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ds.h
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ds.h
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/*
* Copyright 2011, Ben Langmead <[email protected]>
*
* This file is part of Bowtie 2.
*
* Bowtie 2 is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* Bowtie 2 is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with Bowtie 2. If not, see <http://www.gnu.org/licenses/>.
*/
#ifndef DS_H_
#define DS_H_
#include <algorithm>
#include <stdexcept>
#include <utility>
#include <stdint.h>
#include <string.h>
#include <limits>
#include "assert_helpers.h"
#include "threading.h"
#include "random_source.h"
#include "btypes.h"
/**
* Tally how much memory is allocated to certain
*/
class MemoryTally {
public:
MemoryTally() : tot_(0), peak_(0) {
memset(tots_, 0, 256 * sizeof(uint64_t));
memset(peaks_, 0, 256 * sizeof(uint64_t));
}
/**
* Tally a memory allocation of size amt bytes.
*/
void add(int cat, uint64_t amt);
/**
* Tally a memory free of size amt bytes.
*/
void del(int cat, uint64_t amt);
/**
* Return the total amount of memory allocated.
*/
uint64_t total() { return tot_; }
/**
* Return the total amount of memory allocated in a particular
* category.
*/
uint64_t total(int cat) { return tots_[cat]; }
/**
* Return the peak amount of memory allocated.
*/
uint64_t peak() { return peak_; }
/**
* Return the peak amount of memory allocated in a particular
* category.
*/
uint64_t peak(int cat) { return peaks_[cat]; }
#ifndef NDEBUG
/**
* Check that memory tallies are internally consistent;
*/
bool repOk() const {
uint64_t tot = 0;
for(int i = 0; i < 256; i++) {
assert_leq(tots_[i], peaks_[i]);
tot += tots_[i];
}
assert_eq(tot, tot_);
return true;
}
#endif
protected:
MUTEX_T mutex_m;
uint64_t tots_[256];
uint64_t tot_;
uint64_t peaks_[256];
uint64_t peak_;
};
#ifdef USE_MEM_TALLY
extern MemoryTally gMemTally;
#endif
/**
* A simple fixed-length array of type T, automatically freed in the
* destructor.
*/
template<typename T>
class AutoArray {
public:
AutoArray(size_t sz, int cat = 0) : cat_(cat) {
t_ = NULL;
t_ = new T[sz];
#ifdef USE_MEM_TALLY
gMemTally.add(cat_, sz);
#else
(void)cat_;
#endif
memset(t_, 0, sz * sizeof(T));
sz_ = sz;
}
~AutoArray() {
if(t_ != NULL) {
delete[] t_;
#ifdef USE_MEM_TALLY
gMemTally.del(cat_, sz_);
#endif
}
}
T& operator[](size_t sz) {
return t_[sz];
}
const T& operator[](size_t sz) const {
return t_[sz];
}
size_t size() const { return sz_; }
private:
int cat_;
T *t_;
size_t sz_;
};
/**
* A wrapper for a non-array pointer that associates it with a memory
* category for tracking purposes and calls delete on it when the
* PtrWrap is destroyed.
*/
template<typename T>
class PtrWrap {
public:
explicit PtrWrap(
T* p,
bool freeable = true,
int cat = 0) :
cat_(cat),
p_(NULL)
{
init(p, freeable);
}
explicit PtrWrap(int cat = 0) :
cat_(cat),
p_(NULL)
{
reset();
}
void reset() {
free();
init(NULL);
}
~PtrWrap() { free(); }
void init(T* p, bool freeable = true) {
assert(p_ == NULL);
p_ = p;
freeable_ = freeable;
#ifdef USE_MEM_TALLY
if(p != NULL && freeable_) {
gMemTally.add(cat_, sizeof(T));
}
#else
(void)cat_;
#endif
}
void free() {
if(p_ != NULL) {
if(freeable_) {
delete p_;
#ifdef USE_MEM_TALLY
gMemTally.del(cat_, sizeof(T));
#endif
}
p_ = NULL;
}
}
inline T* get() { return p_; }
inline const T* get() const { return p_; }
private:
int cat_;
T *p_;
bool freeable_;
};
/**
* A wrapper for an array pointer that associates it with a memory
* category for tracking purposes and calls delete[] on it when the
* PtrWrap is destroyed.
