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528 lines
14 KiB
C
528 lines
14 KiB
C
/* ARM EABI compliant unwinding routines.
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Copyright (C) 2004, 2005, 2009 Free Software Foundation, Inc.
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Contributed by Paul Brook
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This file is free software; you can redistribute it and/or modify it
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under the terms of the GNU General Public License as published by the
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Free Software Foundation; either version 3, or (at your option) any
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later version.
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This file is distributed in the hope that it will be useful, but
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WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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General Public License for more details.
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Under Section 7 of GPL version 3, you are granted additional
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permissions described in the GCC Runtime Library Exception, version
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3.1, as published by the Free Software Foundation.
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You should have received a copy of the GNU General Public License and
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a copy of the GCC Runtime Library Exception along with this program;
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see the files COPYING3 and COPYING.RUNTIME respectively. If not, see
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<http://www.gnu.org/licenses/>. */
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#include "unwind.h"
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/* Misc constants. */
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#define R_IP 12
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#define R_SP 13
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#define R_LR 14
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#define R_PC 15
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#define VRS_PC(vrs) ((vrs)->core.r[R_PC])
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#define VRS_SP(vrs) ((vrs)->core.r[R_SP])
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#define VRS_RETURN(vrs) ((vrs)->core.r[R_LR])
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struct core_regs
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{
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_uw r[16];
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};
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/* We use normal integer types here to avoid the compiler generating
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coprocessor instructions. */
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struct vfp_regs
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{
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_uw64 d[16];
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_uw pad;
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};
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struct vfpv3_regs
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{
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/* Always populated via VSTM, so no need for the "pad" field from
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vfp_regs (which is used to store the format word for FSTMX). */
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_uw64 d[16];
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};
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struct fpa_reg
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{
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_uw w[3];
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};
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struct fpa_regs
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{
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struct fpa_reg f[8];
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};
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struct wmmxd_regs
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{
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_uw64 wd[16];
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};
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struct wmmxc_regs
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{
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_uw wc[4];
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};
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/* The ABI specifies that the unwind routines may only use core registers,
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except when actually manipulating coprocessor state. This allows
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us to write one implementation that works on all platforms by
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demand-saving coprocessor registers.
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During unwinding we hold the coprocessor state in the actual hardware
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registers and allocate demand-save areas for use during phase1
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unwinding. */
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typedef struct
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{
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/* The first fields must be the same as a phase2_vrs. */
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_uw demand_save_flags;
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struct core_regs core;
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_uw prev_sp; /* Only valid during forced unwinding. */
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struct vfp_regs vfp;
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struct vfpv3_regs vfp_regs_16_to_31;
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struct fpa_regs fpa;
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struct wmmxd_regs wmmxd;
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struct wmmxc_regs wmmxc;
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} phase1_vrs;
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#define DEMAND_SAVE_VFP 1 /* VFP state has been saved if not set */
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#define DEMAND_SAVE_VFP_D 2 /* VFP state is for FLDMD/FSTMD if set */
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#define DEMAND_SAVE_VFP_V3 4 /* VFPv3 state for regs 16 .. 31 has
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been saved if not set */
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#define DEMAND_SAVE_WMMXD 8 /* iWMMXt data registers have been
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saved if not set. */
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#define DEMAND_SAVE_WMMXC 16 /* iWMMXt control registers have been
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saved if not set. */
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/* This must match the structure created by the assembly wrappers. */
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typedef struct
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{
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_uw demand_save_flags;
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struct core_regs core;
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} phase2_vrs;
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/* Coprocessor register state manipulation functions. */
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/* Routines for FLDMX/FSTMX format... */
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void __gnu_Unwind_Save_VFP (struct vfp_regs * p);
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void __gnu_Unwind_Restore_VFP (struct vfp_regs * p);
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void __gnu_Unwind_Save_WMMXD (struct wmmxd_regs * p);
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void __gnu_Unwind_Restore_WMMXD (struct wmmxd_regs * p);
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void __gnu_Unwind_Save_WMMXC (struct wmmxc_regs * p);
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void __gnu_Unwind_Restore_WMMXC (struct wmmxc_regs * p);
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/* ...and those for FLDMD/FSTMD format... */
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void __gnu_Unwind_Save_VFP_D (struct vfp_regs * p);
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void __gnu_Unwind_Restore_VFP_D (struct vfp_regs * p);
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/* ...and those for VLDM/VSTM format, saving/restoring only registers
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16 through 31. */
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void __gnu_Unwind_Save_VFP_D_16_to_31 (struct vfpv3_regs * p);
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void __gnu_Unwind_Restore_VFP_D_16_to_31 (struct vfpv3_regs * p);
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/* Restore coprocessor state after phase1 unwinding. */
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static void
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restore_non_core_regs (phase1_vrs * vrs)
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{
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if ((vrs->demand_save_flags & DEMAND_SAVE_VFP) == 0)
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{
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if (vrs->demand_save_flags & DEMAND_SAVE_VFP_D)
