int ScopeGUI::resize_event(int w, int h)
{
clear_box(0, 0, w, h);
this->w = w;
this->h = h;
calculate_sizes(w, h);
if(waveform)
{
waveform->reposition_window(wave_x, wave_y, wave_w, wave_h);
waveform->clear_box(0, 0, wave_w, wave_h);
}
if(histogram)
{
histogram->reposition_window(hist_x, hist_y, hist_w, hist_h);
histogram->clear_box(0, 0, hist_w, hist_h);
}
if(vectorscope)
{
vectorscope->reposition_window(vector_x, vector_y, vector_w, vector_h);
vectorscope->clear_box(0, 0, vector_w, vector_h);
}
allocate_bitmaps();
clear_points(0);
draw_overlays(1, 1, 1);
return 1;
}
void VWindowCanvas::zoom_resize_window(float percentage)
{
EDL *edl = gui->vwindow->get_edl();
if(!edl) edl = mwindow->edl;
int canvas_w, canvas_h;
int new_w, new_h;
// Get required canvas size
calculate_sizes(edl->get_aspect_ratio(),
edl->session->output_w,
edl->session->output_h,
percentage,
canvas_w,
canvas_h);
// Estimate window size from current borders
new_w = canvas_w + (gui->get_w() - mwindow->theme->vcanvas_w);
new_h = canvas_h + (gui->get_h() - mwindow->theme->vcanvas_h);
mwindow->session->vwindow_w = new_w;
mwindow->session->vwindow_h = new_h;
mwindow->theme->get_vwindow_sizes(gui);
// Estimate again from new borders
new_w = canvas_w + (mwindow->session->vwindow_w - mwindow->theme->vcanvas_w);
new_h = canvas_h + (mwindow->session->vwindow_h - mwindow->theme->vcanvas_h);
gui->resize_window(new_w, new_h);
gui->resize_event(new_w, new_h);
}
/** Pre-unparsing updates */
bool
SgAsmElfSegmentTable::reallocate()
{
bool reallocated = false;
/* Resize based on word size from ELF File Header */
size_t opt_size, nentries;
rose_addr_t need = calculate_sizes(NULL, NULL, &opt_size, &nentries);
if (need < get_size()) {
if (is_mapped()) {
ROSE_ASSERT(get_mapped_size()==get_size());
set_mapped_size(need);
}
set_size(need);
reallocated = true;
} else if (need > get_size()) {
get_file()->shift_extend(this, 0, need-get_size(), SgAsmGenericFile::ADDRSP_ALL, SgAsmGenericFile::ELASTIC_HOLE);
reallocated = true;
}
/* Update data members in the ELF File Header. No need to return true for these changes. */
SgAsmElfFileHeader *fhdr = dynamic_cast<SgAsmElfFileHeader*>(get_header());
fhdr->set_phextrasz(opt_size);
fhdr->set_e_phnum(nentries);
return reallocated;
}
bool
SgAsmElfSection::reallocate()
{
bool reallocated = false;
SgAsmElfSectionTableEntry *sechdr = get_section_entry();
SgAsmElfSegmentTableEntry *seghdr = get_segment_entry();
/* Change section size if this section was defined in the ELF Section Table */
if (sechdr!=NULL) {
rose_addr_t need = calculate_sizes(NULL, NULL, NULL, NULL);
if (need < get_size()) {
if (is_mapped()) {
ROSE_ASSERT(get_mapped_size()==get_size());
set_mapped_size(need);
}
set_size(need);
reallocated = true;
} else if (need > get_size()) {
get_file()->shift_extend(this, 0, need-get_size(), SgAsmGenericFile::ADDRSP_ALL, SgAsmGenericFile::ELASTIC_HOLE);
reallocated = true;
}
}
/* Update entry in the ELF Section Table and/or ELF Segment Table */
if (sechdr)
sechdr->update_from_section(this);
if (seghdr)
seghdr->update_from_section(this);
return reallocated;
}
MonoPIFunc
mono_arch_create_trampoline (MonoMethodSignature *sig, gboolean string_ctor)
{
guint8 *p, *code_buffer;
size_data sz;
DEBUG (printf ("\nPInvoke [start emiting]\n"));
calculate_sizes (sig, &sz, string_ctor);
