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b9de07a5ff
The entry PC for a DIE, e.g. an inline function, might not be the base address of the DIE. Currently though, in block::entry_pc(), GDB always returns the base address (low-pc or the first address of the first range) as the entry PC. This commit extends the block class to carry the entry PC as a separate member variable. Then the DWARF reader is extended to read and set the entry PC for the block. Now in block::entry_pc(), if the entry PC has been set, this is the value returned. If the entry-pc has not been set to a specific value then the old behaviour of block::entry_pc() remains, GDB will use the block's base address. Not every DIE will set the entry-pc, but GDB still needs to have an entry-pc for every block, so the existing logic supplies the entry-pc for any block where the entry-pc was not set. The DWARF-5 spec for reading the entry PC is a super-set of the spec as found in DWARF-4. For example, if there is no DW_AT_entry_pc then DWARF-4 says to use DW_AT_low_pc while DWARF-5 says to use the base address, which is DW_AT_low_pc or the first address in the first range specified by DW_AT_ranges if there is no DW_AT_low_pc. I have taken the approach of just implementing the DWARF-5 spec for everyone. There doesn't seem to be any benefit to deliberately ignoring a ranges based entry PC value for DWARF-4. If some naughty compiler has emitted that, then lets use it. Similarly, DWARF-4 says that DW_AT_entry_pc is an address. DWARF-5 allows an address or a constant, where the constant is an offset from the base address. I allow both approaches for all DWARF versions. There doesn't seem to be any downsides to this approach. I ran into an issue when testing this patch where GCC would have the DW_AT_entry_pc point to an empty range. When GDB parses the ranges any empty ranges are ignored. As a consequence, the entry-pc appears to be outside the address range of a block. The empty range problem is certainly something that we can, and should address, but that is not the focus of this patch, so for now I'm ignoring that problem. What I have done is added a check: if the DW_AT_entry_pc is outside the range of a block then the entry-pc is ignored, GDB will then fall-back to its default algorithm for computing the entry-pc. If/when in the future we address the empty range problem, these DW_AT_entry_pc attributes will suddenly become valid and GDB will start using them. Until then, GDB continues to operate as it always has. An early version of this patch stored the entry-pc within the block like this: std::optional<CORE_ADDR> m_entry_pc; However, a concern was raised that this, on a 64-bit host, effectively increases the size of block by 16-bytes (8-bytes for the CORE_ADDR, and 8-bytes for the std::optional's bool plus padding). If we remove the std::optional part and just use a CORE_ADDR then we need to have a "special" address to indicate if m_entry_pc is in use or not. I don't really like using special addresses; different targets can access different address ranges, even zero is a valid address on some targets. However, Bernd Edlinger suggested storing the entry-pc as an offset, and I think that will resolve my concerns. So, we store the entry-pc as a signed offset from the block's base address (the first address of the first range, or the start() address value if there are now ranges). Remember, ranges can be out of order, in which case the first address of the first range might be greater than the entry-pc. When GDB needs to read the entry-pc we can add the offset onto the blocks base address to recalculate it. With this done, on a 64-bit host, block only needs to increase by 8-bytes. The inline-entry.exp test was originally contributed by Bernd here: https://inbox.sourceware.org/gdb-patches/AS1PR01MB94659E4D9B3F4A6006CC605FE4922@AS1PR01MB9465.eurprd01.prod.exchangelabs.com though I have made some edits, making more use of lib/gdb.exp functions, making the gdb_test output patterns a little tighter, and updating the test to run with Clang. I also moved the test to gdb.opt/ as that seemed like a better home for it. Co-Authored-By: Bernd Edlinger <bernd.edlinger@hotmail.de>
658 lines
20 KiB
C++
658 lines
20 KiB
C++
/* Code dealing with blocks for GDB.
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Copyright (C) 2003-2024 Free Software Foundation, Inc.
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This file is part of GDB.
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This program is free software; you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation; either version 3 of the License, or
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(at your option) any later version.
