bool KoDocumentInfo::saveOasis( KoStore* store )
{
KoStoreDevice dev( store );
KoXmlWriter* xmlWriter = KoDocument::createOasisXmlWriter( &dev, "office:document-meta" );
xmlWriter->startElement( "office:meta" );
xmlWriter->startElement( "meta:generator");
xmlWriter->addTextNode( QString( "KOffice/%1" ).arg( KOFFICE_VERSION_STRING ) );
xmlWriter->endElement();
QStringList lst = pages();
QStringList::ConstIterator it = lst.begin();
for( ; it != lst.end(); ++it )
{
KoDocumentInfoPage* p = page( *it );
Q_ASSERT( p );
if ( !p->saveOasis( *xmlWriter ) )
return false;
}
xmlWriter->endElement();
xmlWriter->endElement(); // root element
xmlWriter->endDocument();
delete xmlWriter;
return true;
}
void
create_warehouse(){
FD fd;
std::vector<PageWarehouse> pages(W);
for(int i=0; i<W; i++){
const int w_id = i+1;
pages[i].page_id = w_id;
pages[i].w_id = w_id;
gen_rand_astring(pages[i].w_name, 6, 10);
gen_rand_astring(pages[i].w_street_1, 10, 20);
gen_rand_astring(pages[i].w_street_2, 10, 20);
gen_rand_astring(pages[i].w_city, 10, 20);
gen_rand_nstring(pages[i].w_state, 2, 2);
gen_rand_zip(pages[i].w_zip);
gen_rand_decimal(&pages[i].w_tax, 0, 2000, 4);
pages[i].w_ytd = 300000.00;
}
fd.open(WFILENAME, O_CREAT | O_TRUNC | O_WRONLY, 0644);
fd.write(&pages[0], pages.size()*sizeof(PageWarehouse));
std::cerr << "create warehouse " << pages.size() << "records: " << WFILENAME << std::endl;
}
bool Score::saveCompressedFile(QIODevice* f, QFileInfo& info, bool onlySelection, bool doCreateThumbnail)
{
MQZipWriter uz(f);
QString fn = info.completeBaseName() + ".mscx";
QBuffer cbuf;
cbuf.open(QIODevice::ReadWrite);
XmlWriter xml(this, &cbuf);
xml << "<?xml version=\"1.0\" encoding=\"UTF-8\"?>\n";
xml.stag("container");
xml.stag("rootfiles");
xml.stag(QString("rootfile full-path=\"%1\"").arg(XmlWriter::xmlString(fn)));
xml.etag();
for (ImageStoreItem* ip : imageStore) {
if (!ip->isUsed(this))
continue;
QString path = QString("Pictures/") + ip->hashName();
xml.tag("file", path);
}
xml.etag();
xml.etag();
cbuf.seek(0);
//uz.addDirectory("META-INF");
uz.addFile("META-INF/container.xml", cbuf.data());
// save images
//uz.addDirectory("Pictures");
foreach (ImageStoreItem* ip, imageStore) {
if (!ip->isUsed(this))
continue;
QString path = QString("Pictures/") + ip->hashName();
uz.addFile(path, ip->buffer());
}
// create thumbnail
if (doCreateThumbnail && !pages().isEmpty()) {
QImage pm = createThumbnail();
QByteArray ba;
QBuffer b(&ba);
if (!b.open(QIODevice::WriteOnly))
qDebug("open buffer failed");
if (!pm.save(&b, "PNG"))
qDebug("save failed");
uz.addFile("Thumbnails/thumbnail.png", ba);
}
#ifdef OMR
//
// save OMR page images
//
if (masterScore()->omr()) {
int n = masterScore()->omr()->numPages();
for (int i = 0; i < n; ++i) {
QString path = QString("OmrPages/page%1.png").arg(i+1);
QBuffer cbuf1;
OmrPage* page = masterScore()->omr()->page(i);
const QImage& image = page->image();
if (!image.save(&cbuf1, "PNG")) {
MScore::lastError = tr("save file: cannot save image (%1x%2)").arg(image.width(), image.height());
return false;
}
uz.addFile(path, cbuf1.data());
cbuf1.close();
}
}
#endif
//
// save audio
//
if (_audio)
uz.addFile("audio.ogg", _audio->data());