p = code_buffer = alloc_code_memory (sz.code_size);
p = emit_prolog (p, sig, &sz);
p = emit_save_parameters (p, sig, &sz);
p = emit_call_and_store_retval (p, sig, &sz, string_ctor);
p = emit_epilog (p, sig, &sz);
#ifdef NEED_MPROTECT
if (mprotect (code_buffer, 1024, PROT_READ | PROT_WRITE | PROT_EXEC)) {
g_error ("Cannot mprotect trampoline\n");
}
#endif
DEBUG (printf ("emited code size: %d\n", p - code_buffer));
DEBUG (printf ("PInvoke [end emiting]\n"));
return (MonoPIFunc) code_buffer;
}
/** Return sizes for various parts of the table. See doc for SgAsmElfSection::calculate_sizes. */
rose_addr_t
SgAsmElfSymbolSection::calculate_sizes(size_t *entsize, size_t *required, size_t *optional, size_t *entcount) const
{
std::vector<size_t> extra_sizes;
for (size_t i=0; i<p_symbols->get_symbols().size(); i++)
extra_sizes.push_back(p_symbols->get_symbols()[i]->get_extra().size());
return calculate_sizes(sizeof(SgAsmElfSymbol::Elf32SymbolEntry_disk),
sizeof(SgAsmElfSymbol::Elf64SymbolEntry_disk),
extra_sizes,
entsize, required, optional, entcount);
}
bool
TaskDijkstra::refresh_task()
{
set_stages(task.TaskSize());
if (num_stages < 2)
return false;
active_stage = task.getActiveTaskPointIndex();
calculate_sizes();
return true;
}
void RecordMonitorCanvas::zoom_resize_window(float percentage)
{
int canvas_w, canvas_h;
calculate_sizes(mwindow->edl->get_aspect_ratio(),
record->default_asset->width, record->default_asset->height,
percentage, canvas_w, canvas_h);
int new_w, new_h;
new_w = canvas_w + (window->get_w() - mwindow->theme->rmonitor_canvas_w);
new_h = canvas_h + (window->get_h() - mwindow->theme->rmonitor_canvas_h);
window->resize_window(new_w, new_h);
window->resize_event(new_w, new_h);
}
/** Write the section table section back to disk */
void
SgAsmElfSectionTable::unparse(std::ostream &f) const
{
SgAsmElfFileHeader *fhdr = dynamic_cast<SgAsmElfFileHeader*>(get_header());
ROSE_ASSERT(fhdr!=NULL);
ByteOrder sex = fhdr->get_sex();
SgAsmGenericSectionPtrList sections = fhdr->get_sectab_sections();
/* Write the sections first */
for (size_t i=0; i<sections.size(); i++)
sections[i]->unparse(f);
unparse_holes(f);
/* Calculate sizes. The ELF File Header should have been updated in reallocate() prior to unparsing. */
size_t ent_size, struct_size, opt_size, nentries;
calculate_sizes(&ent_size, &struct_size, &opt_size, &nentries);
ROSE_ASSERT(fhdr->get_shextrasz()==opt_size);
ROSE_ASSERT(fhdr->get_e_shnum()==nentries);
/* Write the section table entries */
for (size_t i=0; i<sections.size(); ++i) {
SgAsmElfSection *section = dynamic_cast<SgAsmElfSection*>(sections[i]);
ROSE_ASSERT(section!=NULL);
SgAsmElfSectionTableEntry *shdr = section->get_section_entry();
ROSE_ASSERT(shdr!=NULL);
ROSE_ASSERT(shdr->get_sh_offset()==section->get_offset());/*section table entry should have been updated in reallocate()*/
int id = section->get_id();
ROSE_ASSERT(id>=0 && (size_t)id<nentries);
SgAsmElfSectionTableEntry::Elf32SectionTableEntry_disk disk32;
SgAsmElfSectionTableEntry::Elf64SectionTableEntry_disk disk64;
void *disk = NULL;
if (4==fhdr->get_word_size()) {
disk = shdr->encode(sex, &disk32);
} else if (8==fhdr->get_word_size()) {
disk = shdr->encode(sex, &disk64);
} else {
ROSE_ASSERT(!"invalid word size");
}
/* The disk struct */
rose_addr_t spos = write(f, id*ent_size, struct_size, disk);
