Commit 379b5a39 authored by Robert Griesemer's avatar Robert Griesemer

- steps towards implementation of div and mod

- string conversion in different bases
- tracked down a 6g bug, use work-around for now

R=r
OCL=17981
CL=17981
parent b5c739bd
......@@ -14,26 +14,52 @@ package Bignum
// ----------------------------------------------------------------------------
// Support
// Representation
type Word uint64
const LogW = 32;
type Word uint32
const LogH = 4; // bits for a hex digit (= "small" number)
const H = 1 << LogH;
const N = 4;
const L = 28; // = sizeof(Word) * 8
const L = LogW - LogH; // must be even (for Mul1)
const B = 1 << L;
const M = B - 1;
// For division
const (
L3 = L / 3;
B3 = 1 << L3;
M3 = B3 - 1;
)
type (
Word3 uint32;
Natural3 [] Word3;
)
// ----------------------------------------------------------------------------
// Support
// TODO replace this with a Go built-in assert
func ASSERT(p bool) {
func assert(p bool) {
if !p {
panic("ASSERT failed");
panic("assert failed");
}
}
func init() {
assert(L % 2 == 0); // L must be even
}
func IsSmall(x Word) bool {
return x < 1 << N;
return x < H;
}
......@@ -42,96 +68,136 @@ func Update(x Word) (Word, Word) {
}
export func Dump(x *[]Word) {
print("[", len(x), "]");
for i := len(x) - 1; i >= 0; i-- {
print(" ", x[i]);
}
println();
}
// ----------------------------------------------------------------------------
// Naturals
// Natural numbers
export type Natural []Word;
export var NatZero *Natural = new(Natural, 0);
export func NewNat(x Word) *Natural {
var z *Natural;
switch {
case x == 0:
z = NatZero;
case x < B:
z = new(Natural, 1);
z[0] = x;
return z;
default:
z = new(Natural, 2);
z[0], z[1] = Update(x);
}
return z;
}
func Normalize(x *Natural) *Natural {
i := len(x);
for i > 0 && x[i - 1] == 0 { i-- }
if i < len(x) {
x = x[0 : i]; // trim leading 0's
}
return x;
}
func Normalize3(x *Natural3) *Natural3 {
i := len(x);
for i > 0 && x[i - 1] == 0 { i-- }
if i < len(x) {
x = x[0 : i]; // trim leading 0's
}
return x;
}
func (x *Natural) IsZero() bool {
return len(x) == 0;
}
func (x *Natural) Add (y *Natural) *Natural {
xl := len(x);
yl := len(y);
if xl < yl {
func (x *Natural) Add(y *Natural) *Natural {
n := len(x);
m := len(y);
if n < m {
return y.Add(x);
}
ASSERT(xl >= yl);
z := new(Natural, xl + 1);
assert(n >= m);
z := new(Natural, n + 1);
i := 0;
c := Word(0);
for i < yl { z[i], c = Update(x[i] + y[i] + c); i++; }
for i < xl { z[i], c = Update(x[i] + c); i++; }
if c != 0 { z[i] = c; i++; }
z = z[0 : i];
for i < m { z[i], c = Update(x[i] + y[i] + c); i++; }
for i < n { z[i], c = Update(x[i] + c); i++; }
z[i] = c;
return z;
return Normalize(z);
}
func (x *Natural) Sub (y *Natural) *Natural {
xl := len(x);
yl := len(y);
ASSERT(xl >= yl);
z := new(Natural, xl);
func (x *Natural) Sub(y *Natural) *Natural {
n := len(x);
m := len(y);
assert(n >= m);
z := new(Natural, n);
i := 0;
c := Word(0);
for i < yl { z[i], c = Update(x[i] - y[i] + c); i++; }
for i < xl { z[i], c = Update(x[i] + c); i++; }
ASSERT(c == 0); // usub(x, y) must be called with x >= y
for i > 0 && z[i - 1] == 0 { i--; }
z = z[0 : i];
for i < m { z[i], c = Update(x[i] - y[i] + c); i++; }
for i < n { z[i], c = Update(x[i] + c); i++; }
assert(c == 0); // x.Sub(y) must be called with x >= y
return z;
return Normalize(z);
}
// Computes x = x*a + c (in place) for "small" a's.
