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arith_uint256.cpp
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arith_uint256.cpp
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// Copyright (c) 2009-2010 Satoshi Nakamoto
// Copyright (c) 2009-2014 The Bitcoin developers
// Distributed under the MIT software license, see the accompanying
// file COPYING or http://www.opensource.org/licenses/mit-license.php.
#include
"arith_uint256.h"
#include
"uint256.h"
#include
"utilstrencodings.h"
#include
"crypto/common.h"
#include
<stdio.h>
#include
<string.h>
template
<
unsigned
int
BITS
>
base_uint
<
BITS
>::
base_uint
(
const
std
::
string
&
str
)
{
SetHex
(
str
);
}
template
<
unsigned
int
BITS
>
base_uint
<
BITS
>&
base_uint
<
BITS
>::
operator
<<=
(
unsigned
int
shift
)
{
base_uint
<
BITS
>
a
(
*
this
);
for
(
int
i
=
0
;
i
<
WIDTH
;
i
++
)
pn
[
i
]
=
0
;
int
k
=
shift
/
32
;
shift
=
shift
%
32
;
for
(
int
i
=
0
;
i
<
WIDTH
;
i
++
)
{
if
(
i
+
k
+
1
<
WIDTH
&&
shift
!=
0
)
pn
[
i
+
k
+
1
]
|=
(
a
.
pn
[
i
]
>>
(
32
-
shift
));
if
(
i
+
k
<
WIDTH
)
pn
[
i
+
k
]
|=
(
a
.
pn
[
i
]
<<
shift
);
}
return
*
this
;
}
template
<
unsigned
int
BITS
>
base_uint
<
BITS
>&
base_uint
<
BITS
>::
operator
>>=
(
unsigned
int
shift
)
{
base_uint
<
BITS
>
a
(
*
this
);
for
(
int
i
=
0
;
i
<
WIDTH
;
i
++
)
pn
[
i
]
=
0
;
int
k
=
shift
/
32
;
shift
=
shift
%
32
;
for
(
int
i
=
0
;
i
<
WIDTH
;
i
++
)
{
if
(
i
-
k
-
1
>=
0
&&
shift
!=
0
)
pn
[
i
-
k
-
1
]
|=
(
a
.
pn
[
i
]
<<
(
32
-
shift
));
if
(
i
-
k
>=
0
)
pn
[
i
-
k
]
|=
(
a
.
pn
[
i
]
>>
shift
);
}
return
*
this
;
}
template
<
unsigned
int
BITS
>
base_uint
<
BITS
>&
base_uint
<
BITS
>::
operator
*=
(
uint32_t
b32
)
{
uint64_t
carry
=
0
;
for
(
int
i
=
0
;
i
<
WIDTH
;
i
++
)
{
uint64_t
n
=
carry
+
(
uint64_t
)
b32
*
pn
[
i
];
pn
[
i
]
=
n
&
0xffffffff
;
carry
=
n
>>
32
;
}
return
*
this
;
}
template
<
unsigned
int
BITS
>
base_uint
<
BITS
>&
base_uint
<
BITS
>::
operator
*=
(
const
base_uint
&
b
)
{
base_uint
<
BITS
>
a
=
*
this
;
*
this
=
0
;
for
(
int
j
=
0
;
j
<
WIDTH
;
j
++
)
{
uint64_t
carry
=
0
;
for
(
int
i
=
0
;
i
+
j
<
WIDTH
;
i
++
)
{
uint64_t
n
=
carry
+
pn
[
i
+
j
]
+
(
uint64_t
)
a
.
pn
[
j
]
*
b
.
pn
[
i
];
pn
[
i
+
j
]
=
n
&
0xffffffff
;
carry
=
n
>>
32
;
}
}
return
*
this
;
}
template
<
unsigned
int
BITS
>
base_uint
<
BITS
>&
base_uint
<
BITS
>::
operator
/=
(
const
base_uint
&
b
)
{
base_uint
<
BITS
>
div
=
b
;
// make a copy, so we can shift.
base_uint
<
BITS
>
num
=
*
this
;
// make a copy, so we can subtract.
*
this
=
0
;
// the quotient.
int
num_bits
=
num
.
bits
();
int
div_bits
=
div
.
bits
();
if
(
div_bits
==
0
)
throw
uint_error
(
"Division by zero"
);
if
(
div_bits
>
num_bits
)
// the result is certainly 0.
return
*
this
;
int
shift
=
num_bits
-
div_bits
;
div
<<=
shift
;
// shift so that div and num align.
while
(
shift
>=
0
)
{
if
(
num
>=
div
)
{
num
-=
div
;
pn
[
shift
/
32
]
|=
(
1
<<
(
shift
&
31
));
// set a bit of the result.
}
div
>>=
1
;
// shift back.
shift
--
;
}
// num now contains the remainder of the division.
return
*
this
;
}
template
<
unsigned
int
BITS
>
int
base_uint
<
BITS
>::
CompareTo
(
const
base_uint
<
BITS
>&
b
)
const
{
for
(
int
i
=
WIDTH
-
1
;
i
>=
0
;
i
--
)
{
if
(
pn
[
i
]
<
b
.
pn
[
i
])
return
-1
;
if
(
pn
[
i
]
>
b
.
pn
[
i
])
return
1
;
}
return
0
;
}
template
<
unsigned
int
BITS
>
bool
base_uint
<
BITS
>::
EqualTo
(
uint64_t
b
)
const
{
for
(
int
i
=
WIDTH
-
1
;
i
>=
2
;
i
--
)
{
if
(
pn
[
i
])
return
false
;
}
if
(
pn
[
1
]
!=
(
b
>>
32
))
return
false
;
if
(
pn
[
0
]
!=
(
b
&
0xfffffffful
))
return
false
;
return
true
;
}
template
<
unsigned
int
BITS
>
double
base_uint
<
BITS
>::
getdouble
()
const
{
double
ret
=
0.0
;
double
fact
=
1.0
;
for
(
int
i
=
0
;
i
<
WIDTH
;
i
++
)
{
ret
+=
fact
*
pn
[
i
];
fact
*=
4294967296.0
;
}
return
ret
;
}
template
<
unsigned
int
BITS
>
std
::
string
base_uint
<
BITS
>::
GetHex
()
const
{
return
ArithToUint256
(
*
this
).