if (shdr->get_extra().size() > 0) {
ROSE_ASSERT(shdr->get_extra().size()<=opt_size);
write(f, spos, shdr->get_extra());
}
}
}
MonoPIFunc
mono_arch_create_trampoline (MonoMethodSignature *sig, gboolean string_ctor)
{
guint32 *p, *code_buffer;
guint stack_size, code_size, i;
gboolean use_memcpy = FALSE;
static GHashTable *cache = NULL;
MonoPIFunc res;
if (!cache)
cache = g_hash_table_new ((GHashFunc)mono_signature_hash,
(GCompareFunc)mono_metadata_signature_equal);
if ((res = (MonoPIFunc)g_hash_table_lookup(cache, sig)))
return res;
calculate_sizes (sig, &stack_size, &code_size,
string_ctor, &use_memcpy);
p = code_buffer = alloc_code_memory (code_size);
p = emit_prolog (p, sig, stack_size);
p = emit_save_parameters (p, sig, stack_size, use_memcpy);
p = emit_call_and_store_retval (p, sig, stack_size, string_ctor);
/* we don't return structs here so pass in NULL as signature */
p = emit_epilog (p, NULL, stack_size);
g_assert(p <= code_buffer + (code_size / 4));
DEBUG(sparc_disassemble_code (code_buffer, p, sig_to_name(sig, NULL)));
/* So here's the deal...
* UltraSPARC will flush a whole cache line at a time
* BUT, older SPARCs won't.
* So, be compatable and flush dwords at a time...
*/
for (i = 0; i < ((p - code_buffer)/2); i++)
flushi((code_buffer + (i*8)));
g_hash_table_insert(cache, sig, code_buffer);
return (MonoPIFunc)code_buffer;
}
/** Write symbol table sections back to disk */
void
SgAsmElfSymbolSection::unparse(std::ostream &f) const
{
SgAsmElfFileHeader *fhdr = get_elf_header();
ROSE_ASSERT(fhdr);
ByteOrder sex = fhdr->get_sex();
size_t entry_size, struct_size, extra_size, nentries;
calculate_sizes(&entry_size, &struct_size, &extra_size, &nentries);
/* Adjust the entry size stored in the ELF Section Table */
get_section_entry()->set_sh_entsize(entry_size);
/* Write each entry's required part followed by the optional part */
for (size_t i=0; i<nentries; i++) {
SgAsmElfSymbol::Elf32SymbolEntry_disk disk32;
SgAsmElfSymbol::Elf64SymbolEntry_disk disk64;
void *disk=NULL;
SgAsmElfSymbol *entry = p_symbols->get_symbols()[i];
if (4==fhdr->get_word_size()) {
disk = entry->encode(sex, &disk32);
} else if (8==fhdr->get_word_size()) {
disk = entry->encode(sex, &disk64);
} else {
ROSE_ASSERT(!"unsupported word size");
}
rose_addr_t spos = i * entry_size;
spos = write(f, spos, struct_size, disk);
if (entry->get_extra().size()>0) {
ROSE_ASSERT(entry->get_extra().size()<=extra_size);
write(f, spos, entry->get_extra());
}
}
unparse_holes(f);
}
/** Initializes this ELF Symbol Section by parsing a file. */
SgAsmElfSymbolSection *
SgAsmElfSymbolSection::parse()
{
SgAsmElfSection::parse();
SgAsmElfFileHeader *fhdr = get_elf_header();
ROSE_ASSERT(fhdr!=NULL);
SgAsmElfSectionTableEntry *shdr = get_section_entry();
ROSE_ASSERT(shdr!=NULL);
SgAsmElfStringSection *strsec = dynamic_cast<SgAsmElfStringSection*>(get_linked_section());
ROSE_ASSERT(strsec!=NULL);
size_t entry_size, struct_size, extra_size, nentries;
calculate_sizes(&entry_size, &struct_size, &extra_size, &nentries);
ROSE_ASSERT(entry_size==shdr->get_sh_entsize());
/* Parse each entry */
for (size_t i=0; i<nentries; i++) {
SgAsmElfSymbol *entry=0;
if (4==fhdr->get_word_size()) {
entry = new SgAsmElfSymbol(this); /*adds symbol to this symbol table*/
SgAsmElfSymbol::Elf32SymbolEntry_disk disk;
read_content_local(i*entry_size, &disk, struct_size);
