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//
// Copyright 2006 The Android Open Source Project
//
// Build resource files from raw assets.
//
#include "StringPool.h"
#include <utils/ByteOrder.h>
#include <utils/SortedVector.h>
#include <algorithm>
#include "ResourceTable.h"
// Set to true for noisy debug output.
static const bool kIsDebug = false;
#if __cplusplus >= 201103L
void strcpy16_htod(char16_t* dst, const char16_t* src)
{
while (*src) {
char16_t s = htods(*src);
*dst++ = s;
src++;
}
*dst = 0;
}
#endif
void strcpy16_htod(uint16_t* dst, const char16_t* src)
{
while (*src) {
uint16_t s = htods(static_cast<uint16_t>(*src));
*dst++ = s;
src++;
}
*dst = 0;
}
void printStringPool(const ResStringPool* pool)
{
if (pool->getError() == NO_INIT) {
printf("String pool is unitialized.\n");
return;
} else if (pool->getError() != NO_ERROR) {
printf("String pool is corrupt/invalid.\n");
return;
}
SortedVector<const void*> uniqueStrings;
const size_t N = pool->size();
for (size_t i=0; i<N; i++) {
size_t len;
if (pool->isUTF8()) {
uniqueStrings.add(pool->string8At(i, &len));
} else {
uniqueStrings.add(pool->stringAt(i, &len));
}
}
printf("String pool of " ZD " unique %s %s strings, " ZD " entries and "
ZD " styles using " ZD " bytes:\n",
(ZD_TYPE)uniqueStrings.size(), pool->isUTF8() ? "UTF-8" : "UTF-16",
pool->isSorted() ? "sorted" : "non-sorted",
(ZD_TYPE)N, (ZD_TYPE)pool->styleCount(), (ZD_TYPE)pool->bytes());
const size_t NS = pool->size();
for (size_t s=0; s<NS; s++) {
String8 str = pool->string8ObjectAt(s);
printf("String #" ZD ": %s\n", (ZD_TYPE) s, str.string());
}
}
String8 StringPool::entry::makeConfigsString() const {
String8 configStr(configTypeName);
if (configStr.size() > 0) configStr.append(" ");
if (configs.size() > 0) {
for (size_t j=0; j<configs.size(); j++) {
if (j > 0) configStr.append(", ");
configStr.append(configs[j].toString());
}
} else {
configStr = "(none)";
}
return configStr;
}
int StringPool::entry::compare(const entry& o) const {
// Strings with styles go first, to reduce the size of the styles array.
// We don't care about the relative order of these strings.
if (hasStyles) {
return o.hasStyles ? 0 : -1;
}
if (o.hasStyles) {
return 1;
}
// Sort unstyled strings by type, then by logical configuration.
int comp = configTypeName.compare(o.configTypeName);
if (comp != 0) {
return comp;
}
const size_t LHN = configs.size();
const size_t RHN = o.configs.size();
size_t i=0;
while (i < LHN && i < RHN) {
comp = configs[i].compareLogical(o.configs[i]);
if (comp != 0) {
return comp;
}
i++;
}
if (LHN < RHN) return -1;
else if (LHN > RHN) return 1;
return 0;
}
StringPool::StringPool(bool utf8) :
mUTF8(utf8), mValues(-1)
{
}
ssize_t StringPool::add(const String16& value, const Vector<entry_style_span>& spans,
const String8* configTypeName, const ResTable_config* config)
{
ssize_t res = add(value, false, configTypeName, config);
if (res >= 0) {
addStyleSpans(res, spans);
}
return res;
}
ssize_t StringPool::add(const String16& value,
bool mergeDuplicates, const String8* configTypeName, const ResTable_config* config)
{
ssize_t vidx = mValues.indexOfKey(value);
ssize_t pos = vidx >= 0 ? mValues.valueAt(vidx) : -1;
ssize_t eidx = pos >= 0 ? mEntryArray.itemAt(pos) : -1;
if (eidx < 0) {
eidx = mEntries.add(entry(value));
if (eidx < 0) {
fprintf(stderr, "Failure adding string %s\n", String8(value).string());
return eidx;
}
}
if (configTypeName != NULL) {
entry& ent = mEntries.editItemAt(eidx);
if (kIsDebug) {
printf("*** adding config type name %s, was %s\n",
configTypeName->string(), ent.configTypeName.string());
}
if (ent.configTypeName.size() <= 0) {
ent.configTypeName = *configTypeName;
} else if (ent.configTypeName != *configTypeName) {
ent.configTypeName = " ";
}
}
if (config != NULL) {
// Add this to the set of configs associated with the string.