*/
template<typename T>
class APtrWrap {
public:
explicit APtrWrap(
T* p,
size_t sz,
bool freeable = true,
int cat = 0) :
cat_(cat),
p_(NULL)
{
init(p, sz, freeable);
}
explicit APtrWrap(int cat = 0) :
cat_(cat),
p_(NULL)
{
reset();
}
void reset() {
free();
init(NULL, 0);
}
~APtrWrap() { free(); }
void init(T* p, size_t sz, bool freeable = true) {
assert(p_ == NULL);
p_ = p;
sz_ = sz;
freeable_ = freeable;
#ifdef USE_MEM_TALLY
if(p != NULL && freeable_) {
gMemTally.add(cat_, sizeof(T) * sz_);
}
#else
(void)cat_;
#endif
}
void free() {
if(p_ != NULL) {
if(freeable_) {
delete[] p_;
#ifdef USE_MEM_TALLY
gMemTally.del(cat_, sizeof(T) * sz_);
#endif
}
p_ = NULL;
}
}
inline T* get() { return p_; }
inline const T* get() const { return p_; }
private:
int cat_;
T *p_;
bool freeable_;
size_t sz_;
};
/**
* An EList<T> is an expandable list with these features:
*
* - Payload type is a template parameter T.
* - Initial size can be specified at construction time, otherwise
* default of 128 is used.
* - When allocated initially or when expanding, the new[] operator is
* used, which in turn calls the default constructor for T.
* - All copies (e.g. assignment of a const T& to an EList<T> element,
* or during expansion) use operator=.
* - When the EList<T> is resized to a smaller size (or cleared, which
* is like resizing to size 0), the underlying containing is not
* reshaped. Thus, ELists<T>s never release memory before
* destruction.
*
* And these requirements:
*
* - Payload type T must have a default constructor.
*
* For efficiency reasons, ELists should not be declared on the stack
* in often-called worker functions. Best practice is to declare
* ELists at a relatively stable layer of the stack (such that it
* rarely bounces in and out of scope) and let the worker function use
* it and *expand* it only as needed. The effect is that only
* relatively few allocations and copies will be incurred, and they'll
* occur toward the beginning of the computation before stabilizing at
* a "high water mark" for the remainder of the computation.
*
* A word about multidimensional lists. One way to achieve a
* multidimensional lists is to nest ELists. This works, but it often
* involves a lot more calls to the default constructor and to
* operator=, especially when the outermost EList needs expanding, than
* some of the alternatives. One alternative is use a most specialized
* container that still uses ELists but knows to use xfer instead of
* operator= when T=EList.
*
* The 'cat_' fiends encodes a category. This makes it possible to
* distinguish between object subgroups in the global memory tally.
*
* Memory allocation is lazy. Allocation is only triggered when the
* user calls push_back, expand, resize, or another function that
* increases the size of the list. This saves memory and also makes it
* easier to deal with nested ELists, since the default constructor
* doesn't set anything in stone.
*/
template <typename T, int S = 128>
class EList {
public:
/**
* Allocate initial default of S elements.
*/
explicit EList() :
cat_(0), allocCat_(-1), list_(NULL), sz_(S), cur_(0)
{
#ifndef USE_MEM_TALLY
(void)cat_;
#endif
}
/**
* Allocate initial default of S elements.
*/
explicit EList(int cat) :
cat_(cat), allocCat_(-1), list_(NULL), sz_(S), cur_(0)
{
assert_geq(cat, 0);
}
/**
* Initially allocate given number of elements; should be > 0.
*/
explicit EList(size_t isz, int cat = 0) :
cat_(cat), allocCat_(-1), list_(NULL), sz_(isz), cur_(0)
{
assert_geq(cat, 0);
}
/**
* Copy from another EList using operator=.
*/
EList(const EList<T, S>& o) :
cat_(0), allocCat_(-1), list_(NULL), sz_(0), cur_(0)
{
*this = o;
}
/**
* Copy from another EList using operator=.
*/
explicit EList(const EList<T, S>& o, int cat) :
cat_(cat), allocCat_(-1), list_(NULL), sz_(0), cur_(0)
{
*this = o;
assert_geq(cat, 0);
}
/**
* Destructor.
*/
~EList() { free(); }
/**
* Make this object into a copy of o by allocat
*/
EList<T, S>& operator=(const EList<T, S>& o) {
assert_eq(cat_, o.cat());
if(o.cur_ == 0) {
// Nothing to copy
cur_ = 0;
return *this;
}
if(list_ == NULL) {
// cat_ should already be set
lazyInit();
}
if(sz_ < o.cur_) expandNoCopy(o.cur_ + 1);
assert_geq(sz_, o.cur_);
cur_ = o.cur_;
for(size_t i = 0; i < cur_; i++) {
list_[i] = o.list_[i];
}
return *this;
}
/**
* Transfer the guts of another EList into this one without using
* operator=, etc. We have to set EList o's list_ field to NULL to
* avoid o's destructor from deleting list_ out from under us.