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This program is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program. If not, see <http://www.gnu.org/licenses/>. */
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#ifndef BLOCK_H
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#define BLOCK_H
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#include "dictionary.h"
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#include "gdbsupport/array-view.h"
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#include "gdbsupport/next-iterator.h"
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/* Opaque declarations. */
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struct symbol;
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struct compunit_symtab;
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struct block_namespace_info;
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struct using_direct;
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struct obstack;
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struct addrmap_fixed;
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/* Blocks can occupy non-contiguous address ranges. When this occurs,
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startaddr and endaddr within struct block (still) specify the lowest
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and highest addresses of all ranges, but each individual range is
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specified by the addresses in struct blockrange. */
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struct blockrange
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{
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blockrange (CORE_ADDR start, CORE_ADDR end)
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: m_start (start),
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m_end (end)
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{
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}
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/* Return this blockrange's start address. */
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CORE_ADDR start () const
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{ return m_start; }
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/* Set this blockrange's start address. */
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void set_start (CORE_ADDR start)
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{ m_start = start; }
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/* Return this blockrange's end address. */
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CORE_ADDR end () const
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{ return m_end; }
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/* Set this blockrange's end address. */
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void set_end (CORE_ADDR end)
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{ m_end = end; }
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/* Lowest address in this range. */
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CORE_ADDR m_start;
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/* One past the highest address in the range. */
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CORE_ADDR m_end;
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};
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/* Two or more non-contiguous ranges in the same order as that provided
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via the debug info. */
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struct blockranges
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{
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int nranges;
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struct blockrange range[1];
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};
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/* All of the name-scope contours of the program
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are represented by `struct block' objects.
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All of these objects are pointed to by the blockvector.
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Each block represents one name scope.
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Each lexical context has its own block.
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The blockvector begins with some special blocks.
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The GLOBAL_BLOCK contains all the symbols defined in this compilation
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whose scope is the entire program linked together.
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The STATIC_BLOCK contains all the symbols whose scope is the
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entire compilation excluding other separate compilations.
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Blocks starting with the FIRST_LOCAL_BLOCK are not special.
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Each block records a range of core addresses for the code that
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is in the scope of the block. The STATIC_BLOCK and GLOBAL_BLOCK
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give, for the range of code, the entire range of code produced
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by the compilation that the symbol segment belongs to.
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The blocks appear in the blockvector
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in order of increasing starting-address,
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and, within that, in order of decreasing ending-address.
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This implies that within the body of one function
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the blocks appear in the order of a depth-first tree walk. */
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struct block : public allocate_on_obstack<block>
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{
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/* Return this block's start address. */
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CORE_ADDR start () const
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{ return m_start; }
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/* Set this block's start address. */
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void set_start (CORE_ADDR start)
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{ m_start = start; }
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/* Return this block's end address. */
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CORE_ADDR end () const
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{ return m_end; }
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/* Set this block's end address. */
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void set_end (CORE_ADDR end)
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{ m_end = end; }
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/* Return this block's function symbol. */
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symbol *function () const
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{ return m_function; }
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/* Set this block's function symbol. */
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void set_function (symbol *function)
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{ m_function = function; }
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/* Return this block's superblock. */
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const block *superblock () const
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{ return m_superblock; }
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/* Set this block's superblock. */
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void set_superblock (const block *superblock)
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{ m_superblock = superblock; }
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/* Return this block's multidict. */
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multidictionary *multidict () const
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{ return m_multidict; }
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/* Return an iterator range for this block's multidict. */
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iterator_range<mdict_iterator_wrapper> multidict_symbols () const
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{ return iterator_range<mdict_iterator_wrapper> (m_multidict); }
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/* Set this block's multidict. */
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void set_multidict (multidictionary *multidict)
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{ m_multidict = multidict; }
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/* Return a view on this block's ranges. */
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gdb::array_view<blockrange> ranges ()
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{
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if (m_ranges == nullptr)
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return {};
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else
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return gdb::make_array_view (m_ranges->range, m_ranges->nranges);
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}
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/* Const version of the above. */
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gdb::array_view<const blockrange> ranges () const
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{
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if (m_ranges == nullptr)
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return {};
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else
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return gdb::make_array_view (m_ranges->range, m_ranges->nranges);
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}
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/* Set this block's ranges array. */
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void set_ranges (blockranges *ranges)
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{ m_ranges = ranges; }
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/* Return true if all addresses within this block are contiguous. */
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bool is_contiguous () const
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{ return this->ranges ().size () <= 1; }
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/* Return the entry-pc of this block.