QBuffer dbuf;
dbuf.open(QIODevice::ReadWrite);
saveFile(&dbuf, true, onlySelection);
dbuf.seek(0);
uz.addFile(fn, dbuf.data());
uz.close();
return true;
}
//------------------------------------------------------------------------------
// Name: do_find()
// Desc:
//------------------------------------------------------------------------------
void DialogReferences::do_find() {
bool ok;
const edb::address_t address = edb::v1::string_to_address(ui->txtAddress->text(), ok);
const edb::address_t page_size = edb::v1::debugger_core->page_size();
if(ok) {
edb::v1::memory_regions().sync();
const QList<MemRegion> regions = edb::v1::memory_regions().regions();
int i = 0;
Q_FOREACH(const MemRegion ®ion, regions) {
// a short circut for speading things up
if(region.accessible() || !ui->chkSkipNoAccess->isChecked()) {
const edb::address_t size_in_pages = region.size() / page_size;
try {
QVector<quint8> pages(size_in_pages * page_size);
const quint8 *const pages_end = &pages[0] + size_in_pages * page_size;
if(edb::v1::debugger_core->read_pages(region.start, &pages[0], size_in_pages)) {
const quint8 *p = &pages[0];
while(p != pages_end) {
if(static_cast<std::size_t>(pages_end - p) < sizeof(edb::address_t)) {
break;
}
const edb::address_t addr = p - &pages[0] + region.start;
edb::address_t test_address;
memcpy(&test_address, p, sizeof(edb::address_t));
if(test_address == address) {
QListWidgetItem *const item = new QListWidgetItem(edb::v1::format_pointer(addr));
item->setData(Qt::UserRole, 'D');
ui->listWidget->addItem(item);
}
edb::Instruction insn(p, pages_end - p, addr, std::nothrow);
if(insn.valid()) {
switch(insn.type()) {
case edb::Instruction::OP_JMP:
case edb::Instruction::OP_CALL:
case edb::Instruction::OP_JCC:
if(insn.operand(0).general_type() == edb::Operand::TYPE_REL) {
if(insn.operand(0).relative_target() == address) {
QListWidgetItem *const item = new QListWidgetItem(edb::v1::format_pointer(addr));
item->setData(Qt::UserRole, 'C');
ui->listWidget->addItem(item);
}
}
break;
default:
break;
}
}
emit updateProgress(util::percentage(i, regions.size(), p - &pages[0], region.size()));
++p;
}
}
} catch(const std::bad_alloc &) {
QMessageBox::information(
0,
tr("Memroy Allocation Error"),
tr("Unable to satisfy memory allocation request for requested region."));
}
} else {
emit updateProgress(util::percentage(i, regions.size()));
}
++i;
}
}
}
void
Restore::restore_next(Signal* signal, FilePtr file_ptr)
{
Uint32 *data, len= 0;
Uint32 status = file_ptr.p->m_status;
Uint32 page_count = file_ptr.p->m_pages.getSize();
do
{
Uint32 left= file_ptr.p->m_bytes_left;
if (left < 8)
{
jam();
/**
* Not enough bytes to read header
*/
break;
}
Ptr<GlobalPage> page_ptr(0,0), next_page_ptr(0,0);
m_global_page_pool.getPtr(page_ptr, file_ptr.p->m_current_page_ptr_i);
List::Iterator it;
Uint32 pos= file_ptr.p->m_current_page_pos;
if(status & File::READING_RECORDS)
{
jam();
/**
* We are reading records
*/
len= ntohl(* (page_ptr.p->data + pos)) + 1;
ndbrequire(len < GLOBAL_PAGE_SIZE_WORDS);
}
else
{
jam();
/**
* Section length is in 2 word
*/
if(pos + 1 == GLOBAL_PAGE_SIZE_WORDS)
{
jam();
/**
* But that's stored on next page...