entry& ent = mEntries.editItemAt(eidx);
size_t addPos;
for (addPos=0; addPos<ent.configs.size(); addPos++) {
int cmp = ent.configs.itemAt(addPos).compareLogical(*config);
if (cmp >= 0) {
if (cmp > 0) {
if (kIsDebug) {
printf("*** inserting config: %s\n", config->toString().string());
}
ent.configs.insertAt(*config, addPos);
}
break;
}
}
if (addPos >= ent.configs.size()) {
if (kIsDebug) {
printf("*** adding config: %s\n", config->toString().string());
}
ent.configs.add(*config);
}
}
const bool first = vidx < 0;
const bool styled = (pos >= 0 && (size_t)pos < mEntryStyleArray.size()) ?
mEntryStyleArray[pos].spans.size() : 0;
if (first || styled || !mergeDuplicates) {
pos = mEntryArray.add(eidx);
if (first) {
vidx = mValues.add(value, pos);
}
entry& ent = mEntries.editItemAt(eidx);
ent.indices.add(pos);
}
if (kIsDebug) {
printf("Adding string %s to pool: pos=%zd eidx=%zd vidx=%zd\n",
String8(value).string(), pos, eidx, vidx);
}
return pos;
}
status_t StringPool::addStyleSpan(size_t idx, const String16& name,
uint32_t start, uint32_t end)
{
entry_style_span span;
span.name = name;
span.span.firstChar = start;
span.span.lastChar = end;
return addStyleSpan(idx, span);
}
status_t StringPool::addStyleSpans(size_t idx, const Vector<entry_style_span>& spans)
{
const size_t N=spans.size();
for (size_t i=0; i<N; i++) {
status_t err = addStyleSpan(idx, spans[i]);
if (err != NO_ERROR) {
return err;
}
}
return NO_ERROR;
}
status_t StringPool::addStyleSpan(size_t idx, const entry_style_span& span)
{
// Place blank entries in the span array up to this index.
while (mEntryStyleArray.size() <= idx) {
mEntryStyleArray.add();
}
entry_style& style = mEntryStyleArray.editItemAt(idx);
style.spans.add(span);
mEntries.editItemAt(mEntryArray[idx]).hasStyles = true;
return NO_ERROR;
}
StringPool::ConfigSorter::ConfigSorter(const StringPool& pool) : pool(pool)
{
}
bool StringPool::ConfigSorter::operator()(size_t l, size_t r)
{
const StringPool::entry& lhe = pool.mEntries[pool.mEntryArray[l]];
const StringPool::entry& rhe = pool.mEntries[pool.mEntryArray[r]];
return lhe.compare(rhe) < 0;
}
void StringPool::sortByConfig()
{
LOG_ALWAYS_FATAL_IF(mOriginalPosToNewPos.size() > 0, "Can't sort string pool after already sorted.");
const size_t N = mEntryArray.size();
// This is a vector that starts out with a 1:1 mapping to entries
// in the array, which we will sort to come up with the desired order.
// At that point it maps from the new position in the array to the
// original position the entry appeared.
