binutils-gdb/gold/arm-reloc-property.cc
Doug Kwan 6cfaf60bc2 2010-02-04 Doug Kwan <dougkwan@google.com>
PR 11247
	* arm-reloc-property.cc (cstdio): Include.
	* configure.ac (targetobjs): Remove duplicates.
	* configure: Regenerate.
	* resolve.cc (Symbol_table::resolve): Explicit instantiate both
	big and little endian version for a given address size.
2010-02-05 00:30:35 +00:00

332 lines
9.2 KiB
C++

// arm-reloc-property.cc -- ARM relocation property.
// Copyright 2010 Free Software Foundation, Inc.
// Written by Doug Kwan <dougkwan@google.com>.
// This file is part of gold.
// This program is free software; you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation; either version 3 of the License, or
// (at your option) any later version.
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
// You should have received a copy of the GNU General Public License
// along with this program; if not, write to the Free Software
// Foundation, Inc., 51 Franklin Street - Fifth Floor, Boston,
// MA 02110-1301, USA.
#include "gold.h"
#include <cstdio>
#include <cstring>
#include <stack>
#include <string>
#include <vector>
#include "elfcpp.h"
#include "arm.h"
#include "arm-reloc-property.h"
namespace gold
{
// Arm_reloc_property::Tree_node methods.
// Parse an S-expression S and build a tree and return the root node.
// Caller is responsible for releasing tree after use.
Arm_reloc_property::Tree_node*
Arm_reloc_property::Tree_node::make_tree(const std::string& s)
{
std::stack<size_t> size_stack;
Tree_node_vector node_stack;
// strtok needs a non-const string pointer.
char* buffer = new char[s.size() + 1];
memcpy(buffer, s.data(), s.size());
buffer[s.size()] = '\0';
char* token = strtok(buffer, " ");
while (token != NULL)
{
if (strcmp(token, "(") == 0)
// Remember the node stack position for start of a new internal node.
size_stack.push(node_stack.size());
else if (strcmp(token, ")") == 0)
{
// Pop all tree nodes after the previous '(' and use them as
// children to build a new internal node. Push internal node back.
size_t current_size = node_stack.size();
size_t prev_size = size_stack.top();
size_stack.pop();
Tree_node* node =
new Tree_node(node_stack.begin() + prev_size,
node_stack.begin() + current_size);
node_stack.resize(prev_size);
node_stack.push_back(node);
}
else
// Just push a leaf node to node_stack.
node_stack.push_back(new Tree_node(token));
token = strtok(NULL, " ");
}
delete[] buffer;
// At this point, size_stack should be empty and node_stack should only
// contain the root node.
gold_assert(size_stack.empty() && node_stack.size() == 1);
return node_stack[0];
}
// Arm_reloc_property methods.
// Constructor.
Arm_reloc_property::Arm_reloc_property(
unsigned int code,
const char* name,
Reloc_type rtype,
bool is_deprecated,
Reloc_class rclass,
const std::string& operation,
bool is_implemented,
int group_index,
bool checks_overflow)
: code_(code), name_(name), reloc_type_(rtype), reloc_class_(rclass),
group_index_(group_index), size_(0), align_(1),
relative_address_base_(RAB_NONE), is_deprecated_(is_deprecated),
is_implemented_(is_implemented), checks_overflow_(checks_overflow),
uses_got_entry_(false), uses_got_origin_(false), uses_plt_entry_(false),
uses_thumb_bit_(false), uses_symbol_base_(false), uses_addend_(false)
{
// Set size and alignment of static and dynamic relocations.
if (rtype == RT_STATIC)
{
switch (rclass)
{
case RC_DATA:
// Except for R_ARM_ABS16 and R_ARM_ABS8, all static data relocations
// have size 4. All static data relocations have alignment of 1.
if (code == elfcpp::R_ARM_ABS8)
this->size_ = 1;
else if (code == elfcpp::R_ARM_ABS16)
this->size_ = 2;
else
this->size_ = 4;
this->align_ = 1;
break;
case RC_MISC:
// R_ARM_V4BX should be treated as an ARM relocation. For all
// others, just use defaults.
if (code != elfcpp::R_ARM_V4BX)
break;
// Fall through.
case RC_ARM:
this->size_ = 4;
this->align_ = 4;
break;
case RC_THM16:
this->size_ = 2;
this->align_ = 2;
break;
case RC_THM32:
this->size_ = 4;
this->align_ = 2;
break;
default:
gold_unreachable();
}
}
else if (rtype == RT_DYNAMIC)
{
// With the exception of R_ARM_COPY, all dynamic relocations requires
// that the place being relocated is a word-aligned 32-bit object.
if (code != elfcpp::R_ARM_COPY)
{
this->size_ = 4;
this->align_ = 4;
}
}
// If no relocation operation is specified, we are done.
if (operation == "NONE")
return;
// Extract information from relocation operation.