entry->parse(fhdr->get_sex(), &disk);
} else if (8==fhdr->get_word_size()) {
entry = new SgAsmElfSymbol(this); /*adds symbol to this symbol table*/
SgAsmElfSymbol::Elf64SymbolEntry_disk disk;
read_content_local(i*entry_size, &disk, struct_size);
entry->parse(fhdr->get_sex(), &disk);
} else {
throw FormatError("unsupported ELF word size");
}
if (extra_size>0)
entry->get_extra() = read_content_local_ucl(i*entry_size+struct_size, extra_size);
}
return this;
}
void ScopeGUI::create_panels()
{
calculate_sizes(get_w(), get_h());
if((use_wave || use_wave_parade))
{
if(!waveform)
{
add_subwindow(waveform = new ScopeWaveform(this,
wave_x,
wave_y,
wave_w,
wave_h));
waveform->create_objects();
}
else
{
waveform->reposition_window(wave_x,
wave_y,
wave_w,
wave_h);
waveform->clear_box(0, 0, wave_w, wave_h);
}
}
else
if(!(use_wave || use_wave_parade) && waveform)
{
delete waveform;
waveform = 0;
}
if(use_vector)
{
if(!vectorscope)
{
add_subwindow(vectorscope = new ScopeVectorscope(this,
vector_x,
vector_y,
vector_w,
vector_h));
vectorscope->create_objects();
}
else
{
vectorscope->reposition_window(vector_x,
vector_y,
vector_w,
vector_h);
vectorscope->clear_box(0, 0, vector_w, vector_h);
}
}
else
if(!use_vector && vectorscope)
{
delete vectorscope;
vectorscope = 0;
}
if((use_hist || use_hist_parade))
{
if(!histogram)
{
// printf("ScopeGUI::create_panels %d %d %d %d %d\n", __LINE__, hist_x,
// hist_y,
// hist_w,
// hist_h);
add_subwindow(histogram = new ScopeHistogram(this,
hist_x,
hist_y,
hist_w,
hist_h));
histogram->create_objects();
}
else
{
histogram->reposition_window(hist_x,
hist_y,
hist_w,
hist_h);
histogram->clear_box(0, 0, hist_w, hist_h);
}
}
else
if(!(use_hist || use_hist_parade))
{
delete histogram;
histogram = 0;
}
allocate_bitmaps();
clear_points(0);
draw_overlays(1, 1, 0);
}
/** Parses an ELF Segment (Program Header) Table and constructs and parses all segments reachable from the table. The section
* is extended as necessary based on the number of entries and teh size of each entry. */
SgAsmElfSegmentTable *
SgAsmElfSegmentTable::parse()
{
SgAsmGenericSection::parse();
SgAsmElfFileHeader *fhdr = dynamic_cast<SgAsmElfFileHeader*>(get_header());
ROSE_ASSERT(fhdr!=NULL);
ByteOrder sex = fhdr->get_sex();
size_t ent_size, struct_size, opt_size, nentries;
calculate_sizes(&ent_size, &struct_size, &opt_size, &nentries);
ROSE_ASSERT(opt_size==fhdr->get_phextrasz() && nentries==fhdr->get_e_phnum());
/* If the current size is very small (0 or 1 byte) then we're coming straight from the constructor and the parsing should
* also extend this section to hold all the entries. Otherwise the caller must have assigned a specific size for a good
* reason and we should leave that alone, reading zeros if the entries extend beyond the defined size. */
if (get_size()<=1 && get_size()<nentries*ent_size)
extend(nentries*ent_size - get_size());
rose_addr_t offset=0; /* w.r.t. the beginning of this section */
for (size_t i=0; i<nentries; i++, offset+=ent_size) {
/* Read/decode the segment header */
SgAsmElfSegmentTableEntry *shdr = NULL;
if (4==fhdr->get_word_size()) {
SgAsmElfSegmentTableEntry::Elf32SegmentTableEntry_disk disk;
read_content_local(offset, &disk, struct_size);
shdr = new SgAsmElfSegmentTableEntry(sex, &disk);
} else {
SgAsmElfSegmentTableEntry::Elf64SegmentTableEntry_disk disk;
