platform_system_core/libutils/String8.cpp

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/*
* Copyright (C) 2005 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#define __STDC_LIMIT_MACROS
#include <stdint.h>
#include <utils/String8.h>
#include <utils/Compat.h>
#include <utils/Log.h>
#include <utils/Unicode.h>
#include <utils/String16.h>
#include <utils/threads.h>
#include <ctype.h>
#include "SharedBuffer.h"
/*
* Functions outside android is below the namespace android, since they use
* functions and constants in android namespace.
*/
// ---------------------------------------------------------------------------
namespace android {
// Separator used by resource paths. This is not platform dependent contrary
// to OS_PATH_SEPARATOR.
#define RES_PATH_SEPARATOR '/'
static SharedBuffer* gEmptyStringBuf = NULL;
static char* gEmptyString = NULL;
extern int gDarwinCantLoadAllObjects;
int gDarwinIsReallyAnnoying;
void initialize_string8();
static inline char* getEmptyString()
{
gEmptyStringBuf->acquire();
return gEmptyString;
}
void initialize_string8()
{
// HACK: This dummy dependency forces linking libutils Static.cpp,
// which is needed to initialize String8/String16 classes.
// These variables are named for Darwin, but are needed elsewhere too,
// including static linking on any platform.
gDarwinIsReallyAnnoying = gDarwinCantLoadAllObjects;
SharedBuffer* buf = SharedBuffer::alloc(1);
char* str = (char*)buf->data();
*str = 0;
gEmptyStringBuf = buf;
gEmptyString = str;
}
void terminate_string8()
{
SharedBuffer::bufferFromData(gEmptyString)->release();
gEmptyStringBuf = NULL;
gEmptyString = NULL;
}
// ---------------------------------------------------------------------------
static char* allocFromUTF8(const char* in, size_t len)
{
if (len > 0) {
if (len == SIZE_MAX) {
return NULL;
}
SharedBuffer* buf = SharedBuffer::alloc(len+1);
ALOG_ASSERT(buf, "Unable to allocate shared buffer");
if (buf) {
char* str = (char*)buf->data();
memcpy(str, in, len);
str[len] = 0;
return str;
}
return NULL;
}
return getEmptyString();
}
static char* allocFromUTF16(const char16_t* in, size_t len)
{
if (len == 0) return getEmptyString();
const ssize_t bytes = utf16_to_utf8_length(in, len);
if (bytes < 0) {
return getEmptyString();
}
SharedBuffer* buf = SharedBuffer::alloc(bytes+1);
ALOG_ASSERT(buf, "Unable to allocate shared buffer");
if (!buf) {
return getEmptyString();
}
char* str = (char*)buf->data();
utf16_to_utf8(in, len, str);
return str;
}
static char* allocFromUTF32(const char32_t* in, size_t len)
{
if (len == 0) {
return getEmptyString();
}
const ssize_t bytes = utf32_to_utf8_length(in, len);
if (bytes < 0) {
return getEmptyString();
}
SharedBuffer* buf = SharedBuffer::alloc(bytes+1);
ALOG_ASSERT(buf, "Unable to allocate shared buffer");
if (!buf) {
return getEmptyString();
}
char* str = (char*) buf->data();
utf32_to_utf8(in, len, str);
return str;
}
// ---------------------------------------------------------------------------
String8::String8()
: mString(getEmptyString())
{
}
String8::String8(StaticLinkage)
: mString(0)
{
// this constructor is used when we can't rely on the static-initializers
// having run. In this case we always allocate an empty string. It's less
// efficient than using getEmptyString(), but we assume it's uncommon.
char* data = static_cast<char*>(
SharedBuffer::alloc(sizeof(char))->data());
data[0] = 0;
mString = data;
}
String8::String8(const String8& o)
: mString(o.mString)
{
SharedBuffer::bufferFromData(mString)->acquire();
}
String8::String8(const char* o)
: mString(allocFromUTF8(o, strlen(o)))
{
if (mString == NULL) {
mString = getEmptyString();
}
}
String8::String8(const char* o, size_t len)
: mString(allocFromUTF8(o, len))
{
if (mString == NULL) {
mString = getEmptyString();
}
}
String8::String8(const String16& o)
: mString(allocFromUTF16(o.string(), o.size()))
{
}
String8::String8(const char16_t* o)
: mString(allocFromUTF16(o, strlen16(o)))
{
}
String8::String8(const char16_t* o, size_t len)
: mString(allocFromUTF16(o, len))
{
}
String8::String8(const char32_t* o)
: mString(allocFromUTF32(o, strlen32(o)))
{
}
String8::String8(const char32_t* o, size_t len)
: mString(allocFromUTF32(o, len))
{
}
String8::~String8()
{
SharedBuffer::bufferFromData(mString)->release();
}
size_t String8::length() const
{
return SharedBuffer::sizeFromData(mString)-1;
}
String8 String8::format(const char* fmt, ...)
