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Some ravenscar runtimes implement lazy FPU handling. On these runtimes, the FPU is only initialized when a task tries to use it. Furthermore, the FP registers aren't automatically saved on a task switch -- instead, the save is deferred until the new task tries to use the FPU. Furthermore, each task's context area has a flag indicating whether the FPU has been initialized for this task. This patch teaches GDB to understand this implementation. When fetching or storing registers, GDB now checks to see whether the live FP registers should be used. If not, the task's saved FP registers will be used if the task has caused FPU initialization. Currently only AArch64 uses this code. bb-runtimes implements this for ARM as well, but GDB doesn't yet have an arm-ravenscar-thread.c.
134 lines
5.0 KiB
C++
134 lines
5.0 KiB
C++
/* Ada Ravenscar thread support.
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Copyright (C) 2004-2022 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 RAVENSCAR_THREAD_H
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#define RAVENSCAR_THREAD_H
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/* Architecture-specific hooks. */
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struct ravenscar_arch_ops
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{
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ravenscar_arch_ops (gdb::array_view<const int> offsets_,
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int first_stack = -1,
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int last_stack = -1,
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int v_init = -1,
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int fpu_offset = -1,
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int first_fp = -1,
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int last_fp = -1)
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: offsets (offsets_),
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first_stack_register (first_stack),
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last_stack_register (last_stack),
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v_init_offset (v_init),
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fpu_context_offset (fpu_offset),
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first_fp_register (first_fp),
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last_fp_register (last_fp)
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{
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/* These must either both be -1 or both be valid. */
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gdb_assert ((first_stack_register == -1) == (last_stack_register == -1));
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/* They must also be ordered. */
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gdb_assert (last_stack_register >= first_stack_register);
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/* These must either all be -1 or all be valid. */
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gdb_assert ((v_init_offset == -1) == (fpu_context_offset == -1)
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&& (fpu_context_offset == -1) == (first_fp_register == -1)
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&& (first_fp_register == -1) == (last_fp_register == -1));
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}
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/* Return true if this architecture implements on-demand floating
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point. */
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bool on_demand_fp () const
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{ return v_init_offset != -1; }
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/* Return true if REGNUM is a floating-point register for this
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target. If this target does not use the on-demand FP scheme,
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this will always return false. */
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bool is_fp_register (int regnum) const
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{
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return regnum >= first_fp_register && regnum <= last_fp_register;
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}
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/* Return the offset, in the current task context, of the byte
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indicating whether the FPU has been initialized for the task.
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This can only be called when the architecture implements
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on-demand floating-point. */
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int get_v_init_offset () const
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{
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gdb_assert (on_demand_fp ());
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return v_init_offset;
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}
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/* Return the offset, in the current task context, of the FPU
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context. This can only be called when the architecture
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implements on-demand floating-point. */
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int get_fpu_context_offset () const
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{
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gdb_assert (on_demand_fp ());
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return fpu_context_offset;
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}
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void fetch_register (struct regcache *recache, int regnum) const;
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void store_register (struct regcache *recache, int regnum) const;
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private:
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/* An array where the indices are register numbers and the contents
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are offsets. The offsets are either in the thread descriptor or
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the stack, depending on the other fields. An offset of -1 means
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that the corresponding register is not stored. */
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const gdb::array_view<const int> offsets;
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/* If these are -1, then all registers for this architecture are
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stored in the thread descriptor. Otherwise, these mark a range
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of registers that are stored on the stack. */
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const int first_stack_register;
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const int last_stack_register;
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/* If these are -1, there is no special treatment for floating-point
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registers -- they are handled, or not, just like all other
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registers.
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Otherwise, they must all not be -1, and the target is one that
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uses on-demand FP initialization. V_INIT_OFFSET is the offset of
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a boolean field in the context that indicates whether the FP
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registers have been initialized for this task.
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FPU_CONTEXT_OFFSET is the offset of the FPU context from the task
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context. (This is needed to check whether the FPU registers have
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been saved.) FIRST_FP_REGISTER and LAST_FP_REGISTER are the
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register numbers of the first and last (inclusive) floating point
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registers. */
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const int v_init_offset;
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const int fpu_context_offset;
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const int first_fp_register;
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const int last_fp_register;
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/* Helper function to supply one register. */
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void supply_one_register (struct regcache *regcache, int regnum,
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CORE_ADDR descriptor,
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CORE_ADDR stack_base) const;
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/* Helper function to store one register. */
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void store_one_register (struct regcache *regcache, int regnum,
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CORE_ADDR descriptor,
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CORE_ADDR stack_base) const;
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/* Helper function to find stack address where registers are stored.
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This must be called with the stack pointer already supplied in
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the register cache. */
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CORE_ADDR get_stack_base (struct regcache *) const;
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};
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#endif /* !defined (RAVENSCAR_THREAD_H) */
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