read_content_local(offset, &disk, struct_size);
shdr = new SgAsmElfSegmentTableEntry(sex, &disk);
}
shdr->set_index(i);
if (opt_size>0)
shdr->get_extra() = read_content_local_ucl(offset+struct_size, opt_size);
/* Null segments are just unused slots in the table; no real section to create */
if (SgAsmElfSegmentTableEntry::PT_NULL == shdr->get_type())
continue;
/* Create SgAsmElfSection objects for each ELF Segment. However, if the ELF Segment Table describes a segment
* that's the same offset and size as a section from the Elf Section Table (and the memory mappings are
* consistent) then use the preexisting section instead of creating a new one. */
SgAsmElfSection *s = NULL;
SgAsmGenericSectionPtrList possible = fhdr->get_file()->get_sections_by_offset(shdr->get_offset(), shdr->get_filesz());
for (size_t j=0; !s && j<possible.size(); j++) {
if (possible[j]->get_offset()!=shdr->get_offset() || possible[j]->get_size()!=shdr->get_filesz())
continue; /*different file extent*/
if (possible[j]->is_mapped()) {
if (possible[j]->get_mapped_preferred_rva()!=shdr->get_vaddr() ||
possible[j]->get_mapped_size()!=shdr->get_memsz())
continue; /*different mapped address or size*/
unsigned section_perms = (possible[j]->get_mapped_rperm() ? 0x01 : 0x00) |
(possible[j]->get_mapped_wperm() ? 0x02 : 0x00) |
(possible[j]->get_mapped_xperm() ? 0x04 : 0x00);
unsigned segment_perms = (shdr->get_flags() & SgAsmElfSegmentTableEntry::PF_RPERM ? 0x01 : 0x00) |
(shdr->get_flags() & SgAsmElfSegmentTableEntry::PF_WPERM ? 0x02 : 0x00) |
(shdr->get_flags() & SgAsmElfSegmentTableEntry::PF_XPERM ? 0x04 : 0x00);
if (section_perms != segment_perms)
continue; /*different mapped permissions*/
}
/* Found a match. Set memory mapping params only. */
s = dynamic_cast<SgAsmElfSection*>(possible[j]);
if (!s) continue; /*potential match was not from the ELF Section or Segment table*/
if (s->get_segment_entry()) continue; /*potential match is assigned to some other segment table entry*/
s->init_from_segment_table(shdr, true); /*true=>set memory mapping params only*/
}
/* Create a new segment if no matching section was found. */
if (!s) {
if (SgAsmElfSegmentTableEntry::PT_NOTE == shdr->get_type()) {
s = new SgAsmElfNoteSection(fhdr);
} else {
s = new SgAsmElfSection(fhdr);
}
s->init_from_segment_table(shdr);
s->parse();
}
}
return this;
}
rose_addr_t
SgAsmElfSection::calculate_sizes(size_t *entsize, size_t *required, size_t *optional, size_t *entcount) const
{
return calculate_sizes(0, 0, std::vector<size_t>(), entsize, required, optional, entcount);
}
/** Parses an ELF Section Table and constructs and parses all sections reachable from the table. The section is extended as
* necessary based on the number of entries and the size of each entry. */
SgAsmElfSectionTable *
SgAsmElfSectionTable::parse()
{
SgAsmGenericSection::parse();
SgAsmElfFileHeader *fhdr = dynamic_cast<SgAsmElfFileHeader*>(get_header());
ROSE_ASSERT(fhdr!=NULL);
ByteOrder sex = fhdr->get_sex();
size_t ent_size, struct_size, opt_size, nentries;
calculate_sizes(&ent_size, &struct_size, &opt_size, &nentries);
ROSE_ASSERT(opt_size==fhdr->get_shextrasz() && nentries==fhdr->get_e_shnum());
/* If the current size is very small (0 or 1 byte) then we're coming straight from the constructor and the parsing should
