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|
/* ScummVM - Graphic Adventure Engine
*
* ScummVM is the legal property of its developers, whose names
* are too numerous to list here. Please refer to the COPYRIGHT
* file distributed with this source distribution.
*
* This program 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 2
* of the License, or (at your option) any later version.
*
* This program 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 this program; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
*
*/
#include "common/hash-str.h"
#include "common/list.h"
#include "common/memorypool.h"
#include "common/str.h"
#include "common/util.h"
namespace Common {
MemoryPool *g_refCountPool = 0; // FIXME: This is never freed right now
static uint32 computeCapacity(uint32 len) {
// By default, for the capacity we use the next multiple of 32
return ((len + 32 - 1) & ~0x1F);
}
String::String(const char *str) : _size(0), _str(_storage) {
if (str == 0) {
_storage[0] = 0;
_size = 0;
} else
initWithCStr(str, strlen(str));
}
String::String(const char *str, uint32 len) : _size(0), _str(_storage) {
initWithCStr(str, len);
}
String::String(const char *beginP, const char *endP) : _size(0), _str(_storage) {
assert(endP >= beginP);
initWithCStr(beginP, endP - beginP);
}
void String::initWithCStr(const char *str, uint32 len) {
assert(str);
// Init _storage member explicitly (ie. without calling its constructor)
// for GCC 2.95.x compatibility (see also tracker item #1602879).
_storage[0] = 0;
_size = len;
if (len >= _builtinCapacity) {
// Not enough internal storage, so allocate more
_extern._capacity = computeCapacity(len+1);
_extern._refCount = 0;
_str = new char[_extern._capacity];
assert(_str != 0);
}
// Copy the string into the storage area
memmove(_str, str, len);
_str[len] = 0;
}
String::String(const String &str)
: _size(str._size) {
if (str.isStorageIntern()) {
// String in internal storage: just copy it
memcpy(_storage, str._storage, _builtinCapacity);
_str = _storage;
} else {
// String in external storage: use refcount mechanism
str.incRefCount();
_extern._refCount = str._extern._refCount;
_extern._capacity = str._extern._capacity;
_str = str._str;
}
assert(_str != 0);
}
String::String(char c)
: _size(0), _str(_storage) {
_storage[0] = c;
_storage[1] = 0;
_size = (c == 0) ? 0 : 1;
}
String::~String() {
decRefCount(_extern._refCount);
}
void String::makeUnique() {
ensureCapacity(_size, true);
}
/**
* Ensure that enough storage is available to store at least new_size
* characters plus a null byte. In addition, if we currently share
* the storage with another string, unshare it, so that we can safely
* write to the storage.
*/
void String::ensureCapacity(uint32 new_size, bool keep_old) {
bool isShared;
uint32 curCapacity, newCapacity;
char *newStorage;
int *oldRefCount = _extern._refCount;
if (isStorageIntern()) {
isShared = false;
curCapacity = _builtinCapacity;
} else {
isShared = (oldRefCount && *oldRefCount > 1);
curCapacity = _extern._capacity;
}
// Special case: If there is enough space, and we do not share
// the storage, then there is nothing to do.
if (!isShared && new_size < curCapacity)
return;
// We need to allocate storage on the heap!
// Compute a suitable new capacity limit
// If the current capacity is sufficient we use the same capacity
if (new_size < curCapacity)
newCapacity = curCapacity;
else
newCapacity = MAX(curCapacity * 2, computeCapacity(new_size+1));
// Allocate new storage
newStorage = new char[newCapacity];
assert(newStorage);
// Copy old data if needed, elsewise reset the new storage.
if (keep_old) {
assert(_size < newCapacity);
memcpy(newStorage, _str, _size + 1);
} else {
_size = 0;
newStorage[0] = 0;
}
// Release hold on the old storage ...
decRefCount(oldRefCount);
// ... in favor of the new storage
_str = newStorage;
if (!isStorageIntern()) {
// Set the ref count & capacity if we use an external storage.
// It is important to do this *after* copying any old content,
// else we would override data that has not yet been copied!
