) | |
| hi, _ = bits.Add(hi, 0, c) | |
| carry = hi | |
| z[i] = lo | |
| } | |
| return carry | |
| } | |
| // Mul calculates x = x * y mod m. | |
| // | |
| // The length of both operands must be the same as the modulus. Both operands | |
| // must already be reduced modulo m. | |
| // | |
| //go:norace | |
| func (x *Nat) Mul(y *Nat, m *Modulus) *Nat { | |
| if m.odd { | |
| // A Montgomery multiplication by a value out of the Montgomery domain | |
| // takes the result out of Montgomery representation. | |
| xR := NewNat().set(x).montgomeryRepresentation(m) // xR = x * R mod m | |
| return x.montgomeryMul(xR, y, m) // x = xR * y / R mod m | |
| } | |
| n := len(m.nat.limbs) | |
| xLimbs := x.limbs[:n] | |
| yLimbs := y.limbs[:n] | |
| switch n { | |
| default: | |
| // Attempt to use a stack-allocated backing array. | |
| T := make([]uint, 0, preallocLimbs*2) | |
| if cap(T) < n*2 { | |
| T = make([]uint, 0, n*2) | |
| } | |
| T = T[:n*2] | |
| // T = x * y | |
| for i := 0; i < n; i++ { | |
| T[n+i] = addMulVVW(T[i:n+i], xLimbs, yLimbs[i]) | |
| } | |
| // x = T mod m | |
| return x.Mod(&Nat{limbs: T}, m) | |
| // The following specialized cases follow the exact same algorithm, but | |
| // optimized for the sizes most used in RSA. See montgomeryMul for details. | |
| case 1024 / _W: | |
| const n = 1024 / _W // compiler hint | |
| T := make([]uint, n*2) | |
| for i := 0; i < n; i++ { | |
| T[n+i] = addMulVVW1024(&T[i], &xLimbs[0], yLimbs[i]) | |
| } | |
| return x.Mod(&Nat{limbs: T}, m) | |
| case 1536 / _W: | |
| const n = 1536 / _W // compiler hint | |
| T := make([]uint, n*2) | |
| for i := 0; i < n; i++ { | |
| T[n+i] = addMulVVW1536(&T[i], &xLimbs[0], yLimbs[i]) | |
| } | |
| return x.Mod(&Nat{limbs: T}, m) | |
| case 2048 / _W: | |
| const n = 2048 / _W // compiler hint | |
| T := make([]uint, n*2) | |
| for i := 0; i < n; i++ { | |
| T[n+i] = addMulVVW2048(&T[i], &xLimbs[0], yLimbs[i]) | |
| } | |
| return x.Mod(&Nat{limbs: T}, m) | |
| } | |
| } | |
| // Exp calculates out = x^e mod m. | |
| // | |
| // The exponent e is represented in big-endian order. The output will be resized | |
| // to the size of m and overwritten. x must already be reduced modulo m. | |
| // | |
| // m must be odd, or Exp will panic. | |
| // | |
| //go:norace | |
| func (out *Nat) Exp(x *Nat, e []byte, m *Modulus) *Nat { | |
| if !m.odd { | |
| panic("bigmod: modulus for Exp must be odd") | |
| } | |
| // We use a 4 bit window. For our RSA workload, 4 bit windows are faster | |
| // than 2 bit windows, but use an extra 12 nats worth of scratch space. | |
| // Using bit sizes that don't divide 8 are more complex to implement, but | |
| // are likely to be more efficient if necessary. | |
| table := [(1 << 4) - 1]*Nat{ // table[i] = x ^ (i+1) | |
| // newNat calls are unrolled so they are allocated on the stack. | |
| NewNat(), NewNat(), NewNat(), NewNat(), NewNat(), | |
| NewNat(), NewNat(), NewNat(), NewNat(), NewNat(), | |
| NewNat(), NewNat(), NewNat(), NewNat(), NewNat(), | |
| } | |
| table[0].set(x).montgomeryRepresentation(m) | |
| for i := 1; i < len(table); i++ { | |
| table[i].montgomeryMul(table[i-1], table[0], m) | |
| } | |
| out.resetFor(m) | |
| out.limbs[0] = 1 | |
| out.montgomeryRepresentation(m) | |
| tmp := NewNat().ExpandFor(m) | |
| for _, b := range e { | |
| for _, j := range []int{4, 0} { | |
| // Square four times. Optimization note: this can be implemented | |
| // more efficiently than with generic Montgomery multiplication. | |
| out.montgomeryMul(out, out, m) | |
