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binutils-gdb/gdb/regcache.c
Simon Marchi 18b4d0736b gdb: initial support for ROCm platform (AMDGPU) debugging 
This patch adds the foundation for GDB to be able to debug programs
offloaded to AMD GPUs using the AMD ROCm platform [1].  The latest
public release of the ROCm release at the time of writing is 5.4, so
this is what this patch targets.

The ROCm platform allows host programs to schedule bits of code for
execution on GPUs or similar accelerators.  The programs running on GPUs
are typically referred to as `kernels` (not related to operating system
kernels).

Programs offloaded with the AMD ROCm platform can be written in the HIP
language [2], OpenCL and OpenMP, but we're going to focus on HIP here.
The HIP language consists of a C++ Runtime API and kernel language.
Here's an example of a very simple HIP program:

    #include "hip/hip_runtime.h"
    #include <cassert>

    __global__ void
    do_an_addition (int a, int b, int *out)
    {
      *out = a + b;
    }

    int
    main ()
    {
      int *result_ptr, result;

      /* Allocate memory for the device to write the result to.  */
      hipError_t error = hipMalloc (&result_ptr, sizeof (int));
      assert (error == hipSuccess);

      /* Run `do_an_addition` on one workgroup containing one work item.  */
      do_an_addition<<<dim3(1), dim3(1), 0, 0>>> (1, 2, result_ptr);

      /* Copy result from device to host.  Note that this acts as a synchronization
         point, waiting for the kernel dispatch to complete.  */
      error = hipMemcpyDtoH (&result, result_ptr, sizeof (int));
      assert (error == hipSuccess);

      printf ("result is %d\n", result);
      assert (result == 3);

      return 0;
    }

This program can be compiled with:

    $ hipcc simple.cpp -g -O0 -o simple

... where `hipcc` is the HIP compiler, shipped with ROCm releases.  This
generates an ELF binary for the host architecture, containing another
ELF binary with the device code.  The ELF for the device can be
inspected with:

    $ roc-obj-ls simple
    1       host-x86_64-unknown-linux                                           file://simple#offset=8192&size=0
    1       hipv4-amdgcn-amd-amdhsa--gfx906                                     file://simple#offset=8192&size=34216
    $ roc-obj-extract 'file://simple#offset=8192&size=34216'
    $ file simple-offset8192-size34216.co
    simple-offset8192-size34216.co: ELF 64-bit LSB shared object, *unknown arch 0xe0* version 1, dynamically linked, with debug_info, not stripped
                                                                                 ^
                       amcgcn architecture that my `file` doesn't know about ----´

Running the program gives the very unimpressive result:

    $ ./simple
    result is 3

While running, this host program has copied the device program into the
GPU's memory and spawned an execution thread on it.  The goal of this
GDB port is to let the user debug host threads and these GPU threads
simultaneously.  Here's a sample session using a GDB with this patch
applied:

    $ ./gdb -q -nx --data-directory=data-directory ./simple
    Reading symbols from ./simple...
    (gdb) break do_an_addition
    Function "do_an_addition" not defined.
    Make breakpoint pending on future shared library load? (y or [n]) y
    Breakpoint 1 (do_an_addition) pending.
    (gdb) r
    Starting program: /home/smarchi/build/binutils-gdb-amdgpu/gdb/simple
    [Thread debugging using libthread_db enabled]
    Using host libthread_db library "/lib/x86_64-linux-gnu/libthread_db.so.1".
    [New Thread 0x7ffff5db7640 (LWP 1082911)]
    [New Thread 0x7ffef53ff640 (LWP 1082913)]
    [Thread 0x7ffef53ff640 (LWP 1082913) exited]
    [New Thread 0x7ffdecb53640 (LWP 1083185)]
    [New Thread 0x7ffff54bf640 (LWP 1083186)]
    [Thread 0x7ffdecb53640 (LWP 1083185) exited]
    [Switching to AMDGPU Wave 2:2:1:1 (0,0,0)/0]

    Thread 6 hit Breakpoint 1, do_an_addition (a=<error reading variable: DWARF-2 expression error: `DW_OP_regx' operations must be used either alone or in conjunction with DW_OP_piece or DW_OP_bit_piece.>,
        b=<error reading variable: DWARF-2 expression error: `DW_OP_regx' operations must be used either alone or in conjunction with DW_OP_piece or DW_OP_bit_piece.>,
        out=<error reading variable: DWARF-2 expression error: `DW_OP_regx' operations must be used either alone or in conjunction with DW_OP_piece or DW_OP_bit_piece.>) at simple.cpp:24
    24        *out = a + b;
    (gdb) info inferiors
      Num  Description       Connection           Executable
    * 1    process 1082907   1 (native)           /home/smarchi/build/binutils-gdb-amdgpu/gdb/simple
    (gdb) info threads
      Id   Target Id                                    Frame
      1    Thread 0x7ffff5dc9240 (LWP 1082907) "simple" 0x00007ffff5e9410b in ?? () from /opt/rocm-5.4.0/lib/libhsa-runtime64.so.1
      2    Thread 0x7ffff5db7640 (LWP 1082911) "simple" __GI___ioctl (fd=3, request=3222817548) at ../sysdeps/unix/sysv/linux/ioctl.c:36
      5    Thread 0x7ffff54bf640 (LWP 1083186) "simple" __GI___ioctl (fd=3, request=3222817548) at ../sysdeps/unix/sysv/linux/ioctl.c:36
    * 6    AMDGPU Wave 2:2:1:1 (0,0,0)/0                do_an_addition (
        a=<error reading variable: DWARF-2 expression error: `DW_OP_regx' operations must be used either alone or in conjunction with DW_OP_piece or DW_OP_bit_piece.>,
        b=<error reading variable: DWARF-2 expression error: `DW_OP_regx' operations must be used either alone or in conjunction with DW_OP_piece or DW_OP_bit_piece.>,
        out=<error reading variable: DWARF-2 expression error: `DW_OP_regx' operations must be used either alone or in conjunction with DW_OP_piece or DW_OP_bit_piece.>) at simple.cpp:24
    (gdb) bt
    Python Exception <class 'gdb.error'>: Unhandled dwarf expression opcode 0xe1
    #0  do_an_addition (a=<error reading variable: DWARF-2 expression error: `DW_OP_regx' operations must be used either alone or in conjunction with DW_OP_piece or DW_OP_bit_piece.>,
        b=<error reading variable: DWARF-2 expression error: `DW_OP_regx' operations must be used either alone or in conjunction with DW_OP_piece or DW_OP_bit_piece.>,
        out=<error reading variable: DWARF-2 expression error: `DW_OP_regx' operations must be used either alone or in conjunction with DW_OP_piece or DW_OP_bit_piece.>) at simple.cpp:24
    (gdb) continue
    Continuing.
    result is 3
    warning: Temporarily disabling breakpoints for unloaded shared library "file:///home/smarchi/build/binutils-gdb-amdgpu/gdb/simple#offset=8192&size=67208"
    [Thread 0x7ffff54bf640 (LWP 1083186) exited]
    [Thread 0x7ffff5db7640 (LWP 1082911) exited]
    [Inferior 1 (process 1082907) exited normally]

One thing to notice is the host and GPU threads appearing under
the same inferior.  This is a design goal for us, as programmers tend to
think of the threads running on the GPU as part of the same program as
the host threads, so showing them in the same inferior in GDB seems
natural.  Also, the host and GPU threads share a global memory space,
which fits the inferior model.

Another thing to notice is the error messages when trying to read
variables or printing a backtrace.  This is expected for the moment,
since the AMD GPU compiler produces some DWARF that uses some
non-standard extensions:

  https://llvm.org/docs/AMDGPUDwarfExtensionsForHeterogeneousDebugging.html

There were already some patches posted by Zoran Zaric earlier to make
GDB support these extensions:

  https://inbox.sourceware.org/gdb-patches/20211105113849.118800-1-zoran.zaric@amd.com/

We think it's better to get the basic support for AMD GPU in first,
which will then give a better justification for GDB to support these
extensions.

GPU threads are named `AMDGPU Wave`: a wave is essentially a hardware
thread using the SIMT (single-instruction, multiple-threads) [3]
execution model.

GDB uses the amd-dbgapi library [4], included in the ROCm platform, for
a few things related to AMD GPU threads debugging.  Different components
talk to the library, as show on the following diagram:

    +---------------------------+     +-------------+     +------------------+
    | GDB   | amd-dbgapi target | <-> |     AMD     |     |    Linux kernel  |
    |       +-------------------+     |   Debugger  |     +--------+         |
    |       | amdgcn gdbarch    | <-> |     API     | <=> | AMDGPU |         |
    |       +-------------------+     |             |     | driver |         |
    |       | solib-rocm        | <-> | (dbgapi.so) |     +--------+---------+
    +---------------------------+     +-------------+

  - The amd-dbgapi target is a target_ops implementation used to control
    execution of GPU threads.  While the debugging of host threads works
    by using the ptrace / wait Linux kernel interface (as usual), control
    of GPU threads is done through a special interface (dubbed `kfd`)
    exposed by the `amdgpu` Linux kernel module.  GDB doesn't interact
    directly with `kfd`, but instead goes through the amd-dbgapi library
    (AMD Debugger API on the diagram).

    Since it provides execution control, the amd-dbgapi target should
    normally be a process_stratum_target, not just a target_ops.  More
    on that later.

  - The amdgcn gdbarch (describing the hardware architecture of the GPU
    execution units) offloads some requests to the amd-dbgapi library,
    so that knowledge about the various architectures doesn't need to be
    duplicated and baked in GDB.  This is for example for things like
    the list of registers.

  - The solib-rocm component is an solib provider that fetches the list of
    code objects loaded on the device from the amd-dbgapi library, and
    makes GDB read their symbols.  This is very similar to other solib
    providers that handle shared libraries, except that here the shared
    libraries are the pieces of code loaded on the device.