_extern._refCount = 0;
_extern._capacity = newCapacity;
}
}
void String::incRefCount() const {
assert(!isStorageIntern());
if (_extern._refCount == 0) {
if (g_refCountPool == 0) {
g_refCountPool = new MemoryPool(sizeof(int));
assert(g_refCountPool);
}
_extern._refCount = (int *)g_refCountPool->allocChunk();
*_extern._refCount = 2;
} else {
++(*_extern._refCount);
}
}
void String::decRefCount(int *oldRefCount) {
if (isStorageIntern())
return;
if (oldRefCount) {
--(*oldRefCount);
}
if (!oldRefCount || *oldRefCount <= 0) {
// The ref count reached zero, so we free the string storage
// and the ref count storage.
if (oldRefCount) {
assert(g_refCountPool);
g_refCountPool->freeChunk(oldRefCount);
}
delete[] _str;
// Even though _str points to a freed memory block now,
// we do not change its value, because any code that calls
// decRefCount will have to do this afterwards anyway.
}
}
String &String::operator=(const char *str) {
uint32 len = strlen(str);
ensureCapacity(len, false);
_size = len;
memmove(_str, str, len + 1);
return *this;
}
String &String::operator=(const String &str) {
if (&str == this)
return *this;
if (str.isStorageIntern()) {
decRefCount(_extern._refCount);
_size = str._size;
_str = _storage;
memcpy(_str, str._str, _size + 1);
} else {
str.incRefCount();
decRefCount(_extern._refCount);
_extern._refCount = str._extern._refCount;
_extern._capacity = str._extern._capacity;
_size = str._size;
_str = str._str;
}
return *this;
}
String &String::operator=(char c) {
decRefCount(_extern._refCount);
_str = _storage;
_str[0] = c;
_str[1] = 0;
_size = (c == 0) ? 0 : 1;
return *this;
}
String &String::operator+=(const char *str) {
if (_str <= str && str <= _str + _size)
return operator+=(String(str));
int len = strlen(str);
if (len > 0) {
ensureCapacity(_size + len, true);
memcpy(_str + _size, str, len + 1);
_size += len;
}
return *this;
}
String &String::operator+=(const String &str) {
if (&str == this)
return operator+=(String(str));
int len = str._size;
if (len > 0) {
ensureCapacity(_size + len, true);
memcpy(_str + _size, str._str, len + 1);
_size += len;
}
return *this;
}
String &String::operator+=(char c) {
ensureCapacity(_size + 1, true);
_str[_size++] = c;
_str[_size] = 0;
return *this;
}
bool String::hasPrefix(const String &x) const {
return hasPrefix(x.c_str());
}
bool String::hasPrefix(const char *x) const {
assert(x != 0);
// Compare x with the start of _str.
const char *y = c_str();
while (*x && *x == *y) {
++x;
++y;
}
// It's a prefix, if and only if all letters in x are 'used up' before
// _str ends.
return *x == 0;
}
bool String::hasSuffix(const String &x) const {
return hasSuffix(x.c_str());
}
bool String::hasSuffix(const char *x) const {
assert(x != 0);
// Compare x with the end of _str.
const uint32 x_size = strlen(x);
if (x_size > _size)
return false;
const char *y = c_str() + _size - x_size;
while (*x && *x == *y) {
++x;
++y;
}
// It's a suffix, if and only if all letters in x are 'used up' before
// _str ends.