* and since we have atleast 8 bytes left in buffer
* we can be sure that that's in buffer
*/
LocalDataBuffer<15> pages(m_databuffer_pool, file_ptr.p->m_pages);
Uint32 next_page = file_ptr.p->m_current_page_index + 1;
pages.position(it, next_page % page_count);
m_global_page_pool.getPtr(next_page_ptr, * it.data);
len= ntohl(* next_page_ptr.p->data);
}
else
{
jam();
len= ntohl(* (page_ptr.p->data + pos + 1));
}
}
if (file_ptr.p->m_status & File::FIRST_READ)
{
jam();
len= 3;
file_ptr.p->m_status &= ~(Uint32)File::FIRST_READ;
}
if (4 * len > left)
{
jam();
/**
* Not enought bytes to read "record"
*/
if (unlikely((status & File:: FILE_THREAD_RUNNING) == 0))
{
crash_during_restore(file_ptr, __LINE__, 0);
}
len= 0;
break;
}
/**
* Entire record is in buffer
*/
if(pos + len >= GLOBAL_PAGE_SIZE_WORDS)
{
jam();
/**
* But it's split over pages
*/
if(next_page_ptr.p == 0)
{
LocalDataBuffer<15> pages(m_databuffer_pool, file_ptr.p->m_pages);
Uint32 next_page = file_ptr.p->m_current_page_index + 1;
pages.position(it, next_page % page_count);
m_global_page_pool.getPtr(next_page_ptr, * it.data);
}
file_ptr.p->m_current_page_ptr_i = next_page_ptr.i;
file_ptr.p->m_current_page_pos = (pos + len) - GLOBAL_PAGE_SIZE_WORDS;
file_ptr.p->m_current_page_index =
(file_ptr.p->m_current_page_index + 1) % page_count;
if (len <= GLOBAL_PAGE_SIZE_WORDS)
{
jam();
Uint32 first = (GLOBAL_PAGE_SIZE_WORDS - pos);
// wl4391_todo removing valgrind overlap warning for now
memmove(page_ptr.p, page_ptr.p->data+pos, 4 * first);
memcpy(page_ptr.p->data+first, next_page_ptr.p, 4 * (len - first));
data= page_ptr.p->data;
}
else
{
jam();
/**
* A table definition can be larger than one page...
* when that happens copy it out to side buffer
*
* First copy part belonging to page_ptr
* Then copy full middle pages (moving forward in page-list)
* Last copy last part
*/
Uint32 save = len;
assert(len <= NDB_ARRAY_SIZE(m_table_buf));
Uint32 * dst = m_table_buf;
/**
* First
*/
Uint32 first = (GLOBAL_PAGE_SIZE_WORDS - pos);
memcpy(dst, page_ptr.p->data+pos, 4 * first);
len -= first;
dst += first;
/**
* Middle
*/
while (len > GLOBAL_PAGE_SIZE_WORDS)
{
jam();
memcpy(dst, next_page_ptr.p, 4 * GLOBAL_PAGE_SIZE_WORDS);
len -= GLOBAL_PAGE_SIZE_WORDS;
dst += GLOBAL_PAGE_SIZE_WORDS;
{
LocalDataBuffer<15> pages(m_databuffer_pool, file_ptr.p->m_pages);
Uint32 next_page = (file_ptr.p->m_current_page_index + 1) % page_count;
pages.position(it, next_page % page_count);
m_global_page_pool.getPtr(next_page_ptr, * it.data);
file_ptr.p->m_current_page_ptr_i = next_page_ptr.i;
file_ptr.p->m_current_page_index = next_page;
}
}
/**
* last
*/
memcpy(dst, next_page_ptr.p, 4 * len);
file_ptr.p->m_current_page_pos = len;
/**
* Set pointer and len
*/
len = save;
data = m_table_buf;
}
}
else
{
file_ptr.p->m_current_page_pos = pos + len;
data= page_ptr.p->data+pos;
}
file_ptr.p->m_bytes_left -= 4*len;
if(status & File::READING_RECORDS)
{
if(len == 1)
{
file_ptr.p->m_status = status & ~(Uint32)File::READING_RECORDS;
}
else
{
parse_record(signal, file_ptr, data, len);
}
}
else
{
switch(ntohl(* data)){
case BackupFormat::FILE_HEADER:
parse_file_header(signal, file_ptr, data-3, len+3);
break;
case BackupFormat::FRAGMENT_HEADER:
file_ptr.p->m_status = status | File::READING_RECORDS;