func (x* Natural) Mul1Add(a, c Word) *Natural {
ASSERT(IsSmall(a) && IsSmall(c));
if (x.IsZero() || a == 0) && c == 0 {
return NatZero;
func (x* Natural) MulAdd1(a, c Word) *Natural {
assert(IsSmall(a-1) && IsSmall(c));
if x.IsZero() || a == 0 {
return NewNat(c);
}
xl := len(x);
n := len(x);
z := new(Natural, xl + 1);
i := 0;
for i < xl { z[i], c = Update(x[i] * a + c); i++; }
if c != 0 { z[i] = c; i++; }
z = z[0 : i];
z := new(Natural, n + 1);
for i := 0; i < n; i++ { z[i], c = Update(x[i] * a + c); }
z[n] = c;
return z;
return Normalize(z);
}
// Returns z = (x * y) div B, c = (x * y) mod B.
func Mul1(x, y Word) (z Word, c Word) {
const L2 = (L + 1) >> 1;
func Mul1(x, y Word) (Word, Word) {
const L2 = (L + 1) / 2; // TODO check if we can run with odd L
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
z0 := x0*y0;
z1 := x1*y0 + x0*y1 + z0 >> L2; z0 &= M2;
z2 := x1*y1 + z1 >> L2; z1 &= M2;
return z1 << L2 | z0, z2;
}
func (x *Natural) Mul (y *Natural) *Natural {
func (x *Natural) Mul(y *Natural) *Natural {
if x.IsZero() || y.IsZero() {
return NatZero;
}
......@@ -140,17 +206,16 @@ func (x *Natural) Mul (y *Natural) *Natural {
if xl < yl {
return y.Mul(x); // for speed
}
ASSERT(xl >= yl && yl > 0);
assert(xl >= yl && yl > 0);
// initialize z
zl := xl + yl;
z := new(Natural, zl);
k := 0;
for j := 0; j < yl; j++ {
d := y[j];
if d != 0 {
k = j;
k := j;
c := Word(0);
for i := 0; i < xl; i++ {
// compute z[k] += x[i] * d + c;
......@@ -162,31 +227,118 @@ func (x *Natural) Mul (y *Natural) *Natural {
c += t >> L;
k++;
}
if c != 0 {
z[k] = c;
k++;
}
z[k] = c;
}
}
z = z[0 : k];
return z;
return Normalize(z);
}
func Shl1(x Word, s int) (Word, Word) {
return 0, 0
}
func Shr1(x Word, s int) (Word, Word) {
return 0, 0
}
func (x *Natural) Div (y *Natural) *Natural {
func (x *Natural) Shl(s int) *Natural {
panic("incomplete");
if s == 0 {
return x;
}
S := s/L;
s = s%L;
n := len(x) + S + 1;
z := new(Natural, n);
c := Word(0);
for i := 0; i < n; i++ {
z[i + S], c = Shl1(x[i], s);
}
z[n + S] = c;
return Normalize(z);
}
func (x *Natural) Shr(s uint) *Natural {
panic("incomplete");
if s == 0 {
return x;
}
return nil
}
func SplitBase(x *Natural) *Natural3 {
xl := len(x);
z := new(Natural3, xl * 3);
for i, j := 0, 0; i < xl; i, j = i + 1, j + 3 {
t := x[i];
z[j] = Word3(t & M3); t >>= L3; j++;
z[j] = Word3(t & M3); t >>= L3; j++;
z[j] = Word3(t & M3); t >>= L3; j++;
}
return Normalize3(z);
}
func Scale(x *Natural, f Word) *Natural3 {
return nil;
}
func TrialDigit(r, d *Natural3, k, m int) Word {
km := k + m;
assert(2 <= m && m <= km);
r3 := (Word(r[km]) << L3 + Word(r[km - 1])) << L3 + Word(r[km - 2]);
d2 := Word(d[m - 1]) << L3 + Word(d[m - 2]);
qt := r3 / d2;
if qt >= B {
qt = B - 1;
}
return qt;
}
func DivMod(x, y *Natural) {
xl := len(x);
yl := len(y);
assert(2 <= yl && yl <= xl); // use special-case algorithm otherwise
f := B / (y[yl - 1] + 1);
r := Scale(x, f);