Given that Linux host threads are managed by the linux-nat target, and
the GPU threads are managed by the amd-dbgapi target, having all threads
appear in the same inferior requires the two targets to be in that
inferior's target stack.  However, there can only be one
process_stratum_target in a given target stack, since there can be only
one target per slot.  To achieve it, we therefore resort the hack^W
solution of placing the amd-dbgapi target in the arch_stratum slot of
the target stack, on top of the linux-nat target.  Doing so allows the
amd-dbgapi target to intercept target calls and handle them if they
concern GPU threads, and offload to beneath otherwise.  See
amd_dbgapi_target::fetch_registers for a simple example:

    void
    amd_dbgapi_target::fetch_registers (struct regcache *regcache, int regno)
    {
      if (!ptid_is_gpu (regcache->ptid ()))
        {
          beneath ()->fetch_registers (regcache, regno);
          return;
        }

      // handle it
    }

ptids of GPU threads are crafted with the following pattern:

  (pid, 1, wave id)

Where pid is the inferior's pid and "wave id" is the wave handle handed
to us by the amd-dbgapi library (in practice, a monotonically
incrementing integer).  The idea is that on Linux systems, the
combination (pid != 1, lwp == 1) is not possible.  lwp == 1 would always
belong to the init process, which would also have pid == 1 (and it's
improbable for the init process to offload work to the GPU and much less
for the user to debug it).  We can therefore differentiate GPU and
non-GPU ptids this way.  See ptid_is_gpu for more details.

Note that we believe that this scheme could break down in the context of
containers, where the initial process executed in a container has pid 1
(in its own pid namespace).  For instance, if you were to execute a ROCm
program in a container, then spawn a GDB in that container and attach to
the process, it will likely not work.  This is a known limitation.  A
workaround for this is to have a dummy process (like a shell) fork and
execute the program of interest.

The amd-dbgapi target watches native inferiors, and "attaches" to them
using amd_dbgapi_process_attach, which gives it a notifier fd that is
registered in the event loop (see enable_amd_dbgapi).  Note that this
isn't the same "attach" as in PTRACE_ATTACH, but being ptrace-attached
is a precondition for amd_dbgapi_process_attach to work.  When the
debugged process enables the ROCm runtime, the amd-dbgapi target gets
notified through that fd, and pushes itself on the target stack of the
inferior.  The amd-dbgapi target is then able to intercept target_ops
calls.  If the debugged process disables the ROCm runtime, the
amd-dbgapi target unpushes itself from the target stack.

This way, the amd-dbgapi target's footprint stays minimal when debugging
a process that doesn't use the AMD ROCm platform, it does not intercept
target calls.

The amd-dbgapi library is found using pkg-config.  Since enabling
support for the amdgpu architecture (amdgpu-tdep.c) depends on the
amd-dbgapi library being present, we have the following logic for
the interaction with --target and --enable-targets:

 - if the user explicitly asks for amdgcn support with
   --target=amdgcn-*-* or --enable-targets=amdgcn-*-*, we probe for
   the amd-dbgapi and fail if not found

 - if the user uses --enable-targets=all, we probe for amd-dbgapi,
   enable amdgcn support if found, disable amdgcn support if not found

 - if the user uses --enable-targets=all and --with-amd-dbgapi=yes,
   we probe for amd-dbgapi, enable amdgcn if found and fail if not found

 - if the user uses --enable-targets=all and --with-amd-dbgapi=no,
   we do not probe for amd-dbgapi, disable amdgcn support

 - otherwise, amd-dbgapi is not probed for and support for amdgcn is not
   enabled

Finally, a simple test is included.  It only tests hitting a breakpoint
in device code and resuming execution, pretty much like the example
shown above.

[1] https://docs.amd.com/category/ROCm_v5.4
[2] https://docs.amd.com/bundle/HIP-Programming-Guide-v5.4
[3] https://en.wikipedia.org/wiki/Single_instruction,_multiple_threads
[4] https://docs.amd.com/bundle/ROCDebugger-API-Guide-v5.4

Change-Id: I591edca98b8927b1e49e4b0abe4e304765fed9ee
Co-Authored-By: Zoran Zaric <zoran.zaric@amd.com>
Co-Authored-By: Laurent Morichetti <laurent.morichetti@amd.com>
Co-Authored-By: Tony Tye <Tony.Tye@amd.com>
Co-Authored-By: Lancelot SIX <lancelot.six@amd.com>
Co-Authored-By: Pedro Alves <pedro@palves.net>
2023-02-02 10:02:34 -05:00