* also extend this section to hold all the entries. Otherwise the caller must have assigned a specific size for a good
* reason and we should leave that alone, reading zeros if the entries extend beyond the defined size. */
if (get_size()<=1 && get_size()<nentries*ent_size)
extend(nentries*ent_size - get_size());
/* Read all the section headers. */
std::vector<SgAsmElfSectionTableEntry*> entries;
rose_addr_t offset = 0;
for (size_t i=0; i<nentries; i++, offset+=ent_size) {
SgAsmElfSectionTableEntry *shdr = NULL;
if (4 == fhdr->get_word_size()) {
SgAsmElfSectionTableEntry::Elf32SectionTableEntry_disk disk;
read_content_local(offset, &disk, struct_size);
shdr = new SgAsmElfSectionTableEntry(sex, &disk);
} else {
SgAsmElfSectionTableEntry::Elf64SectionTableEntry_disk disk;
read_content_local(offset, &disk, struct_size);
shdr = new SgAsmElfSectionTableEntry(sex, &disk);
}
if (opt_size>0)
shdr->get_extra() = read_content_local_ucl(offset+struct_size, opt_size);
entries.push_back(shdr);
}
/* This vector keeps track of which sections have already been parsed. We could get the same information by calling
* fhdr->get_section_by_id() and passing the entry number since entry numbers and IDs are one and the same in ELF. However,
* this is a bit easier. */
std::vector<SgAsmElfSection*> is_parsed;
is_parsed.resize(entries.size(), NULL);
/* All sections implicitly depend on the section string table for their names. */
SgAsmElfStringSection *section_name_strings=NULL;
if (fhdr->get_e_shstrndx() > 0) {
SgAsmElfSectionTableEntry *entry = entries[fhdr->get_e_shstrndx()];
section_name_strings = new SgAsmElfStringSection(fhdr);
section_name_strings->init_from_section_table(entry, section_name_strings, fhdr->get_e_shstrndx());
section_name_strings->parse();
is_parsed[fhdr->get_e_shstrndx()] = section_name_strings;
}
/* Read all the sections. Some sections depend on other sections, so we read them in such an order that all dependencies
* are satisfied first. */
while (1) {
bool try_again=false;
for (size_t i=0; i<entries.size(); i++) {
SgAsmElfSectionTableEntry *entry = entries[i];
ROSE_ASSERT(entry->get_sh_link()<entries.size());
/* Some sections might reference another section through the sh_link member. */
bool need_linked = entry->get_sh_link() > 0;
ROSE_ASSERT(!need_linked || entry->get_sh_link()<entries.size());
SgAsmElfSection *linked = need_linked ? is_parsed[entry->get_sh_link()] : NULL;
/* Relocation sections might have a second linked section stored in sh_info. */
bool need_info_linked = (entry->get_sh_type() == SgAsmElfSectionTableEntry::SHT_REL ||
entry->get_sh_type() == SgAsmElfSectionTableEntry::SHT_RELA) &&
entry->get_sh_info() > 0;
ROSE_ASSERT(!need_info_linked || entry->get_sh_info()<entries.size());
SgAsmElfSection *info_linked = need_info_linked ? is_parsed[entry->get_sh_info()] : NULL;
if (is_parsed[i]) {
/* This section has already been parsed. */
} else if ((need_linked && !linked) || (need_info_linked && !info_linked)) {
/* Don't parse this section yet because it depends on something that's not parsed yet. */
try_again = true;
} else {
switch (entry->get_sh_type()) {
case SgAsmElfSectionTableEntry::SHT_NULL:
/* Null entry. We still create the section just to hold the section header. */
is_parsed[i] = new SgAsmElfSection(fhdr);
break;
case SgAsmElfSectionTableEntry::SHT_NOBITS:
