darling-gdb/gold/merge.h

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2007-05-16 17:42:48 +00:00
// merge.h -- handle section merging for gold -*- C++ -*-
#ifndef GOLD_MERGE_H
#define GOLD_MERGE_H
#include <climits>
#include "stringpool.h"
#include "output.h"
namespace gold
{
// A general class for SHF_MERGE data, to hold functions shared by
// fixed-size constant data and string data.
class Output_merge_base : public Output_section_data
{
public:
Output_merge_base(uint64_t entsize)
: Output_section_data(1), merge_map_(), entsize_(entsize)
{ }
// Return the output address for an input address.
bool
do_output_address(const Relobj* object, unsigned int shndx, off_t offset,
uint64_t output_section_address, uint64_t* poutput) const;
protected:
// Return the entry size.
uint64_t
entsize() const
{ return this->entsize_; }
// Add a mapping from an OFFSET in input section SHNDX in object
// OBJECT to an OUTPUT_OFFSET in the output section.
void
add_mapping(Relobj* object, unsigned int shndx, off_t offset,
off_t output_offset);
private:
// We build a mapping from OBJECT/SHNDX/OFFSET to an offset in the
// output section.
struct Merge_key
{
const Relobj* object;
unsigned int shndx;
off_t offset;
};
struct Merge_key_less
{
bool
operator()(const Merge_key&, const Merge_key&) const;
};
typedef std::map<Merge_key, off_t, Merge_key_less> Merge_map;
// A mapping from input object/section/offset to offset in output
// section.
Merge_map merge_map_;
// The entry size. For fixed-size constants, this is the size of
// the constants. For strings, this is the size of a character.
uint64_t entsize_;
};
// Handle SHF_MERGE sections with fixed-size constant data.
class Output_merge_data : public Output_merge_base
{
public:
Output_merge_data(uint64_t entsize)
: Output_merge_base(entsize), p_(NULL), len_(0), alc_(0),
hashtable_(128, Merge_data_hash(this), Merge_data_eq(this))
{ }
// Add an input section.
bool
do_add_input_section(Relobj* object, unsigned int shndx);
// Set the final data size.
void
do_set_address(uint64_t, off_t);
// Write the data to the file.
void
do_write(Output_file*);
private:
// We build a hash table of the fixed-size constants. Each constant
// is stored as a pointer into the section data we are accumulating.
// A key in the hash table. This is an offset in the section
// contents we are building.
typedef off_t Merge_data_key;
// Compute the hash code. To do this we need a pointer back to the
// object holding the data.
class Merge_data_hash
{
public:
Merge_data_hash(const Output_merge_data* pomd)
: pomd_(pomd)
{ }
size_t
operator()(Merge_data_key) const;
private:
const Output_merge_data* pomd_;
};
friend class Merge_data_hash;
// Compare two entries in the hash table for equality. To do this
// we need a pointer back to the object holding the data. Note that
// we now have a pointer to the object stored in two places in the
// hash table. Fixing this would require specializing the hash
// table, which would be hard to do portably.
class Merge_data_eq
{
public:
Merge_data_eq(const Output_merge_data* pomd)
: pomd_(pomd)
{ }
bool
operator()(Merge_data_key k1, Merge_data_key k2) const;
private:
const Output_merge_data* pomd_;
};
friend class Merge_data_eq;
// The type of the hash table.
typedef Unordered_set<Merge_data_key, Merge_data_hash, Merge_data_eq>
Merge_data_hashtable;
// Given a hash table key, which is just an offset into the section
// data, return a pointer to the corresponding constant.
const unsigned char*
constant(Merge_data_key k) const
{
gold_assert(k >= 0 && k < this->len_);
return this->p_ + k;
}
// Add a constant to the output.
void
add_constant(const unsigned char*);
// The accumulated data.
unsigned char* p_;
// The length of the accumulated data.
off_t len_;
// The size of the allocated buffer.
size_t alc_;
// The hash table.
Merge_data_hashtable hashtable_;
};
// Handle SHF_MERGE sections with string data. This is a template
// based on the type of the characters in the string.
template<typename Char_type>
class Output_merge_string : public Output_merge_base
{
public:
Output_merge_string()
: Output_merge_base(sizeof(Char_type)), stringpool_(false), hashtable_()
{ }
// Add an input section.
bool
do_add_input_section(Relobj* object, unsigned int shndx);
// Set the final data size.
void
do_set_address(uint64_t, off_t);
// Write the data to the file.
void
do_write(Output_file*);
private:
// As we see input sections, we build a mapping from object, section
// index and offset to strings.
struct Merge_string_key
{
Relobj* object;
unsigned int shndx;
off_t offset;
Merge_string_key(Relobj *objecta, unsigned int shndxa, off_t offseta)
: object(objecta), shndx(shndxa), offset(offseta)
{ }
};
struct Merge_string_key_hash
{
size_t
operator()(const Merge_string_key&) const;
};
struct Merge_string_key_eq
{
bool
operator()(const Merge_string_key&, const Merge_string_key&) const;
};
typedef Unordered_map<Merge_string_key, const Char_type*,
Merge_string_key_hash, Merge_string_key_eq>
Merge_string_hashtable;
// As we see the strings, we add them to a Stringpool.
Stringpool_template<Char_type> stringpool_;
// Map from a location in an input object to an entry in the
// Stringpool.
Merge_string_hashtable hashtable_;
};
} // End namespace gold.
#endif // !defined(GOLD_MERGE_H)