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/* Cache and manage the values of registers for GDB, the GNU debugger.
Copyright (C) 1986-2023 Free Software Foundation, Inc.
This file is part of GDB.
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, see <http://www.gnu.org/licenses/>. */
#include "defs.h"
#include "inferior.h"
#include "gdbthread.h"
#include "target.h"
#include "test-target.h"
#include "scoped-mock-context.h"
#include "gdbarch.h"
#include "gdbcmd.h"
#include "regcache.h"
#include "reggroups.h"
#include "observable.h"
#include "regset.h"
#include <unordered_map>
#include "cli/cli-cmds.h"
/*
* DATA STRUCTURE
*
* Here is the actual register cache.
*/
/* Per-architecture object describing the layout of a register cache.
Computed once when the architecture is created. */
struct regcache_descr
{
/* The architecture this descriptor belongs to. */
struct gdbarch *gdbarch = nullptr;
/* The raw register cache. Each raw (or hard) register is supplied
by the target interface. The raw cache should not contain
redundant information - if the PC is constructed from two
registers then those registers and not the PC lives in the raw
cache. */
long sizeof_raw_registers = 0;
/* The cooked register space. Each cooked register in the range
[0..NR_RAW_REGISTERS) is direct-mapped onto the corresponding raw
register. The remaining [NR_RAW_REGISTERS
.. NR_COOKED_REGISTERS) (a.k.a. pseudo registers) are mapped onto
both raw registers and memory by the architecture methods
gdbarch_pseudo_register_read and gdbarch_pseudo_register_write. */
int nr_cooked_registers = 0;
long sizeof_cooked_registers = 0;
/* Offset and size (in 8 bit bytes), of each register in the
register cache. All registers (including those in the range
[NR_RAW_REGISTERS .. NR_COOKED_REGISTERS) are given an
offset. */
long *register_offset = nullptr;
long *sizeof_register = nullptr;
/* Cached table containing the type of each register. */
struct type **register_type = nullptr;
};
static const registry<gdbarch>::key<struct regcache_descr>
regcache_descr_handle;
static struct regcache_descr *
init_regcache_descr (struct gdbarch *gdbarch)
{
int i;
struct regcache_descr *descr;
gdb_assert (gdbarch != NULL);
/* Create an initial, zero filled, table. */
descr = new struct regcache_descr;
descr->gdbarch = gdbarch;
/* Total size of the register space. The raw registers are mapped
directly onto the raw register cache while the pseudo's are
either mapped onto raw-registers or memory. */
descr->nr_cooked_registers = gdbarch_num_cooked_regs (gdbarch);
/* Fill in a table of register types. */
descr->register_type
= GDBARCH_OBSTACK_CALLOC (gdbarch, descr->nr_cooked_registers,
struct type *);
for (i = 0; i < descr->nr_cooked_registers; i++)
descr->register_type[i] = gdbarch_register_type (gdbarch, i);
/* Construct a strictly RAW register cache. Don't allow pseudo's
into the register cache. */
/* Lay out the register cache.
NOTE: cagney/2002-05-22: Only register_type () is used when
constructing the register cache. It is assumed that the
register's raw size, virtual size and type length are all the
same. */
{
long offset = 0;
descr->sizeof_register
= GDBARCH_OBSTACK_CALLOC (gdbarch, descr->nr_cooked_registers, long);
descr->register_offset
= GDBARCH_OBSTACK_CALLOC (gdbarch, descr->nr_cooked_registers, long);
for (i = 0; i < gdbarch_num_regs (gdbarch); i++)
{
descr->sizeof_register[i] = descr->register_type[i]->length ();
descr->register_offset[i] = offset;
offset += descr->sizeof_register[i];
}
/* Set the real size of the raw register cache buffer. */
descr->sizeof_raw_registers = offset;
for (; i < descr->nr_cooked_registers; i++)
{
descr->sizeof_register[i] = descr->register_type[i]->length ();
descr->register_offset[i] = offset;
offset += descr->sizeof_register[i];
}
/* Set the real size of the readonly register cache buffer. */
descr->sizeof_cooked_registers = offset;
}
return descr;
}
static struct regcache_descr *
regcache_descr (struct gdbarch *gdbarch)
{
struct regcache_descr *result = regcache_descr_handle.get (gdbarch);
if (result == nullptr)
{
result = init_regcache_descr (gdbarch);
regcache_descr_handle.set (gdbarch, result);
}
return result;
}
/* Utility functions returning useful register attributes stored in
the regcache descr. */
struct type *
register_type (struct gdbarch *gdbarch, int regnum)
{
struct regcache_descr *descr = regcache_descr (gdbarch);
gdb_assert (regnum >= 0 && regnum < descr->nr_cooked_registers);
return descr->register_type[regnum];
}
/* Utility functions returning useful register attributes stored in
the regcache descr. */
int
register_size (struct gdbarch *gdbarch, int regnum)
{
struct regcache_descr *descr = regcache_descr (gdbarch);
int size;
gdb_assert (regnum >= 0 && regnum < gdbarch_num_cooked_regs (gdbarch));
size = descr->sizeof_register[regnum];
return size;
}
/* See gdbsupport/common-regcache.h. */
int
regcache_register_size (const struct regcache *regcache, int n)
{
return register_size (regcache->arch (), n);
}
reg_buffer::reg_buffer (gdbarch *gdbarch, bool has_pseudo)
: m_has_pseudo (has_pseudo)
{
gdb_assert (gdbarch != NULL);
m_descr = regcache_descr (gdbarch);
/* We don't zero-initialize the M_REGISTERS array, as the bytes it contains
aren't meaningful as long as the corresponding register status is not
REG_VALID. */
if (has_pseudo)
{
m_registers.reset (new gdb_byte[m_descr->sizeof_cooked_registers]);
m_register_status.reset
(new register_status[m_descr->nr_cooked_registers] ());
}
else
{
m_registers.reset (new gdb_byte[m_descr->sizeof_raw_registers]);
m_register_status.reset
(new register_status[gdbarch_num_regs (gdbarch)] ());
}
}
regcache::regcache (process_stratum_target *target, gdbarch *gdbarch,
const address_space *aspace_)
/* The register buffers. A read/write register cache can only hold
[0 .. gdbarch_num_regs). */
: detached_regcache (gdbarch, false), m_aspace (aspace_), m_target (target)
{
m_ptid = minus_one_ptid;
}
readonly_detached_regcache::readonly_detached_regcache (regcache &src)
: readonly_detached_regcache (src.arch (),
[&src] (int regnum, gdb_byte *buf)
{
return src.cooked_read (regnum, buf);
})
{
}
gdbarch *
reg_buffer::arch () const
{
return m_descr->gdbarch;
}
/* Return a pointer to register REGNUM's buffer cache. */
gdb_byte *
reg_buffer::register_buffer (int regnum) const
{
return m_registers.get () + m_descr->register_offset[regnum];
}
void
reg_buffer::save (register_read_ftype cooked_read)
{
struct gdbarch *gdbarch = m_descr->gdbarch;
int regnum;
/* It should have pseudo registers. */
gdb_assert (m_has_pseudo);
/* Clear the dest. */
memset (m_registers.get (), 0, m_descr->sizeof_cooked_registers);
memset (m_register_status.get (), REG_UNKNOWN, m_descr->nr_cooked_registers);
/* Copy over any registers (identified by their membership in the
save_reggroup) and mark them as valid. The full [0 .. gdbarch_num_regs +
gdbarch_num_pseudo_regs) range is checked since some architectures need
to save/restore `cooked' registers that live in memory. */
for (regnum = 0; regnum < m_descr->nr_cooked_registers; regnum++)
{
if (gdbarch_register_reggroup_p (gdbarch, regnum, save_reggroup))
{
gdb_byte *dst_buf = register_buffer (regnum);
enum register_status status = cooked_read (regnum, dst_buf);
gdb_assert (status != REG_UNKNOWN);
if (status != REG_VALID)
memset (dst_buf, 0, register_size (gdbarch, regnum));
m_register_status[regnum] = status;
}
}
}
void
regcache::restore (readonly_detached_regcache *src)
{
struct gdbarch *gdbarch = m_descr->gdbarch;
int regnum;
gdb_assert (src != NULL);
gdb_assert (src->m_has_pseudo);
gdb_assert (gdbarch == src->arch ());
/* Copy over any registers, being careful to only restore those that
were both saved and need to be restored. The full [0 .. gdbarch_num_regs
+ gdbarch_num_pseudo_regs) range is checked since some architectures need
to save/restore `cooked' registers that live in memory. */
for (regnum = 0; regnum < m_descr->nr_cooked_registers; regnum++)
{
if (gdbarch_register_reggroup_p (gdbarch, regnum, restore_reggroup))
{
if (src->m_register_status[regnum] == REG_VALID)
cooked_write (regnum, src->register_buffer (regnum));
}
}
}
/* See gdbsupport/common-regcache.h. */
enum register_status
reg_buffer::get_register_status (int regnum) const
{
assert_regnum (regnum);
return m_register_status[regnum];
}
void
reg_buffer::invalidate (int regnum)
{
assert_regnum (regnum);
m_register_status[regnum] = REG_UNKNOWN;
}
void
reg_buffer::assert_regnum (int regnum) const
{
gdb_assert (regnum >= 0);
if (m_has_pseudo)
gdb_assert (regnum < m_descr->nr_cooked_registers);
else
gdb_assert (regnum < gdbarch_num_regs (arch ()));
}
/* Type to map a ptid to a list of regcaches (one thread may have multiple
regcaches, associated to different gdbarches). */
using ptid_regcache_map
= std::unordered_multimap<ptid_t, regcache_up, hash_ptid>;
/* Type holding regcaches for a given pid. */
using pid_ptid_regcache_map = std::unordered_map<int, ptid_regcache_map>;
/* Type holding regcaches for a given target. */
using target_pid_ptid_regcache_map
= std::unordered_map<process_stratum_target *, pid_ptid_regcache_map>;
/* Global structure containing the existing regcaches. */
/* NOTE: this is a write-through cache. There is no "dirty" bit for
recording if the register values have been changed (eg. by the