d := Scale(y, f);
n := len(r);
m := len(d);
for k := n - m; k >= 0; k-- {
qt := TrialDigit(r, d, k, m);
}
}
func (x *Natural) Div(y *Natural) *Natural {
panic("UNIMPLEMENTED");
return nil;
}
func (x *Natural) Mod (y *Natural) *Natural {
func (x *Natural) Mod(y *Natural) *Natural {
panic("UNIMPLEMENTED");
return nil;
}
func (x *Natural) Cmp (y *Natural) int {
func (x *Natural) Cmp(y *Natural) int {
xl := len(x);
yl := len(y);
......@@ -202,176 +354,173 @@ func (x *Natural) Cmp (y *Natural) int {
case x[i] < y[i]: d = -1;
case x[i] > y[i]: d = 1;
}
return d;
}
func (x *Natural) Log() int {
xl := len(x);
if xl == 0 { return 0; }
n := (xl - 1) * L;
for t := x[xl - 1]; t != 0; t >>= 1 { n++ };
n := len(x);
if n == 0 { return 0; }
assert(n > 0);
c := (n - 1) * L;
for t := x[n - 1]; t != 0; t >>= 1 { c++ };
return n;
return c;
}
func (x *Natural) And (y *Natural) *Natural {
xl := len(x);
yl := len(y);
if xl < yl {
func (x *Natural) And(y *Natural) *Natural {
n := len(x);
m := len(y);
if n < m {
return y.And(x);
}
ASSERT(xl >= yl);
z := new(Natural, xl);
assert(n >= m);
z := new(Natural, n);
i := 0;
for i < yl { z[i] = x[i] & y[i]; i++; }
for i < xl { z[i] = x[i]; i++; }
for i > 0 && z[i - 1] == 0 { i--; }
z = z[0 : i];
for i < m { z[i] = x[i] & y[i]; i++; }
for i < n { z[i] = x[i]; i++; }
return z;
return Normalize(z);
}
func (x *Natural) Or (y *Natural) *Natural {
xl := len(x);
yl := len(y);
if xl < yl {
func (x *Natural) Or(y *Natural) *Natural {
n := len(x);
m := len(y);
if n < m {
return y.Or(x);
}
ASSERT(xl >= yl);
z := new(Natural, xl);
assert(n >= m);
z := new(Natural, n);
i := 0;
for i < yl { z[i] = x[i] | y[i]; i++; }
for i < xl { z[i] = x[i]; i++; }
for i < m { z[i] = x[i] | y[i]; i++; }
for i < n { z[i] = x[i]; i++; }
return z;
return Normalize(z);
}
func (x *Natural) Xor (y *Natural) *Natural {
xl := len(x);
yl := len(y);
if xl < yl {
func (x *Natural) Xor(y *Natural) *Natural {
n := len(x);
m := len(y);
if n < m {
return y.Xor(x);
}
ASSERT(xl >= yl);
z := new(Natural, xl);
assert(n >= m);
z := new(Natural, n);
i := 0;
for i < yl { z[i] = x[i] ^ y[i]; i++; }
for i < xl { z[i] = x[i]; i++; }
for i > 0 && z[i - 1] == 0 { i--; }
z = z[0 : i];
for i < m { z[i] = x[i] ^ y[i]; i++; }
for i < n { z[i] = x[i]; i++; }
return z;
return Normalize(z);
}
// Returns a copy of x with space for one extra digit (for Div/Mod use)
func Copy(x *Natural) *Natural {
xl := len(x);
z := new(Natural, xl + 1); // add space for one extra digit
for i := 0; i < xl; i++ { z[i] = x[i]; }
z = z[0 : xl];
z := new(Natural, len(x));
//*z = *x; // BUG assignment does't work yet
for i := len(x) - 1; i >= 0; i-- { z[i] = x[i]; }
return z;
}
// Computes x = x div d (in place) for "small" d's. Returns updated x, x mod d.
func (x *Natural) Mod1 (d Word) (*Natural, Word) {
ASSERT(IsSmall(d));
xl := len(x);
// Computes x = x div d (in place - the recv maybe modified) for "small" d's.
