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Follows suit with https://go-review.googlesource.com/#/c/20111. Generated by running $ grep -R 'Go Authors. All' * | cut -d":" -f1 | while read F;do perl -pi -e 's/Go Authors. All/Go Authors. All/g' $F;done The code in cmd/internal/unvendor wasn't changed. Fixes #15213 Change-Id: I4f235cee0a62ec435f9e8540a1ec08ae03b1a75f Reviewed-on: https://go-review.googlesource.com/21819 Reviewed-by: Ian Lance Taylor <iant@golang.org> Run-TryBot: Ian Lance Taylor <iant@golang.org> TryBot-Result: Gobot Gobot <gobot@golang.org>
381 lines
9.5 KiB
Go
381 lines
9.5 KiB
Go
// Copyright 2009 The Go Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style
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// license that can be found in the LICENSE file.
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/*
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An example of wrapping a C library in Go. This is the GNU
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multiprecision library gmp's integer type mpz_t wrapped to look like
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the Go package big's integer type Int.
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This is a syntactically valid Go program—it can be parsed with the Go
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parser and processed by godoc—but it is not compiled directly by gc.
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Instead, a separate tool, cgo, processes it to produce three output
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files. The first two, 6g.go and 6c.c, are a Go source file for 6g and
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a C source file for 6c; both compile as part of the named package
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(gmp, in this example). The third, gcc.c, is a C source file for gcc;
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it compiles into a shared object (.so) that is dynamically linked into
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any 6.out that imports the first two files.
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The stanza
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// #include <gmp.h>
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import "C"
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is a signal to cgo. The doc comment on the import of "C" provides
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additional context for the C file. Here it is just a single #include
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but it could contain arbitrary C definitions to be imported and used.
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Cgo recognizes any use of a qualified identifier C.xxx and uses gcc to
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find the definition of xxx. If xxx is a type, cgo replaces C.xxx with
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a Go translation. C arithmetic types translate to precisely-sized Go
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arithmetic types. A C struct translates to a Go struct, field by
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field; unrepresentable fields are replaced with opaque byte arrays. A
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C union translates into a struct containing the first union member and
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perhaps additional padding. C arrays become Go arrays. C pointers
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become Go pointers. C function pointers become Go's uintptr.
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C void pointers become Go's unsafe.Pointer.
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For example, mpz_t is defined in <gmp.h> as:
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typedef unsigned long int mp_limb_t;
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typedef struct
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{
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int _mp_alloc;
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int _mp_size;
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mp_limb_t *_mp_d;
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} __mpz_struct;
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typedef __mpz_struct mpz_t[1];
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Cgo generates:
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type _C_int int32
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type _C_mp_limb_t uint64
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type _C___mpz_struct struct {
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_mp_alloc _C_int;
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_mp_size _C_int;
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_mp_d *_C_mp_limb_t;
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}
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type _C_mpz_t [1]_C___mpz_struct
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and then replaces each occurrence of a type C.xxx with _C_xxx.
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If xxx is data, cgo arranges for C.xxx to refer to the C variable,
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with the type translated as described above. To do this, cgo must
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introduce a Go variable that points at the C variable (the linker can
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be told to initialize this pointer). For example, if the gmp library
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provided
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mpz_t zero;
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then cgo would rewrite a reference to C.zero by introducing
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var _C_zero *C.mpz_t
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and then replacing all instances of C.zero with (*_C_zero).
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Cgo's most interesting translation is for functions. If xxx is a C
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function, then cgo rewrites C.xxx into a new function _C_xxx that
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calls the C xxx in a standard pthread. The new function translates
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its arguments, calls xxx, and translates the return value.
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Translation of parameters and the return value follows the type
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translation above except that arrays passed as parameters translate
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explicitly in Go to pointers to arrays, as they do (implicitly) in C.
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Garbage collection is the big problem. It is fine for the Go world to
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have pointers into the C world and to free those pointers when they
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are no longer needed. To help, the Go code can define Go objects
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holding the C pointers and use runtime.SetFinalizer on those Go objects.
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It is much more difficult for the C world to have pointers into the Go
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world, because the Go garbage collector is unaware of the memory
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allocated by C. The most important consideration is not to
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constrain future implementations, so the rule is that Go code can
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hand a Go pointer to C code but must separately arrange for
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Go to hang on to a reference to the pointer until C is done with it.