return *x == 0;
}
bool String::contains(const String &x) const {
return strstr(c_str(), x.c_str()) != NULL;
}
bool String::contains(const char *x) const {
assert(x != 0);
return strstr(c_str(), x) != NULL;
}
bool String::contains(char x) const {
return strchr(c_str(), x) != NULL;
}
bool String::matchString(const char *pat, bool ignoreCase, bool pathMode) const {
return Common::matchString(c_str(), pat, ignoreCase, pathMode);
}
bool String::matchString(const String &pat, bool ignoreCase, bool pathMode) const {
return Common::matchString(c_str(), pat.c_str(), ignoreCase, pathMode);
}
void String::deleteLastChar() {
if (_size > 0)
deleteChar(_size - 1);
}
void String::deleteChar(uint32 p) {
assert(p < _size);
makeUnique();
while (p++ < _size)
_str[p - 1] = _str[p];
_size--;
}
void String::erase(uint32 p, uint32 len) {
assert(p < _size);
makeUnique();
// If len == npos or p + len is over the end, remove all the way to the end
if (len == npos || p + len >= _size) {
// Delete char at p as well. So _size = (p - 1) + 1
_size = p;
// Null terminate
_str[_size] = 0;
return;
}
for ( ; p + len <= _size; p++) {
_str[p] = _str[p + len];
}
_size -= len;
}
void String::clear() {
decRefCount(_extern._refCount);
_size = 0;
_str = _storage;
_storage[0] = 0;
}
void String::setChar(char c, uint32 p) {
assert(p < _size);
makeUnique();
_str[p] = c;
}
void String::insertChar(char c, uint32 p) {
assert(p <= _size);
ensureCapacity(_size + 1, true);
_size++;
for (uint32 i = _size; i > p; --i)
_str[i] = _str[i - 1];
_str[p] = c;
}
void String::toLowercase() {
makeUnique();
for (uint32 i = 0; i < _size; ++i)
_str[i] = tolower(_str[i]);
}
void String::toUppercase() {
makeUnique();
for (uint32 i = 0; i < _size; ++i)
_str[i] = toupper(_str[i]);
}
void String::trim() {
if (_size == 0)
return;
makeUnique();
// Trim trailing whitespace
while (_size >= 1 && isSpace(_str[_size - 1]))
--_size;
_str[_size] = 0;
// Trim leading whitespace
char *t = _str;
while (isSpace(*t))
t++;
if (t != _str) {
_size -= t - _str;
memmove(_str, t, _size + 1);
}
}
uint String::hash() const {
return hashit(c_str());
}
void String::replace(uint32 pos, uint32 count, const String &str) {
replace(pos, count, str, 0, str._size);
}
void String::replace(uint32 pos, uint32 count, const char *str) {
replace(pos, count, str, 0, strlen(str));
}
void String::replace(iterator begin_, iterator end_, const String &str) {
replace(begin_ - _str, end_ - begin_, str._str, 0, str._size);
}
void String::replace(iterator begin_, iterator end_, const char *str) {
replace(begin_ - _str, end_ - begin_, str, 0, strlen(str));
}
void String::replace(uint32 posOri, uint32 countOri, const String &str,
uint32 posDest, uint32 countDest) {
replace(posOri, countOri, str._str, posDest, countDest);
}
void String::replace(uint32 posOri, uint32 countOri, const char *str,
uint32 posDest, uint32 countDest) {
ensureCapacity(_size + countDest - countOri, true);
// Prepare string for the replaced text.
if (countOri < countDest) {
uint32 offset = countDest - countOri; ///< Offset to copy the characters
uint32 newSize = _size + offset;
_size = newSize;
// Push the old characters to the end of the string
for (uint32 i = _size; i >= posOri + countDest; i--)
_str[i] = _str[i - offset];
} else if (countOri > countDest){
uint32 offset = countOri - countDest; ///< Number of positions that we have to pull back
// Pull the remainder string back
for (uint32 i = posOri + countDest; i < _size; i++)
_str[i] = _str[i + offset];
_size -= offset;
}
// Copy the replaced part of the string
for (uint32 i = 0; i < countDest; i++)
_str[posOri + i] = str[posDest + i];
}
// static
String String::format(const char *fmt, ...) {
String output;
va_list va;
va_start(va, fmt);
output = String::vformat(fmt, va);
va_end(va);
return output;
}
// static
String String::vformat(const char *fmt, va_list args) {
String output;
assert(output.isStorageIntern());
va_list va;
scumm_va_copy(va, args);
int len = vsnprintf(output._str, _builtinCapacity, fmt, va);
va_end(va);
if (len == -1 || len == _builtinCapacity - 1) {
// MSVC and IRIX don't return the size the full string would take up.
// MSVC returns -1, IRIX returns the number of characters actually written,
// which is at the most the size of the buffer minus one, as the string is
// truncated to fit.
// We assume MSVC failed to output the correct, null-terminated string
// if the return value is either -1 or size.
// For IRIX, because we lack a better mechanism, we assume failure
// if the return value equals size - 1.
// The downside to this is that whenever we try to format a string where the
// size is 1 below the built-in capacity, the size is needlessly increased.