{
va_list args;
va_start(args, fmt);
String8 result(formatV(fmt, args));
va_end(args);
return result;
}
String8 String8::formatV(const char* fmt, va_list args)
{
String8 result;
result.appendFormatV(fmt, args);
return result;
}
Add keycodes and meta-key modifiers to support external keyboards. Added new key maps for external keyboards. These maps are intended to be shared across devices by inheriting the "keyboards.mk" product makefile as part of the device's product definition. One of the trickier changes here was to unwind some code in MetaKeyKeyListener that assumed that only the low 8 bits of the meta key state were actually used. The new code abandons bitshifts in favor of simple conditionals that are probably easier to read anyways. The special meta key state constants used by MetaKeyKeyListener are now (@hide) defined in KeyEvent now so as to make it clearer that they share the same code space even if those codes are not valid for KeyEvents. The EventHub now takes care of detecting the appropriate key layout map and key character map when the device is added and sets system properties accordingly. This avoids having duplicate code in KeyCharacterMap to probe for the appropriate key character map although the current probing mechanism has been preserved for legacy reasons just in case. Added support for tracking caps lock, num lock and scroll lock and turning their corresponding LEDs on and off as needed. The key character map format will need to be updated to correctly support PC style external keyboard semantics related to modifier keys. That will come in a later change so caps lock doesn't actually do anything right now except turn the shiny LEDs on and off... Added a list of symbolic key names to KeyEvent and improved the toString() output for debug diagnosis. Having this list in a central place in the framework also allows us to remove it from Monkey so there is one less thing to maintain when we add new keycodes. Bug: 2912307 Change-Id: If8c25e8d50a7c29bbf5d663c94284f5f86de5da4
2010-09-13 02:55:08 +02:00
void String8::clear() {
SharedBuffer::bufferFromData(mString)->release();
mString = getEmptyString();
}
void String8::setTo(const String8& other)
{
SharedBuffer::bufferFromData(other.mString)->acquire();
SharedBuffer::bufferFromData(mString)->release();
mString = other.mString;
}
status_t String8::setTo(const char* other)
{
const char *newString = allocFromUTF8(other, strlen(other));
SharedBuffer::bufferFromData(mString)->release();
mString = newString;
if (mString) return NO_ERROR;
mString = getEmptyString();
return NO_MEMORY;
}
status_t String8::setTo(const char* other, size_t len)
{
const char *newString = allocFromUTF8(other, len);
SharedBuffer::bufferFromData(mString)->release();
mString = newString;
if (mString) return NO_ERROR;
mString = getEmptyString();
return NO_MEMORY;
}
status_t String8::setTo(const char16_t* other, size_t len)
{
const char *newString = allocFromUTF16(other, len);
SharedBuffer::bufferFromData(mString)->release();
mString = newString;
if (mString) return NO_ERROR;
mString = getEmptyString();
return NO_MEMORY;
}
status_t String8::setTo(const char32_t* other, size_t len)
{
const char *newString = allocFromUTF32(other, len);
SharedBuffer::bufferFromData(mString)->release();
mString = newString;
if (mString) return NO_ERROR;
mString = getEmptyString();
return NO_MEMORY;
}
status_t String8::append(const String8& other)
{
const size_t otherLen = other.bytes();
if (bytes() == 0) {
setTo(other);
return NO_ERROR;
} else if (otherLen == 0) {
return NO_ERROR;
}
return real_append(other.string(), otherLen);
}
status_t String8::append(const char* other)
{
return append(other, strlen(other));
}
status_t String8::append(const char* other, size_t otherLen)
{
if (bytes() == 0) {
return setTo(other, otherLen);
} else if (otherLen == 0) {
return NO_ERROR;
}
return real_append(other, otherLen);
}
status_t String8::appendFormat(const char* fmt, ...)