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*/
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package gmp
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/*
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#cgo LDFLAGS: -lgmp
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#include <gmp.h>
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#include <stdlib.h>
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// gmp 5.0.0+ changed the type of the 3rd argument to mp_bitcnt_t,
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// so, to support older versions, we wrap these two functions.
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void _mpz_mul_2exp(mpz_ptr a, mpz_ptr b, unsigned long n) {
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mpz_mul_2exp(a, b, n);
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}
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void _mpz_div_2exp(mpz_ptr a, mpz_ptr b, unsigned long n) {
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mpz_div_2exp(a, b, n);
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}
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*/
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import "C"
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import (
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"os"
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"unsafe"
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)
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/*
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* one of a kind
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*/
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// An Int represents a signed multi-precision integer.
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// The zero value for an Int represents the value 0.
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type Int struct {
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i C.mpz_t
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init bool
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}
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// NewInt returns a new Int initialized to x.
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func NewInt(x int64) *Int { return new(Int).SetInt64(x) }
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// Int promises that the zero value is a 0, but in gmp
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// the zero value is a crash. To bridge the gap, the
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// init bool says whether this is a valid gmp value.
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// doinit initializes z.i if it needs it. This is not inherent
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// to FFI, just a mismatch between Go's convention of
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// making zero values useful and gmp's decision not to.
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func (z *Int) doinit() {
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if z.init {
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return
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}
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z.init = true
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C.mpz_init(&z.i[0])
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}
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// Bytes returns z's representation as a big-endian byte array.
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func (z *Int) Bytes() []byte {
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b := make([]byte, (z.Len()+7)/8)
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n := C.size_t(len(b))
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C.mpz_export(unsafe.Pointer(&b[0]), &n, 1, 1, 1, 0, &z.i[0])
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return b[0:n]
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}
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// Len returns the length of z in bits. 0 is considered to have length 1.
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func (z *Int) Len() int {
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z.doinit()
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return int(C.mpz_sizeinbase(&z.i[0], 2))
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}
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// Set sets z = x and returns z.
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func (z *Int) Set(x *Int) *Int {
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z.doinit()
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C.mpz_set(&z.i[0], &x.i[0])
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return z
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}
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// SetBytes interprets b as the bytes of a big-endian integer
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// and sets z to that value.
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func (z *Int) SetBytes(b []byte) *Int {
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z.doinit()
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if len(b) == 0 {
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z.SetInt64(0)
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} else {
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C.mpz_import(&z.i[0], C.size_t(len(b)), 1, 1, 1, 0, unsafe.Pointer(&b[0]))
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}
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return z
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}
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// SetInt64 sets z = x and returns z.
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func (z *Int) SetInt64(x int64) *Int {
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z.doinit()
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// TODO(rsc): more work on 32-bit platforms
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C.mpz_set_si(&z.i[0], C.long(x))
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return z
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}
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// SetString interprets s as a number in the given base
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// and sets z to that value. The base must be in the range [2,36].
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// SetString returns an error if s cannot be parsed or the base is invalid.
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func (z *Int) SetString(s string, base int) error {
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z.doinit()
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if base < 2 || base > 36 {
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return os.ErrInvalid
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}
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p := C.CString(s)
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defer C.free(unsafe.Pointer(p))
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if C.mpz_set_str(&z.i[0], p, C.int(base)) < 0 {
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return os.ErrInvalid
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}
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return nil
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}
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// String returns the decimal representation of z.
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func (z *Int) String() string {
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if z == nil {
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return "nil"
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}
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z.doinit()
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p := C.mpz_get_str(nil, 10, &z.i[0])
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s := C.GoString(p)
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C.free(unsafe.Pointer(p))
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return s
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}
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func (z *Int) destroy() {
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if z.init {
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C.mpz_clear(&z.i[0])
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}
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z.init = false
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}
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/*
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* arithmetic
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*/
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// Add sets z = x + y and returns z.
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func (z *Int) Add(x, y *Int) *Int {
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x.doinit()
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y.doinit()
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z.doinit()
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C.mpz_add(&z.i[0], &x.i[0], &y.i[0])
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return z
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}
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// Sub sets z = x - y and returns z.