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If the entry PC has been set to a specific value then this is
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returned. Otherwise, the default_entry_pc() address is returned. */
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CORE_ADDR entry_pc () const
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{
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return default_entry_pc () + m_entry_pc_offset;
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}
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/* Set this block's entry-pc to ADDR, which must lie between start() and
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end(). The entry-pc is stored as the signed offset from the
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default_entry_pc() address.
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Note that block sub-ranges can be out of order, as such the offset of
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the entry-pc might be negative. */
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void set_entry_pc (CORE_ADDR addr)
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{
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CORE_ADDR start = default_entry_pc ();
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gdb_assert (addr >= this->start () && addr < this->end ());
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gdb_assert (start >= this->start () && start < this->end ());
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m_entry_pc_offset = addr - start;
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}
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/* Return the objfile of this block. */
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struct objfile *objfile () const;
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/* Return the architecture of this block. */
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struct gdbarch *gdbarch () const;
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/* Return true if BL represents an inlined function. */
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bool inlined_p () const;
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/* This returns the namespace that this block is enclosed in, or ""
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if it isn't enclosed in a namespace at all. This travels the
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chain of superblocks looking for a scope, if necessary. */
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const char *scope () const;
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/* Set this block's scope member to SCOPE; if needed, allocate
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memory via OBSTACK. (It won't make a copy of SCOPE, however, so
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that already has to be allocated correctly.) */
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void set_scope (const char *scope, struct obstack *obstack);
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/* This returns the using directives list associated with this
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block, if any. */
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next_range<using_direct> get_using () const;
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/* Set this block's using member to USING; if needed, allocate
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memory via OBSTACK. (It won't make a copy of USING, however, so
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that already has to be allocated correctly.) */
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void set_using (struct using_direct *using_decl, struct obstack *obstack);
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/* Return the symbol for the function which contains a specified
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lexical block, described by a struct block. The return value
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will not be an inlined function; the containing function will be
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returned instead. */
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struct symbol *linkage_function () const;
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/* Return the symbol for the function which contains a specified
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block, described by a struct block. The return value will be the
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closest enclosing function, which might be an inline
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function. */
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struct symbol *containing_function () const;
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/* Return the static block associated with this block. Return NULL
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if block is a global block. */
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const struct block *static_block () const;
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/* Return true if this block is a static block. */
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bool is_static_block () const
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{
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const block *sup = superblock ();
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if (sup == nullptr)
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return false;
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return sup->is_global_block ();
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}
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/* Return the global block associated with block. */
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const struct global_block *global_block () const;
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/* Return true if this block is a global block. */
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bool is_global_block () const
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{ return superblock () == nullptr; }
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/* Return this block as a global_block. This block must be a global
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block. */
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struct global_block *as_global_block ();
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const struct global_block *as_global_block () const;
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/* Return the function block for this block. Returns nullptr if
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there is no enclosing function, i.e., if this block is a static
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or global block. */
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const struct block *function_block () const;
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/* Return a property to evaluate the static link associated to this
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block.
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In the context of nested functions (available in Pascal, Ada and
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GNU C, for instance), a static link (as in DWARF's
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DW_AT_static_link attribute) for a function is a way to get the
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frame corresponding to the enclosing function.