*/
void xfer(EList<T, S>& o) {
// What does it mean to transfer to a different-category list?
assert_eq(cat_, o.cat());
// Can only transfer into an empty object
free();
allocCat_ = cat_;
list_ = o.list_;
sz_ = o.sz_;
cur_ = o.cur_;
o.list_ = NULL;
o.sz_ = o.cur_ = 0;
o.allocCat_ = -1;
}
/**
* Return number of elements.
*/
inline size_t size() const { return cur_; }
/**
* Return number of elements allocated.
*/
inline size_t capacity() const { return sz_; }
/**
* Return the total size in bytes occupied by this list.
*/
size_t totalSizeBytes() const {
return 2 * sizeof(int) +
2 * sizeof(size_t) +
cur_ * sizeof(T);
}
/**
* Return the total capacity in bytes occupied by this list.
*/
size_t totalCapacityBytes() const {
return 2 * sizeof(int) +
2 * sizeof(size_t) +
sz_ * sizeof(T);
}
/**
* Ensure that there is sufficient capacity to expand to include
* 'thresh' more elements without having to expand.
*/
inline void ensure(size_t thresh) {
if(list_ == NULL) lazyInit();
expandCopy(cur_ + thresh);
}
/**
* Ensure that there is sufficient capacity to include 'newsz' elements.
* If there isn't enough capacity right now, expand capacity to exactly
* equal 'newsz'.
*/
inline void reserveExact(size_t newsz) {
if(list_ == NULL) lazyInitExact(newsz);
expandCopyExact(newsz);
}
/**
* Return true iff there are no elements.
*/
inline bool empty() const { return cur_ == 0; }
/**
* Return true iff list hasn't been initialized yet.
*/
inline bool null() const { return list_ == NULL; }
/**
* Add an element to the back and immediately initialize it via
* operator=.
*/
void push_back(const T& el) {
if(list_ == NULL) lazyInit();
if(cur_ == sz_) expandCopy(sz_+1);
list_[cur_++] = el;
}
/**
* Add an element to the back. No intialization is done.
*/
void expand() {
if(list_ == NULL) lazyInit();
if(cur_ == sz_) expandCopy(sz_+1);
cur_++;
}
/**
* Add an element to the back. No intialization is done.
*/
void fill(size_t begin, size_t end, const T& v) {
assert_leq(begin, end);
assert_leq(end, cur_);
for(size_t i = begin; i < end; i++) {
list_[i] = v;
}
}
/**
* Add an element to the back. No intialization is done.
*/
void fill(const T& v) {
for(size_t i = 0; i < cur_; i++) {
list_[i] = v;
}
}
/**
* Set all bits in specified range of elements in list array to 0.
*/
void fillZero(size_t begin, size_t end) {
assert_leq(begin, end);
memset(&list_[begin], 0, sizeof(T) * (end-begin));
}
/**
* Set all bits in the list array to 0.
*/
void fillZero() {
memset(list_, 0, sizeof(T) * cur_);
}
/**
* If size is less than requested size, resize up to at least sz
* and set cur_ to requested sz.
*/
void resizeNoCopy(size_t sz) {
if(sz > 0 && list_ == NULL) lazyInit();
if(sz <= cur_) {
cur_ = sz;
return;
}
if(sz_ < sz) expandNoCopy(sz);
cur_ = sz;
}
/**
* If size is less than requested size, resize up to at least sz
* and set cur_ to requested sz.
*/
void resize(size_t sz) {
if(sz > 0 && list_ == NULL) lazyInit();
if(sz <= cur_) {
cur_ = sz;
return;
}
if(sz_ < sz) {
expandCopy(sz);
}
cur_ = sz;
}
/**
* If size is less than requested size, resize up to exactly sz and set
* cur_ to requested sz.
*/
void resizeExact(size_t sz) {
if(sz > 0 && list_ == NULL) lazyInitExact(sz);
if(sz <= cur_) {
cur_ = sz;
return;
}
if(sz_ < sz) expandCopyExact(sz);
cur_ = sz;
}
/**
* Erase element at offset idx.
*/
void erase(size_t idx) {
assert_lt(idx, cur_);
for(size_t i = idx; i < cur_-1; i++) {
list_[i] = list_[i+1];
}
cur_--;
}
/**
* Erase range of elements starting at offset idx and going for len.
