src/third_party/icu/source/common/uvectr32.cpp - cobalt - Git at Google

 /*
 ******************************************************************************
 * Copyright (C) 1999-2015, International Business Machines Corporation and
 * others. All Rights Reserved.
 ******************************************************************************
 *   Date        Name        Description
 *   10/22/99    alan        Creation.
 **********************************************************************
 */

 #include "starboard/client_porting/poem/assert_poem.h"
 #include "starboard/client_porting/poem/string_poem.h"
 #include "uvectr32.h"
 #include "cmemory.h"
 #include "putilimp.h"

 U_NAMESPACE_BEGIN

 #define DEFAULT_CAPACITY 8

 /*
  * Constants for hinting whether a key is an integer
  * or a pointer.  If a hint bit is zero, then the associated
  * token is assumed to be an integer. This is needed for iSeries
  */

 UOBJECT_DEFINE_RTTI_IMPLEMENTATION(UVector32)

 UVector32::UVector32(UErrorCode &status) :
     count(0),
     capacity(0),
     maxCapacity(0),
     elements(NULL)
 {
     _init(DEFAULT_CAPACITY, status);
 }

 UVector32::UVector32(int32_t initialCapacity, UErrorCode &status) :
     count(0),
     capacity(0),
     maxCapacity(0),
     elements(0)
 {
     _init(initialCapacity, status);
 }


 void UVector32::_init(int32_t initialCapacity, UErrorCode &status) {
     // Fix bogus initialCapacity values; avoid malloc(0)
     if (initialCapacity < 1) {
         initialCapacity = DEFAULT_CAPACITY;
     }
     if (maxCapacity>0 && maxCapacity<initialCapacity) {
         initialCapacity = maxCapacity;
     }
     if (initialCapacity > (int32_t)(INT32_MAX / sizeof(int32_t))) {
         initialCapacity = uprv_min(DEFAULT_CAPACITY, maxCapacity);
     }
     elements = (int32_t *)uprv_malloc(sizeof(int32_t)*initialCapacity);
     if (elements == 0) {
         status = U_MEMORY_ALLOCATION_ERROR;
     } else {
         capacity = initialCapacity;
     }
 }

 UVector32::~UVector32() {
     uprv_free(elements);
     elements = 0;
 }

 /**
  * Assign this object to another (make this a copy of 'other').
  */
 void UVector32::assign(const UVector32& other, UErrorCode &ec) {
     if (ensureCapacity(other.count, ec)) {
         setSize(other.count);
         for (int32_t i=0; i<other.count; ++i) {
             elements[i] = other.elements[i];
         }
     }
 }


 UBool UVector32::operator==(const UVector32& other) {
     int32_t i;
     if (count != other.count) return FALSE;
     for (i=0; i<count; ++i) {
         if (elements[i] != other.elements[i]) {
             return FALSE;
         }
     }
     return TRUE;
 }


 void UVector32::setElementAt(int32_t elem, int32_t index) {
     if (0 <= index && index < count) {
         elements[index] = elem;
     }
     /* else index out of range */
 }

 void UVector32::insertElementAt(int32_t elem, int32_t index, UErrorCode &status) {
     // must have 0 <= index <= count
     if (0 <= index && index <= count && ensureCapacity(count + 1, status)) {
         for (int32_t i=count; i>index; --i) {
             elements[i] = elements[i-1];
         }
         elements[index] = elem;
         ++count;
     }
     /* else index out of range */
 }

 UBool UVector32::containsAll(const UVector32& other) const {
     for (int32_t i=0; i<other.size(); ++i) {
         if (indexOf(other.elements[i]) < 0) {
             return FALSE;
         }
     }
     return TRUE;
 }

 UBool UVector32::containsNone(const UVector32& other) const {
     for (int32_t i=0; i<other.size(); ++i) {
         if (indexOf(other.elements[i]) >= 0) {
             return FALSE;
         }
     }
     return TRUE;
 }

 UBool UVector32::removeAll(const UVector32& other) {
     UBool changed = FALSE;
     for (int32_t i=0; i<other.size(); ++i) {
         int32_t j = indexOf(other.elements[i]);
         if (j >= 0) {
             removeElementAt(j);
             changed = TRUE;
         }
     }
     return changed;
 }