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Note that only objfile-owned and function-level blocks can have a
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static link. Return NULL if there is no such property. */
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struct dynamic_prop *static_link () const;
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/* Return true if block A is lexically nested within this block, or
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if A and this block have the same pc range. Return false
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otherwise. If ALLOW_NESTED is true, then block A is considered
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to be in this block if A is in a nested function in this block's
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function. If ALLOW_NESTED is false (the default), then blocks in
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nested functions are not considered to be contained. */
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bool contains (const struct block *a, bool allow_nested = false) const;
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private:
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/* Return the default entry-pc of this block. The default is the address
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we use if the debug information hasn't specifically set a different
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entry-pc value. This is the lowest address for the block when all
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addresses within the block are contiguous. If non-contiguous, then
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use the start address for the first range in the block.
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This almost matches what DWARF specifies as the entry pc, except that
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the final case, using the first address of the first range, is a GDB
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extension. However, the DWARF reader sets the specific entry-pc
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wherever possible, so this non-standard fallback case is only used as
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a last resort. */
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CORE_ADDR default_entry_pc () const
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{
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if (this->is_contiguous ())
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return this->start ();
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else
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return this->ranges ()[0].start ();
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}
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/* If the namespace_info is NULL, allocate it via OBSTACK and
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initialize its members to zero. */
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void initialize_namespace (struct obstack *obstack);
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/* Addresses in the executable code that are in this block. */
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CORE_ADDR m_start = 0;
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CORE_ADDR m_end = 0;
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/* The symbol that names this block, if the block is the body of a
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function (real or inlined); otherwise, zero. */
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struct symbol *m_function = nullptr;
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/* The `struct block' for the containing block, or 0 if none.
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The superblock of a top-level local block (i.e. a function in the
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case of C) is the STATIC_BLOCK. The superblock of the
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STATIC_BLOCK is the GLOBAL_BLOCK. */
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const struct block *m_superblock = nullptr;
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/* This is used to store the symbols in the block. */
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struct multidictionary *m_multidict = nullptr;
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/* Contains information about namespace-related info relevant to this block:
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using directives and the current namespace scope. */
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struct block_namespace_info *m_namespace_info = nullptr;
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/* Address ranges for blocks with non-contiguous ranges. If this
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is NULL, then there is only one range which is specified by
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startaddr and endaddr above. */
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struct blockranges *m_ranges = nullptr;
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/* The offset of the actual entry-pc value from the default entry-pc
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value. If space was no object then we'd store an actual address along
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with a flag to indicate if the address has been set or not. But we'd
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like to keep the size of block low, so we'd like to use a single
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member variable.
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We would also like to avoid using 0 as a special address; some targets
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do allow for accesses to address 0.
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So instead we store the offset of the defined entry-pc from the
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default entry-pc. See default_entry_pc() for the definition of the
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default entry-pc. See entry_pc() for how this offset is used. */
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LONGEST m_entry_pc_offset = 0;
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};
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/* The global block is singled out so that we can provide a back-link
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to the compunit. */
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struct global_block : public block
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{
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/* Set the compunit of this global block.
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The compunit must not have been set previously. */
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void set_compunit (compunit_symtab *cu)
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{
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gdb_assert (m_compunit == nullptr);
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m_compunit = cu;
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}
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/* Return the compunit of this global block.
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The compunit must have been set previously. */
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compunit_symtab *compunit () const
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{
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gdb_assert (m_compunit != nullptr);
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return m_compunit;
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}
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private:
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/* This holds a pointer to the compunit holding this block. */
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compunit_symtab *m_compunit = nullptr;
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};
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struct blockvector
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{
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/* Return a view on the blocks of this blockvector. */
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gdb::array_view<struct block *> blocks ()
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{
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return gdb::array_view<struct block *> (m_blocks, m_num_blocks);
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}
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/* Const version of the above. */
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gdb::array_view<const struct block *const> blocks () const
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{
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const struct block **blocks = (const struct block **) m_blocks;
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return gdb::array_view<const struct block *const> (blocks, m_num_blocks);
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}
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/* Return the block at index I. */
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struct block *block (size_t i)
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{ return this->blocks ()[i]; }
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/* Const version of the above. */
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const struct block *block (size_t i) const
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{ return this->blocks ()[i]; }
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/* Set the block at index I. */
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void set_block (int i, struct block *block)
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{ m_blocks[i] = block; }
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/* Set the number of blocks of this blockvector.