*/
void erase(size_t idx, size_t len) {
assert_geq(len, 0);
if(len == 0) {
return;
}
assert_lt(idx, cur_);
for(size_t i = idx; i < cur_-len; i++) {
list_[i] = list_[i+len];
}
cur_ -= len;
}
/**
* Insert value 'el' at offset 'idx'
*/
void insert(const T& el, size_t idx) {
if(list_ == NULL) lazyInit();
assert_leq(idx, cur_);
if(cur_ == sz_) expandCopy(sz_+1);
for(size_t i = cur_; i > idx; i--) {
list_[i] = list_[i-1];
}
list_[idx] = el;
cur_++;
}
/**
* Insert contents of list 'l' at offset 'idx'
*/
void insert(const EList<T>& l, size_t idx) {
if(list_ == NULL) lazyInit();
assert_lt(idx, cur_);
if(l.cur_ == 0) return;
if(cur_ + l.cur_ > sz_) expandCopy(cur_ + l.cur_);
for(size_t i = cur_ + l.cur_ - 1; i > idx + (l.cur_ - 1); i--) {
list_[i] = list_[i - l.cur_];
}
for(size_t i = 0; i < l.cur_; i++) {
list_[i+idx] = l.list_[i];
}
cur_ += l.cur_;
}
/**
* Remove an element from the top of the stack.
*/
void pop_back() {
assert_gt(cur_, 0);
cur_--;
}
/**
* Make the stack empty.
*/
void clear() {
cur_ = 0; // re-use stack memory
// Don't clear heap; re-use it
}
/**
* Get the element on the top of the stack.
*/
inline T& back() {
assert_gt(cur_, 0);
return list_[cur_-1];
}
/**
* Reverse list elements.
*/
void reverse() {
if(cur_ > 1) {
size_t n = cur_ >> 1;
for(size_t i = 0; i < n; i++) {
T tmp = list_[i];
list_[i] = list_[cur_ - i - 1];
list_[cur_ - i - 1] = tmp;
}
}
}
/**
* Get the element on the top of the stack, const version.
*/
inline const T& back() const {
assert_gt(cur_, 0);
return list_[cur_-1];
}
/**
* Get the frontmost element (bottom of stack).
*/
inline T& front() {
assert_gt(cur_, 0);
return list_[0];
}
/**
* Get the element on the bottom of the stack, const version.
*/
inline const T& front() const { return front(); }
/**
* Return true iff this list and list o contain the same elements in the
* same order according to type T's operator==.
*/
bool operator==(const EList<T, S>& o) const {
if(size() != o.size()) {
return false;
}
for(size_t i = 0; i < size(); i++) {
if(!(get(i) == o.get(i))) {
return false;
}
}
return true;
}
/**
* Return true iff this list contains all of the elements in o according to
* type T's operator==.
*/
bool isSuperset(const EList<T, S>& o) const {
if(o.size() > size()) {
// This can't be a superset if the other set contains more elts
return false;
}
// For each element in o
for(size_t i = 0; i < o.size(); i++) {
bool inthis = false;
// Check if it's in this
for(size_t j = 0; j < size(); j++) {
if(o[i] == (*this)[j]) {
inthis = true;
break;
}
}
if(!inthis) {
return false;
}
}
return true;
}
/**
* Return a reference to the ith element.
*/
inline T& operator[](size_t i) {
assert_lt(i, cur_);
return list_[i];
}
/**
* Return a reference to the ith element.
*/
inline const T& operator[](size_t i) const {
assert_lt(i, cur_);
return list_[i];
}
/**
* Return a reference to the ith element.
*/
inline T& get(size_t i) {
return operator[](i);
}
/**
* Return a reference to the ith element.
*/
inline const T& get(size_t i) const {
return operator[](i);
}
/**
* Return a reference to the ith element. This version is not
* inlined, which guarantees we can use it from the debugger.
*/
T& getSlow(size_t i) {
return operator[](i);
}
/**
* Return a reference to the ith element. This version is not
* inlined, which guarantees we can use it from the debugger.
*/
const T& getSlow(size_t i) const {
return operator[](i);
}
/**
* Sort some of the contents.
*/
void sortPortion(size_t begin, size_t num) {
assert_leq(begin+num, cur_);
if(num < 2) return;
std::stable_sort(list_ + begin, list_ + begin + num);
}
/**
* Shuffle a portion of the list.