{
Added support for full PC-style keyboards. BREAKING CHANGE: Redesigned the key character map format to accomodate full keyboards with more comprehensive suite of modifiers. Old key character maps will not work anymore and must be updated. The new format is plain text only and it not compiled to a binary file (so the "kcm" tool will be removed in a subsequent check-in). Added FULL keyboard type to support full PC-style keyboards. Added SPECIAL_FUNCTION keyboard type to support special function keypads that do not have any printable keys suitable for typing and only have keys like HOME and POWER Added a special VIRTUAL_KEYBOARD device id convention that maps to a virtual keyboard with a fixed known layout. This is designed to work around issues injecting input events on devices whose built-in keyboard does not have a useful key character map (ie. when the built-in keyboard is a special function keyboard only.) Modified several places where events were being synthesized to use the virtual keyboard. Removed support for the "qwerty" default layout. The new default layout is "Generic". For the most part "qwerty" was being used as a backstop in case the built-in keyboard did not have a key character map (probably because it was a special function keypad) and the framework needed to be able to inject key events anyways. The latter issue is resolved by using the special VIRTUAL_KEYBOARD device instead of BUILT_IN_KEYBOARD. Added the concept of a key modifier behavior so that MetaKeyKeyListener can distinguish between keyboards that use chorded vs. toggled modifiers. Wrote more robust key layout and key character map parsers to enable support for new keyboard features and user installable key maps. Fixed a bug in InputReader generating key ups when keys are released out of sequence. Updated tons of documentation. Currently QwertyKeyListener is being used for full keyboards with autotext and capitalization disabled. This mostly works but causes some problems with character pickers, etc. These issues will be resolved in subsequent changes. Change-Id: Ica48f6097a551141c215bc0d2c6f7b3fb634d354
2010-11-11 01:03:06 +01:00
va_list args;
va_start(args, fmt);
Added support for full PC-style keyboards. BREAKING CHANGE: Redesigned the key character map format to accomodate full keyboards with more comprehensive suite of modifiers. Old key character maps will not work anymore and must be updated. The new format is plain text only and it not compiled to a binary file (so the "kcm" tool will be removed in a subsequent check-in). Added FULL keyboard type to support full PC-style keyboards. Added SPECIAL_FUNCTION keyboard type to support special function keypads that do not have any printable keys suitable for typing and only have keys like HOME and POWER Added a special VIRTUAL_KEYBOARD device id convention that maps to a virtual keyboard with a fixed known layout. This is designed to work around issues injecting input events on devices whose built-in keyboard does not have a useful key character map (ie. when the built-in keyboard is a special function keyboard only.) Modified several places where events were being synthesized to use the virtual keyboard. Removed support for the "qwerty" default layout. The new default layout is "Generic". For the most part "qwerty" was being used as a backstop in case the built-in keyboard did not have a key character map (probably because it was a special function keypad) and the framework needed to be able to inject key events anyways. The latter issue is resolved by using the special VIRTUAL_KEYBOARD device instead of BUILT_IN_KEYBOARD. Added the concept of a key modifier behavior so that MetaKeyKeyListener can distinguish between keyboards that use chorded vs. toggled modifiers. Wrote more robust key layout and key character map parsers to enable support for new keyboard features and user installable key maps. Fixed a bug in InputReader generating key ups when keys are released out of sequence. Updated tons of documentation. Currently QwertyKeyListener is being used for full keyboards with autotext and capitalization disabled. This mostly works but causes some problems with character pickers, etc. These issues will be resolved in subsequent changes. Change-Id: Ica48f6097a551141c215bc0d2c6f7b3fb634d354
2010-11-11 01:03:06 +01:00
status_t result = appendFormatV(fmt, args);
va_end(args);
return result;
}
status_t String8::appendFormatV(const char* fmt, va_list args)
{
int n, result = NO_ERROR;
va_list tmp_args;
/* args is undefined after vsnprintf.
* So we need a copy here to avoid the
* second vsnprintf access undefined args.
