52059ffd69
In C, an enum or structure defined inside other structure has global scope just like it had been defined outside the struct in the first place. However, in C++, such a nested structure is given a name that is nested inside the structure. This patch moves such affected structures/enums out to global scope, so that code using them works the same in C++ as it works today in C. gdb/ChangeLog: 2015-02-27 Tom Tromey <tromey@redhat.com> Pedro Alves <palves@redhat.com> * dwarf2-frame.c (enum cfa_how_kind, struct dwarf2_frame_state_reg_info): Move out of struct dwarf2_frame_state. * dwarf2read.c (struct tu_stats): Move out of struct dwarf2_per_objfile. (struct file_entry): Move out of struct line_header. (struct nextfield, struct nextfnfield, struct fnfieldlist, struct typedef_field_list): Move out of struct field_info. * gdbtypes.h (enum dynamic_prop_kind, union dynamic_prop_data): Move out of struct dynamic_prop. (union type_owner, union field_location, struct field, struct range_bounds, union type_specific): Move out of struct main_type. (struct fn_fieldlist, struct fn_field, struct typedef_field) (VOFFSET_STATIC): Move out of struct cplus_struct_type. (struct call_site_target, union call_site_parameter_u, struct call_site_parameter): Move out of struct call_site. * m32c-tdep.c (enum m32c_prologue_kind): Move out of struct m32c_prologue. (enum srcdest_kind): Move out of struct srcdest. * main.c (enum cmdarg_kind): Move out of struct cmdarg. * prologue-value.h (enum prologue_value_kind): Move out of struct prologue_value. * s390-linux-tdep.c (enum s390_abi_kind): Move out of struct gdbarch_tdep. * stabsread.c (struct nextfield, struct next_fnfieldlist): Move out of struct field_info. * symfile.h (struct other_sections): Move out of struct section_addr_info. * symtab.c (struct symbol_cache_slot): Move out struct block_symbol_cache. * target-descriptions.c (enum tdesc_type_kind): Move out of typedef struct tdesc_type. * tui/tui-data.h (enum tui_line_or_address_kind): Move out of struct tui_line_or_address. * value.c (enum internalvar_kind, union internalvar_data): Move out of struct internalvar. * xtensa-tdep.h (struct ctype_cache): Move out of struct gdbarch_tdep.
304 lines
12 KiB
C
304 lines
12 KiB
C
/* Interface to prologue value handling for GDB.
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Copyright (C) 2003-2015 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 PROLOGUE_VALUE_H
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#define PROLOGUE_VALUE_H
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/* What sort of value is this? This determines the interpretation
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of subsequent fields. */
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enum prologue_value_kind
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{
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/* We don't know anything about the value. This is also used for
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values we could have kept track of, when doing so would have
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been too complex and we don't want to bother. The bottom of
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our lattice. */
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pvk_unknown,
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/* A known constant. K is its value. */
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pvk_constant,
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/* The value that register REG originally had *UPON ENTRY TO THE
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FUNCTION*, plus K. If K is zero, this means, obviously, just
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the value REG had upon entry to the function. REG is a GDB
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register number. Before we start interpreting, we initialize
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every register R to { pvk_register, R, 0 }. */
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pvk_register,
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};
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/* When we analyze a prologue, we're really doing 'abstract
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interpretation' or 'pseudo-evaluation': running the function's code
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in simulation, but using conservative approximations of the values
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it would have when it actually runs. For example, if our function
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starts with the instruction:
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addi r1, 42 # add 42 to r1
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we don't know exactly what value will be in r1 after executing this
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instruction, but we do know it'll be 42 greater than its original
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value.
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If we then see an instruction like:
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addi r1, 22 # add 22 to r1
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we still don't know what r1's value is, but again, we can say it is
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now 64 greater than its original value.
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If the next instruction were:
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mov r2, r1 # set r2 to r1's value
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then we can say that r2's value is now the original value of r1
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plus 64.
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It's common for prologues to save registers on the stack, so we'll
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need to track the values of stack frame slots, as well as the
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registers. So after an instruction like this:
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mov (fp+4), r2
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then we'd know that the stack slot four bytes above the frame
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pointer holds the original value of r1 plus 64.