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func (z *Int) Sub(x, y *Int) *Int {
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x.doinit()
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y.doinit()
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z.doinit()
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C.mpz_sub(&z.i[0], &x.i[0], &y.i[0])
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return z
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}
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// Mul sets z = x * y and returns z.
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func (z *Int) Mul(x, y *Int) *Int {
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x.doinit()
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y.doinit()
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z.doinit()
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C.mpz_mul(&z.i[0], &x.i[0], &y.i[0])
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return z
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}
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// Div sets z = x / y, rounding toward zero, and returns z.
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func (z *Int) Div(x, y *Int) *Int {
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x.doinit()
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y.doinit()
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z.doinit()
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C.mpz_tdiv_q(&z.i[0], &x.i[0], &y.i[0])
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return z
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}
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// Mod sets z = x % y and returns z.
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// Like the result of the Go % operator, z has the same sign as x.
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func (z *Int) Mod(x, y *Int) *Int {
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x.doinit()
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y.doinit()
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z.doinit()
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C.mpz_tdiv_r(&z.i[0], &x.i[0], &y.i[0])
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return z
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}
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// Lsh sets z = x << s and returns z.
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func (z *Int) Lsh(x *Int, s uint) *Int {
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x.doinit()
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z.doinit()
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C._mpz_mul_2exp(&z.i[0], &x.i[0], C.ulong(s))
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return z
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}
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// Rsh sets z = x >> s and returns z.
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func (z *Int) Rsh(x *Int, s uint) *Int {
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x.doinit()
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z.doinit()
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C._mpz_div_2exp(&z.i[0], &x.i[0], C.ulong(s))
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return z
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}
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// Exp sets z = x^y % m and returns z.
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// If m == nil, Exp sets z = x^y.
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func (z *Int) Exp(x, y, m *Int) *Int {
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m.doinit()
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x.doinit()
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y.doinit()
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z.doinit()
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if m == nil {
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C.mpz_pow_ui(&z.i[0], &x.i[0], C.mpz_get_ui(&y.i[0]))
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} else {
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C.mpz_powm(&z.i[0], &x.i[0], &y.i[0], &m.i[0])
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}
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return z
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}
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func (z *Int) Int64() int64 {
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if !z.init {
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return 0
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}
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return int64(C.mpz_get_si(&z.i[0]))
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}
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// Neg sets z = -x and returns z.
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func (z *Int) Neg(x *Int) *Int {
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x.doinit()
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z.doinit()
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C.mpz_neg(&z.i[0], &x.i[0])
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return z
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}
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// Abs sets z to the absolute value of x and returns z.
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func (z *Int) Abs(x *Int) *Int {
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x.doinit()
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z.doinit()
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C.mpz_abs(&z.i[0], &x.i[0])
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return z
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}
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/*
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* functions without a clear receiver
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*/
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// CmpInt compares x and y. The result is
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//
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// -1 if x < y
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// 0 if x == y
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// +1 if x > y
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//
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func CmpInt(x, y *Int) int {
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x.doinit()
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y.doinit()
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switch cmp := C.mpz_cmp(&x.i[0], &y.i[0]); {
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case cmp < 0:
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return -1
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case cmp == 0:
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return 0
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}
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return +1
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}
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// DivModInt sets q = x / y and r = x % y.
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func DivModInt(q, r, x, y *Int) {
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q.doinit()
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r.doinit()
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x.doinit()
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y.doinit()
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C.mpz_tdiv_qr(&q.i[0], &r.i[0], &x.i[0], &y.i[0])
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}
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// GcdInt sets d to the greatest common divisor of a and b,
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// which must be positive numbers.
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// If x and y are not nil, GcdInt sets x and y such that d = a*x + b*y.
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// If either a or b is not positive, GcdInt sets d = x = y = 0.
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func GcdInt(d, x, y, a, b *Int) {
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d.doinit()
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x.doinit()
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y.doinit()
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a.doinit()
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b.doinit()
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C.mpz_gcdext(&d.i[0], &x.i[0], &y.i[0], &a.i[0], &b.i[0])
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}
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// ProbablyPrime performs n Miller-Rabin tests to check whether z is prime.
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// If it returns true, z is prime with probability 1 - 1/4^n.
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// If it returns false, z is not prime.
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func (z *Int) ProbablyPrime(n int) bool {
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z.doinit()
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return int(C.mpz_probab_prime_p(&z.i[0], C.int(n))) > 0
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}
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