// Try increasing the size of the string until it fits.
int size = _builtinCapacity;
do {
size *= 2;
output.ensureCapacity(size - 1, false);
assert(!output.isStorageIntern());
size = output._extern._capacity;
scumm_va_copy(va, args);
len = vsnprintf(output._str, size, fmt, va);
va_end(va);
} while (len == -1 || len >= size - 1);
output._size = len;
} else if (len < (int)_builtinCapacity) {
// vsnprintf succeeded
output._size = len;
} else {
// vsnprintf didn't have enough space, so grow buffer
output.ensureCapacity(len, false);
scumm_va_copy(va, args);
int len2 = vsnprintf(output._str, len+1, fmt, va);
va_end(va);
assert(len == len2);
output._size = len2;
}
return output;
}
#pragma mark -
bool String::operator==(const String &x) const {
return equals(x);
}
bool String::operator==(const char *x) const {
assert(x != 0);
return equals(x);
}
bool String::operator!=(const String &x) const {
return !equals(x);
}
bool String::operator !=(const char *x) const {
assert(x != 0);
return !equals(x);
}
bool String::operator<(const String &x) const {
return compareTo(x) < 0;
}
bool String::operator<=(const String &x) const {
return compareTo(x) <= 0;
}
bool String::operator>(const String &x) const {
return compareTo(x) > 0;
}
bool String::operator>=(const String &x) const {
return compareTo(x) >= 0;
}
#pragma mark -
bool operator==(const char* y, const String &x) {
return (x == y);
}
bool operator!=(const char* y, const String &x) {
return x != y;
}
#pragma mark -
bool String::equals(const String &x) const {
return (0 == compareTo(x));
}
bool String::equals(const char *x) const {
assert(x != 0);
return (0 == compareTo(x));
}
bool String::equalsIgnoreCase(const String &x) const {
return (0 == compareToIgnoreCase(x));
}
bool String::equalsIgnoreCase(const char *x) const {
assert(x != 0);
return (0 == compareToIgnoreCase(x));
}
int String::compareTo(const String &x) const {
return compareTo(x.c_str());
}
int String::compareTo(const char *x) const {
assert(x != 0);
return strcmp(c_str(), x);
}
int String::compareToIgnoreCase(const String &x) const {
return compareToIgnoreCase(x.c_str());
}
int String::compareToIgnoreCase(const char *x) const {
assert(x != 0);
return scumm_stricmp(c_str(), x);
}
#pragma mark -
String operator+(const String &x, const String &y) {
String temp(x);
temp += y;
return temp;
}
String operator+(const char *x, const String &y) {
String temp(x);
temp += y;
return temp;
}
String operator+(const String &x, const char *y) {
String temp(x);
temp += y;
return temp;
}
String operator+(char x, const String &y) {
String temp(x);
temp += y;
return temp;
}
String operator+(const String &x, char y) {
String temp(x);
temp += y;
return temp;
}
char *ltrim(char *t) {
while (isSpace(*t))
t++;
return t;
}
char *rtrim(char *t) {
int l = strlen(t) - 1;
while (l >= 0 && isSpace(t[l]))
t[l--] = 0;
return t;
}
char *trim(char *t) {
return rtrim(ltrim(t));
}
String lastPathComponent(const String &path, const char sep) {
const char *str = path.c_str();
const char *last = str + path.size();
// Skip over trailing slashes
while (last > str && *(last-1) == sep)
--last;
// Path consisted of only slashes -> return empty string
if (last == str)
return String();
// Now scan the whole component
const char *first = last - 1;
while (first > str && *first != sep)
--first;
if (*first == sep)
first++;
return String(first, last);
}
String normalizePath(const String &path, const char sep) {
if (path.empty())
return path;
const char *cur = path.c_str();
String result;
// If there is a leading slash, preserve that:
if (*cur == sep) {
result += sep;
// Skip over multiple leading slashes, so "//" equals "/"
while (*cur == sep)
++cur;
}
// Scan for path components till the end of the String
List<String> comps;
while (*cur != 0) {
const char *start = cur;
// Scan till the next path separator resp. the end of the string
while (*cur != sep && *cur != 0)
cur++;
const String component(start, cur);
if (component.empty() || component == ".") {
// Skip empty components and dot components
} else if (!comps.empty() && component == ".." && comps.back() != "..") {
// If stack is non-empty and top is not "..", remove top
comps.pop_back();
} else {
// Add the component to the stack
comps.push_back(component);
}
// Skip over separator chars
while (*cur == sep)
cur++;
}
// Finally, assemble all components back into a path
while (!comps.empty()) {
result += comps.front();
comps.pop_front();
if (!comps.empty())
result += sep;
}
return result;
}
bool matchString(const char *str, const char *pat, bool ignoreCase, bool pathMode) {
assert(str);
assert(pat);
const char *p = 0;
const char *q = 0;
for (;;) {
if (pathMode && *str == '/') {
p = 0;
q = 0;
if (*pat == '?')
return false;
}
switch (*pat) {
case '*':
if (*str) {
// Record pattern / string position for backtracking
p = ++pat;
q = str;
} else {
// If we've reached the end of str, we can't backtrack further
// NB: We can't simply check if pat also ended here, because
// the pattern might end with any number of *s.
