// merge.cc -- handle section merging for gold #include "gold.h" #include #include "merge.h" namespace gold { // Sort the entries in a merge mapping. The key is an input object, a // section index in that object, and an offset in that section. bool Output_merge_base::Merge_key_less::operator()(const Merge_key& mk1, const Merge_key& mk2) const { // The order of different objects and different sections doesn't // matter. We want to get consistent results across links so we // don't use pointer comparison. if (mk1.object != mk2.object) return mk1.object->name() < mk2.object->name(); if (mk1.shndx != mk2.shndx) return mk1.shndx < mk2.shndx; return mk1.offset < mk2.offset; } // Add a mapping from an OFFSET in input section SHNDX in object // OBJECT to an OUTPUT_OFFSET in a merged output section. This // manages the mapping used to resolve relocations against merged // sections. void Output_merge_base::add_mapping(Relobj* object, unsigned int shndx, off_t offset, off_t output_offset) { Merge_key mk; mk.object = object; mk.shndx = shndx; mk.offset = offset; std::pair ins = this->merge_map_.insert(std::make_pair(mk, output_offset)); gold_assert(ins.second); } // Return the output address for an input address. The input address // is at offset OFFSET in section SHNDX in OBJECT. // OUTPUT_SECTION_ADDRESS is the address of the output section. If we // know the address, set *POUTPUT and return true. Otherwise return // false. bool Output_merge_base::do_output_address(const Relobj* object, unsigned int shndx, off_t offset, uint64_t output_section_address, uint64_t* poutput) const { gold_assert(output_section_address == this->address()); Merge_key mk; mk.object = object; mk.shndx = shndx; mk.offset = offset; Merge_map::const_iterator p = this->merge_map_.lower_bound(mk); // If MK is not in the map, lower_bound returns the next iterator // larger than it. if (p->first.object != object || p->first.shndx != shndx || p->first.offset != offset) { if (p == this->merge_map_.begin()) return false; --p; } if (p->first.object != object || p->first.shndx != shndx) return false; // Any input section is fully mapped: we don't need to know the size // of the range starting at P->FIRST.OFFSET. *poutput = output_section_address + p->second + (offset - p->first.offset); return true; } // Compute the hash code for a fixed-size constant. size_t Output_merge_data::Merge_data_hash::operator()(Merge_data_key k) const { const unsigned char* p = this->pomd_->constant(k); uint64_t entsize = this->pomd_->entsize(); // Fowler/Noll/Vo (FNV) hash (type FNV-1a). if (sizeof(size_t) == 8) { size_t result = static_cast(14695981039346656037ULL); for (uint64_t i = 0; i < entsize; ++i) { result &= (size_t) *p++; result *= 1099511628211ULL; } return result; } else { size_t result = 2166136261UL; for (uint64_t i = 0; i < entsize; ++i) { result ^= (size_t) *p++; result *= 16777619UL; } return result; } } // Return whether one hash table key equals another. bool Output_merge_data::Merge_data_eq::operator()(Merge_data_key k1, Merge_data_key k2) const { const unsigned char* p1 = this->pomd_->constant(k1); const unsigned char* p2 = this->pomd_->constant(k2); return memcmp(p1, p2, this->pomd_->entsize()) == 0; } // Add a constant to the end of the section contents. void Output_merge_data::add_constant(const unsigned char* p) { uint64_t entsize = this->entsize(); if (this->len_ + entsize > this->alc_) { if (this->alc_ == 0) this->alc_ = 128 * entsize; else this->alc_ *= 2; this->p_ = static_cast(realloc(this->p_, this->alc_)); if (this->p_ == NULL) gold_fatal("out of memory", true); } memcpy(this->p_ + this->len_, p, entsize); this->len_ += entsize; } // Add the input section SHNDX in OBJECT to a merged output section // which holds fixed length constants. Return whether we were able to // handle the section; if not, it will be linked as usual without // constant merging. bool Output_merge_data::do_add_input_section(Relobj* object, unsigned int shndx) { off_t len; const unsigned char* p = object->section_contents(shndx, &len); uint64_t entsize = this->entsize(); if (len % entsize != 0) return false; for (off_t i = 0; i < len; i += entsize, p += entsize) { // Add the constant to the section contents. If we find that it // is already in the hash table, we will remove it again. Merge_data_key k = this->len_; this->add_constant(p); std::pair ins = this->hashtable_.insert(k); if (!ins.second) { // Key was already present. Remove the copy we just added. this->len_ -= entsize; k = *ins.first; } // Record the offset of this constant in the output section. this->add_mapping(object, shndx, i, k); } return true; } // Set the final data size in a merged output section with fixed size // constants. void Output_merge_data::do_set_address(uint64_t, off_t) { // Release the memory we don't need. this->p_ = static_cast(realloc(this->p_, this->len_)); gold_assert(this->p_ != NULL); this->set_data_size(this->len_); } // Write the data of a merged output section with fixed size constants // to the file. void Output_merge_data::do_write(Output_file* of) { of->write(this->offset(), this->p_, this->len_); } // Compute a hash code for a Merge_string_key, which is an object, a // section index, and an offset. template size_t Output_merge_string::Merge_string_key_hash::operator()( const Merge_string_key& key) const { // This is a very simple minded hash code. Fix it if it we get too // many collisions. const std::string& oname(key.object->name()); return oname[0] + oname.length() + key.shndx + key.offset; } // Compare two Merge_string_keys for equality. template bool Output_merge_string::Merge_string_key_eq::operator()( const Merge_string_key& k1, const Merge_string_key& k2) const { return (k1.object == k2.object && k1.shndx == k2.shndx && k1.offset == k2.offset); } // Add an input section to a merged string section. template bool Output_merge_string::do_add_input_section(Relobj* object, unsigned int shndx) { off_t len; const unsigned char* pdata = object->section_contents(shndx, &len); const Char_type* p = reinterpret_cast(pdata); if (len % sizeof(Char_type) != 0) { fprintf(stderr, _("%s: %s: mergeable string section length not multiple of " "character size\n"), program_name, object->name().c_str()); gold_exit(false); } len /= sizeof(Char_type); off_t i = 0; while (i < len) { off_t plen = 0; for (const Char_type* pl = p; *pl != 0; ++pl) { ++plen; if (i + plen >= len) { fprintf(stderr, _("%s: %s: entry in mergeable string section " "not null terminated\n"), program_name, object->name().c_str()); gold_exit(false); } } const Char_type* str = this->stringpool_.add(p, NULL); Merge_string_key k(object, shndx, i); typename Merge_string_hashtable::value_type v(k, str); bool b = this->hashtable_.insert(v).second; gold_assert(b); p += plen + 1; i += plen + 1; } return true; } // Set the final data size of a merged string section. This is where // we finalize the mappings from the input sections to the output // section. template void Output_merge_string::do_set_address(uint64_t, off_t) { this->stringpool_.set_string_offsets(); for (typename Merge_string_hashtable::const_iterator p = this->hashtable_.begin(); p != this->hashtable_.end(); ++p) this->add_mapping(p->first.object, p->first.shndx, p->first.offset, this->stringpool_.get_offset(p->second)); this->set_data_size(this->stringpool_.get_strtab_size()); // Save some memory. this->hashtable_.clear(); } // Write out a merged string section. template void Output_merge_string::do_write(Output_file* of) { this->stringpool_.write(of, this->offset()); } // Instantiate the templates we need. template class Output_merge_string; template class Output_merge_string; template class Output_merge_string; } // End namespace gold.