user). Therefore all registers must be written back to the
target when appropriate. */
static target_pid_ptid_regcache_map regcaches;
struct regcache *
get_thread_arch_aspace_regcache (process_stratum_target *target,
ptid_t ptid, gdbarch *arch,
struct address_space *aspace)
{
gdb_assert (target != nullptr);
/* Find the map for this target. */
pid_ptid_regcache_map &pid_ptid_regc_map = regcaches[target];
/* Find the map for this pid. */
ptid_regcache_map &ptid_regc_map = pid_ptid_regc_map[ptid.pid ()];
/* Check first if a regcache for this arch already exists. */
auto range = ptid_regc_map.equal_range (ptid);
for (auto it = range.first; it != range.second; ++it)
{
if (it->second->arch () == arch)
return it->second.get ();
}
/* It does not exist, create it. */
regcache *new_regcache = new regcache (target, arch, aspace);
new_regcache->set_ptid (ptid);
/* Work around a problem with g++ 4.8 (PR96537): Call the regcache_up
constructor explictly instead of implicitly. */
ptid_regc_map.insert (std::make_pair (ptid, regcache_up (new_regcache)));
return new_regcache;
}
struct regcache *
get_thread_arch_regcache (process_stratum_target *target, ptid_t ptid,
struct gdbarch *gdbarch)
{
scoped_restore_current_inferior restore_current_inferior;
set_current_inferior (find_inferior_ptid (target, ptid));
address_space *aspace = target_thread_address_space (ptid);
return get_thread_arch_aspace_regcache (target, ptid, gdbarch, aspace);
}
static process_stratum_target *current_thread_target;
static ptid_t current_thread_ptid;
static struct gdbarch *current_thread_arch;
struct regcache *
get_thread_regcache (process_stratum_target *target, ptid_t ptid)
{
if (!current_thread_arch
|| target != current_thread_target
|| current_thread_ptid != ptid)
{
gdb_assert (ptid != null_ptid);
current_thread_ptid = ptid;
current_thread_target = target;
scoped_restore_current_inferior restore_current_inferior;
set_current_inferior (find_inferior_ptid (target, ptid));
current_thread_arch = target_thread_architecture (ptid);
}
return get_thread_arch_regcache (target, ptid, current_thread_arch);
}
/* See regcache.h. */
struct regcache *
get_thread_regcache (thread_info *thread)
{
return get_thread_regcache (thread->inf->process_target (),
thread->ptid);
}
struct regcache *
get_current_regcache (void)
{
return get_thread_regcache (inferior_thread ());
}
/* See gdbsupport/common-regcache.h. */
struct regcache *
get_thread_regcache_for_ptid (ptid_t ptid)
{
/* This function doesn't take a process_stratum_target parameter
because it's a gdbsupport/ routine implemented by both gdb and
gdbserver. It always refers to a ptid of the current target. */
process_stratum_target *proc_target = current_inferior ()->process_target ();
return get_thread_regcache (proc_target, ptid);
}
/* Observer for the target_changed event. */
static void
regcache_observer_target_changed (struct target_ops *target)
{
registers_changed ();
}
/* Update regcaches related to OLD_PTID to now use NEW_PTID. */
static void
regcache_thread_ptid_changed (process_stratum_target *target,
ptid_t old_ptid, ptid_t new_ptid)
{
/* Look up map for target. */
auto pid_ptid_regc_map_it = regcaches.find (target);
if (pid_ptid_regc_map_it == regcaches.end ())
return;
/* Look up map for pid. */
pid_ptid_regcache_map &pid_ptid_regc_map = pid_ptid_regc_map_it->second;
auto ptid_regc_map_it = pid_ptid_regc_map.find (old_ptid.pid ());
if (ptid_regc_map_it == pid_ptid_regc_map.end ())
return;
/* Update all regcaches belonging to old_ptid. */
ptid_regcache_map &ptid_regc_map = ptid_regc_map_it->second;
auto range = ptid_regc_map.equal_range (old_ptid);
for (auto it = range.first; it != range.second;)
{
regcache_up rc = std::move (it->second);
rc->set_ptid (new_ptid);
/* Remove old before inserting new, to avoid rehashing,
which would invalidate iterators. */
it = ptid_regc_map.erase (it);
ptid_regc_map.insert (std::make_pair (new_ptid, std::move (rc)));
}
}
/* Low level examining and depositing of registers.
The caller is responsible for making sure that the inferior is
stopped before calling the fetching routines, or it will get
garbage. (a change from GDB version 3, in which the caller got the
value from the last stop). */
/* REGISTERS_CHANGED ()
Indicate that registers may have changed, so invalidate the cache. */
void
registers_changed_ptid (process_stratum_target *target, ptid_t ptid)
{
if (target == nullptr)
{
/* Since there can be ptid clashes between targets, it's not valid to
pass a ptid without saying to which target it belongs. */
gdb_assert (ptid == minus_one_ptid);
/* Delete all the regcaches of all targets. */
regcaches.clear ();
}
else if (ptid.is_pid ())
{
/* Non-NULL target and pid ptid, delete all regcaches belonging
to this (TARGET, PID). */
/* Look up map for target. */
auto pid_ptid_regc_map_it = regcaches.find (target);
if (pid_ptid_regc_map_it != regcaches.end ())
{
pid_ptid_regcache_map &pid_ptid_regc_map
= pid_ptid_regc_map_it->second;
pid_ptid_regc_map.erase (ptid.pid ());
}
}
else if (ptid != minus_one_ptid)
{
/* Non-NULL target and non-minus_one_ptid, delete all regcaches belonging
to this (TARGET, PTID). */
/* Look up map for target. */
auto pid_ptid_regc_map_it = regcaches.find (target);
if (pid_ptid_regc_map_it != regcaches.end ())
{
pid_ptid_regcache_map &pid_ptid_regc_map
= pid_ptid_regc_map_it->second;
/* Look up map for pid. */
auto ptid_regc_map_it
= pid_ptid_regc_map.find (ptid.pid ());
if (ptid_regc_map_it != pid_ptid_regc_map.end ())
{
ptid_regcache_map &ptid_regc_map
= ptid_regc_map_it->second;
ptid_regc_map.erase (ptid);
}
}
}
else
{
/* Non-NULL target and minus_one_ptid, delete all regcaches
associated to this target. */
regcaches.erase (target);
}
if ((target == nullptr || current_thread_target == target)
&& current_thread_ptid.matches (ptid))
{
current_thread_target = NULL;
current_thread_ptid = null_ptid;
current_thread_arch = NULL;
}
if ((target == nullptr || current_inferior ()->process_target () == target)
&& inferior_ptid.matches (ptid))
{
/* We just deleted the regcache of the current thread. Need to
forget about any frames we have cached, too. */
reinit_frame_cache ();
}
}
/* See regcache.h. */
void
registers_changed_thread (thread_info *thread)
{
registers_changed_ptid (thread->inf->process_target (), thread->ptid);
}
void
registers_changed (void)
{
registers_changed_ptid (nullptr, minus_one_ptid);
}
void
regcache::raw_update (int regnum)
{
assert_regnum (regnum);
/* Make certain that the register cache is up-to-date with respect
to the current thread. This switching shouldn't be necessary
only there is still only one target side register cache. Sigh!
On the bright side, at least there is a regcache object. */
if (get_register_status (regnum) == REG_UNKNOWN)
{
target_fetch_registers (this, regnum);
/* A number of targets can't access the whole set of raw
registers (because the debug API provides no means to get at
them). */
if (m_register_status[regnum] == REG_UNKNOWN)
m_register_status[regnum] = REG_UNAVAILABLE;
}
}
enum register_status
readable_regcache::raw_read (int regnum, gdb_byte *buf)
{
gdb_assert (buf != NULL);
raw_update (regnum);
if (m_register_status[regnum] != REG_VALID)
memset (buf, 0, m_descr->sizeof_register[regnum]);
else
memcpy (buf, register_buffer (regnum),
m_descr->sizeof_register[regnum]);
return m_register_status[regnum];
}
enum register_status
regcache_raw_read_signed (struct regcache *regcache, int regnum, LONGEST *val)
{
gdb_assert (regcache != NULL);
return regcache->raw_read (regnum, val);
}
template<typename T, typename>
enum register_status
readable_regcache::raw_read (int regnum, T *val)
{
assert_regnum (regnum);
size_t len = m_descr->sizeof_register[regnum];
gdb_byte *buf = (gdb_byte *) alloca (len);
register_status status = raw_read (regnum, buf);
if (status == REG_VALID)
*val = extract_integer<T> ({buf, len},
gdbarch_byte_order (m_descr->gdbarch));
else
*val = 0;
return status;
}
enum register_status
regcache_raw_read_unsigned (struct regcache *regcache, int regnum,
ULONGEST *val)
{
gdb_assert (regcache != NULL);
return regcache->raw_read (regnum, val);
}
void
regcache_raw_write_signed (struct regcache *regcache, int regnum, LONGEST val)
{
gdb_assert (regcache != NULL);
regcache->raw_write (regnum, val);
}
template<typename T, typename>
void
regcache::raw_write (int regnum, T val)
{
gdb_byte *buf;
assert_regnum (regnum);
buf = (gdb_byte *) alloca (m_descr->sizeof_register[regnum]);
store_integer (buf, m_descr->sizeof_register[regnum],
gdbarch_byte_order (m_descr->gdbarch), val);
raw_write (regnum, buf);
}
void
regcache_raw_write_unsigned (struct regcache *regcache, int regnum,
ULONGEST val)
{
gdb_assert (regcache != NULL);
regcache->raw_write (regnum, val);
}
LONGEST
regcache_raw_get_signed (struct regcache *regcache, int regnum)
{
LONGEST value;
enum register_status status;
status = regcache_raw_read_signed (regcache, regnum, &value);
if (status == REG_UNAVAILABLE)
throw_error (NOT_AVAILABLE_ERROR,
_("Register %d is not available"), regnum);
return value;
}
enum register_status
readable_regcache::cooked_read (int regnum, gdb_byte *buf)
{
gdb_assert (regnum >= 0);
gdb_assert (regnum < m_descr->nr_cooked_registers);
if (regnum < num_raw_registers ())
return raw_read (regnum, buf);