parse_fragment_header(signal, file_ptr, data, len);
break;
case BackupFormat::FRAGMENT_FOOTER:
parse_fragment_footer(signal, file_ptr, data, len);
break;
case BackupFormat::TABLE_LIST:
parse_table_list(signal, file_ptr, data, len);
break;
case BackupFormat::TABLE_DESCRIPTION:
parse_table_description(signal, file_ptr, data, len);
break;
case BackupFormat::GCP_ENTRY:
parse_gcp_entry(signal, file_ptr, data, len);
break;
case BackupFormat::EMPTY_ENTRY:
// skip
break;
case 0x4e444242: // 'NDBB'
if (check_file_version(signal, ntohl(* (data+2))) == 0)
{
break;
}
default:
parse_error(signal, file_ptr, __LINE__, ntohl(* data));
}
}
} while(0);
if(file_ptr.p->m_bytes_left == 0 && status & File::FILE_EOF)
{
file_ptr.p->m_status &= ~(Uint32)File::RESTORE_THREAD_RUNNING;
/**
* File is finished...
*/
close_file(signal, file_ptr);
return;
}
/**
* We send an immediate signal to continue the restore, at times this
* could lead to burning some extra CPU since we might still wait for
* input from the disk reading. This code is however only executed
* as part of restarts, so it should be ok to spend some extra CPU
* to ensure that restarts are quick.
*/
signal->theData[0] = RestoreContinueB::RESTORE_NEXT;
signal->theData[1] = file_ptr.i;
sendSignal(reference(), GSN_CONTINUEB, signal, 2, JBB);
}
Uint32
Restore::init_file(const RestoreLcpReq* req, FilePtr file_ptr)
{
new (file_ptr.p) File();
file_ptr.p->m_sender_ref = req->senderRef;
file_ptr.p->m_sender_data = req->senderData;
file_ptr.p->m_fd = RNIL;
file_ptr.p->m_file_type = BackupFormat::LCP_FILE;
file_ptr.p->m_status = File::FIRST_READ;
file_ptr.p->m_lcp_no = req->lcpNo;
file_ptr.p->m_table_id = req->tableId;
file_ptr.p->m_fragment_id = req->fragmentId;
file_ptr.p->m_table_version = RNIL;
file_ptr.p->m_bytes_left = 0; // Bytes read from FS
file_ptr.p->m_current_page_ptr_i = RNIL;
file_ptr.p->m_current_page_pos = 0;
file_ptr.p->m_current_page_index = 0;
file_ptr.p->m_current_file_page = 0;
file_ptr.p->m_outstanding_reads = 0;
file_ptr.p->m_outstanding_operations = 0;
file_ptr.p->m_rows_restored = 0;
file_ptr.p->m_bytes_restored = 0;
file_ptr.p->m_restore_start_time = NdbTick_CurrentMillisecond();;
LocalDataBuffer<15> pages(m_databuffer_pool, file_ptr.p->m_pages);
LocalDataBuffer<15> columns(m_databuffer_pool, file_ptr.p->m_columns);
ndbassert(columns.isEmpty());
columns.release();
ndbassert(pages.isEmpty());
pages.release();
Uint32 buf_size= PAGES*GLOBAL_PAGE_SIZE;
Uint32 page_count= (buf_size+GLOBAL_PAGE_SIZE-1)/GLOBAL_PAGE_SIZE;
if(!pages.seize(page_count))
{
return RestoreLcpRef::OutOfDataBuffer;
}
List::Iterator it;
for(pages.first(it); !it.isNull(); pages.next(it))
{
* it.data = RNIL;
}
Uint32 err= 0;
for(pages.first(it); !it.isNull(); pages.next(it))
{
Ptr<GlobalPage> page_ptr;
if(!m_global_page_pool.seize(page_ptr))
{
err= RestoreLcpRef::OutOfReadBufferPages;
break;
}
* it.data = page_ptr.i;
}
if(err)
{
for(pages.first(it); !it.isNull(); pages.next(it))
{
if(* it.data == RNIL)
break;
m_global_page_pool.release(* it.data);
}
}
else
{
pages.first(it);
file_ptr.p->m_current_page_ptr_i = *it.data;
}
return err;
}
void WServer::initialize()
{
//Start time
_ptBeforeLoad = boost::posix_time::microsec_clock::local_time();