Tree_node* root_node = Tree_node::make_tree(operation);
Tree_node* node = root_node;
// Check for an expression of the form XXX - YYY.
if (!node->is_leaf()
&& node->child(0)->is_leaf()
&& node->child(0)->name() == "-")
{
struct RAB_table_entry
{
Relative_address_base rab;
const char* name;
};
static const RAB_table_entry rab_table[] =
{
{ RAB_B_S, "( B S )" },
{ RAB_DELTA_B_S, "( DELTA_B ( S ) )" },
{ RAB_GOT_ORG, "GOT_ORG" },
{ RAB_P, "P" },
{ RAB_Pa, "Pa" },
{ RAB_TLS, "TLS" },
{ RAB_tp, "tp" }
};
static size_t rab_table_size = sizeof(rab_table) / sizeof(rab_table[0]);
const std::string rhs(node->child(2)->s_expression());
for (size_t i = 0; i < rab_table_size; ++i)
if (rhs == rab_table[i].name)
{
this->relative_address_base_ = rab_table[i].rab;
break;
}
gold_assert(this->relative_address_base_ != RAB_NONE);
if (this->relative_address_base_ == RAB_B_S)
this->uses_symbol_base_ = true;
node = node->child(1);
}
// Check for an expression of the form XXX | T.
if (!node->is_leaf()
&& node->child(0)->is_leaf()
&& node->child(0)->name() == "|")
{
gold_assert(node->number_of_children() == 3
&& node->child(2)->is_leaf()
&& node->child(2)->name() == "T");
this->uses_thumb_bit_ = true;
node = node->child(1);
}
// Check for an expression of the form XXX + A.
if (!node->is_leaf()
&& node->child(0)->is_leaf()
&& node->child(0)->name() == "+")
{
gold_assert(node->number_of_children() == 3
&& node->child(2)->is_leaf()
&& node->child(2)->name() == "A");
this->uses_addend_ = true;
node = node->child(1);
}
// Check for an expression of the form XXX(S).
if (!node->is_leaf() && node->child(0)->is_leaf())
{
gold_assert(node->number_of_children() == 2
&& node->child(1)->is_leaf()
&& node->child(1)->name() == "S");
const std::string func(node->child(0)->name());
if (func == "B")
this->uses_symbol_base_ = true;
else if (func == "GOT")
this->uses_got_entry_ = true;
else if (func == "PLT")
this->uses_plt_entry_ = true;
else if (func == "Module" || func == "DELTA_B")
// These are used in dynamic relocations.
;
else
gold_unreachable();
node = node->child(1);
}
gold_assert(node->is_leaf() && node->name() == "S");
delete root_node;
}
// Arm_reloc_property_table methods.
// Constructor. This processing informations in arm-reloc.def to
// initialize the table.
Arm_reloc_property_table::Arm_reloc_property_table()
{
// These appers in arm-reloc.def. Do not rename them.
Parse_expression A("A"), GOT_ORG("GOT_ORG"), NONE("NONE"), P("P"),
Pa("Pa"), S("S"), T("T"), TLS("TLS"), tp("tp");
const bool Y(true), N(false);
for (unsigned int i = 0; i < Property_table_size; ++i)
this->table_[i] = NULL;
#undef RD
#define RD(name, type, deprecated, class, operation, is_implemented, \
group_index, checks_oveflow) \
do \
{ \
unsigned int code = elfcpp::R_ARM_##name; \
gold_assert(code < Property_table_size); \
this->table_[code] = \
new Arm_reloc_property(elfcpp::R_ARM_##name, "R_ARM_" #name, \
Arm_reloc_property::RT_##type, deprecated, \
Arm_reloc_property::RC_##class, \
(operation).s_expression(), is_implemented, \
group_index, checks_oveflow); \
} \
while(0);
#include "arm-reloc.def"
#undef RD
}
// Return a string describing a relocation code that fails to get a
// relocation property in get_implemented_static_reloc_property().
std::string
Arm_reloc_property_table::reloc_name_in_error_message(unsigned int code)
{
gold_assert(code < Property_table_size);
const Arm_reloc_property* arp = this->table_[code];
if (arp == NULL)
{
char buffer[100];
sprintf(buffer, _("invalid reloc %u"), code);
return std::string(buffer);
}
// gold only implements static relocation codes.
Arm_reloc_property::Reloc_type reloc_type = arp->reloc_type();
gold_assert(reloc_type == Arm_reloc_property::RT_STATIC
|| !arp->is_implemented());
const char* prefix = NULL;
switch (reloc_type)
{
case Arm_reloc_property::RT_STATIC:
prefix = arp->is_implemented() ? _("reloc ") : _("unimplemented reloc ");
break;
case Arm_reloc_property::RT_DYNAMIC:
prefix = _("dynamic reloc ");
break;
case Arm_reloc_property::RT_PRIVATE:
prefix = _("private reloc ");
break;
case Arm_reloc_property::RT_OBSOLETE:
prefix = _("obsolete reloc ");
break;
default:
gold_unreachable();
}
return std::string(prefix) + arp->name();
}
} // End namespace gold.