else if (m_has_pseudo
&& m_register_status[regnum] != REG_UNKNOWN)
{
if (m_register_status[regnum] == REG_VALID)
memcpy (buf, register_buffer (regnum),
m_descr->sizeof_register[regnum]);
else
memset (buf, 0, m_descr->sizeof_register[regnum]);
return m_register_status[regnum];
}
else if (gdbarch_pseudo_register_read_value_p (m_descr->gdbarch))
{
struct value *computed;
enum register_status result = REG_VALID;
scoped_value_mark mark;
computed = gdbarch_pseudo_register_read_value (m_descr->gdbarch,
this, regnum);
if (value_entirely_available (computed))
memcpy (buf, value_contents_raw (computed).data (),
m_descr->sizeof_register[regnum]);
else
{
memset (buf, 0, m_descr->sizeof_register[regnum]);
result = REG_UNAVAILABLE;
}
return result;
}
else
return gdbarch_pseudo_register_read (m_descr->gdbarch, this,
regnum, buf);
}
struct value *
readable_regcache::cooked_read_value (int regnum)
{
gdb_assert (regnum >= 0);
gdb_assert (regnum < m_descr->nr_cooked_registers);
if (regnum < num_raw_registers ()
|| (m_has_pseudo && m_register_status[regnum] != REG_UNKNOWN)
|| !gdbarch_pseudo_register_read_value_p (m_descr->gdbarch))
{
struct value *result;
result = allocate_value (register_type (m_descr->gdbarch, regnum));
VALUE_LVAL (result) = lval_register;
VALUE_REGNUM (result) = regnum;
/* It is more efficient in general to do this delegation in this
direction than in the other one, even though the value-based
API is preferred. */
if (cooked_read (regnum,
value_contents_raw (result).data ()) == REG_UNAVAILABLE)
mark_value_bytes_unavailable (result, 0,
value_type (result)->length ());
return result;
}
else
return gdbarch_pseudo_register_read_value (m_descr->gdbarch,
this, regnum);
}
enum register_status
regcache_cooked_read_signed (struct regcache *regcache, int regnum,
LONGEST *val)
{
gdb_assert (regcache != NULL);
return regcache->cooked_read (regnum, val);
}
template<typename T, typename>
enum register_status
readable_regcache::cooked_read (int regnum, T *val)
{
gdb_assert (regnum >= 0 && regnum < m_descr->nr_cooked_registers);
size_t len = m_descr->sizeof_register[regnum];
gdb_byte *buf = (gdb_byte *) alloca (len);
register_status status = cooked_read (regnum, buf);
if (status == REG_VALID)
*val = extract_integer<T> ({buf, len},
gdbarch_byte_order (m_descr->gdbarch));
else
*val = 0;
return status;
}
enum register_status
regcache_cooked_read_unsigned (struct regcache *regcache, int regnum,
ULONGEST *val)
{
gdb_assert (regcache != NULL);
return regcache->cooked_read (regnum, val);
}
void
regcache_cooked_write_signed (struct regcache *regcache, int regnum,
LONGEST val)
{
gdb_assert (regcache != NULL);
regcache->cooked_write (regnum, val);
}
template<typename T, typename>
void
regcache::cooked_write (int regnum, T val)
{
gdb_byte *buf;
gdb_assert (regnum >=0 && regnum < m_descr->nr_cooked_registers);
buf = (gdb_byte *) alloca (m_descr->sizeof_register[regnum]);
store_integer (buf, m_descr->sizeof_register[regnum],
gdbarch_byte_order (m_descr->gdbarch), val);
cooked_write (regnum, buf);
}
void
regcache_cooked_write_unsigned (struct regcache *regcache, int regnum,
ULONGEST val)
{
gdb_assert (regcache != NULL);
regcache->cooked_write (regnum, val);
}
void
regcache::raw_write (int regnum, const gdb_byte *buf)
{
gdb_assert (buf != NULL);
assert_regnum (regnum);
/* On the sparc, writing %g0 is a no-op, so we don't even want to
change the registers array if something writes to this register. */
if (gdbarch_cannot_store_register (arch (), regnum))
return;
/* If we have a valid copy of the register, and new value == old
value, then don't bother doing the actual store. */
if (get_register_status (regnum) == REG_VALID
&& (memcmp (register_buffer (regnum), buf,
m_descr->sizeof_register[regnum]) == 0))
return;
target_prepare_to_store (this);
raw_supply (regnum, buf);
/* Invalidate the register after it is written, in case of a
failure. */
auto invalidator
= make_scope_exit ([&] { this->invalidate (regnum); });
target_store_registers (this, regnum);
/* The target did not throw an error so we can discard invalidating
the register. */
invalidator.release ();
}
void
regcache::cooked_write (int regnum, const gdb_byte *buf)
{
gdb_assert (regnum >= 0);
gdb_assert (regnum < m_descr->nr_cooked_registers);
if (regnum < num_raw_registers ())
raw_write (regnum, buf);
else
gdbarch_pseudo_register_write (m_descr->gdbarch, this,
regnum, buf);
}
/* See regcache.h. */
enum register_status
readable_regcache::read_part (int regnum, int offset, int len,
gdb_byte *out, bool is_raw)
{
int reg_size = register_size (arch (), regnum);
gdb_assert (out != NULL);
gdb_assert (offset >= 0 && offset <= reg_size);
gdb_assert (len >= 0 && offset + len <= reg_size);
if (offset == 0 && len == 0)
{
/* Nothing to do. */
return REG_VALID;
}
if (offset == 0 && len == reg_size)
{
/* Read the full register. */
return (is_raw) ? raw_read (regnum, out) : cooked_read (regnum, out);
}
enum register_status status;
gdb_byte *reg = (gdb_byte *) alloca (reg_size);
/* Read full register to buffer. */
status = (is_raw) ? raw_read (regnum, reg) : cooked_read (regnum, reg);
if (status != REG_VALID)
return status;
/* Copy out. */
memcpy (out, reg + offset, len);
return REG_VALID;
}
/* See regcache.h. */
void
reg_buffer::raw_collect_part (int regnum, int offset, int len,
gdb_byte *out) const
{
int reg_size = register_size (arch (), regnum);
gdb_assert (out != nullptr);
gdb_assert (offset >= 0 && offset <= reg_size);
gdb_assert (len >= 0 && offset + len <= reg_size);
if (offset == 0 && len == 0)
{
/* Nothing to do. */
return;
}
if (offset == 0 && len == reg_size)
{
/* Collect the full register. */
return raw_collect (regnum, out);
}
/* Read to buffer, then write out. */
gdb_byte *reg = (gdb_byte *) alloca (reg_size);
raw_collect (regnum, reg);
memcpy (out, reg + offset, len);
}
/* See regcache.h. */
enum register_status
regcache::write_part (int regnum, int offset, int len,
const gdb_byte *in, bool is_raw)
{
int reg_size = register_size (arch (), regnum);
gdb_assert (in != NULL);
gdb_assert (offset >= 0 && offset <= reg_size);
gdb_assert (len >= 0 && offset + len <= reg_size);
if (offset == 0 && len == 0)
{
/* Nothing to do. */
return REG_VALID;
}
if (offset == 0 && len == reg_size)
{
/* Write the full register. */
(is_raw) ? raw_write (regnum, in) : cooked_write (regnum, in);
return REG_VALID;
}
enum register_status status;
gdb_byte *reg = (gdb_byte *) alloca (reg_size);
/* Read existing register to buffer. */
status = (is_raw) ? raw_read (regnum, reg) : cooked_read (regnum, reg);
if (status != REG_VALID)
return status;
/* Update buffer, then write back to regcache. */
memcpy (reg + offset, in, len);
is_raw ? raw_write (regnum, reg) : cooked_write (regnum, reg);
return REG_VALID;
}
/* See regcache.h. */
void
reg_buffer::raw_supply_part (int regnum, int offset, int len,
const gdb_byte *in)
{
int reg_size = register_size (arch (), regnum);
gdb_assert (in != nullptr);
gdb_assert (offset >= 0 && offset <= reg_size);
gdb_assert (len >= 0 && offset + len <= reg_size);
if (offset == 0 && len == 0)
{
/* Nothing to do. */
return;
}
if (offset == 0 && len == reg_size)
{
/* Supply the full register. */
return raw_supply (regnum, in);
}
gdb_byte *reg = (gdb_byte *) alloca (reg_size);
/* Read existing value to buffer. */
raw_collect (regnum, reg);
/* Write to buffer, then write out. */
memcpy (reg + offset, in, len);
raw_supply (regnum, reg);
}
enum register_status
readable_regcache::raw_read_part (int regnum, int offset, int len,
gdb_byte *buf)
{
assert_regnum (regnum);
return read_part (regnum, offset, len, buf, true);
}
/* See regcache.h. */
void
regcache::raw_write_part (int regnum, int offset, int len,
const gdb_byte *buf)
{
assert_regnum (regnum);
write_part (regnum, offset, len, buf, true);
}
/* See regcache.h. */
enum register_status
readable_regcache::cooked_read_part (int regnum, int offset, int len,
gdb_byte *buf)
{
gdb_assert (regnum >= 0 && regnum < m_descr->nr_cooked_registers);
return read_part (regnum, offset, len, buf, false);
}
/* See regcache.h. */
void
regcache::cooked_write_part (int regnum, int offset, int len,
const gdb_byte *buf)
{
gdb_assert (regnum >= 0 && regnum < m_descr->nr_cooked_registers);
write_part (regnum, offset, len, buf, false);
}
/* See gdbsupport/common-regcache.h. */
void
reg_buffer::raw_supply (int regnum, const void *buf)
{
void *regbuf;
size_t size;
assert_regnum (regnum);
regbuf = register_buffer (regnum);
size = m_descr->sizeof_register[regnum];
if (buf)
{
memcpy (regbuf, buf, size);
m_register_status[regnum] = REG_VALID;
}
else
{
/* This memset not strictly necessary, but better than garbage
in case the register value manages to escape somewhere (due
to a bug, no less). */
memset (regbuf, 0, size);
m_register_status[regnum] = REG_UNAVAILABLE;
}
}
/* See regcache.h. */
void
reg_buffer::raw_supply_integer (int regnum, const gdb_byte *addr,
int addr_len, bool is_signed)
{
enum bfd_endian byte_order = gdbarch_byte_order (m_descr->gdbarch);
gdb_byte *regbuf;
size_t regsize;
assert_regnum (regnum);
regbuf = register_buffer (regnum);
regsize = m_descr->sizeof_register[regnum];
copy_integer_to_size (regbuf, regsize, addr, addr_len, is_signed,
byte_order);
m_register_status[regnum] = REG_VALID;
}
/* See regcache.h. */
void