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The storage of blocks is done using a flexible array member, so the number
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of blocks set here must agree with what was effectively allocated. */
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void set_num_blocks (int num_blocks)
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{ m_num_blocks = num_blocks; }
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/* Return the number of blocks in this blockvector. */
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int num_blocks () const
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{ return m_num_blocks; }
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/* Return the global block of this blockvector. */
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struct global_block *global_block ()
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{ return static_cast<struct global_block *> (this->block (GLOBAL_BLOCK)); }
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/* Const version of the above. */
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const struct global_block *global_block () const
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{
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return static_cast<const struct global_block *>
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(this->block (GLOBAL_BLOCK));
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}
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/* Return the static block of this blockvector. */
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struct block *static_block ()
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{ return this->block (STATIC_BLOCK); }
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/* Const version of the above. */
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const struct block *static_block () const
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{ return this->block (STATIC_BLOCK); }
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/* Return the address -> block map of this blockvector. */
|
|
addrmap_fixed *map ()
|
|
{ return m_map; }
|
|
|
|
/* Const version of the above. */
|
|
const addrmap_fixed *map () const
|
|
{ return m_map; }
|
|
|
|
/* Set this blockvector's address -> block map. */
|
|
void set_map (addrmap_fixed *map)
|
|
{ m_map = map; }
|
|
|
|
private:
|
|
/* An address map mapping addresses to blocks in this blockvector.
|
|
This pointer is zero if the blocks' start and end addresses are
|
|
enough. */
|
|
addrmap_fixed *m_map;
|
|
|
|
/* Number of blocks in the list. */
|
|
int m_num_blocks;
|
|
|
|
/* The blocks themselves. */
|
|
struct block *m_blocks[1];
|
|
};
|
|
|
|
extern const struct blockvector *blockvector_for_pc (CORE_ADDR,
|
|
const struct block **);
|
|
|
|
extern const struct blockvector *
|
|
blockvector_for_pc_sect (CORE_ADDR, struct obj_section *,
|
|
const struct block **, struct compunit_symtab *);
|
|
|
|
extern int blockvector_contains_pc (const struct blockvector *bv, CORE_ADDR pc);
|
|
|
|
extern struct call_site *call_site_for_pc (struct gdbarch *gdbarch,
|
|
CORE_ADDR pc);
|
|
|
|
extern const struct block *block_for_pc (CORE_ADDR);
|
|
|
|
extern const struct block *block_for_pc_sect (CORE_ADDR, struct obj_section *);
|
|
|
|
/* A block iterator. This structure should be treated as though it
|
|
were opaque; it is only defined here because we want to support
|
|
stack allocation of iterators. */
|
|
|
|
struct block_iterator
|
|
{
|
|
/* If we're iterating over a single block, this holds the block.
|
|
Otherwise, it holds the canonical compunit. */
|
|
|
|
union
|
|
{
|
|
struct compunit_symtab *compunit_symtab;
|
|
const struct block *block;
|
|
} d;
|
|
|
|
/* If we're trying to match a name, this will be non-NULL. */
|
|
const lookup_name_info *name;
|
|
|
|
/* If we're iterating over a single block, this is always -1.
|
|
Otherwise, it holds the index of the current "included" symtab in
|
|
the canonical symtab (that is, d.symtab->includes[idx]), with -1
|
|
meaning the canonical symtab itself. */
|
|
|
|
int idx;
|
|
|
|
/* Which block, either static or global, to iterate over. If this
|
|
is FIRST_LOCAL_BLOCK, then we are iterating over a single block.