*/
va_copy(tmp_args, args);
n = vsnprintf(NULL, 0, fmt, tmp_args);
va_end(tmp_args);
if (n != 0) {
size_t oldLength = length();
char* buf = lockBuffer(oldLength + n);
if (buf) {
Added support for full PC-style keyboards. BREAKING CHANGE: Redesigned the key character map format to accomodate full keyboards with more comprehensive suite of modifiers. Old key character maps will not work anymore and must be updated. The new format is plain text only and it not compiled to a binary file (so the "kcm" tool will be removed in a subsequent check-in). Added FULL keyboard type to support full PC-style keyboards. Added SPECIAL_FUNCTION keyboard type to support special function keypads that do not have any printable keys suitable for typing and only have keys like HOME and POWER Added a special VIRTUAL_KEYBOARD device id convention that maps to a virtual keyboard with a fixed known layout. This is designed to work around issues injecting input events on devices whose built-in keyboard does not have a useful key character map (ie. when the built-in keyboard is a special function keyboard only.) Modified several places where events were being synthesized to use the virtual keyboard. Removed support for the "qwerty" default layout. The new default layout is "Generic". For the most part "qwerty" was being used as a backstop in case the built-in keyboard did not have a key character map (probably because it was a special function keypad) and the framework needed to be able to inject key events anyways. The latter issue is resolved by using the special VIRTUAL_KEYBOARD device instead of BUILT_IN_KEYBOARD. Added the concept of a key modifier behavior so that MetaKeyKeyListener can distinguish between keyboards that use chorded vs. toggled modifiers. Wrote more robust key layout and key character map parsers to enable support for new keyboard features and user installable key maps. Fixed a bug in InputReader generating key ups when keys are released out of sequence. Updated tons of documentation. Currently QwertyKeyListener is being used for full keyboards with autotext and capitalization disabled. This mostly works but causes some problems with character pickers, etc. These issues will be resolved in subsequent changes. Change-Id: Ica48f6097a551141c215bc0d2c6f7b3fb634d354
2010-11-11 01:03:06 +01:00
vsnprintf(buf + oldLength, n + 1, fmt, args);
} else {
result = NO_MEMORY;
}
}
return result;
}
status_t String8::real_append(const char* other, size_t otherLen)
{
const size_t myLen = bytes();
SharedBuffer* buf = SharedBuffer::bufferFromData(mString)
->editResize(myLen+otherLen+1);
if (buf) {
char* str = (char*)buf->data();
mString = str;
str += myLen;
memcpy(str, other, otherLen);
str[otherLen] = '\0';
return NO_ERROR;
}
return NO_MEMORY;
}
char* String8::lockBuffer(size_t size)
{
SharedBuffer* buf = SharedBuffer::bufferFromData(mString)
->editResize(size+1);
if (buf) {
char* str = (char*)buf->data();
mString = str;
return str;
}
return NULL;
}
void String8::unlockBuffer()
{
unlockBuffer(strlen(mString));
}
status_t String8::unlockBuffer(size_t size)
{
if (size != this->size()) {
SharedBuffer* buf = SharedBuffer::bufferFromData(mString)
->editResize(size+1);
if (! buf) {
return NO_MEMORY;
}
char* str = (char*)buf->data();
str[size] = 0;
mString = str;
}
return NO_ERROR;
}
ssize_t String8::find(const char* other, size_t start) const
{
size_t len = size();
if (start >= len) {
return -1;
}
const char* s = mString+start;
const char* p = strstr(s, other);
return p ? p-mString : -1;
}
bool String8::removeAll(const char* other) {
ssize_t index = find(other);
if (index < 0) return false;
char* buf = lockBuffer(size());
if (!buf) return false; // out of memory
size_t skip = strlen(other);
size_t len = size();
size_t tail = index;
while (size_t(index) < len) {
ssize_t next = find(other, index + skip);
if (next < 0) {
next = len;
}
memmove(buf + tail, buf + index + skip, next - index - skip);
tail += next - index - skip;
index = next;
}
unlockBuffer(tail);
return true;
}
void String8::toLower()
{
toLower(0, size());
}