Vector<size_t> newPosToOriginalPos;
newPosToOriginalPos.setCapacity(N);
for (size_t i=0; i < N; i++) {
newPosToOriginalPos.add(i);
}
// Sort the array.
if (kIsDebug) {
printf("SORTING STRINGS BY CONFIGURATION...\n");
}
ConfigSorter sorter(*this);
std::sort(newPosToOriginalPos.begin(), newPosToOriginalPos.end(), sorter);
if (kIsDebug) {
printf("DONE SORTING STRINGS BY CONFIGURATION.\n");
}
// Create the reverse mapping from the original position in the array
// to the new position where it appears in the sorted array. This is
// so that clients can re-map any positions they had previously stored.
mOriginalPosToNewPos = newPosToOriginalPos;
for (size_t i=0; i<N; i++) {
mOriginalPosToNewPos.editItemAt(newPosToOriginalPos[i]) = i;
}
#if 0
SortedVector<entry> entries;
for (size_t i=0; i<N; i++) {
printf("#%d was %d: %s\n", i, newPosToOriginalPos[i],
mEntries[mEntryArray[newPosToOriginalPos[i]]].makeConfigsString().string());
entries.add(mEntries[mEntryArray[i]]);
}
for (size_t i=0; i<entries.size(); i++) {
printf("Sorted config #%d: %s\n", i,
entries[i].makeConfigsString().string());
}
#endif
// Now we rebuild the arrays.
Vector<entry> newEntries;
Vector<size_t> newEntryArray;
Vector<entry_style> newEntryStyleArray;
DefaultKeyedVector<size_t, size_t> origOffsetToNewOffset;
for (size_t i=0; i<N; i++) {
// We are filling in new offset 'i'; oldI is where we can find it
// in the original data structure.
size_t oldI = newPosToOriginalPos[i];
// This is the actual entry associated with the old offset.
const entry& oldEnt = mEntries[mEntryArray[oldI]];
// This is the same entry the last time we added it to the
// new entry array, if any.
ssize_t newIndexOfOffset = origOffsetToNewOffset.indexOfKey(oldI);
size_t newOffset;
if (newIndexOfOffset < 0) {
// This is the first time we have seen the entry, so add
// it.
newOffset = newEntries.add(oldEnt);
newEntries.editItemAt(newOffset).indices.clear();
} else {
// We have seen this entry before, use the existing one
// instead of adding it again.
newOffset = origOffsetToNewOffset.valueAt(newIndexOfOffset);
}
// Update the indices to include this new position.
newEntries.editItemAt(newOffset).indices.add(i);
// And add the offset of the entry to the new entry array.
newEntryArray.add(newOffset);
// Add any old style to the new style array.
if (mEntryStyleArray.size() > 0) {
if (oldI < mEntryStyleArray.size()) {
newEntryStyleArray.add(mEntryStyleArray[oldI]);
} else {
newEntryStyleArray.add(entry_style());
}
}
}
// Now trim any entries at the end of the new style array that are
// not needed.
for (ssize_t i=newEntryStyleArray.size()-1; i>=0; i--) {
const entry_style& style = newEntryStyleArray[i];
if (style.spans.size() > 0) {
// That's it.
break;
}
// This one is not needed; remove.
newEntryStyleArray.removeAt(i);
}
// All done, install the new data structures and upate mValues with
// the new positions.
mEntries = newEntries;
mEntryArray = newEntryArray;
mEntryStyleArray = newEntryStyleArray;
mValues.clear();
for (size_t i=0; i<mEntries.size(); i++) {
const entry& ent = mEntries[i];
mValues.add(ent.value, ent.indices[0]);
}
#if 0
printf("FINAL SORTED STRING CONFIGS:\n");
for (size_t i=0; i<mEntries.size(); i++) {
const entry& ent = mEntries[i];
printf("#" ZD " %s: %s\n", (ZD_TYPE)i, ent.makeConfigsString().string(),
String8(ent.value).string());
}
#endif
}
sp<AaptFile> StringPool::createStringBlock()
{
sp<AaptFile> pool = new AaptFile(String8(), AaptGroupEntry(),
String8());
status_t err = writeStringBlock(pool);
return err == NO_ERROR ? pool : NULL;
}
#define ENCODE_LENGTH(str, chrsz, strSize) \
{ \
size_t maxMask = 1 << (((chrsz)*8)-1); \
size_t maxSize = maxMask-1; \
if ((strSize) > maxSize) { \
*(str)++ = maxMask | (((strSize)>>((chrsz)*8))&maxSize); \
} \
*(str)++ = strSize; \
}
status_t StringPool::writeStringBlock(const sp<AaptFile>& pool)
{
// Allow appending. Sorry this is a little wacky.