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And so on.
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Of course, this can only go so far before it gets unreasonable. If
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we wanted to be able to say anything about the value of r1 after
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the instruction:
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xor r1, r3 # exclusive-or r1 and r3, place result in r1
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then things would get pretty complex. But remember, we're just
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doing a conservative approximation; if exclusive-or instructions
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aren't relevant to prologues, we can just say r1's value is now
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'unknown'. We can ignore things that are too complex, if that loss
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of information is acceptable for our application.
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So when I say "conservative approximation" here, what I mean is an
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approximation that is either accurate, or marked "unknown", but
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never inaccurate.
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Once you've reached the current PC, or an instruction that you
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don't know how to simulate, you stop. Now you can examine the
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state of the registers and stack slots you've kept track of.
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- To see how large your stack frame is, just check the value of the
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stack pointer register; if it's the original value of the SP
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minus a constant, then that constant is the stack frame's size.
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If the SP's value has been marked as 'unknown', then that means
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the prologue has done something too complex for us to track, and
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we don't know the frame size.
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- To see where we've saved the previous frame's registers, we just
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search the values we've tracked --- stack slots, usually, but
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registers, too, if you want --- for something equal to the
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register's original value. If the ABI suggests a standard place
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to save a given register, then we can check there first, but
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really, anything that will get us back the original value will
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probably work.
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Sure, this takes some work. But prologue analyzers aren't
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quick-and-simple pattern patching to recognize a few fixed prologue
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forms any more; they're big, hairy functions. Along with inferior
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function calls, prologue analysis accounts for a substantial
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portion of the time needed to stabilize a GDB port. So I think
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it's worthwhile to look for an approach that will be easier to
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understand and maintain. In the approach used here:
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- It's easier to see that the analyzer is correct: you just see
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whether the analyzer properly (albiet conservatively) simulates
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the effect of each instruction.
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- It's easier to extend the analyzer: you can add support for new
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instructions, and know that you haven't broken anything that
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wasn't already broken before.
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- It's orthogonal: to gather new information, you don't need to
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complicate the code for each instruction. As long as your domain
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of conservative values is already detailed enough to tell you
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what you need, then all the existing instruction simulations are
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already gathering the right data for you.
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A 'struct prologue_value' is a conservative approximation of the
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real value the register or stack slot will have. */
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struct prologue_value {
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/* What sort of value is this? This determines the interpretation
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of subsequent fields. */
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enum prologue_value_kind kind;
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/* The meanings of the following fields depend on 'kind'; see the
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comments for the specific 'kind' values. */
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int reg;
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CORE_ADDR k;
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};
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typedef struct prologue_value pv_t;
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/* Return the unknown prologue value --- { pvk_unknown, ?, ? }. */
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pv_t pv_unknown (void);
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/* Return the prologue value representing the constant K. */
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pv_t pv_constant (CORE_ADDR k);
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/* Return the prologue value representing the original value of
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register REG, plus the constant K. */
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pv_t pv_register (int reg, CORE_ADDR k);
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/* Return conservative approximations of the results of the following
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operations. */
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pv_t pv_add (pv_t a, pv_t b); /* a + b */
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pv_t pv_add_constant (pv_t v, CORE_ADDR k); /* a + k */
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pv_t pv_subtract (pv_t a, pv_t b); /* a - b */
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pv_t pv_logical_and (pv_t a, pv_t b); /* a & b */
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/* Return non-zero iff A and B are identical expressions.
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This is not the same as asking if the two values are equal; the
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result of such a comparison would have to be a pv_boolean, and
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asking whether two 'unknown' values were equal would give you
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pv_maybe. Same for comparing, say, { pvk_register, R1, 0 } and {
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pvk_register, R2, 0}.