 UBool UVector32::retainAll(const UVector32& other) {
     UBool changed = FALSE;
     for (int32_t j=size()-1; j>=0; --j) {
         int32_t i = other.indexOf(elements[j]);
         if (i < 0) {
             removeElementAt(j);
             changed = TRUE;
         }
     }
     return changed;
 }

 void UVector32::removeElementAt(int32_t index) {
     if (index >= 0) {
         for (int32_t i=index; i<count-1; ++i) {
             elements[i] = elements[i+1];
         }
         --count;
     }
 }

 void UVector32::removeAllElements(void) {
     count = 0;
 }

 UBool   UVector32::equals(const UVector32 &other) const {
     int      i;

     if (this->count != other.count) {
         return FALSE;
     }
     for (i=0; i<count; i++) {
         if (elements[i] != other.elements[i]) {
             return FALSE;
         }
     }
     return TRUE;
 }


 int32_t UVector32::indexOf(int32_t key, int32_t startIndex) const {
     int32_t i;
     for (i=startIndex; i<count; ++i) {
         if (key == elements[i]) {
             return i;
         }
     }
     return -1;
 }


 UBool UVector32::expandCapacity(int32_t minimumCapacity, UErrorCode &status) {
     if (U_FAILURE(status)) {
         return FALSE;
     }
     if (minimumCapacity < 0) {
         status = U_ILLEGAL_ARGUMENT_ERROR;
         return FALSE;
     }
     if (capacity >= minimumCapacity) {
         return TRUE;
     }
     if (maxCapacity>0 && minimumCapacity>maxCapacity) {
         status = U_BUFFER_OVERFLOW_ERROR;
         return FALSE;
     }
     if (capacity > (INT32_MAX - 1) / 2) {  // integer overflow check
         status = U_ILLEGAL_ARGUMENT_ERROR;
         return FALSE;
     }
     int32_t newCap = capacity * 2;
     if (newCap < minimumCapacity) {
         newCap = minimumCapacity;
     }
     if (maxCapacity > 0 && newCap > maxCapacity) {
         newCap = maxCapacity;
     }
     if (newCap > (int32_t)(INT32_MAX / sizeof(int32_t))) {  // integer overflow check
         // We keep the original memory contents on bad minimumCapacity/maxCapacity.
         status = U_ILLEGAL_ARGUMENT_ERROR;
         return FALSE;
     }
     int32_t* newElems = (int32_t *)uprv_realloc(elements, sizeof(int32_t)*newCap);
     if (newElems == NULL) {
         // We keep the original contents on the memory failure on realloc.
         status = U_MEMORY_ALLOCATION_ERROR;
         return FALSE;
     }
     elements = newElems;
     capacity = newCap;
     return TRUE;
 }

 void UVector32::setMaxCapacity(int32_t limit) {
     U_ASSERT(limit >= 0);
     if (limit < 0) {
         limit = 0;
     }
     if (limit > (int32_t)(INT32_MAX / sizeof(int32_t))) {  // integer overflow check for realloc
         //  Something is very wrong, don't realloc, leave capacity and maxCapacity unchanged
         return;
     }
     maxCapacity = limit;
     if (capacity <= maxCapacity || maxCapacity == 0) {
         // Current capacity is within the new limit.
         return;
     }

     // New maximum capacity is smaller than the current size.
     // Realloc the storage to the new, smaller size.
     int32_t* newElems = (int32_t *)uprv_realloc(elements, sizeof(int32_t)*maxCapacity);
     if (newElems == NULL) {
         // Realloc to smaller failed.
         //   Just keep what we had.  No need to call it a failure.
         return;
     }
     elements = newElems;
     capacity = maxCapacity;
     if (count > capacity) {
         count = capacity;
     }
 }

 /**
  * Change the size of this vector as follows: If newSize is smaller,
  * then truncate the array, possibly deleting held elements for i >=
  * newSize.  If newSize is larger, grow the array, filling in new
  * slots with NULL.
  */
 void UVector32::setSize(int32_t newSize) {
     int32_t i;
     if (newSize < 0) {
         return;
     }
     if (newSize > count) {
         UErrorCode ec = U_ZERO_ERROR;
         if (!ensureCapacity(newSize, ec)) {
             return;
         }
         for (i=count; i<newSize; ++i) {
             elements[i] = 0;
         }
     }
     count = newSize;
 }


 /**
  * Insert the given integer into this vector at its sorted position
  * as defined by 'compare'.  The current elements are assumed to
  * be sorted already.
  */
 void UVector32::sortedInsert(int32_t tok, UErrorCode& ec) {
     // Perform a binary search for the location to insert tok at.  Tok
     // will be inserted between two elements a and b such that a <=
     // tok && tok < b, where there is a 'virtual' elements[-1] always
     // less than tok and a 'virtual' elements[count] always greater
     // than tok.
     int32_t min = 0, max = count;
     while (min != max) {
         int32_t probe = (min + max) / 2;
         //int8_t c = (*compare)(elements[probe], tok);
         //if (c > 0) {
         if (elements[probe] > tok) {
             max = probe;
         } else {
             // assert(c <= 0);
             min = probe + 1;
         }
     }
     if (ensureCapacity(count + 1, ec)) {
         for (int32_t i=count; i>min; --i) {
             elements[i] = elements[i-1];
         }
         elements[min] = tok;
         ++count;
     }
 }


