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kpermuter.hh
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kpermuter.hh
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/* Masstree
* Eddie Kohler, Yandong Mao, Robert Morris
* Copyright (c) 2012-2014 President and Fellows of Harvard College
* Copyright (c) 2012-2014 Massachusetts Institute of Technology
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the "Software"),
* to deal in the Software without restriction, subject to the conditions
* listed in the Masstree LICENSE file. These conditions include: you must
* preserve this copyright notice, and you cannot mention the copyright
* holders in advertising related to the Software without their permission.
* The Software is provided WITHOUT ANY WARRANTY, EXPRESS OR IMPLIED. This
* notice is a summary of the Masstree LICENSE file; the license in that file
* is legally binding.
*/
#ifndef KPERMUTER_HH
#define KPERMUTER_HH
#include "string.hh"
class identity_kpermuter {
int size_;
public:
identity_kpermuter(int size)
: size_(size) {
}
int size() const {
return size_;
}
int operator[](int i) const {
return i;
}
bool operator==(const identity_kpermuter&) const {
return true;
}
bool operator!=(const identity_kpermuter&) const {
return false;
}
};
template <int C> struct sized_kpermuter_info {};
template <> struct sized_kpermuter_info<0> {
typedef uint16_t storage_type;
typedef unsigned value_type;
enum { initial_value = 0x0120U, full_value = 0x2100U };
};
template <> struct sized_kpermuter_info<1> {
typedef uint32_t storage_type;
typedef unsigned value_type;
enum { initial_value = 0x01234560U, full_value = 0x65432100U };
};
template <> struct sized_kpermuter_info<2> {
typedef uint64_t storage_type;
typedef uint64_t value_type;
enum { initial_value = (uint64_t) 0x0123456789ABCDE0ULL,
full_value = (uint64_t) 0xEDCBA98765432100ULL };
};
template <int width> class kpermuter {
public:
typedef sized_kpermuter_info<(width > 3) + (width > 7) + (width > 15)> info;
typedef typename info::storage_type storage_type;
typedef typename info::value_type value_type;
enum { max_width = (int) (sizeof(storage_type) * 2 - 1) };
enum { size_bits = 4 };
/** @brief Construct an uninitialized permuter. */
kpermuter() {
}
/** @brief Construct a permuter with value @a x. */
kpermuter(value_type x)
: x_(x) {
}
/** @brief Return an empty permuter with size 0.
Elements will be allocated in order 0, 1, ..., @a width - 1. */
static inline value_type make_empty() {
value_type p = (value_type) info::initial_value >> ((max_width - width) << 2);
return p & ~(value_type) 15;
}
/** @brief Return a permuter with size @a n.
The returned permutation has size() @a n. For 0 <= i < @a n,
(*this)[i] == i. Elements n through @a width - 1 are free, and will be
allocated in that order. */
static inline value_type make_sorted(int n) {
value_type mask = (n == width ? (value_type) 0 : (value_type) 16 << (n << 2)) - 1;
return (make_empty() << (n << 2))
| ((value_type) info::full_value & mask)
| n;
}
/** @brief Return the permuter's size. */
int size() const {
return x_ & 15;
}
/** @brief Return the permuter's element @a i.
@pre 0 <= i < width */
int operator[](int i) const {
return (x_ >> ((i << 2) + 4)) & 15;
}
int back() const {
return (*this)[width - 1];
}
value_type value() const {
return x_;
}
value_type value_from(int i) const {
return x_ >> ((i + 1) << 2);
}
void set_size(int n) {
x_ = (x_ & ~(value_type) 15) | n;
}
/** @brief Allocate a new element and insert it at position @a i.
@pre 0 <= @a i < @a width
@pre size() < @a width
@return The newly allocated element.
Consider the following code:
<code>
kpermuter<...> p = ..., q = p;
int x = q.insert_from_back(i);
</code>
The modified permuter, q, has the following properties.
<ul>
<li>q.size() == p.size() + 1</li>
<li>Given j with 0 <= j < i, q[j] == p[j] && q[j] != x</li>
<li>Given j with j == i, q[j] == x</li>
<li>Given j with i < j < q.size(), q[j] == p[j-1] && q[j] != x</li>
</ul> */
int insert_from_back(int i) {
int value = back();
// increment size, leave lower slots unchanged
x_ = ((x_ + 1) & (((value_type) 16 << (i << 2)) - 1))
// insert slot
| ((value_type) value << ((i << 2) + 4))
// shift up unchanged higher entries & empty slots
| ((x_ << 4) & ~(((value_type) 256 << (i << 2)) - 1));
return value;
}
/** @brief Insert an unallocated element from position @a si at position @a di.
@pre 0 <= @a di < @a width
@pre size() < @a width
@pre size() <= @a si
@return The newly allocated element. */
void insert_selected(int di, int si) {
(void) width;
int value = (*this)[si];
value_type mask = ((value_type) 256 << (si << 2)) - 1;
// increment size, leave lower slots unchanged
x_ = ((x_ + 1) & (((value_type) 16 << (di << 2)) - 1))
// insert slot
| ((value_type) value << ((di << 2) + 4))
// shift up unchanged higher entries & empty slots
| ((x_ << 4) & mask & ~(((value_type) 256 << (di << 2)) - 1))
// leave uppermost slots alone
| (x_ & ~mask);
}
/** @brief Remove the element at position @a i.