// Returns updated x and x mod d.
func (x *Natural) DivMod1(d Word) (*Natural, Word) {
assert(0 < d && IsSmall(d - 1));
c := Word(0);
for i := xl - 1; i >= 0; i-- {
c = c << L + x[i];
x[i], c = c / d, c %d;
}
if xl > 0 && x[xl - 1] == 0 {
x = x[0 : xl - 1];
for i := len(x) - 1; i >= 0; i-- {
var LL Word = L; // BUG shift broken for const L
c = c << LL + x[i];
x[i] = c / d;
c %= d;
}
return x, c;
return Normalize(x), c;
}
func (x *Natural) String() string {
func (x *Natural) String(base Word) string {
if x.IsZero() {
return "0";
}
// allocate string
// TODO n is too small for bases < 10!!!
assert(base >= 10); // for now
// approx. length: 1 char for 3 bits
n := x.Log()/3 + 1; // +1 (round up)
s := new([]byte, n);
// convert
const hex = "0123456789abcdef";
i := n;
x = Copy(x); // don't destroy recv
for !x.IsZero() {
i--;
var d Word;
x, d = x.Mod1(10);
s[i] = byte(d) + '0';
x, d = x.DivMod1(base);
s[i] = hex[d];
};
return string(s[i : n]);
}
export func NatFromWord(x Word) *Natural {
var z *Natural;
switch {
case x == 0:
z = NatZero;
case x < B:
z = new(Natural, 1);
z[0] = x;
return z;
default:
z = new(Natural, 2);
z[0], z[1] = Update(x);
}
return z;
}
// Support function for faster factorial computation.
func MulRange(a, b Word) *Natural {
switch {
case a > b: return NatFromWord(1);
case a == b: return NatFromWord(a);
case a + 1 == b: return NatFromWord(a).Mul(NatFromWord(b));
case a > b: return NewNat(1);
case a == b: return NewNat(a);
case a + 1 == b: return NewNat(a).Mul(NewNat(b));
}
m := (a + b) >> 1;
ASSERT(a <= m && m < b);
assert(a <= m && m < b);
return MulRange(a, m).Mul(MulRange(m + 1, b));
}
export func Fact(n Word) *Natural {
return MulRange(2, n);
// Using MulRange() instead of the basic for-loop
// lead to faster factorial computation.
return MulRange(2, n);
}
export func NatFromString(s string) *Natural {
func HexValue(ch byte) Word {
d := Word(H);
switch {
case '0' <= ch && ch <= '9': d = Word(ch - '0');
case 'a' <= ch && ch <= 'f': d = Word(ch - 'a') + 10;
case 'A' <= ch && ch <= 'F': d = Word(ch - 'A') + 10;
}
return d;
}
// TODO auto-detect base if base argument is 0
export func NatFromString(s string, base Word) *Natural {
x := NatZero;
for i := 0; i < len(s) && '0' <= s[i] && s[i] <= '9'; i++ {
x = x.Mul1Add(10, Word(s[i] - '0'));
for i := 0; i < len(s); i++ {
d := HexValue(s[i]);
if d < base {
x = x.MulAdd1(base, d);
} else {
break;
}
}
return x;
}
// ----------------------------------------------------------------------------
// Integers
// Integer numbers
export type Integer struct {
sign bool;
......@@ -379,7 +528,7 @@ export type Integer struct {
}
func (x *Integer) Add (y *Integer) *Integer {
func (x *Integer) Add(y *Integer) *Integer {
var z *Integer;
if x.sign == y.sign {
// x + y == x + y
......@@ -401,7 +550,7 @@ func (x *Integer) Add (y *Integer) *Integer {
}
func (x *Integer) Sub (y *Integer) *Integer {
func (x *Integer) Sub(y *Integer) *Integer {
var z *Integer;
if x.sign != y.sign {
// x - (-y) == x + y
......@@ -423,7 +572,7 @@ func (x *Integer) Sub (y *Integer) *Integer {
}
func (x *Integer) Mul (y *Integer) *Integer {
func (x *Integer) Mul(y *Integer) *Integer {
// x * y == x * y