 U_NAMESPACE_END
	/*
	******************************************************************************
	* Copyright (C) 1999-2015, International Business Machines Corporation and
	* others. All Rights Reserved.
	******************************************************************************
	* Date Name Description
	* 10/22/99 alan Creation.
	**********************************************************************
	*/

	#include "starboard/client_porting/poem/assert_poem.h"
	#include "starboard/client_porting/poem/string_poem.h"
	#include "uvectr32.h"
	#include "cmemory.h"
	#include "putilimp.h"

	U_NAMESPACE_BEGIN

	#define DEFAULT_CAPACITY 8

	/*
	* Constants for hinting whether a key is an integer
	* or a pointer. If a hint bit is zero, then the associated
	* token is assumed to be an integer. This is needed for iSeries
	*/

	UOBJECT_DEFINE_RTTI_IMPLEMENTATION(UVector32)

	UVector32::UVector32(UErrorCode &status) :
	count(0),
	capacity(0),
	maxCapacity(0),
	elements(NULL)
	{
	_init(DEFAULT_CAPACITY, status);
	}

	UVector32::UVector32(int32_t initialCapacity, UErrorCode &status) :
	count(0),
	capacity(0),
	maxCapacity(0),
	elements(0)
	{
	_init(initialCapacity, status);
	}



	void UVector32::_init(int32_t initialCapacity, UErrorCode &status) {
	// Fix bogus initialCapacity values; avoid malloc(0)
	if (initialCapacity < 1) {
	initialCapacity = DEFAULT_CAPACITY;
	}
	if (maxCapacity>0 && maxCapacity<initialCapacity) {
	initialCapacity = maxCapacity;
	}
	if (initialCapacity > (int32_t)(INT32_MAX / sizeof(int32_t))) {
	initialCapacity = uprv_min(DEFAULT_CAPACITY, maxCapacity);
	}
	elements = (int32_t )uprv_malloc(sizeof(int32_t)initialCapacity);
	if (elements == 0) {
	status = U_MEMORY_ALLOCATION_ERROR;
	} else {
	capacity = initialCapacity;
	}
	}

	UVector32::~UVector32() {
	uprv_free(elements);
	elements = 0;
	}

	/**
	* Assign this object to another (make this a copy of 'other').
	*/
	void UVector32::assign(const UVector32& other, UErrorCode &ec) {
	if (ensureCapacity(other.count, ec)) {
	setSize(other.count);
	for (int32_t i=0; i<other.count; ++i) {
	elements[i] = other.elements[i];
	}
	}
	}


	UBool UVector32::operator==(const UVector32& other) {
	int32_t i;
	if (count != other.count) return FALSE;
	for (i=0; i<count; ++i) {
	if (elements[i] != other.elements[i]) {
	return FALSE;
	}
	}
	return TRUE;
	}


	void UVector32::setElementAt(int32_t elem, int32_t index) {
	if (0 <= index && index < count) {
	elements[index] = elem;
	}
	/* else index out of range */
	}

	void UVector32::insertElementAt(int32_t elem, int32_t index, UErrorCode &status) {
	// must have 0 <= index <= count
	if (0 <= index && index <= count && ensureCapacity(count + 1, status)) {
	for (int32_t i=count; i>index; --i) {
	elements[i] = elements[i-1];
	}
	elements[index] = elem;
	++count;
	}
	/* else index out of range */
	}

	UBool UVector32::containsAll(const UVector32& other) const {
	for (int32_t i=0; i<other.size(); ++i) {
	if (indexOf(other.elements[i]) < 0) {
	return FALSE;
	}
	}
	return TRUE;
	}

	UBool UVector32::containsNone(const UVector32& other) const {
	for (int32_t i=0; i<other.size(); ++i) {
	if (indexOf(other.elements[i]) >= 0) {
	return FALSE;
	}
	}
	return TRUE;
	}

	UBool UVector32::removeAll(const UVector32& other) {
	UBool changed = FALSE;
	for (int32_t i=0; i<other.size(); ++i) {
	int32_t j = indexOf(other.elements[i]);
	if (j >= 0) {
	removeElementAt(j);
	changed = TRUE;
	}
	}
	return changed;
	}

	UBool UVector32::retainAll(const UVector32& other) {
	UBool changed = FALSE;
	for (int32_t j=size()-1; j>=0; --j) {
	int32_t i = other.indexOf(elements[j]);
	if (i < 0) {
	removeElementAt(j);
	changed = TRUE;
	}
	}
	return changed;
	}

	void UVector32::removeElementAt(int32_t index) {
	if (index >= 0) {
	for (int32_t i=index; i<count-1; ++i) {
	elements[i] = elements[i+1];
	}
	--count;
	}
	}

	void UVector32::removeAllElements(void) {
	count = 0;
	}

	UBool UVector32::equals(const UVector32 &other) const {
	int i;

	if (this->count != other.count) {
	return FALSE;
	}
	for (i=0; i<count; i++) {
	if (elements[i] != other.elements[i]) {
	return FALSE;
	}
	}
	return TRUE;
	}




	int32_t UVector32::indexOf(int32_t key, int32_t startIndex) const {
	int32_t i;
	for (i=startIndex; i<count; ++i) {
	if (key == elements[i]) {
	return i;
	}
	}
	return -1;
	}