| out.montgomeryMul(out, out, m) | |
| out.montgomeryMul(out, out, m) | |
| out.montgomeryMul(out, out, m) | |
| // Select x^k in constant time from the table. | |
| k := uint((b >> j) & 0b1111) | |
| for i := range table { | |
| tmp.assign(ctEq(k, uint(i+1)), table[i]) | |
| } | |
| // Multiply by x^k, discarding the result if k = 0. | |
| tmp.montgomeryMul(out, tmp, m) | |
| out.assign(not(ctEq(k, 0)), tmp) | |
| } | |
| } | |
| return out.montgomeryReduction(m) | |
| } | |
| // ExpShortVarTime calculates out = x^e mod m. | |
| // | |
| // The output will be resized to the size of m and overwritten. x must already | |
| // be reduced modulo m. This leaks the exponent through timing side-channels. | |
| // | |
| // m must be odd, or ExpShortVarTime will panic. | |
| func (out *Nat) ExpShortVarTime(x *Nat, e uint, m *Modulus) *Nat { | |
| if !m.odd { | |
| panic("bigmod: modulus for ExpShortVarTime must be odd") | |
| } | |
| // For short exponents, precomputing a table and using a window like in Exp | |
| // doesn't pay off. Instead, we do a simple conditional square-and-multiply | |
| // chain, skipping the initial run of zeroes. | |
| xR := NewNat().set(x).montgomeryRepresentation(m) | |
| out.set(xR) | |
| for i := bits.UintSize - bits.Len(e) + 1; i < bits.UintSize; i++ { | |
| out.montgomeryMul(out, out, m) | |
| if k := (e >> (bits.UintSize - i - 1)) & 1; k != 0 { | |
| out.montgomeryMul(out, xR, m) | |
| } | |
| } | |
| return out.montgomeryReduction(m) | |
| } | |
| // InverseVarTime calculates x = a⁻¹ mod m and returns (x, true) if a is | |
| // invertible. Otherwise, InverseVarTime returns (x, false) and x is not | |
| // modified. | |
| // | |
| // a must be reduced modulo m, but doesn't need to have the same size. The | |
| // output will be resized to the size of m and overwritten. | |
| // | |
| //go:norace | |
| func (x *Nat) InverseVarTime(a *Nat, m *Modulus) (*Nat, bool) { | |
| u, A, err := extendedGCD(a, m.nat) | |
| if err != nil { | |
| return x, false | |
| } | |
| if u.IsOne() == no { | |
| return x, false | |
| } | |
| return x.set(A), true | |
| } | |
| // GCDVarTime calculates x = GCD(a, b) where at least one of a or b is odd, and | |
| // both are non-zero. If GCDVarTime returns an error, x is not modified. | |
| // | |
| // The output will be resized to the size of the larger of a and b. | |
| func (x *Nat) GCDVarTime(a, b *Nat) (*Nat, error) { | |
| u, _, err := extendedGCD(a, b) | |
| if err != nil { | |
| return nil, err | |
| } | |
| return x.set(u), nil | |
| } | |
| // extendedGCD computes u and A such that u = GCD(a, m) = A*a - B*m. | |
| // | |
| // u will have the size of the larger of a and m, and A will have the size of m. | |
| // | |
| // It is an error if either a or m is zero, or if they are both even. | |
| func extendedGCD(a, m *Nat) (u, A *Nat, err error) { | |
| // This is the extended binary GCD algorithm described in the Handbook of | |
| // Applied Cryptography, Algorithm 14.61, adapted by BoringSSL to bound | |
| // coefficients and avoid negative numbers. For more details and proof of | |
| // correctness, see https://github.com/mit-plv/fiat-crypto/pull/333/files. | |
| // | |
| // Following the proof linked in the PR above, the changes are: | |
| // | |
| // 1. Negate [B] and [C] so they are positive. The invariant now involves a | |
| // subtraction. | |
| // 2. If step 2 (both [x] and [y] are even) runs, abort immediately. This | |
| // case needs to be handled by the caller. | |
| // 3. Subtract copies of [x] and [y] as needed in step 6 (both [u] and [v] | |