// x * (-y) == -(x * y)
// (-x) * y == -(x * y)
......@@ -432,50 +581,48 @@ func (x *Integer) Mul (y *Integer) *Integer {
}
func (x *Integer) Div (y *Integer) *Integer {
func (x *Integer) Div(y *Integer) *Integer {
panic("UNIMPLEMENTED");
return nil;
}
func (x *Integer) Mod (y *Integer) *Integer {
func (x *Integer) Mod(y *Integer) *Integer {
panic("UNIMPLEMENTED");
return nil;
}
func (x *Integer) Cmp (y *Integer) int {
func (x *Integer) Cmp(y *Integer) int {
panic("UNIMPLEMENTED");
return 0;
}
func (x *Integer) String() string {
func (x *Integer) String(base Word) string {
if x.mant.IsZero() {
return "0";
}
var s string;
if x.sign {
s = "-" + x.mant.String();
} else {
s = x.mant.String();
s = "-";
}
return s;
return s + x.mant.String(base);
}
export func IntFromString(s string) *Integer {
export func IntFromString(s string, base Word) *Integer {
// get sign, if any
sign := false;
if len(s) > 0 && (s[0] == '-' || s[0] == '+') {
sign = s[0] == '-';
}
return &Integer{sign, NatFromString(s[1 : len(s)])};
return &Integer{sign, NatFromString(s[1 : len(s)], base)};
}
// ----------------------------------------------------------------------------
// Rationals
// Rational numbers
export type Rational struct {
a, b *Integer; // a = numerator, b = denominator
......@@ -488,33 +635,33 @@ func NewRat(a, b *Integer) *Rational {
}
func (x *Rational) Add (y *Rational) *Rational {
func (x *Rational) Add(y *Rational) *Rational {
return NewRat((x.a.Mul(y.b)).Add(x.b.Mul(y.a)), x.b.Mul(y.b));
}
func (x *Rational) Sub (y *Rational) *Rational {
func (x *Rational) Sub(y *Rational) *Rational {
return NewRat((x.a.Mul(y.b)).Sub(x.b.Mul(y.a)), x.b.Mul(y.b));
}
func (x *Rational) Mul (y *Rational) *Rational {
func (x *Rational) Mul(y *Rational) *Rational {
return NewRat(x.a.Mul(y.a), x.b.Mul(y.b));
}
func (x *Rational) Div (y *Rational) *Rational {
func (x *Rational) Div(y *Rational) *Rational {
return NewRat(x.a.Mul(y.b), x.b.Mul(y.a));
}
func (x *Rational) Mod (y *Rational) *Rational {
func (x *Rational) Mod(y *Rational) *Rational {
panic("UNIMPLEMENTED");
return nil;
}
func (x *Rational) Cmp (y *Rational) int {
func (x *Rational) Cmp(y *Rational) int {
panic("UNIMPLEMENTED");
return 0;
}
......@@ -527,7 +674,7 @@ export func RatFromString(s string) *Rational {
// ----------------------------------------------------------------------------
// Numbers
// Scaled numbers
export type Number struct {
mant *Rational;
......
......@@ -14,9 +14,9 @@ const (
var (
a = Bignum.NatFromString(sa);
b = Bignum.NatFromString(sb);
c = Bignum.NatFromString(sc);
a = Bignum.NatFromString(sa, 10);
b = Bignum.NatFromString(sb, 10);
c = Bignum.NatFromString(sc, 10);
)
......@@ -28,12 +28,12 @@ func TEST(msg string, b bool) {
func TestConv() {
TEST("TC1", a.Cmp(Bignum.NatFromWord(991)) == 0);
TEST("TC1", a.Cmp(Bignum.NewNat(991)) == 0);
TEST("TC2", b.Cmp(Bignum.Fact(20)) == 0);
TEST("TC3", c.Cmp(Bignum.Fact(100)) == 0);
TEST("TC4", a.String() == sa);
TEST("TC5", b.String() == sb);
TEST("TC6", c.String() == sc);
TEST("TC4", a.String(10) == sa);
TEST("TC5", b.String(10) == sb);
TEST("TC6", c.String(10) == sc);
}
......
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