++pat;
p = 0;
q = 0;
}
// If pattern ended with * -> match
if (!*pat)
return true;
break;
case '#':
if (!isDigit(*str))
return false;
pat++;
str++;
break;
default:
if ((!ignoreCase && *pat != *str) ||
(ignoreCase && tolower(*pat) != tolower(*str))) {
if (p) {
// No match, oops -> try to backtrack
pat = p;
str = ++q;
if (!*str)
return !*pat;
break;
}
else
return false;
}
// fallthrough
case '?':
if (!*str)
return !*pat;
pat++;
str++;
}
}
}
String tag2string(uint32 tag) {
char str[5];
str[0] = (char)(tag >> 24);
str[1] = (char)(tag >> 16);
str[2] = (char)(tag >> 8);
str[3] = (char)tag;
str[4] = '\0';
// Replace non-printable chars by dot
for (int i = 0; i < 4; ++i) {
if (!Common::isPrint(str[i]))
str[i] = '.';
}
return String(str);
}
size_t strlcpy(char *dst, const char *src, size_t size) {
// Our backup of the source's start, we need this
// to calculate the source's length.
const char * const srcStart = src;
// In case a non-empty size was specified we
// copy over (size - 1) bytes at max.
if (size != 0) {
// Copy over (size - 1) bytes at max.
while (--size != 0) {
if ((*dst++ = *src) == 0)
break;
++src;
}
// In case the source string was longer than the
// destination, we need to add a terminating
// zero.
if (size == 0)
*dst = 0;
}
// Move to the terminating zero of the source
// string, we need this to determine the length
// of the source string.
while (*src)
++src;
// Return the source string's length.
return src - srcStart;
}
size_t strlcat(char *dst, const char *src, size_t size) {
// In case the destination buffer does not contain
// space for at least 1 character, we will just
// return the source string's length.
if (size == 0)
return strlen(src);
// Our backup of the source's start, we need this
// to calculate the source's length.
const char * const srcStart = src;
// Our backup of the destination's start, we need
// this to calculate the destination's length.
const char * const dstStart = dst;
// Search the end of the destination, but do not
// move past the terminating zero.
while (size-- != 0 && *dst != 0)
++dst;
// Calculate the destination's length;
const size_t dstLength = dst - dstStart;
// In case we reached the end of the destination
// buffer before we had a chance to append any
// characters we will just return the destination
// length plus the source string's length.
if (size == 0)
return dstLength + strlen(srcStart);
// Copy over all of the source that fits
// the destination buffer. We also need
// to take the terminating zero we will
// add into consideration.
while (size-- != 0 && *src != 0)
*dst++ = *src++;
*dst = 0;
// Move to the terminating zero of the source
// string, we need this to determine the length
// of the source string.
while (*src)
++src;
// Return the total length of the result string
return dstLength + (src - srcStart);
}
} // End of namespace Common
// Portable implementation of stricmp / strcasecmp / strcmpi.
// TODO: Rename this to Common::strcasecmp
int scumm_stricmp(const char *s1, const char *s2) {
byte l1, l2;
do {
// Don't use ++ inside tolower, in case the macro uses its
// arguments more than once.
l1 = (byte)*s1++;
l1 = tolower(l1);
l2 = (byte)*s2++;
l2 = tolower(l2);
} while (l1 == l2 && l1 != 0);
return l1 - l2;
}
// Portable implementation of strnicmp / strncasecmp / strncmpi.
// TODO: Rename this to Common::strncasecmp
int scumm_strnicmp(const char *s1, const char *s2, uint n) {
byte l1, l2;
do {
if (n-- == 0)
return 0; // no difference found so far -> signal equality
// Don't use ++ inside tolower, in case the macro uses its
// arguments more than once.
l1 = (byte)*s1++;
l1 = tolower(l1);
l2 = (byte)*s2++;
l2 = tolower(l2);
} while (l1 == l2 && l1 != 0);
return l1 - l2;
}
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