| // are odd) so coefficients stay in bounds. | |
| // 4. Replace the [u >= v] check with [u > v]. This changes the end | |
| // condition to [v = 0] rather than [u = 0]. This saves an extra | |
| // subtraction due to which coefficients were negated. | |
| // 5. Rename x and y to a and n, to capture that one is a modulus. | |
| // 6. Rearrange steps 4 through 6 slightly. Merge the loops in steps 4 and | |
| // 5 into the main loop (step 7's goto), and move step 6 to the start of | |
| // the loop iteration, ensuring each loop iteration halves at least one | |
| // value. | |
| // | |
| // Note this algorithm does not handle either input being zero. | |
| if a.IsZero() == yes || m.IsZero() == yes { | |
| return nil, nil, errors.New("extendedGCD: a or m is zero") | |
| } | |
| if a.IsOdd() == no && m.IsOdd() == no { | |
| return nil, nil, errors.New("extendedGCD: both a and m are even") | |
| } | |
| size := max(len(a.limbs), len(m.limbs)) | |
| u = NewNat().set(a).expand(size) | |
| v := NewNat().set(m).expand(size) | |
| A = NewNat().reset(len(m.limbs)) | |
| A.limbs[0] = 1 | |
| B := NewNat().reset(len(a.limbs)) | |
| C := NewNat().reset(len(m.limbs)) | |
| D := NewNat().reset(len(a.limbs)) | |
| D.limbs[0] = 1 | |
| // Before and after each loop iteration, the following hold: | |
| // | |
| // u = A*a - B*m | |
| // v = D*m - C*a | |
| // 0 < u <= a | |
| // 0 <= v <= m | |
| // 0 <= A < m | |
| // 0 <= B <= a | |
| // 0 <= C < m | |
| // 0 <= D <= a | |
| // | |
| // After each loop iteration, u and v only get smaller, and at least one of | |
| // them shrinks by at least a factor of two. | |
| for { | |
| // If both u and v are odd, subtract the smaller from the larger. | |
| // If u = v, we need to subtract from v to hit the modified exit condition. | |
| if u.IsOdd() == yes && v.IsOdd() == yes { | |
| if v.cmpGeq(u) == no { | |
| u.sub(v) | |
| A.Add(C, &Modulus{nat: m}) | |
| B.Add(D, &Modulus{nat: a}) | |
| } else { | |
| v.sub(u) | |
| C.Add(A, &Modulus{nat: m}) | |
| D.Add(B, &Modulus{nat: a}) | |
| } | |
| } | |
| // Exactly one of u and v is now even. | |
| if u.IsOdd() == v.IsOdd() { | |
| panic("bigmod: internal error: u and v are not in the expected state") | |
| } | |
| // Halve the even one and adjust the corresponding coefficient. | |
| if u.IsOdd() == no { | |
| rshift1(u, 0) | |
| if A.IsOdd() == yes || B.IsOdd() == yes { | |
| rshift1(A, A.add(m)) | |
| rshift1(B, B.add(a)) | |
| } else { | |
| rshift1(A, 0) | |
| rshift1(B, 0) | |
| } | |
| } else { // v.IsOdd() == no | |
| rshift1(v, 0) | |
| if C.IsOdd() == yes || D.IsOdd() == yes { | |
| rshift1(C, C.add(m)) | |
| rshift1(D, D.add(a)) | |
| } else { | |
| rshift1(C, 0) | |
| rshift1(D, 0) | |
| } | |
| } | |
| if v.IsZero() == yes { | |
| return u, A, nil | |
| } | |
| } | |
| } | |
| //go:norace | |
| func rshift1(a *Nat, carry uint) { | |
| size := len(a.limbs) | |
| aLimbs := a.limbs[:size] | |
| for i := range size { | |
| aLimbs[i] >>= 1 | |
| if i+1 < size { | |
| aLimbs[i] |= aLimbs[i+1] << (_W - 1) | |
| } else { | |
| aLimbs[i] |= carry << (_W - 1) | |
| } | |
| } | |
| } | |
| // DivShortVarTime calculates x = x / y and returns the remainder. | |
| // | |
| // It panics if y is zero. | |
| // | |
| //go:norace | |
| func (x *Nat) DivShortVarTime(y uint) uint { | |
| if y == 0 { | |
| panic("bigmod: division by zero") | |
| } | |
| var r uint | |
| for i := len(x.limbs) - 1; i >= 0; i-- { | |
| x.limbs[i], r = bits.Div(r, x.limbs[i], y) | |
| } | |
| return r | |
| } | |