/* *************************************************************************
* *********************** Connect to SQL Server *************************
* *************************************************************************/
try
{
log("info") << "Connecting to database backend";
//Wt::Dbo::SqlConnection *sqlConnection = new Wt::Dbo::backend::MySQL("wt", "root", "", "127.0.0.1");
Wt::Dbo::SqlConnection *sqlConnection = new Wt::Dbo::backend::Sqlite3(":memory:");
sqlConnection->setProperty("show-queries", "true");
_sqlPool = new Wt::Dbo::FixedSqlConnectionPool(sqlConnection, 1);
log("success") << "Successfully connected to database";
}
catch(Wt::Dbo::Exception &e)
{
log("fatal") << "Database error connecting to database: " << e.what();
throw e;
}
catch(std::exception &e)
{
log("fatal") << "Error connecting to database: " << e.what();
throw e;
}
/* *************************************************************************
* *********************** Initialize Databases **************************
* *************************************************************************/
try
{
_dboManager = new DboDatabaseManager(this, _sqlPool);
_modules = new ModuleDatabase(_dboManager);
_configurations = new ConfigurationsDatabase(_dboManager);
_languages = new LanguageDatabase(_dboManager);
_styles = new StyleDatabase(_dboManager);
_pages = new PageDatabase(_dboManager);
_accessPaths = new AccessPathDatabase(_dboManager);
_navigationMenus = new NavigationMenuDatabase(_dboManager);
}
catch(std::exception &e)
{
log("fatal") << "Error initializing databases: " << e.what();
throw e;
}
/* *************************************************************************
* *************************** Create Tables *****************************
* *************************************************************************/
#define REINSTALL_DBO
#ifdef REINSTALL_DBO
//Drop
try
{
_installer = new Installer::DboInstaller(*_sqlPool);
_installer->dropTables();
}
catch(Wt::Dbo::Exception &e)
{
log("error") << "Database error dropping tables: " << e.what();
}
catch(std::exception &e)
{
log("error") << "Error dropping tables: " << e.what();
}
//Create
try
{
_installer->createTables();
}
catch(Wt::Dbo::Exception &e)
{
log("fatal") << "Database error creating tables: " << e.what();
throw e;
}
catch(std::exception &e)
{
log("fatal") << "Error creating tables: " << e.what();
throw e;
}
//Insert
// try
// {
_installer->insertRows();
// }
// catch(Wt::Dbo::Exception &e)
// {
// log("fatal") << "Database error inserting data: " << e.what();
// throw e;
// }
// catch(std::exception &e)
// {
// log("fatal") << "Error inserting data: " << e.what();
// throw e;
// }
#endif
/* *************************************************************************
* ************************* Load DboDatabases ***************************
* *************************************************************************/
// try
// {
log("info") << "Loading DboDatabaseManager";
_dboManager->load();
// }
// catch(Wt::Dbo::Exception &e)
// {
// log("fatal") << "Database error loading DboDatabaseManager: " << e.what();
// throw e;
// }
// catch(std::exception &e)
// {
// log("fatal") << "Error loading DboDatabaseManager: " << e.what();
// throw e;
// }
//Server localized strings