reg_buffer::raw_supply_zeroed (int regnum)
{
void *regbuf;
size_t size;
assert_regnum (regnum);
regbuf = register_buffer (regnum);
size = m_descr->sizeof_register[regnum];
memset (regbuf, 0, size);
m_register_status[regnum] = REG_VALID;
}
/* See gdbsupport/common-regcache.h. */
void
reg_buffer::raw_collect (int regnum, void *buf) const
{
const void *regbuf;
size_t size;
gdb_assert (buf != NULL);
assert_regnum (regnum);
regbuf = register_buffer (regnum);
size = m_descr->sizeof_register[regnum];
memcpy (buf, regbuf, size);
}
/* See regcache.h. */
void
reg_buffer::raw_collect_integer (int regnum, gdb_byte *addr, int addr_len,
bool is_signed) const
{
enum bfd_endian byte_order = gdbarch_byte_order (m_descr->gdbarch);
const gdb_byte *regbuf;
size_t regsize;
assert_regnum (regnum);
regbuf = register_buffer (regnum);
regsize = m_descr->sizeof_register[regnum];
copy_integer_to_size (addr, addr_len, regbuf, regsize, is_signed,
byte_order);
}
/* See regcache.h. */
void
regcache::transfer_regset_register (struct regcache *out_regcache, int regnum,
const gdb_byte *in_buf, gdb_byte *out_buf,
int slot_size, int offs) const
{
struct gdbarch *gdbarch = arch ();
int reg_size = std::min (register_size (gdbarch, regnum), slot_size);
/* Use part versions and reg_size to prevent possible buffer overflows when
accessing the regcache. */
if (out_buf != nullptr)
{
raw_collect_part (regnum, 0, reg_size, out_buf + offs);
/* Ensure any additional space is cleared. */
if (slot_size > reg_size)
memset (out_buf + offs + reg_size, 0, slot_size - reg_size);
}
else if (in_buf != nullptr)
{
/* Zero-extend the register value if the slot is smaller than the register. */
if (slot_size < register_size (gdbarch, regnum))
out_regcache->raw_supply_zeroed (regnum);
out_regcache->raw_supply_part (regnum, 0, reg_size, in_buf + offs);
}
else
{
/* Invalidate the register. */
out_regcache->raw_supply (regnum, nullptr);
}
}
/* See regcache.h. */
void
regcache::transfer_regset (const struct regset *regset, int regbase,
struct regcache *out_regcache,
int regnum, const gdb_byte *in_buf,
gdb_byte *out_buf, size_t size) const
{
const struct regcache_map_entry *map;
int offs = 0, count;
for (map = (const struct regcache_map_entry *) regset->regmap;
(count = map->count) != 0;
map++)
{
int regno = map->regno;
int slot_size = map->size;
if (regno != REGCACHE_MAP_SKIP)
regno += regbase;
if (slot_size == 0 && regno != REGCACHE_MAP_SKIP)
slot_size = m_descr->sizeof_register[regno];
if (regno == REGCACHE_MAP_SKIP
|| (regnum != -1
&& (regnum < regno || regnum >= regno + count)))
offs += count * slot_size;
else if (regnum == -1)
for (; count--; regno++, offs += slot_size)
{
if (offs + slot_size > size)
break;
transfer_regset_register (out_regcache, regno, in_buf, out_buf,
slot_size, offs);
}
else
{
/* Transfer a single register and return. */
offs += (regnum - regno) * slot_size;
if (offs + slot_size > size)
return;
transfer_regset_register (out_regcache, regnum, in_buf, out_buf,
slot_size, offs);
return;
}
}
}
/* Supply register REGNUM from BUF to REGCACHE, using the register map
in REGSET. If REGNUM is -1, do this for all registers in REGSET.
If BUF is NULL, set the register(s) to "unavailable" status. */
void
regcache_supply_regset (const struct regset *regset,
struct regcache *regcache,
int regnum, const void *buf, size_t size)
{
regcache->supply_regset (regset, regnum, (const gdb_byte *) buf, size);
}
/* See regcache.h. */
void
regcache::supply_regset (const struct regset *regset, int regbase,
int regnum, const void *buf, size_t size)
{
transfer_regset (regset, regbase, this, regnum, (const gdb_byte *) buf,
nullptr, size);
}
/* Collect register REGNUM from REGCACHE to BUF, using the register
map in REGSET. If REGNUM is -1, do this for all registers in
REGSET. */
void
regcache_collect_regset (const struct regset *regset,
const struct regcache *regcache,
int regnum, void *buf, size_t size)
{
regcache->collect_regset (regset, regnum, (gdb_byte *) buf, size);
}
/* See regcache.h */
void
regcache::collect_regset (const struct regset *regset, int regbase,
int regnum, void *buf, size_t size) const
{
transfer_regset (regset, regbase, nullptr, regnum, nullptr, (gdb_byte *) buf,
size);
}
bool
regcache_map_supplies (const struct regcache_map_entry *map, int regnum,
struct gdbarch *gdbarch, size_t size)
{
int offs = 0, count;
for (; (count = map->count) != 0; map++)
{
int regno = map->regno;
int slot_size = map->size;
if (slot_size == 0 && regno != REGCACHE_MAP_SKIP)
slot_size = register_size (gdbarch, regno);
if (regno != REGCACHE_MAP_SKIP && regnum >= regno
&& regnum < regno + count)
return offs + (regnum - regno + 1) * slot_size <= size;
offs += count * slot_size;
if (offs >= size)
return false;
}
return false;
}
/* See gdbsupport/common-regcache.h. */
bool
reg_buffer::raw_compare (int regnum, const void *buf, int offset) const
{
gdb_assert (buf != NULL);
assert_regnum (regnum);
const char *regbuf = (const char *) register_buffer (regnum);
size_t size = m_descr->sizeof_register[regnum];
gdb_assert (size >= offset);
return (memcmp (buf, regbuf + offset, size - offset) == 0);
}
/* Special handling for register PC. */
CORE_ADDR
regcache_read_pc (struct regcache *regcache)
{
struct gdbarch *gdbarch = regcache->arch ();
CORE_ADDR pc_val;
if (gdbarch_read_pc_p (gdbarch))
pc_val = gdbarch_read_pc (gdbarch, regcache);
/* Else use per-frame method on get_current_frame. */
else if (gdbarch_pc_regnum (gdbarch) >= 0)
{
ULONGEST raw_val;
if (regcache_cooked_read_unsigned (regcache,
gdbarch_pc_regnum (gdbarch),
&raw_val) == REG_UNAVAILABLE)
throw_error (NOT_AVAILABLE_ERROR, _("PC register is not available"));
pc_val = gdbarch_addr_bits_remove (gdbarch, raw_val);
}
else
internal_error (_("regcache_read_pc: Unable to find PC"));
return pc_val;
}
/* See gdbsupport/common-regcache.h. */
CORE_ADDR
regcache_read_pc_protected (regcache *regcache)
{
CORE_ADDR pc;
try
{
pc = regcache_read_pc (regcache);
}
catch (const gdb_exception_error &ex)
{
pc = 0;
}
return pc;
}
void
regcache_write_pc (struct regcache *regcache, CORE_ADDR pc)
{
struct gdbarch *gdbarch = regcache->arch ();
if (gdbarch_write_pc_p (gdbarch))
gdbarch_write_pc (gdbarch, regcache, pc);
else if (gdbarch_pc_regnum (gdbarch) >= 0)
regcache_cooked_write_unsigned (regcache,
gdbarch_pc_regnum (gdbarch), pc);
else
internal_error (_("regcache_write_pc: Unable to update PC"));
/* Writing the PC (for instance, from "load") invalidates the
current frame. */
reinit_frame_cache ();
}
int
reg_buffer::num_raw_registers () const
{
return gdbarch_num_regs (arch ());
}
void
regcache::debug_print_register (const char *func, int regno)
{
struct gdbarch *gdbarch = arch ();
gdb_printf (gdb_stdlog, "%s ", func);
if (regno >= 0 && regno < gdbarch_num_regs (gdbarch)
&& gdbarch_register_name (gdbarch, regno)[0] != '\0')
gdb_printf (gdb_stdlog, "(%s)",
gdbarch_register_name (gdbarch, regno));
else
gdb_printf (gdb_stdlog, "(%d)", regno);
if (regno >= 0 && regno < gdbarch_num_regs (gdbarch))
{
enum bfd_endian byte_order = gdbarch_byte_order (gdbarch);
int size = register_size (gdbarch, regno);
gdb_byte *buf = register_buffer (regno);
gdb_printf (gdb_stdlog, " = ");
for (int i = 0; i < size; i++)
{
gdb_printf (gdb_stdlog, "%02x", buf[i]);
}
if (size <= sizeof (LONGEST))
{
ULONGEST val = extract_unsigned_integer (buf, size, byte_order);
gdb_printf (gdb_stdlog, " %s %s",
core_addr_to_string_nz (val), plongest (val));
}
}
gdb_printf (gdb_stdlog, "\n");
}
/* Implement 'maint flush register-cache' command. */
static void
reg_flush_command (const char *command, int from_tty)
{
/* Force-flush the register cache. */
registers_changed ();
if (from_tty)
gdb_printf (_("Register cache flushed.\n"));
}
void
register_dump::dump (ui_file *file)
{
auto descr = regcache_descr (m_gdbarch);
int regnum;
int footnote_nr = 0;
int footnote_register_offset = 0;
int footnote_register_type_name_null = 0;
long register_offset = 0;
gdb_assert (descr->nr_cooked_registers
== gdbarch_num_cooked_regs (m_gdbarch));
for (regnum = -1; regnum < descr->nr_cooked_registers; regnum++)
{
/* Name. */
if (regnum < 0)
gdb_printf (file, " %-10s", "Name");
else
{
const char *p = gdbarch_register_name (m_gdbarch, regnum);
if (p[0] == '\0')
p = "''";
gdb_printf (file, " %-10s", p);
}
/* Number. */
if (regnum < 0)
gdb_printf (file, " %4s", "Nr");
else
gdb_printf (file, " %4d", regnum);
/* Relative number. */
if (regnum < 0)
gdb_printf (file, " %4s", "Rel");
else if (regnum < gdbarch_num_regs (m_gdbarch))
gdb_printf (file, " %4d", regnum);
else
gdb_printf (file, " %4d",
(regnum - gdbarch_num_regs (m_gdbarch)));
/* Offset. */
if (regnum < 0)
gdb_printf (file, " %6s ", "Offset");
else
{
gdb_printf (file, " %6ld",
descr->register_offset[regnum]);
if (register_offset != descr->register_offset[regnum]
|| (regnum > 0
&& (descr->register_offset[regnum]
!= (descr->register_offset[regnum - 1]
+ descr->sizeof_register[regnum - 1])))
)
{
if (!footnote_register_offset)
footnote_register_offset = ++footnote_nr;
gdb_printf (file, "*%d", footnote_register_offset);
}
else
gdb_printf (file, " ");
register_offset = (descr->register_offset[regnum]
+ descr->sizeof_register[regnum]);
}
/* Size. */
if (regnum < 0)
gdb_printf (file, " %5s ", "Size");
else
gdb_printf (file, " %5ld", descr->sizeof_register[regnum]);