|
|
This is used to select which field of 'd' is in use. */
|
|
|
|
enum block_enum which;
|
|
|
|
/* The underlying multidictionary iterator. */
|
|
|
|
struct mdict_iterator mdict_iter;
|
|
};
|
|
|
|
/* Initialize ITERATOR to point at the first symbol in BLOCK, and
|
|
return that first symbol, or NULL if BLOCK is empty. If NAME is
|
|
not NULL, only return symbols matching that name. */
|
|
|
|
extern struct symbol *block_iterator_first
|
|
(const struct block *block,
|
|
struct block_iterator *iterator,
|
|
const lookup_name_info *name = nullptr);
|
|
|
|
/* Advance ITERATOR, and return the next symbol, or NULL if there are
|
|
no more symbols. Don't call this if you've previously received
|
|
NULL from block_iterator_first or block_iterator_next on this
|
|
iteration. */
|
|
|
|
extern struct symbol *block_iterator_next (struct block_iterator *iterator);
|
|
|
|
/* An iterator that wraps a block_iterator. The naming here is
|
|
unfortunate, but block_iterator was named before gdb switched to
|
|
C++. */
|
|
struct block_iterator_wrapper
|
|
{
|
|
typedef block_iterator_wrapper self_type;
|
|
typedef struct symbol *value_type;
|
|
|
|
explicit block_iterator_wrapper (const struct block *block,
|
|
const lookup_name_info *name = nullptr)
|
|
: m_sym (block_iterator_first (block, &m_iter, name))
|
|
{
|
|
}
|
|
|
|
block_iterator_wrapper ()
|
|
: m_sym (nullptr)
|
|
{
|
|
}
|
|
|
|
value_type operator* () const
|
|
{
|
|
return m_sym;
|
|
}
|
|
|
|
bool operator== (const self_type &other) const
|
|
{
|
|
return m_sym == other.m_sym;
|
|
}
|
|
|
|
bool operator!= (const self_type &other) const
|
|
{
|
|
return m_sym != other.m_sym;
|
|
}
|
|
|
|
self_type &operator++ ()
|
|
{
|
|
m_sym = block_iterator_next (&m_iter);
|
|
return *this;
|
|
}
|
|
|
|
private:
|
|
|
|
struct symbol *m_sym;
|
|
struct block_iterator m_iter;
|
|
};
|
|
|
|
/* An iterator range for block_iterator_wrapper. */
|
|
|
|
typedef iterator_range<block_iterator_wrapper> block_iterator_range;
|
|
|
|
/* Return true if symbol A is the best match possible for DOMAIN. */
|
|
|
|
extern bool best_symbol (struct symbol *a, const domain_search_flags domain);
|
|
|
|
/* Return symbol B if it is a better match than symbol A for DOMAIN.
|
|
Otherwise return A. */
|
|
|
|
extern struct symbol *better_symbol (struct symbol *a, struct symbol *b,
|
|
const domain_search_flags domain);
|
|
|
|
/* Search BLOCK for symbol NAME in DOMAIN. */
|
|
|
|
extern struct symbol *block_lookup_symbol (const struct block *block,
|
|
const lookup_name_info &name,
|
|
const domain_search_flags domain);
|
|
|
|
/* Search BLOCK for symbol NAME in DOMAIN but only in primary symbol table of
|
|
BLOCK. BLOCK must be STATIC_BLOCK or GLOBAL_BLOCK. Function is useful if
|
|
one iterates all global/static blocks of an objfile. */
|
|
|
|
extern struct symbol *block_lookup_symbol_primary
|
|
(const struct block *block,
|
|
const char *name,
|
|
const domain_search_flags domain);
|
|
|
|
/* Find symbol NAME in BLOCK and in DOMAIN. This will return a
|
|
matching symbol whose type is not a "opaque", see TYPE_IS_OPAQUE.
|
|
If STUB is non-NULL, an otherwise matching symbol whose type is a
|
|
opaque will be stored here. */
|
|
|
|
extern struct symbol *block_find_symbol (const struct block *block,
|
|
const lookup_name_info &name,
|
|
const domain_search_flags domain,
|
|
struct symbol **stub);
|
|
|
|
/* Given a vector of pairs, allocate and build an obstack allocated
|
|
blockranges struct for a block. */
|
|
struct blockranges *make_blockranges (struct objfile *objfile,
|
|
const std::vector<blockrange> &rangevec);
|
|
|
|
#endif /* BLOCK_H */
|