void String8::toLower(size_t start, size_t length)
{
const size_t len = size();
if (start >= len) {
return;
}
if (start+length > len) {
length = len-start;
}
char* buf = lockBuffer(len);
buf += start;
while (length > 0) {
*buf = tolower(*buf);
buf++;
length--;
}
unlockBuffer(len);
}
void String8::toUpper()
{
toUpper(0, size());
}
void String8::toUpper(size_t start, size_t length)
{
const size_t len = size();
if (start >= len) {
return;
}
if (start+length > len) {
length = len-start;
}
char* buf = lockBuffer(len);
buf += start;
while (length > 0) {
*buf = toupper(*buf);
buf++;
length--;
}
unlockBuffer(len);
}
size_t String8::getUtf32Length() const
{
return utf8_to_utf32_length(mString, length());
}
int32_t String8::getUtf32At(size_t index, size_t *next_index) const
{
return utf32_from_utf8_at(mString, length(), index, next_index);
}
void String8::getUtf32(char32_t* dst) const
{
utf8_to_utf32(mString, length(), dst);
}
// ---------------------------------------------------------------------------
// Path functions
void String8::setPathName(const char* name)
{
setPathName(name, strlen(name));
}
void String8::setPathName(const char* name, size_t len)
{
char* buf = lockBuffer(len);
memcpy(buf, name, len);
// remove trailing path separator, if present
if (len > 0 && buf[len-1] == OS_PATH_SEPARATOR)
len--;
buf[len] = '\0';
unlockBuffer(len);
}
String8 String8::getPathLeaf(void) const
{
const char* cp;
const char*const buf = mString;
cp = strrchr(buf, OS_PATH_SEPARATOR);
if (cp == NULL)
return String8(*this);
else
return String8(cp+1);
}
String8 String8::getPathDir(void) const
{
const char* cp;
const char*const str = mString;
cp = strrchr(str, OS_PATH_SEPARATOR);
if (cp == NULL)
return String8("");
else
return String8(str, cp - str);
}
String8 String8::walkPath(String8* outRemains) const
{
const char* cp;
const char*const str = mString;
const char* buf = str;
cp = strchr(buf, OS_PATH_SEPARATOR);
if (cp == buf) {
// don't include a leading '/'.
buf = buf+1;
cp = strchr(buf, OS_PATH_SEPARATOR);
}
if (cp == NULL) {
String8 res = buf != str ? String8(buf) : *this;
if (outRemains) *outRemains = String8("");
return res;
}
String8 res(buf, cp-buf);
if (outRemains) *outRemains = String8(cp+1);
return res;
}
/*
* Helper function for finding the start of an extension in a pathname.
*
* Returns a pointer inside mString, or NULL if no extension was found.
*/
char* String8::find_extension(void) const
{
const char* lastSlash;
const char* lastDot;
const char* const str = mString;
// only look at the filename
lastSlash = strrchr(str, OS_PATH_SEPARATOR);
if (lastSlash == NULL)
lastSlash = str;
else
lastSlash++;
// find the last dot
lastDot = strrchr(lastSlash, '.');
if (lastDot == NULL)
return NULL;
// looks good, ship it
return const_cast<char*>(lastDot);
}
String8 String8::getPathExtension(void) const
{
char* ext;
ext = find_extension();
if (ext != NULL)
return String8(ext);
else
return String8("");
}
String8 String8::getBasePath(void) const
{
char* ext;
const char* const str = mString;
ext = find_extension();
if (ext == NULL)
return String8(*this);
else
return String8(str, ext - str);
}
String8& String8::appendPath(const char* name)
{
// TODO: The test below will fail for Win32 paths. Fix later or ignore.
if (name[0] != OS_PATH_SEPARATOR) {
if (*name == '\0') {
// nothing to do
return *this;
}
size_t len = length();
if (len == 0) {
// no existing filename, just use the new one
setPathName(name);
return *this;
}
// make room for oldPath + '/' + newPath
int newlen = strlen(name);
char* buf = lockBuffer(len+1+newlen);
// insert a '/' if needed
if (buf[len-1] != OS_PATH_SEPARATOR)
buf[len++] = OS_PATH_SEPARATOR;
memcpy(buf+len, name, newlen+1);
len += newlen;
unlockBuffer(len);
return *this;
} else {
setPathName(name);
return *this;
}
}
String8& String8::convertToResPath()
{
#if OS_PATH_SEPARATOR != RES_PATH_SEPARATOR
size_t len = length();
if (len > 0) {
char * buf = lockBuffer(len);
for (char * end = buf + len; buf < end; ++buf) {
if (*buf == OS_PATH_SEPARATOR)
*buf = RES_PATH_SEPARATOR;
}
unlockBuffer(len);
}
#endif
return *this;
}
}; // namespace android