	UBool UVector32::expandCapacity(int32_t minimumCapacity, UErrorCode &status) {
	if (U_FAILURE(status)) {
	return FALSE;
	}
	if (minimumCapacity < 0) {
	status = U_ILLEGAL_ARGUMENT_ERROR;
	return FALSE;
	}
	if (capacity >= minimumCapacity) {
	return TRUE;
	}
	if (maxCapacity>0 && minimumCapacity>maxCapacity) {
	status = U_BUFFER_OVERFLOW_ERROR;
	return FALSE;
	}
	if (capacity > (INT32_MAX - 1) / 2) { // integer overflow check
	status = U_ILLEGAL_ARGUMENT_ERROR;
	return FALSE;
	}
	int32_t newCap = capacity * 2;
	if (newCap < minimumCapacity) {
	newCap = minimumCapacity;
	}
	if (maxCapacity > 0 && newCap > maxCapacity) {
	newCap = maxCapacity;
	}
	if (newCap > (int32_t)(INT32_MAX / sizeof(int32_t))) { // integer overflow check
	// We keep the original memory contents on bad minimumCapacity/maxCapacity.
	status = U_ILLEGAL_ARGUMENT_ERROR;
	return FALSE;
	}
	int32_t* newElems = (int32_t )uprv_realloc(elements, sizeof(int32_t)newCap);
	if (newElems == NULL) {
	// We keep the original contents on the memory failure on realloc.
	status = U_MEMORY_ALLOCATION_ERROR;
	return FALSE;
	}
	elements = newElems;
	capacity = newCap;
	return TRUE;
	}

	void UVector32::setMaxCapacity(int32_t limit) {
	U_ASSERT(limit >= 0);
	if (limit < 0) {
	limit = 0;
	}
	if (limit > (int32_t)(INT32_MAX / sizeof(int32_t))) { // integer overflow check for realloc
	// Something is very wrong, don't realloc, leave capacity and maxCapacity unchanged
	return;
	}
	maxCapacity = limit;
	if (capacity <= maxCapacity \|\| maxCapacity == 0) {
	// Current capacity is within the new limit.
	return;
	}

	// New maximum capacity is smaller than the current size.
	// Realloc the storage to the new, smaller size.
	int32_t* newElems = (int32_t )uprv_realloc(elements, sizeof(int32_t)maxCapacity);
	if (newElems == NULL) {
	// Realloc to smaller failed.
	// Just keep what we had. No need to call it a failure.
	return;
	}
	elements = newElems;
	capacity = maxCapacity;
	if (count > capacity) {
	count = capacity;
	}
	}

	/**
	* Change the size of this vector as follows: If newSize is smaller,
	* then truncate the array, possibly deleting held elements for i >=
	* newSize. If newSize is larger, grow the array, filling in new
	* slots with NULL.
	*/
	void UVector32::setSize(int32_t newSize) {
	int32_t i;
	if (newSize < 0) {
	return;
	}
	if (newSize > count) {
	UErrorCode ec = U_ZERO_ERROR;
	if (!ensureCapacity(newSize, ec)) {
	return;
	}
	for (i=count; i<newSize; ++i) {
	elements[i] = 0;
	}
	}
	count = newSize;
	}




	/**
	* Insert the given integer into this vector at its sorted position
	* as defined by 'compare'. The current elements are assumed to
	* be sorted already.
	*/
	void UVector32::sortedInsert(int32_t tok, UErrorCode& ec) {
	// Perform a binary search for the location to insert tok at. Tok
	// will be inserted between two elements a and b such that a <=
	// tok && tok < b, where there is a 'virtual' elements[-1] always
	// less than tok and a 'virtual' elements[count] always greater
	// than tok.
	int32_t min = 0, max = count;
	while (min != max) {
	int32_t probe = (min + max) / 2;
	//int8_t c = (*compare)(elements[probe], tok);
	//if (c > 0) {
	if (elements[probe] > tok) {
	max = probe;
	} else {
	// assert(c <= 0);
	min = probe + 1;
	}
	}
	if (ensureCapacity(count + 1, ec)) {
	for (int32_t i=count; i>min; --i) {
	elements[i] = elements[i-1];
	}
	elements[min] = tok;
	++count;
	}
	}





	U_NAMESPACE_END