setLocalizedStrings(new DboLocalizedStrings(this));
pages()->register404PageHandler(new Default404Page());
pages()->registerPageHandler("home", ModuleDatabase::Navigation, new AnotherPage());
pages()->registerPageHandler("sitemap", ModuleDatabase::Navigation, new AnotherPage());
pages()->registerPageHandler("login", ModuleDatabase::Authentication, new LoginPage());
pages()->registerPageHandler("register", ModuleDatabase::Authentication, new RegistrationPage());
/* *************************************************************************
* ********************* Create temporary XML file ***********************
* *************************************************************************/
try
{
log("info") << "Writing XML Configuration file";
createWtXmlConfiguration();
log("success") << "XML Configuration file created";
}
catch(std::exception &e)
{
log("fatal") << "Error creating XML Configuration file: " << e.what();
throw e;
}
//Configure authorization module
configureAuth();
}
int main(int argc, char **argv)
{
boot_img_hdr hdr;
int bootimg_fd;
void *boot_data = 0;
unsigned boot_size = 0;
char boot_magic[BOOT_MAGIC_SIZE+1];
char kernel_fn[MAXNAMELEN];
void *kernel_data = 0;
char ramdisk_fn[MAXNAMELEN];
void *ramdisk_data = 0;
char second_fn[MAXNAMELEN];
void *second_data = 0;
char header_fn[MAXNAMELEN];
char *cmdline = "";
char *bootimg_fn = 0;
char *board = "";
unsigned pagesize = 2048;
int fd;
/*SHA_CTX ctx;*/
/*uint8_t* sha;*/
unsigned long i;
unsigned count;
char *msg1 = "";
char *msg2 = "";
int offset;
FILE *fp;
unsigned kernel_offset = 0x00008000;
unsigned ramdisk_offset = 0x01000000;
unsigned second_offset = 0x00F00000;
unsigned tags_offset = 0x00000100;
unsigned kernel_base = 0;
unsigned ramdisk_base = 0;
unsigned second_base = 0;
unsigned tags_base = 0;
argc--;
argv++;
while(argc > 0){
char *arg = argv[0];
char *val = argv[1];
if(argc < 2) {
return usage();
}
argc -= 2;
argv += 2;
if(!strcmp(arg, "--input") || !strcmp(arg, "-i")) {
bootimg_fn = val;
} else {
return usage();
}
}
if(bootimg_fn == 0) {
fprintf(stderr,"error: no input filename specified\n");
return usage();
}
sprintf(kernel_fn, "%s-kernel", bootimg_fn);
bootimg_fd = open(bootimg_fn, O_RDONLY);
if (bootimg_fd < 0) {
fprintf(stderr,"error: could not open %s\n", bootimg_fn);
return 1;
}
count = read(bootimg_fd, (void *)&hdr, sizeof(hdr));
if (count != sizeof(hdr)) {
msg1 = "could not read hdr from input";
goto fail;
}
for (i = 0; i < BOOT_MAGIC_SIZE; i++) {
boot_magic[i] = hdr.magic[i];
}
boot_magic[BOOT_MAGIC_SIZE] = '\0';
if (strcmp(BOOT_MAGIC, boot_magic)) {
fprintf(stderr, "error: %s boot image file's magic value %s does not match %s\n",
bootimg_fn, boot_magic, BOOT_MAGIC);
goto fail;
}
if (hdr.page_size != 2048 && hdr.page_size != 4096 &&
hdr.page_size != 8192 && hdr.page_size != 16384) {
fprintf(stderr, "warning: hdr.page_size %d must be 2048, 4096, 8192 or 16384\n",
hdr.page_size);
goto fail;
}
count = lseek(bootimg_fd, hdr.page_size, SEEK_SET);
if (count != hdr.page_size) {
msg1 = "boot header is not a page";
goto fail;
}
sprintf(header_fn, "%s-header", bootimg_fn);
fp = fopen(header_fn, "w+");
if(!fp) {
msg1 = "could not create";
msg2 = header_fn;
goto fail;
}
kernel_base = hdr.kernel_addr - kernel_offset;