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Instead, this function asks whether the two representations are the
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same. */
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int pv_is_identical (pv_t a, pv_t b);
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/* Return non-zero if A is known to be a constant. */
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int pv_is_constant (pv_t a);
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/* Return non-zero if A is the original value of register number R
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plus some constant, zero otherwise. */
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int pv_is_register (pv_t a, int r);
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/* Return non-zero if A is the original value of register R plus the
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constant K. */
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int pv_is_register_k (pv_t a, int r, CORE_ADDR k);
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/* A conservative boolean type, including "maybe", when we can't
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figure out whether something is true or not. */
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enum pv_boolean {
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pv_maybe,
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pv_definite_yes,
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pv_definite_no,
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};
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/* Decide whether a reference to SIZE bytes at ADDR refers exactly to
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an element of an array. The array starts at ARRAY_ADDR, and has
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ARRAY_LEN values of ELT_SIZE bytes each. If ADDR definitely does
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refer to an array element, set *I to the index of the referenced
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element in the array, and return pv_definite_yes. If it definitely
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doesn't, return pv_definite_no. If we can't tell, return pv_maybe.
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If the reference does touch the array, but doesn't fall exactly on
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an element boundary, or doesn't refer to the whole element, return
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pv_maybe. */
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enum pv_boolean pv_is_array_ref (pv_t addr, CORE_ADDR size,
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pv_t array_addr, CORE_ADDR array_len,
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CORE_ADDR elt_size,
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int *i);
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/* A 'struct pv_area' keeps track of values stored in a particular
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region of memory. */
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struct pv_area;
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/* Create a new area, tracking stores relative to the original value
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of BASE_REG. If BASE_REG is SP, then this effectively records the
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contents of the stack frame: the original value of the SP is the
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frame's CFA, or some constant offset from it.
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Stores to constant addresses, unknown addresses, or to addresses
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relative to registers other than BASE_REG will trash this area; see
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pv_area_store_would_trash.
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To check whether a pointer refers to this area, only the low
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ADDR_BIT bits will be compared. */
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struct pv_area *make_pv_area (int base_reg, int addr_bit);
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/* Free AREA. */
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void free_pv_area (struct pv_area *area);
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/* Register a cleanup to free AREA. */
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struct cleanup *make_cleanup_free_pv_area (struct pv_area *area);
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/* Store the SIZE-byte value VALUE at ADDR in AREA.
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If ADDR is not relative to the same base register we used in
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creating AREA, then we can't tell which values here the stored
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value might overlap, and we'll have to mark everything as
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unknown. */
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void pv_area_store (struct pv_area *area,
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pv_t addr,
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CORE_ADDR size,
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pv_t value);
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/* Return the SIZE-byte value at ADDR in AREA. This may return
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pv_unknown (). */
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pv_t pv_area_fetch (struct pv_area *area, pv_t addr, CORE_ADDR size);
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/* Return true if storing to address ADDR in AREA would force us to
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mark the contents of the entire area as unknown. This could happen
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if, say, ADDR is unknown, since we could be storing anywhere. Or,
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it could happen if ADDR is relative to a different register than
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the other stores base register, since we don't know the relative
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values of the two registers.
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If you've reached such a store, it may be better to simply stop the
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prologue analysis, and return the information you've gathered,
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instead of losing all that information, most of which is probably
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okay. */
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int pv_area_store_would_trash (struct pv_area *area, pv_t addr);
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/* Search AREA for the original value of REGISTER. If we can't find
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it, return zero; if we can find it, return a non-zero value, and if
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OFFSET_P is non-zero, set *OFFSET_P to the register's offset within
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AREA. GDBARCH is the architecture of which REGISTER is a member.
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In the worst case, this takes time proportional to the number of
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items stored in AREA. If you plan to gather a lot of information
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about registers saved in AREA, consider calling pv_area_scan
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instead, and collecting all your information in one pass. */
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int pv_area_find_reg (struct pv_area *area,
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struct gdbarch *gdbarch,
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int reg,
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CORE_ADDR *offset_p);
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/* For every part of AREA whose value we know, apply FUNC to CLOSURE,
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the value's address, its size, and the value itself. */
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void pv_area_scan (struct pv_area *area,
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void (*func) (void *closure,
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pv_t addr,
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CORE_ADDR size,
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pv_t value),
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void *closure);
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#endif /* PROLOGUE_VALUE_H */
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