/* Type. */
{
const char *t;
std::string name_holder;
if (regnum < 0)
t = "Type";
else
{
static const char blt[] = "builtin_type";
t = register_type (m_gdbarch, regnum)->name ();
if (t == NULL)
{
if (!footnote_register_type_name_null)
footnote_register_type_name_null = ++footnote_nr;
name_holder = string_printf ("*%d",
footnote_register_type_name_null);
t = name_holder.c_str ();
}
/* Chop a leading builtin_type. */
if (startswith (t, blt))
t += strlen (blt);
}
gdb_printf (file, " %-15s", t);
}
/* Leading space always present. */
gdb_printf (file, " ");
dump_reg (file, regnum);
gdb_printf (file, "\n");
}
if (footnote_register_offset)
gdb_printf (file, "*%d: Inconsistent register offsets.\n",
footnote_register_offset);
if (footnote_register_type_name_null)
gdb_printf (file,
"*%d: Register type's name NULL.\n",
footnote_register_type_name_null);
}
#if GDB_SELF_TEST
#include "gdbsupport/selftest.h"
#include "selftest-arch.h"
#include "target-float.h"
namespace selftests {
static size_t
regcaches_size ()
{
size_t size = 0;
for (auto pid_ptid_regc_map_it = regcaches.cbegin ();
pid_ptid_regc_map_it != regcaches.cend ();
++pid_ptid_regc_map_it)
{
const pid_ptid_regcache_map &pid_ptid_regc_map
= pid_ptid_regc_map_it->second;
for (auto ptid_regc_map_it = pid_ptid_regc_map.cbegin ();
ptid_regc_map_it != pid_ptid_regc_map.cend ();
++ptid_regc_map_it)
{
const ptid_regcache_map &ptid_regc_map
= ptid_regc_map_it->second;
size += ptid_regc_map.size ();
}
}
return size;
}
/* Return the count of regcaches for (TARGET, PTID) in REGCACHES. */
static int
regcache_count (process_stratum_target *target, ptid_t ptid)
{
/* Look up map for target. */
auto pid_ptid_regc_map_it = regcaches.find (target);
if (pid_ptid_regc_map_it != regcaches.end ())
{
pid_ptid_regcache_map &pid_ptid_regc_map = pid_ptid_regc_map_it->second;
/* Look map for pid. */
auto ptid_regc_map_it = pid_ptid_regc_map.find (ptid.pid ());
if (ptid_regc_map_it != pid_ptid_regc_map.end ())
{
ptid_regcache_map &ptid_regc_map = ptid_regc_map_it->second;
auto range = ptid_regc_map.equal_range (ptid);
return std::distance (range.first, range.second);
}
}
return 0;
};
/* Wrapper around get_thread_arch_aspace_regcache that does some self checks. */
static void
get_thread_arch_aspace_regcache_and_check (process_stratum_target *target,
ptid_t ptid)
{
/* We currently only test with a single gdbarch. Any gdbarch will do, so use
the current inferior's gdbarch. Also use the current inferior's address
space. */
gdbarch *arch = current_inferior ()->gdbarch;
address_space *aspace = current_inferior ()->aspace;
regcache *regcache
= get_thread_arch_aspace_regcache (target, ptid, arch, aspace);
SELF_CHECK (regcache != NULL);
SELF_CHECK (regcache->target () == target);
SELF_CHECK (regcache->ptid () == ptid);
SELF_CHECK (regcache->arch () == arch);
SELF_CHECK (regcache->aspace () == aspace);
}
/* The data that the regcaches selftests must hold onto for the duration of the
test. */
struct regcache_test_data
{
regcache_test_data ()
{
/* Ensure the regcaches container is empty at the start. */
registers_changed ();
}
~regcache_test_data ()
{
/* Make sure to leave the global regcaches container empty. */
registers_changed ();
}
test_target_ops test_target1;
test_target_ops test_target2;
};
using regcache_test_data_up = std::unique_ptr<regcache_test_data>;
/* Set up a few regcaches from two different targets, for use in
regcache-management tests.
Return a pointer, because the `regcache_test_data` type is not moveable. */
static regcache_test_data_up
populate_regcaches_for_test ()
{
regcache_test_data_up data (new regcache_test_data);
size_t expected_regcache_size = 0;
SELF_CHECK (regcaches_size () == 0);
/* Populate the regcache container with a few regcaches for the two test
targets. */
for (int pid : { 1, 2 })
{
for (long lwp : { 1, 2, 3 })
{
get_thread_arch_aspace_regcache_and_check
(&data->test_target1, ptid_t (pid, lwp));
expected_regcache_size++;
SELF_CHECK (regcaches_size () == expected_regcache_size);
get_thread_arch_aspace_regcache_and_check
(&data->test_target2, ptid_t (pid, lwp));
expected_regcache_size++;
SELF_CHECK (regcaches_size () == expected_regcache_size);
}
}
return data;
}
static void
get_thread_arch_aspace_regcache_test ()
{
/* populate_regcaches_for_test already tests most of the
get_thread_arch_aspace_regcache functionality. */
regcache_test_data_up data = populate_regcaches_for_test ();
size_t regcaches_size_before = regcaches_size ();
/* Test that getting an existing regcache doesn't create a new one. */
get_thread_arch_aspace_regcache_and_check (&data->test_target1, ptid_t (2, 2));
SELF_CHECK (regcaches_size () == regcaches_size_before);
}
/* Test marking all regcaches of all targets as changed. */
static void
registers_changed_ptid_all_test ()
{
regcache_test_data_up data = populate_regcaches_for_test ();
registers_changed_ptid (nullptr, minus_one_ptid);
SELF_CHECK (regcaches_size () == 0);
}
/* Test marking regcaches of a specific target as changed. */
static void
registers_changed_ptid_target_test ()
{
regcache_test_data_up data = populate_regcaches_for_test ();
registers_changed_ptid (&data->test_target1, minus_one_ptid);
SELF_CHECK (regcaches_size () == 6);
/* Check that we deleted the regcache for the right target. */
SELF_CHECK (regcache_count (&data->test_target1, ptid_t (2, 2)) == 0);
SELF_CHECK (regcache_count (&data->test_target2, ptid_t (2, 2)) == 1);
}
/* Test marking regcaches of a specific (target, pid) as changed. */
static void
registers_changed_ptid_target_pid_test ()
{
regcache_test_data_up data = populate_regcaches_for_test ();
registers_changed_ptid (&data->test_target1, ptid_t (2));
SELF_CHECK (regcaches_size () == 9);
/* Regcaches from target1 should not exist, while regcaches from target2
should exist. */
SELF_CHECK (regcache_count (&data->test_target1, ptid_t (2, 2)) == 0);
SELF_CHECK (regcache_count (&data->test_target2, ptid_t (2, 2)) == 1);
}
/* Test marking regcaches of a specific (target, ptid) as changed. */
static void
registers_changed_ptid_target_ptid_test ()
{
regcache_test_data_up data = populate_regcaches_for_test ();
registers_changed_ptid (&data->test_target1, ptid_t (2, 2));
SELF_CHECK (regcaches_size () == 11);
/* Check that we deleted the regcache for the right target. */
SELF_CHECK (regcache_count (&data->test_target1, ptid_t (2, 2)) == 0);
SELF_CHECK (regcache_count (&data->test_target2, ptid_t (2, 2)) == 1);
}
class target_ops_no_register : public test_target_ops
{
public:
target_ops_no_register ()
: test_target_ops {}
{}
void reset ()
{
fetch_registers_called = 0;
store_registers_called = 0;
xfer_partial_called = 0;
}
void fetch_registers (regcache *regs, int regno) override;
void store_registers (regcache *regs, int regno) override;
enum target_xfer_status xfer_partial (enum target_object object,
const char *annex, gdb_byte *readbuf,
const gdb_byte *writebuf,
ULONGEST offset, ULONGEST len,
ULONGEST *xfered_len) override;
unsigned int fetch_registers_called = 0;
unsigned int store_registers_called = 0;
unsigned int xfer_partial_called = 0;
};
void
target_ops_no_register::fetch_registers (regcache *regs, int regno)
{
/* Mark register available. */
regs->raw_supply_zeroed (regno);
this->fetch_registers_called++;
}
void
target_ops_no_register::store_registers (regcache *regs, int regno)
{
this->store_registers_called++;
}
enum target_xfer_status
target_ops_no_register::xfer_partial (enum target_object object,
const char *annex, gdb_byte *readbuf,
const gdb_byte *writebuf,
ULONGEST offset, ULONGEST len,
ULONGEST *xfered_len)
{
this->xfer_partial_called++;
*xfered_len = len;
return TARGET_XFER_OK;
}
class readwrite_regcache : public regcache
{
public:
readwrite_regcache (process_stratum_target *target,
struct gdbarch *gdbarch)
: regcache (target, gdbarch, nullptr)
{}
};
/* Return true if regcache::cooked_{read,write}_test should be skipped for
GDBARCH. */
static bool
selftest_skiparch (struct gdbarch *gdbarch)
{
const char *name = gdbarch_bfd_arch_info (gdbarch)->printable_name;
/* Avoid warning:
Running selftest regcache::cooked_{read,write}_test::m68hc11.
warning: No frame soft register found in the symbol table.
Stack backtrace will not work.
We could instead capture the output and then filter out the warning, but
that seems more trouble than it's worth. */
return (strcmp (name, "m68hc11") == 0
|| strcmp (name, "m68hc12") == 0
|| strcmp (name, "m68hc12:HCS12") == 0);
}
/* Test regcache::cooked_read gets registers from raw registers and
memory instead of target to_{fetch,store}_registers. */
static void
cooked_read_test (struct gdbarch *gdbarch)
{
if (selftest_skiparch (gdbarch))
return;
scoped_mock_context<target_ops_no_register> mockctx (gdbarch);
/* Test that read one raw register from regcache_no_target will go
to the target layer. */
/* Find a raw register which size isn't zero. */
int nonzero_regnum;
for (nonzero_regnum = 0;
nonzero_regnum < gdbarch_num_regs (gdbarch);
nonzero_regnum++)
{
if (register_size (gdbarch, nonzero_regnum) != 0)
break;
}
readwrite_regcache readwrite (&mockctx.mock_target, gdbarch);
gdb::def_vector<gdb_byte> buf (register_size (gdbarch, nonzero_regnum));
readwrite.raw_read (nonzero_regnum, buf.data ());
/* raw_read calls target_fetch_registers. */