ramdisk_base = hdr.ramdisk_addr - ramdisk_offset;
second_base = hdr.second_addr - second_offset;
tags_base = hdr.tags_addr - tags_offset;
fprintf(fp, "Assumptions\n");
fprintf(fp, "kernel_offset = 0x%X\n", kernel_offset);
fprintf(fp, "ramdisk_offset = 0x%X\n", ramdisk_offset);
fprintf(fp, "second_offset = 0x%X\n", second_offset);
fprintf(fp, "tags_offset = 0x%X\n", tags_offset);
fprintf(fp, "Detected values\n");
fprintf(fp, "kernel_size = %d\n", hdr.kernel_size);
fprintf(fp, "kernel_addr = 0x%X\n", hdr.kernel_addr);
fprintf(fp, "ramdisk_size = %d\n", hdr.ramdisk_size);
fprintf(fp, "ramdisk_addr = 0x%X\n", hdr.ramdisk_addr);
fprintf(fp, "second_size = %d\n", hdr.second_size);
fprintf(fp, "second_addr = 0x%X\n", hdr.second_addr);
fprintf(fp, "tags_addr = 0x%X\n", hdr.tags_addr);
fprintf(fp, "page_size = %d\n", hdr.page_size);
/*fprintf(fp, "unused = %d%d\n", hdr.unused[0], hdr.unused[1]);*/
fprintf(fp, "name/board = %s\n", hdr.name);
fprintf(fp, "cmdline = %s\n", hdr.cmdline);
/*fprintf(fp, "id = %s\n", hdr.id);*/
fprintf(fp, "Computed values\n");
fprintf(fp, "kernel_base = 0x%X\n", kernel_base);
fprintf(fp, "ramdisk_base = 0x%X, kernel_base - ramdisk_offset=0x%X\n", ramdisk_base,
kernel_base - ramdisk_base);
fprintf(fp, "second_base = 0x%X, kernel_base - second_offset=0x%X\n", second_base,
kernel_base - second_base);
fprintf(fp, "tags_base = 0x%X, kernel_base - tags_offset = 0x%X\n", tags_base,
kernel_base - tags_base);
if (kernel_base != ramdisk_base ||
kernel_base != second_base ||
kernel_base != tags_base) {
fprintf(fp, "WARNING! base addresses do not match!\n");
fprintf(stderr, "WARNING! base addresses do not match!\n");
}
fclose(fp);
/* kernel */
if(hdr.kernel_size == 0) {
msg1 = "kernel size is zero";
goto fail;
}
offset = hdr.page_size;
write_chunk(bootimg_fd, bootimg_fn, hdr.kernel_size, "kernel", offset);
/* ramdisk */
if(hdr.ramdisk_size == 0) {
msg1 = "ramdisk size is zero";
goto fail;
}
offset += pages(hdr.page_size, hdr.kernel_size) * hdr.page_size;
write_chunk(bootimg_fd, bootimg_fn, hdr.ramdisk_size, "first-ramdisk", offset);
/* ramdisk 2 */
if(hdr.second_size > 0) {
offset += pages(hdr.page_size, hdr.ramdisk_size) * hdr.page_size;
write_chunk(bootimg_fd, bootimg_fn, hdr.second_size, "second-ramdisk", offset);
}
return 0;
fail:
close(bootimg_fd);
fprintf(stderr,"error: %s %s '%s': %s\n", msg1, msg2, bootimg_fn,
strerror(errno));
return 1;
}
void ObxTreeView::reportPosition()
{
emit positionChanged(currentPage(), pages());
}
void handle(JsonObject& resp, JsonObject& req) {
Serial.begin(BAUDRATE, SerialConfig::SERIAL_8E1, SerialMode::SERIAL_FULL);
Serial.swap();
String cmd = req["request"];
resp["id"] = req["id"];
resp["reply"] = req["request"];
uint32_t startTime = millis();
Erc erc = 0;
if (cmd.equals("resetBootloader")) {
erc = stm32.resetSystem();
} else if (cmd.equals("resetFlash")) {
erc = stm32.resetFlash();
} else if (cmd.equals("goFlash")) {
uint32_t address = req["address"];
erc = stm32.go(address);
resp["address"] = address;
} else if (cmd.equals("status")) {
resp["esp_id"] = ESP.getChipId();
resp["heap"] = ESP.getFreeHeap();
resp["upTime"] = millis();
resp["version"] = __DATE__ " " __TIME__;
resp["usart.rxd"] = Stm32::_usartRxd;
resp["mode"] =
stm32.getMode() == Stm32::M_FLASH ?