GetHex
();
}
template
<
unsigned
int
BITS
>
void
base_uint
<
BITS
>::
SetHex
(
const
char
*
psz
)
{
*
this
=
UintToArith256
(
uint256S
(
psz
));
}
template
<
unsigned
int
BITS
>
void
base_uint
<
BITS
>::
SetHex
(
const
std
::
string
&
str
)
{
SetHex
(
str
.
c_str
());
}
template
<
unsigned
int
BITS
>
std
::
string
base_uint
<
BITS
>::
ToString
()
const
{
return
(
GetHex
());
}
template
<
unsigned
int
BITS
>
unsigned
int
base_uint
<
BITS
>::
bits
()
const
{
for
(
int
pos
=
WIDTH
-
1
;
pos
>=
0
;
pos
--
)
{
if
(
pn
[
pos
])
{
for
(
int
bits
=
31
;
bits
>
0
;
bits
--
)
{
if
(
pn
[
pos
]
&
1
<<
bits
)
return
32
*
pos
+
bits
+
1
;
}
return
32
*
pos
+
1
;
}
}
return
0
;
}
// Explicit instantiations for base_uint<256>
template
base_uint
<
256
>::
base_uint
(
const
std
::
string
&
);
template
base_uint
<
256
>&
base_uint
<
256
>::
operator
<<=
(
unsigned
int
);
template
base_uint
<
256
>&
base_uint
<
256
>::
operator
>>=
(
unsigned
int
);
template
base_uint
<
256
>&
base_uint
<
256
>::
operator
*=
(
uint32_t
b32
);
template
base_uint
<
256
>&
base_uint
<
256
>::
operator
*=
(
const
base_uint
<
256
>&
b
);
template
base_uint
<
256
>&
base_uint
<
256
>::
operator
/=
(
const
base_uint
<
256
>&
b
);
template
int
base_uint
<
256
>::
CompareTo
(
const
base_uint
<
256
>&
)
const
;
template
bool
base_uint
<
256
>::
EqualTo
(
uint64_t
)
const
;
template
double
base_uint
<
256
>::
getdouble
()
const
;
template
std
::
string
base_uint
<
256
>::
GetHex
()
const
;
template
std
::
string
base_uint
<
256
>::
ToString
()
const
;
template
void
base_uint
<
256
>::
SetHex
(
const
char
*
);
template
void
base_uint
<
256
>::
SetHex
(
const
std
::
string
&
);
template
unsigned
int
base_uint
<
256
>::
bits
()
const
;
// This implementation directly uses shifts instead of going
// through an intermediate MPI representation.
arith_uint256
&
arith_uint256
::
SetCompact
(
uint32_t
nCompact
,
bool
*
pfNegative
,
bool
*
pfOverflow
)
{
int
nSize
=
nCompact
>>
24
;
uint32_t
nWord
=
nCompact
&
0x007fffff
;
if
(
nSize
<=
3
)
{
nWord
>>=
8
*
(
3
-
nSize
);
*
this
=
nWord
;
}
else
{
*
this
=
nWord
;
*
this
<<=
8
*
(
nSize
-
3
);
}
if
(
pfNegative
)
*
pfNegative
=
nWord
!=
0
&&
(
nCompact
&
0x00800000
)
!=
0
;
if
(
pfOverflow
)
*
pfOverflow
=
nWord
!=
0
&&
((
nSize
>
34
)
||
(
nWord
>
0xff
&&
nSize
>
33
)
||
(
nWord
>
0xffff
&&
nSize
>
32
));
return
*
this
;
}
uint32_t
arith_uint256
::
GetCompact
(
bool
fNegative
)
const
{
int
nSize
=
(
bits
()
+
7
)
/
8
;
uint32_t
nCompact
=
0
;
if
(
nSize
<=
3
)
{
nCompact
=
GetLow64
()
<<
8
*
(
3
-
nSize
);
}
else
{
arith_uint256
bn
=
*
this
>>
8
*
(
nSize
-
3
);
nCompact
=
bn
.
GetLow64
();
}
// The 0x00800000 bit denotes the sign.
// Thus, if it is already set, divide the mantissa by 256 and increase the exponent.
if
(
nCompact
&
0x00800000
)
{
nCompact
>>=
8
;
nSize
++
;
}
assert
((
nCompact
&
~
0x007fffff
)
==
0
);
assert
(
nSize
<
256
);
nCompact
|=
nSize
<<
24
;
nCompact
|=
(
fNegative
&&
(
nCompact
&
0x007fffff
)
?
0x00800000
:
0
);
return
nCompact
;
}
uint256
ArithToUint256
(
const
arith_uint256
&
a
)
{
uint256
b
;
for
(
int
x
=
0
;
x
<
a
.
WIDTH
;
++
x
)
WriteLE32
(
b
.
begin
()
+
x
*
4
,
a
.
pn
[
x
]);
return
b
;
}
arith_uint256
UintToArith256
(
const
uint256
&
a
)
{
arith_uint256
b
;
for
(
int
x
=
0
;
x
<
b
.
WIDTH
;
++
x
)
b
.
pn
[
x
]
=
ReadLE32
(
a
.
begin
()
+
x
*
4
);
return
b
;
}
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