*/
void shufflePortion(size_t begin, size_t num, RandomSource& rnd) {
assert_leq(begin+num, cur_);
if(num < 2) return;
size_t left = num;
for(size_t i = begin; i < begin + num - 1; i++) {
size_t rndi = rnd.nextSizeT() % left;
if(rndi > 0) {
std::swap(list_[i], list_[i + rndi]);
}
left--;
}
}
/**
* Sort contents
*/
void sort() {
sortPortion(0, cur_);
}
/**
* Return true iff every element is < its successor. Only operator< is
* used.
*/
bool sorted() const {
for(size_t i = 1; i < cur_; i++) {
if(!(list_[i-1] < list_[i])) {
return false;
}
}
return true;
}
/**
* Delete element at position 'idx'; slide subsequent chars up.
*/
void remove(size_t idx) {
assert_lt(idx, cur_);
assert_gt(cur_, 0);
for(size_t i = idx; i < cur_-1; i++) {
list_[i] = list_[i+1];
}
cur_--;
}
/**
* Return a pointer to the beginning of the buffer.
*/
T *ptr() { return list_; }
/**
* Return a const pointer to the beginning of the buffer.
*/
const T *ptr() const { return list_; }
/**
* Set the memory category for this object.
*/
void setCat(int cat) {
// What does it mean to set the category after the list_ is
// already allocated?
assert(null());
assert_gt(cat, 0); cat_ = cat;
}
/**
* Return memory category.
*/
int cat() const { return cat_; }
/**
* Perform a binary search for the first element that is not less
* than 'el'. Return cur_ if all elements are less than el.
*/
size_t bsearchLoBound(const T& el) const {
size_t hi = cur_;
size_t lo = 0;
while(true) {
if(lo == hi) {
return lo;
}
size_t mid = lo + ((hi-lo)>>1);
assert_neq(mid, hi);
if(list_[mid] < el) {
if(lo == mid) {
return hi;
}
lo = mid;
} else {
hi = mid;
}
}
}
private:
/**
* Initialize memory for EList.
*/
void lazyInit() {
assert(list_ == NULL);
list_ = alloc(sz_);
}
/**
* Initialize exactly the prescribed number of elements for EList.
*/
void lazyInitExact(size_t sz) {
assert_gt(sz, 0);
assert(list_ == NULL);
sz_ = sz;
list_ = alloc(sz);
}
/**
* Allocate a T array of length sz_ and store in list_. Also,
* tally into the global memory tally.
*/
T *alloc(size_t sz) {
T* tmp = new T[sz];
assert(tmp != NULL);
#ifdef USE_MEM_TALLY
gMemTally.add(cat_, sz);
#endif
allocCat_ = cat_;
return tmp;
}
/**
* Allocate a T array of length sz_ and store in list_. Also,
* tally into the global memory tally.
*/
void free() {
if(list_ != NULL) {
assert_neq(-1, allocCat_);
assert_eq(allocCat_, cat_);
delete[] list_;
#ifdef USE_MEM_TALLY
gMemTally.del(cat_, sz_);
#endif
list_ = NULL;
sz_ = cur_ = 0;
}
}
/**
* Expand the list_ buffer until it has at least 'thresh' elements. Size
* increases quadratically with number of expansions. Copy old contents
* into new buffer using operator=.
*/
void expandCopy(size_t thresh) {
if(thresh <= sz_) return;
size_t newsz = (sz_ * 2)+1;
while(newsz < thresh) newsz *= 2;
expandCopyExact(newsz);
}
/**
* Expand the list_ buffer until it has exactly 'newsz' elements. Copy
* old contents into new buffer using operator=.
*/
void expandCopyExact(size_t newsz) {
if(newsz <= sz_) return;
T* tmp = alloc(newsz);
assert(tmp != NULL);
size_t cur = cur_;
if(list_ != NULL) {
for(size_t i = 0; i < cur_; i++) {
// Note: operator= is used
tmp[i] = list_[i];
}
free();
}
list_ = tmp;
sz_ = newsz;
cur_ = cur;
}
/**
* Expand the list_ buffer until it has at least 'thresh' elements.
* Size increases quadratically with number of expansions. Don't copy old
* contents into the new buffer.
*/
void expandNoCopy(size_t thresh) {
assert(list_ != NULL);
if(thresh <= sz_) return;
size_t newsz = (sz_ * 2)+1;
while(newsz < thresh) newsz *= 2;
expandNoCopyExact(newsz);
}
/**
* Expand the list_ buffer until it has exactly 'newsz' elements. Don't
* copy old contents into the new buffer.
*/
void expandNoCopyExact(size_t newsz) {
assert(list_ != NULL);