if (pool->getSize() > 0) {
sp<AaptFile> block = createStringBlock();
if (block == NULL) {
return UNKNOWN_ERROR;
}
ssize_t res = pool->writeData(block->getData(), block->getSize());
return (res >= 0) ? (status_t)NO_ERROR : res;
}
// First we need to add all style span names to the string pool.
// We do this now (instead of when the span is added) so that these
// will appear at the end of the pool, not disrupting the order
// our client placed their own strings in it.
const size_t STYLES = mEntryStyleArray.size();
size_t i;
for (i=0; i<STYLES; i++) {
entry_style& style = mEntryStyleArray.editItemAt(i);
const size_t N = style.spans.size();
for (size_t i=0; i<N; i++) {
entry_style_span& span = style.spans.editItemAt(i);
ssize_t idx = add(span.name, true);
if (idx < 0) {
fprintf(stderr, "Error adding span for style tag '%s'\n",
String8(span.name).string());
return idx;
}
span.span.name.index = (uint32_t)idx;
}
}
const size_t ENTRIES = mEntryArray.size();
// Now build the pool of unique strings.
const size_t STRINGS = mEntries.size();
const size_t preSize = sizeof(ResStringPool_header)
+ (sizeof(uint32_t)*ENTRIES)
+ (sizeof(uint32_t)*STYLES);
if (pool->editData(preSize) == NULL) {
fprintf(stderr, "ERROR: Out of memory for string pool\n");
return NO_MEMORY;
}
const size_t charSize = mUTF8 ? sizeof(uint8_t) : sizeof(uint16_t);
size_t strPos = 0;
for (i=0; i<STRINGS; i++) {
entry& ent = mEntries.editItemAt(i);
const size_t strSize = (ent.value.size());
const size_t lenSize = strSize > (size_t)(1<<((charSize*8)-1))-1 ?
charSize*2 : charSize;
String8 encStr;
if (mUTF8) {
encStr = String8(ent.value);
}
const size_t encSize = mUTF8 ? encStr.size() : 0;
const size_t encLenSize = mUTF8 ?
(encSize > (size_t)(1<<((charSize*8)-1))-1 ?
charSize*2 : charSize) : 0;
ent.offset = strPos;
const size_t totalSize = lenSize + encLenSize +
((mUTF8 ? encSize : strSize)+1)*charSize;
void* dat = (void*)pool->editData(preSize + strPos + totalSize);
if (dat == NULL) {
fprintf(stderr, "ERROR: Out of memory for string pool\n");
return NO_MEMORY;
}
dat = (uint8_t*)dat + preSize + strPos;
if (mUTF8) {
uint8_t* strings = (uint8_t*)dat;
ENCODE_LENGTH(strings, sizeof(uint8_t), strSize)
ENCODE_LENGTH(strings, sizeof(uint8_t), encSize)
strncpy((char*)strings, encStr, encSize+1);
} else {
char16_t* strings = (char16_t*)dat;
ENCODE_LENGTH(strings, sizeof(char16_t), strSize)
strcpy16_htod(strings, ent.value);
}
strPos += totalSize;
}
// Pad ending string position up to a uint32_t boundary.