@pre 0 <= @a i < @a size()
@pre size() < @a width
Consider the following code:
<code>
kpermuter<...> p = ..., q = p;
q.remove(i);
</code>
The modified permuter, q, has the following properties.
<ul>
<li>q.size() == p.size() - 1</li>
<li>Given j with 0 <= j < i, q[j] == p[j]</li>
<li>Given j with i <= j < q.size(), q[j] == p[j+1]</li>
<li>q[q.size()] == p[i]</li>
</ul> */
void remove(int i) {
(void) width;
if (int(x_ & 15) == i + 1)
--x_;
else {
int rot_amount = ((x_ & 15) - i - 1) << 2;
value_type rot_mask =
(((value_type) 16 << rot_amount) - 1) << ((i + 1) << 2);
// decrement size, leave lower slots unchanged
x_ = ((x_ - 1) & ~rot_mask)
// shift higher entries down
| (((x_ & rot_mask) >> 4) & rot_mask)
// shift value up
| (((x_ & rot_mask) << rot_amount) & rot_mask);
}
}
/** @brief Remove the element at position @a i to the back.
@pre 0 <= @a i < @a size()
@pre size() < @a width
Consider the following code:
<code>
kpermuter<...> p = ..., q = p;
q.remove_to_back(i);
</code>
The modified permuter, q, has the following properties.
<ul>
<li>q.size() == p.size() - 1</li>
<li>Given j with 0 <= j < i, q[j] == p[j]</li>
<li>Given j with i <= j < @a width - 1, q[j] == p[j+1]</li>
<li>q.back() == p[i]</li>
</ul> */
void remove_to_back(int i) {
value_type mask = ~(((value_type) 16 << (i << 2)) - 1);
// clear unused slots
value_type x = x_ & (((value_type) 16 << (width << 2)) - 1);
// decrement size, leave lower slots unchanged
x_ = ((x - 1) & ~mask)
// shift higher entries down
| ((x >> 4) & mask)
// shift removed element up
| ((x & mask) << ((width - i - 1) << 2));
}
/** @brief Rotate the permuter's elements between @a i and size().
@pre 0 <= @a i <= @a j <= size()
Consider the following code:
<code>
kpermuter<...> p = ..., q = p;
q.rotate(i, j);
</code>
The modified permuter, q, has the following properties.
<ul>
<li>q.size() == p.size()</li>
<li>Given k with 0 <= k < i, q[k] == p[k]</li>
<li>Given k with i <= k < q.size(), q[k] == p[i + (k - i + j - i) mod (size() - i)]</li>
</ul> */
void rotate(int i, int j) {
value_type mask = (i == width ? (value_type) 0 : (value_type) 16 << (i << 2)) - 1;
// clear unused slots
value_type x = x_ & (((value_type) 16 << (width << 2)) - 1);
x_ = (x & mask)
| ((x >> ((j - i) << 2)) & ~mask)
| ((x & ~mask) << ((width - j) << 2));
}
/** @brief Exchange the elements at positions @a i and @a j. */
void exchange(int i, int j) {
value_type diff = ((x_ >> (i << 2)) ^ (x_ >> (j << 2))) & 240;
x_ ^= (diff << (i << 2)) | (diff << (j << 2));
}
/** @brief Exchange positions of values @a x and @a y. */
void exchange_values(int x, int y) {
value_type diff = 0, p = x_;
for (int i = 0; i < width; ++i, diff <<= 4, p <<= 4) {
int v = (p >> (width << 2)) & 15;
diff ^= -((v == x) | (v == y)) & (x ^ y);
}
x_ ^= diff;
}
lcdf::String unparse() const;
bool operator==(const kpermuter<width>& x) const {
return x_ == x.x_;
}
bool operator!=(const kpermuter<width>& x) const {
return !(*this == x);
}
static inline int size(value_type p) {
return p & 15;
}
private:
value_type x_;
};
template <int width>
lcdf::String kpermuter<width>::unparse() const
{
char buf[max_width + 3], *s = buf;
value_type p(x_);
value_type seen(0);
int n = p & 15;
p >>= 4;
for (int i = 0; true; ++i) {
if (i == n)
*s++ = ':';
if (i == width)
break;
if ((p & 15) < 10)
*s++ = '0' + (p & 15);
else
*s++ = 'a' + (p & 15) - 10;
seen |= 1 << (p & 15);
p >>= 4;
}
if (seen != (1 << width) - 1) {
*s++ = '?';
*s++ = '!';
}
return lcdf::String(buf, s);
}
template <typename T> struct has_permuter_type {
template <typename C> static char test(typename C::permuter_type *);
template <typename> static int test(...);
static constexpr bool value = sizeof(test<T>(0)) == 1;
};
template <typename T, bool HP = has_permuter_type<T>::value> struct key_permuter {};
template <typename T> struct key_permuter<T, true> {
typedef typename T::permuter_type type;
static type permutation(const T& n) {
return n.permutation();
}
};
template <typename T> struct key_permuter<T, false> {
typedef identity_kpermuter type;
static type permutation(const T& n) {
return identity_kpermuter(n.size());
}
};
#endif