/* These types of sections don't occupy any file space (e.g., BSS) */
is_parsed[i] = new SgAsmElfSection(fhdr);
break;
case SgAsmElfSectionTableEntry::SHT_DYNAMIC: {
SgAsmElfStringSection *strsec = dynamic_cast<SgAsmElfStringSection*>(linked);
ROSE_ASSERT(strsec);
is_parsed[i] = new SgAsmElfDynamicSection(fhdr, strsec);
break;
}
case SgAsmElfSectionTableEntry::SHT_DYNSYM: {
SgAsmElfStringSection *strsec = dynamic_cast<SgAsmElfStringSection*>(linked);
ROSE_ASSERT(strsec);
SgAsmElfSymbolSection *symsec = new SgAsmElfSymbolSection(fhdr, strsec);
symsec->set_is_dynamic(true);
is_parsed[i] = symsec;
break;
}
case SgAsmElfSectionTableEntry::SHT_SYMTAB: {
SgAsmElfStringSection *strsec = dynamic_cast<SgAsmElfStringSection*>(linked);
ROSE_ASSERT(strsec);
SgAsmElfSymbolSection *symsec = new SgAsmElfSymbolSection(fhdr, strsec);
symsec->set_is_dynamic(false);
is_parsed[i] = symsec;
break;
}
case SgAsmElfSectionTableEntry::SHT_STRTAB:
is_parsed[i] = new SgAsmElfStringSection(fhdr);
break;
case SgAsmElfSectionTableEntry::SHT_REL: {
SgAsmElfSymbolSection *symbols = dynamic_cast<SgAsmElfSymbolSection*>(linked);
SgAsmElfRelocSection *relocsec = new SgAsmElfRelocSection(fhdr, symbols, info_linked);
relocsec->set_uses_addend(false);
is_parsed[i] = relocsec;
break;
}
case SgAsmElfSectionTableEntry::SHT_RELA: {
SgAsmElfSymbolSection *symbols = dynamic_cast<SgAsmElfSymbolSection*>(linked);
SgAsmElfRelocSection *relocsec = new SgAsmElfRelocSection(fhdr, symbols, info_linked);
relocsec->set_uses_addend(true);
is_parsed[i] = relocsec;
break;
}
case SgAsmElfSectionTableEntry::SHT_PROGBITS: {
if (!section_name_strings) {
fprintf(stderr, "SgAsmElfSectionTable::parse(): no string table for section table\n");
is_parsed[i] = new SgAsmElfSection(fhdr);
} else {
std::string section_name = section_name_strings->read_content_local_str(entry->get_sh_name());
if (section_name == ".eh_frame") {
is_parsed[i] = new SgAsmElfEHFrameSection(fhdr);
} else {
is_parsed[i] = new SgAsmElfSection(fhdr);
}
}
break;
}
case SgAsmElfSectionTableEntry::SHT_GNU_versym: {
is_parsed[i] = new SgAsmElfSymverSection(fhdr);
break;
}
case SgAsmElfSectionTableEntry::SHT_GNU_verdef: {
SgAsmElfStringSection *strsec = dynamic_cast<SgAsmElfStringSection*>(linked);
ROSE_ASSERT(strsec);
is_parsed[i] = new SgAsmElfSymverDefinedSection(fhdr,strsec);
break;
}
case SgAsmElfSectionTableEntry::SHT_GNU_verneed: {
SgAsmElfStringSection *strsec = dynamic_cast<SgAsmElfStringSection*>(linked);
ROSE_ASSERT(strsec);
is_parsed[i] = new SgAsmElfSymverNeededSection(fhdr,strsec);
break;
}
default:
is_parsed[i] = new SgAsmElfSection(fhdr);
break;
}
is_parsed[i]->init_from_section_table(entry, section_name_strings, i);
is_parsed[i]->parse();
}
}
if (!try_again)
break;
}
/* Initialize links between sections */
for (size_t i = 0; i < entries.size(); i++) {
SgAsmElfSectionTableEntry *shdr = entries[i];
if (shdr->get_sh_link() > 0) {
SgAsmElfSection *source = isSgAsmElfSection(fhdr->get_file()->get_section_by_id(i));
SgAsmElfSection *target = isSgAsmElfSection(fhdr->get_file()->get_section_by_id(shdr->get_sh_link()));
assert(source); /* because we created it above */
source->set_linked_section(target);
}
}
/* Finish parsing sections now that we have basic info for all the sections. */
for (size_t i=0; i<is_parsed.size(); i++)
is_parsed[i]->finish_parsing();
return this;
}