if (strPos&0x3) {
size_t padPos = ((strPos+3)&~0x3);
uint8_t* dat = (uint8_t*)pool->editData(preSize + padPos);
if (dat == NULL) {
fprintf(stderr, "ERROR: Out of memory padding string pool\n");
return NO_MEMORY;
}
memset(dat+preSize+strPos, 0, padPos-strPos);
strPos = padPos;
}
// Build the pool of style spans.
size_t styPos = strPos;
for (i=0; i<STYLES; i++) {
entry_style& ent = mEntryStyleArray.editItemAt(i);
const size_t N = ent.spans.size();
const size_t totalSize = (N*sizeof(ResStringPool_span))
+ sizeof(ResStringPool_ref);
ent.offset = styPos-strPos;
uint8_t* dat = (uint8_t*)pool->editData(preSize + styPos + totalSize);
if (dat == NULL) {
fprintf(stderr, "ERROR: Out of memory for string styles\n");
return NO_MEMORY;
}
ResStringPool_span* span = (ResStringPool_span*)(dat+preSize+styPos);
for (size_t i=0; i<N; i++) {
span->name.index = htodl(ent.spans[i].span.name.index);
span->firstChar = htodl(ent.spans[i].span.firstChar);
span->lastChar = htodl(ent.spans[i].span.lastChar);
span++;
}
span->name.index = htodl(ResStringPool_span::END);
styPos += totalSize;
}
if (STYLES > 0) {
// Add full terminator at the end (when reading we validate that
// the end of the pool is fully terminated to simplify error
// checking).
size_t extra = sizeof(ResStringPool_span)-sizeof(ResStringPool_ref);
uint8_t* dat = (uint8_t*)pool->editData(preSize + styPos + extra);
if (dat == NULL) {
fprintf(stderr, "ERROR: Out of memory for string styles\n");
return NO_MEMORY;
}
uint32_t* p = (uint32_t*)(dat+preSize+styPos);
while (extra > 0) {
*p++ = htodl(ResStringPool_span::END);
extra -= sizeof(uint32_t);
}
styPos += extra;
}
// Write header.
ResStringPool_header* header =
(ResStringPool_header*)pool->padData(sizeof(uint32_t));
if (header == NULL) {
fprintf(stderr, "ERROR: Out of memory for string pool\n");
return NO_MEMORY;
}
memset(header, 0, sizeof(*header));
header->header.type = htods(RES_STRING_POOL_TYPE);
header->header.headerSize = htods(sizeof(*header));
header->header.size = htodl(pool->getSize());
header->stringCount = htodl(ENTRIES);
header->styleCount = htodl(STYLES);
if (mUTF8) {
header->flags |= htodl(ResStringPool_header::UTF8_FLAG);
}
header->stringsStart = htodl(preSize);
header->stylesStart = htodl(STYLES > 0 ? (preSize+strPos) : 0);
// Write string index array.
uint32_t* index = (uint32_t*)(header+1);
for (i=0; i<ENTRIES; i++) {
entry& ent = mEntries.editItemAt(mEntryArray[i]);
*index++ = htodl(ent.offset);
if (kIsDebug) {
printf("Writing entry #%zu: \"%s\" ent=%zu off=%zu\n",
i,
String8(ent.value).string(),
mEntryArray[i],
ent.offset);
}
}
// Write style index array.
for (i=0; i<STYLES; i++) {
*index++ = htodl(mEntryStyleArray[i].offset);
}
return NO_ERROR;
}
ssize_t StringPool::offsetForString(const String16& val) const
{
const Vector<size_t>* indices = offsetsForString(val);
ssize_t res = indices != NULL && indices->size() > 0 ? indices->itemAt(0) : -1;
if (kIsDebug) {
printf("Offset for string %s: %zd (%s)\n", String8(val).string(), res,
res >= 0 ? String8(mEntries[mEntryArray[res]].value).string() : String8());
}
return res;
}
const Vector<size_t>* StringPool::offsetsForString(const String16& val) const
{
ssize_t pos = mValues.valueFor(val);
if (pos < 0) {
return NULL;
}
return &mEntries[mEntryArray[pos]].indices;
}