SELF_CHECK (mockctx.mock_target.fetch_registers_called > 0);
mockctx.mock_target.reset ();
/* Mark all raw registers valid, so the following raw registers
accesses won't go to target. */
for (auto i = 0; i < gdbarch_num_regs (gdbarch); i++)
readwrite.raw_update (i);
mockctx.mock_target.reset ();
/* Then, read all raw and pseudo registers, and don't expect calling
to_{fetch,store}_registers. */
for (int regnum = 0; regnum < gdbarch_num_cooked_regs (gdbarch); regnum++)
{
if (register_size (gdbarch, regnum) == 0)
continue;
gdb::def_vector<gdb_byte> inner_buf (register_size (gdbarch, regnum));
SELF_CHECK (REG_VALID == readwrite.cooked_read (regnum,
inner_buf.data ()));
SELF_CHECK (mockctx.mock_target.fetch_registers_called == 0);
SELF_CHECK (mockctx.mock_target.store_registers_called == 0);
SELF_CHECK (mockctx.mock_target.xfer_partial_called == 0);
mockctx.mock_target.reset ();
}
readonly_detached_regcache readonly (readwrite);
/* GDB may go to target layer to fetch all registers and memory for
readonly regcache. */
mockctx.mock_target.reset ();
for (int regnum = 0; regnum < gdbarch_num_cooked_regs (gdbarch); regnum++)
{
if (register_size (gdbarch, regnum) == 0)
continue;
gdb::def_vector<gdb_byte> inner_buf (register_size (gdbarch, regnum));
enum register_status status = readonly.cooked_read (regnum,
inner_buf.data ());
if (regnum < gdbarch_num_regs (gdbarch))
{
auto bfd_arch = gdbarch_bfd_arch_info (gdbarch)->arch;
if (bfd_arch == bfd_arch_amdgcn
|| bfd_arch == bfd_arch_frv || bfd_arch == bfd_arch_h8300
|| bfd_arch == bfd_arch_m32c || bfd_arch == bfd_arch_sh
|| bfd_arch == bfd_arch_alpha || bfd_arch == bfd_arch_v850
|| bfd_arch == bfd_arch_msp430 || bfd_arch == bfd_arch_mep
|| bfd_arch == bfd_arch_mips || bfd_arch == bfd_arch_v850_rh850
|| bfd_arch == bfd_arch_tic6x || bfd_arch == bfd_arch_mn10300
|| bfd_arch == bfd_arch_rl78 || bfd_arch == bfd_arch_score
|| bfd_arch == bfd_arch_riscv || bfd_arch == bfd_arch_csky)
{
/* Raw registers. If raw registers are not in save_reggroup,
their status are unknown. */
if (gdbarch_register_reggroup_p (gdbarch, regnum, save_reggroup))
SELF_CHECK (status == REG_VALID);
else
SELF_CHECK (status == REG_UNKNOWN);
}
else
SELF_CHECK (status == REG_VALID);
}
else
{
if (gdbarch_register_reggroup_p (gdbarch, regnum, save_reggroup))
SELF_CHECK (status == REG_VALID);
else
{
/* If pseudo registers are not in save_reggroup, some of
them can be computed from saved raw registers, but some
of them are unknown. */
auto bfd_arch = gdbarch_bfd_arch_info (gdbarch)->arch;
if (bfd_arch == bfd_arch_frv
|| bfd_arch == bfd_arch_m32c
|| bfd_arch == bfd_arch_mep
|| bfd_arch == bfd_arch_sh)
SELF_CHECK (status == REG_VALID || status == REG_UNKNOWN);
else if (bfd_arch == bfd_arch_mips
|| bfd_arch == bfd_arch_h8300)
SELF_CHECK (status == REG_UNKNOWN);
else
SELF_CHECK (status == REG_VALID);
}
}
SELF_CHECK (mockctx.mock_target.fetch_registers_called == 0);
SELF_CHECK (mockctx.mock_target.store_registers_called == 0);
SELF_CHECK (mockctx.mock_target.xfer_partial_called == 0);
mockctx.mock_target.reset ();
}
}
/* Test regcache::cooked_write by writing some expected contents to
registers, and checking that contents read from registers and the
expected contents are the same. */
static void
cooked_write_test (struct gdbarch *gdbarch)
{
if (selftest_skiparch (gdbarch))
return;
/* Create a mock environment. A process_stratum target pushed. */
scoped_mock_context<target_ops_no_register> ctx (gdbarch);
readwrite_regcache readwrite (&ctx.mock_target, gdbarch);
const int num_regs = gdbarch_num_cooked_regs (gdbarch);
for (auto regnum = 0; regnum < num_regs; regnum++)
{
if (register_size (gdbarch, regnum) == 0
|| gdbarch_cannot_store_register (gdbarch, regnum))
continue;
auto bfd_arch = gdbarch_bfd_arch_info (gdbarch)->arch;
if (bfd_arch == bfd_arch_sparc
/* SPARC64_CWP_REGNUM, SPARC64_PSTATE_REGNUM,
SPARC64_ASI_REGNUM and SPARC64_CCR_REGNUM are hard to test. */
&& gdbarch_ptr_bit (gdbarch) == 64
&& (regnum >= gdbarch_num_regs (gdbarch)
&& regnum <= gdbarch_num_regs (gdbarch) + 4))
continue;
std::vector<gdb_byte> expected (register_size (gdbarch, regnum), 0);
std::vector<gdb_byte> buf (register_size (gdbarch, regnum), 0);
const auto type = register_type (gdbarch, regnum);
if (type->code () == TYPE_CODE_FLT
|| type->code () == TYPE_CODE_DECFLOAT)
{
/* Generate valid float format. */
target_float_from_string (expected.data (), type, "1.25");
}
else if (type->code () == TYPE_CODE_INT
|| type->code () == TYPE_CODE_ARRAY
|| type->code () == TYPE_CODE_PTR
|| type->code () == TYPE_CODE_UNION
|| type->code () == TYPE_CODE_STRUCT)
{
if (bfd_arch == bfd_arch_ia64
|| (regnum >= gdbarch_num_regs (gdbarch)
&& (bfd_arch == bfd_arch_xtensa
|| bfd_arch == bfd_arch_bfin
|| bfd_arch == bfd_arch_m32c
/* m68hc11 pseudo registers are in memory. */
|| bfd_arch == bfd_arch_m68hc11
|| bfd_arch == bfd_arch_m68hc12
|| bfd_arch == bfd_arch_s390))
|| (bfd_arch == bfd_arch_frv
/* FRV pseudo registers except iacc0. */
&& regnum > gdbarch_num_regs (gdbarch)))
{
/* Skip setting the expected values for some architecture
registers. */
}
else if (bfd_arch == bfd_arch_rl78 && regnum == 40)
{
/* RL78_PC_REGNUM */
for (auto j = 0; j < register_size (gdbarch, regnum) - 1; j++)
expected[j] = j;
}
else
{
for (auto j = 0; j < register_size (gdbarch, regnum); j++)
expected[j] = j;
}
}
else if (type->code () == TYPE_CODE_FLAGS)
{
/* No idea how to test flags. */
continue;
}
else
{
/* If we don't know how to create the expected value for the
this type, make it fail. */
SELF_CHECK (0);
}
readwrite.cooked_write (regnum, expected.data ());
SELF_CHECK (readwrite.cooked_read (regnum, buf.data ()) == REG_VALID);
SELF_CHECK (expected == buf);
}
}
/* Verify that when two threads with the same ptid exist (from two different
targets) and one of them changes ptid, we only update the appropriate
regcaches. */
static void
regcache_thread_ptid_changed ()
{
/* This test relies on the global regcache list to initially be empty. */
registers_changed ();
/* Any arch will do. */
gdbarch *arch = current_inferior ()->gdbarch;
/* Prepare two targets with one thread each, with the same ptid. */
scoped_mock_context<test_target_ops> target1 (arch);
scoped_mock_context<test_target_ops> target2 (arch);
ptid_t old_ptid (111, 222);
ptid_t new_ptid (111, 333);
target1.mock_inferior.pid = old_ptid.pid ();
target1.mock_thread.ptid = old_ptid;
target1.mock_inferior.ptid_thread_map.clear ();
target1.mock_inferior.ptid_thread_map[old_ptid] = &target1.mock_thread;
target2.mock_inferior.pid = old_ptid.pid ();
target2.mock_thread.ptid = old_ptid;
target2.mock_inferior.ptid_thread_map.clear ();
target2.mock_inferior.ptid_thread_map[old_ptid] = &target2.mock_thread;
gdb_assert (regcaches.empty ());
/* Populate the regcaches container. */
get_thread_arch_aspace_regcache (&target1.mock_target, old_ptid, arch,
nullptr);
get_thread_arch_aspace_regcache (&target2.mock_target, old_ptid, arch,
nullptr);
gdb_assert (regcaches.size () == 2);
gdb_assert (regcache_count (&target1.mock_target, old_ptid) == 1);
gdb_assert (regcache_count (&target1.mock_target, new_ptid) == 0);
gdb_assert (regcache_count (&target2.mock_target, old_ptid) == 1);
gdb_assert (regcache_count (&target2.mock_target, new_ptid) == 0);
thread_change_ptid (&target1.mock_target, old_ptid, new_ptid);
gdb_assert (regcaches.size () == 2);
gdb_assert (regcache_count (&target1.mock_target, old_ptid) == 0);
gdb_assert (regcache_count (&target1.mock_target, new_ptid) == 1);
gdb_assert (regcache_count (&target2.mock_target, old_ptid) == 1);
gdb_assert (regcache_count (&target2.mock_target, new_ptid) == 0);
/* Leave the regcache list empty. */
registers_changed ();
gdb_assert (regcaches.empty ());
}
} // namespace selftests
#endif /* GDB_SELF_TEST */
void _initialize_regcache ();
void
_initialize_regcache ()
{
struct cmd_list_element *c;
gdb::observers::target_changed.attach (regcache_observer_target_changed,
"regcache");
gdb::observers::thread_ptid_changed.attach (regcache_thread_ptid_changed,
"regcache");
cmd_list_element *maintenance_flush_register_cache_cmd
= add_cmd ("register-cache", class_maintenance, reg_flush_command,
_("Force gdb to flush its register and frame cache."),
&maintenanceflushlist);
c = add_com_alias ("flushregs", maintenance_flush_register_cache_cmd,
class_maintenance, 0);
deprecate_cmd (c, "maintenance flush register-cache");
#if GDB_SELF_TEST
selftests::register_test ("get_thread_arch_aspace_regcache",
selftests::get_thread_arch_aspace_regcache_test);
selftests::register_test ("registers_changed_ptid_all",
selftests::registers_changed_ptid_all_test);
selftests::register_test ("registers_changed_ptid_target",
selftests::registers_changed_ptid_target_test);
selftests::register_test ("registers_changed_ptid_target_pid",
selftests::registers_changed_ptid_target_pid_test);
selftests::register_test ("registers_changed_ptid_target_ptid",
selftests::registers_changed_ptid_target_ptid_test);
selftests::register_test_foreach_arch ("regcache::cooked_read_test",
selftests::cooked_read_test);
selftests::register_test_foreach_arch ("regcache::cooked_write_test",
selftests::cooked_write_test);
selftests::register_test ("regcache_thread_ptid_changed",
selftests::regcache_thread_ptid_changed);
#endif
}
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