"APPLICATION" : "BOOTLOADER";
resp["baudrate"] = BAUDRATE;
} else if (cmd.equals("getId")) {
uint16_t chipId;
erc = stm32.getId(chipId);
if (erc == E_OK) {
resp["chipId"] = chipId;
}
} else if (cmd.equals("getVersion")) {
uint8_t version;
erc = stm32.getVersion(version);
if (erc == E_OK) {
resp["version"] = version;
}
} else if (cmd.equals("get")) {
Bytes data(30);
Str strData(60);
uint8_t version;
erc = stm32.get(version, data);
if (erc == E_OK) {
erc = Base64::encode(strData, data);
resp["cmds"] = String(strData.c_str());
resp["version"] = version;
}
} else if (cmd.equals("writeMemory")) {
Bytes data(256);
Str str((const char*) req["data"]);
uint32_t address = req["address"];
resp["address"] = address;
erc = Base64::decode(data, str);
resp["length"] = data.length();
if (erc == E_OK) {
erc = stm32.writeMemory(address, data);
}
} else if (cmd.equals("eraseMemory")) {
Bytes pages(256);
Str str((const char*) req["pages"]);
erc = Base64::decode(pages, str);
resp["length"] = pages.length();
erc = stm32.eraseMemory(pages);
} else if (cmd.equals("extendedEraseMemory")) {
erc = stm32.extendedEraseMemory();
} else if (cmd.equals("eraseAll")) {
erc = stm32.eraseAll();
} else if (cmd.equals("readMemory")) {
Str strData(410);
Bytes data(256);
uint32_t address = req["address"];
uint32_t length = req["length"];
resp["address"] = address;
resp["length"] = length;
erc = stm32.readMemory(address, length, data);
if (erc == E_OK) {
erc = Base64::encode(strData, data);
resp["data"] = String(strData.c_str());
}
} else if (cmd.equals("writeProtect")) {
Bytes data(256);
Str str((const char*) req["data"]);
erc = Base64::decode(data, str);
erc = stm32.writeProtect(data);
} else if (cmd.equals("writeUnprotect")) {
erc = stm32.writeUnprotect();
} else if (cmd.equals("readoutProtect")) {
erc = stm32.readoutProtect();
} else if (cmd.equals("readoutUnprotect")) {
erc = stm32.readoutUnprotect();
} else if (cmd.equals("settings")) {
if (req.containsKey("baudrate")) {
BAUDRATE = req["baudrate"];
resp["baudrate"] = BAUDRATE;
Config.set("uart.baudrate", BAUDRATE);
}
String config;
Config.load(config);
resp["config"] = config;
} else {
erc = EINVAL;
}
resp["delta"] = millis() - startTime;
resp["error"] = erc;
Serial.begin(BAUDRATE, SerialConfig::SERIAL_8N1, SerialMode::SERIAL_FULL);
Serial.swap();
}
