// Copyright 2009 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 Integer const ValueLen = 1000; type Word uint32 type Value *[ValueLen]Word type IntegerImpl struct { val Value } type Integer *IntegerImpl export IntegerImpl, Integer const N = 4; const H = 1 const L = 28; const M = 1 << L - 1; // ---------------------------------------------------------------------------- // Support // TODO What are we going to about asserts? func ASSERT(p bool) { if !p { panic "ASSERT failed"; } } func CHECK(p bool) { if !p { panic "CHECK failed"; } } func UNIMPLEMENTED(s string) { panic "UNIMPLEMENTED: ", s; } // ---------------------------------------------------------------------------- // // TODO "len" is a reserved word at the moment - I think that's wrong func len_(x Value) int { l := int(x[0]); if l < 0 { return -l; } return l; } func set_len(x Value, len_ int) { x[0] = Word(len_); } func alloc(len_ int) Value { ASSERT(len_ >= 0); z := new([ValueLen] Word); set_len(z, len_); return z; } func sign(x Value) bool { return int(x[0]) < 0; } func zero(x Value) bool { return x[0] == 0; } func neg(x Value) { x[0] = Word(-int(x[0])); } // ---------------------------------------------------------------------------- // Unsigned ops func make(x int) Value; func Update(x Word) (z, c Word) { // z = x & M; // c = x >> L; return x & M, x >> L; } func uadd(x, y Value) Value { xl := len_(x); yl := len_(y); if xl < yl { return uadd(y, x); } ASSERT(xl >= yl); z := alloc(xl + 1); i := 0; c := Word(0); for i < yl { z[i + H], c = Update(x[i + H] + y[i + H] + c); i++; } for i < xl { z[i + H], c = Update(x[i + H] + c); i++; } if c != 0 { z[i + H] = c; i++; } set_len(z, i); return z; } func usub(x, y Value) Value { xl := len_(x); yl := len_(y); if xl < yl { return uadd(y, x); } ASSERT(xl >= yl); z := alloc(xl + 1); i := 0; c := Word(0); for i < yl { z[i + H], c = Update(x[i + H] - y[i + H] + c); i++; } for i < xl { z[i + H], c = Update(x[i + H] + c); i++; } ASSERT(c == 0); // usub(x, y) must be called with x >= y for i > 0 && z[i - 1 + H] == 0 { i--; } set_len(z, i); return z; } // Computes x = x*a + c (in place) for "small" a's. func umul_add(x Value, a, c Word) Value { CHECK(0 <= a && a < (1 << N)); CHECK(0 <= c && c < (1 << N)); if (zero(x) || a == 0) && c == 0 { return make(0); } xl := len_(x); z := alloc(xl + 1); i := 0; for i < xl { z[i + H], c = Update(x[i + H] * a + c); i++; } if c != 0 { z[i + H] = c; i++; } set_len(z, i); return z; } // Computes x = x div d (in place) for "small" d's. Returns x mod d. func umod(x Value, d Word) Word { CHECK(0 < d && d < (1 << N)); xl := len_(x); c := Word(0); i := xl; for i > 0 { i--; c = c << L + x[i + H]; q := c / d; x[i + H] = q; //x[i + H] = c / d; // BUG c = c % d; } if xl > 0 && x[xl - 1 + H] == 0 { set_len(x, xl - 1); } return c; } // Returns z = (x * y) div B, c = (x * y) mod B. func umul1(x, y Word) (z Word, c Word) { const L2 = (L + 1) >> 1; const B2 = 1 << L2; const M2 = B2 - 1; x0 := x & M2; x1 := x >> L2; y0 := y & M2; y1 := y >> L2; z10 := x0*y0; z21 := x1*y0 + x0*y1 + (z10 >> L2); cc := x1*y1 + (z21 >> L2); zz := ((z21 & M2) << L2) | (z10 & M2); return zz, cc } func umul(x Value, y Value) Value { if zero(x) || zero(y) { return make(0); } xl := len_(x); yl := len_(y); if xl < yl { return umul(y, x); // for speed } ASSERT(xl >= yl && yl > 0); // initialize z zl := xl + yl; z := alloc(zl); for i := 0; i < zl; i++ { z[i + H] = 0; } k := 0; for j := 0; j < yl; j++ { d := y[j + H]; if d != 0 { k = j; c := Word(0); for i := 0; i < xl; i++ { // compute z[k + H] += x[i + H] * d + c; t := z[k + H] + c; var z1 Word; z1, c = umul1(x[i + H], d); t += z1; z[k + H] = t & M; c += t >> L; k++; } if c != 0 { z[k + H] = Word(c); k++; } } } set_len(z, k); return z; } func ucmp(x Value, y Value) int { xl := len_(x); yl := len_(y); if xl != yl || xl == 0 { return xl - yl; } i := xl - 1; for i > 0 && x[i + H] == y[i + H] { i--; } return int(x[i + H]) - int(y[i + H]); } func ulog(x Value) int { xl := len_(x); if xl == 0 { return 0; } n := (xl - 1) * L; for t := x[xl - 1 + H]; t != 0; t >>= 1 { n++ }; return n; } func make(x int) Value { if x == 0 { z := alloc(0); set_len(z, 0); return z; } if x == -x { // smallest int z := alloc(2); z[0 + H] = 0; z[1 + H] = 1; set_len(z, -2); return z; } z := alloc(1); if x < 0 { z[0 + H] = Word(-x); set_len(z, -1); } else { z[0 + H] = Word(x); set_len(z, 1); } return z; } func make_from_string(s string) Value { // skip sign, if any i := 0; if len(s) > 0 && (s[i] == '-' || s[i] == '+') { i = 1; } // read digits x := make(0); for i < len(s) && '0' <= s[i] && s[i] <= '9' { x = umul_add(x, 10, Word(s[i] - '0')); i++; } // read sign if len(s) > 0 && s[0] == '-' { neg(x); } return x; } // ---------------------------------------------------------------------------- // Creation func (x Integer) Init(val Value) Integer { x.val = val; return x; } // ---------------------------------------------------------------------------- // Signed ops func add(x Value, y Value) Value { var z Value; if sign(x) == sign(y) { // x + y == x + y // (-x) + (-y) == -(x + y) z = uadd(x, y); } else { // x + (-y) == x - y == -(y - x) // (-x) + y == y - x == -(x - y) if ucmp(x, y) >= 0 { z = usub(x, y); } else { z = usub(y, x); neg(z); } } if sign(x) { neg(z); } return z; } func sub(x Value, y Value) Value { var z Value; if sign(x) != sign(y) { // x - (-y) == x + y // (-x) - y == -(x + y) z = uadd(x, y); } else { // x - y == x - y == -(y - x) // (-x) - (-y) == y - x == -(x - y) if ucmp(x, y) >= 0 { z = usub(x, y); } else { z = usub(y, x); neg(z); } } if sign(x) { neg(z); } return z; } func mul(x Value, y Value) Value { // x * y == x * y // x * (-y) == -(x * y) // (-x) * y == -(x * y) // (-x) * (-y) == x * y z := umul(x, y); if sign(x) != sign(y) { neg(z); } return z; } func mul_range(a, b int) Value { if a > b { return make(1) }; if a == b { return make(a) }; if a + 1 == b { return mul(make(a), make(b)) }; m := (a + b) >> 1; ASSERT(a <= m && m < b); return mul(mul_range(a, m), mul_range(m + 1, b)); } func fact(n int) Value { return mul_range(2, n); } // Returns a copy of x with space for one extra digit. func copy(x Value) Value { xl := len_(x); z := alloc(xl + 1); // add space for one extra digit for i := 0; i < xl; i++ { z[i + H] = x[i + H]; } set_len(z, xl); return z; } func tostring(x Value) string { // allocate string // approx. length: 1 char for 3 bits n := ulog(x)/3 + 3; // +1 (round up) +1 (sign) +1 (0 termination) //s := new([]byte, n); s := new([100000]byte); // convert z := copy(x); i := 0; for i == 0 || !zero(z) { s[i] = byte(umod(z, 10) + '0'); i++; }; if sign(x) { s[i] = '-'; i++; } s[i] = 0; ASSERT(0 < i && i < n); // reverse in place i--; for j := 0; j < i; j++ { t := s[j]; s[j] = s[i]; s[i] = t; i--; } return string(s); } // ---------------------------------------------------------------------------- // Creation export FromInt func FromInt(v int) Integer { return new(IntegerImpl).Init(make(v)); } export FromString func FromString(s string) Integer { return new(IntegerImpl).Init(make_from_string(s)); } // ---------------------------------------------------------------------------- // Arithmetic ops func (x Integer) neg () Integer { if (zero(x.val)) { return new(IntegerImpl).Init(make(0)); } z := copy(x.val); neg(z); return new(IntegerImpl).Init(z); } func (x Integer) add (y Integer) Integer { return new(IntegerImpl).Init(add(x.val, y.val)); } func (x Integer) sub (y Integer) Integer { return new(IntegerImpl).Init(sub(x.val, y.val)); } func (x Integer) mul (y Integer) Integer { return new(IntegerImpl).Init(mul(x.val, y.val)); } func (x Integer) quo (y Integer) Integer { UNIMPLEMENTED("quo"); return nil; } func (x Integer) rem (y Integer) Integer { UNIMPLEMENTED("rem"); return nil; } func (x Integer) div (y Integer) Integer { UNIMPLEMENTED("div"); return nil; } func (x Integer) mod (y Integer) Integer { UNIMPLEMENTED("mod"); return nil; } // ---------------------------------------------------------------------------- // Arithmetic shifts func (x Integer) shl (s uint) Integer { UNIMPLEMENTED("shl"); return nil; } func (x Integer) shr (s uint) Integer { UNIMPLEMENTED("shr"); return nil; } // ---------------------------------------------------------------------------- // Logical ops func (x Integer) inv () Integer { UNIMPLEMENTED("inv"); return nil; } func (x Integer) and (y Integer) Integer { UNIMPLEMENTED("and"); return nil; } func (x Integer) or (y Integer) Integer { UNIMPLEMENTED("or"); return nil; } func (x Integer) xor (y Integer) Integer { UNIMPLEMENTED("xor"); return nil; } // ---------------------------------------------------------------------------- // Comparisons func (x Integer) cmp (y Integer) int { return 0; } func (x Integer) eql (y Integer) bool { return x.cmp(y) == 0; } func (x Integer) neq (y Integer) bool { return x.cmp(y) != 0; } func (x Integer) lss (y Integer) bool { return x.cmp(y) < 0; } func (x Integer) leq (y Integer) bool { return x.cmp(y) <= 0; } func (x Integer) gtr (y Integer) bool { return x.cmp(y) > 0; } func (x Integer) geq (y Integer) bool { return x.cmp(y) >= 0; } // ---------------------------------------------------------------------------- // Specials export Fact func Fact(n int) Integer { return new(IntegerImpl).Init(fact(n)); } func (x Integer) ToString() string { return tostring(x.val); }