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__gnu_Unwind_Restore_VFP_D (&vrs->vfp);
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else
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__gnu_Unwind_Restore_VFP (&vrs->vfp);
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}
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if ((vrs->demand_save_flags & DEMAND_SAVE_VFP_V3) == 0)
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__gnu_Unwind_Restore_VFP_D_16_to_31 (&vrs->vfp_regs_16_to_31);
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if ((vrs->demand_save_flags & DEMAND_SAVE_WMMXD) == 0)
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__gnu_Unwind_Restore_WMMXD (&vrs->wmmxd);
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if ((vrs->demand_save_flags & DEMAND_SAVE_WMMXC) == 0)
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__gnu_Unwind_Restore_WMMXC (&vrs->wmmxc);
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}
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#include "unwind-arm-common.inc"
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/* ABI defined personality routines. */
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extern _Unwind_Reason_Code __aeabi_unwind_cpp_pr0 (_Unwind_State,
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_Unwind_Control_Block *, _Unwind_Context *);// __attribute__((weak));
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extern _Unwind_Reason_Code __aeabi_unwind_cpp_pr1 (_Unwind_State,
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_Unwind_Control_Block *, _Unwind_Context *) __attribute__((weak));
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extern _Unwind_Reason_Code __aeabi_unwind_cpp_pr2 (_Unwind_State,
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_Unwind_Control_Block *, _Unwind_Context *) __attribute__((weak));
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/* ABI defined routine to store a virtual register to memory. */
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_Unwind_VRS_Result _Unwind_VRS_Get (_Unwind_Context *context,
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_Unwind_VRS_RegClass regclass,
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_uw regno,
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_Unwind_VRS_DataRepresentation representation,
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void *valuep)
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{
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phase1_vrs *vrs = (phase1_vrs *) context;
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switch (regclass)
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{
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case _UVRSC_CORE:
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if (representation != _UVRSD_UINT32
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|| regno > 15)
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return _UVRSR_FAILED;
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*(_uw *) valuep = vrs->core.r[regno];
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return _UVRSR_OK;
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case _UVRSC_VFP:
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case _UVRSC_FPA:
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case _UVRSC_WMMXD:
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case _UVRSC_WMMXC:
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return _UVRSR_NOT_IMPLEMENTED;
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default:
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return _UVRSR_FAILED;
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}
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}
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/* ABI defined function to load a virtual register from memory. */
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_Unwind_VRS_Result _Unwind_VRS_Set (_Unwind_Context *context,
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_Unwind_VRS_RegClass regclass,
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_uw regno,
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_Unwind_VRS_DataRepresentation representation,
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void *valuep)
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{
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phase1_vrs *vrs = (phase1_vrs *) context;
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switch (regclass)
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{
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case _UVRSC_CORE:
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if (representation != _UVRSD_UINT32
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|| regno > 15)
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return _UVRSR_FAILED;
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vrs->core.r[regno] = *(_uw *) valuep;
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return _UVRSR_OK;
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case _UVRSC_VFP:
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case _UVRSC_FPA:
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case _UVRSC_WMMXD:
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case _UVRSC_WMMXC:
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return _UVRSR_NOT_IMPLEMENTED;
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default:
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return _UVRSR_FAILED;
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}
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}
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/* ABI defined function to pop registers off the stack. */
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_Unwind_VRS_Result _Unwind_VRS_Pop (_Unwind_Context *context,
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_Unwind_VRS_RegClass regclass,
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_uw discriminator,
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_Unwind_VRS_DataRepresentation representation)
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{
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phase1_vrs *vrs = (phase1_vrs *) context;
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switch (regclass)
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{
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case _UVRSC_CORE:
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{
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_uw *ptr;
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_uw mask;
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int i;
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if (representation != _UVRSD_UINT32)
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return _UVRSR_FAILED;
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mask = discriminator & 0xffff;
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ptr = (_uw *) vrs->core.r[R_SP];
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/* Pop the requested registers. */
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for (i = 0; i < 16; i++)
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{
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if (mask & (1 << i))
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vrs->core.r[i] = *(ptr++);
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}
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/* Writeback the stack pointer value if it wasn't restored. */
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if ((mask & (1 << R_SP)) == 0)
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vrs->core.r[R_SP] = (_uw) ptr;
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}
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return _UVRSR_OK;
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case _UVRSC_VFP:
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{
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_uw start = discriminator >> 16;
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_uw count = discriminator & 0xffff;
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struct vfp_regs tmp;
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struct vfpv3_regs tmp_16_to_31;
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int tmp_count;
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_uw *sp;
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_uw *dest;
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int num_vfpv3_regs = 0;
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/* We use an approximation here by bounding _UVRSD_DOUBLE
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register numbers at 32 always, since we can't detect if
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VFPv3 isn't present (in such a case the upper limit is 16). */
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if ((representation != _UVRSD_VFPX && representation != _UVRSD_DOUBLE)
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|| start + count > (representation == _UVRSD_VFPX ? 16 : 32)
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|| (representation == _UVRSD_VFPX && start >= 16))
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return _UVRSR_FAILED;
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/* Check if we're being asked to pop VFPv3-only registers
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(numbers 16 through 31). */
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if (start >= 16)
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num_vfpv3_regs = count;
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else if (start + count > 16)
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num_vfpv3_regs = start + count - 16;
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if (num_vfpv3_regs && representation != _UVRSD_DOUBLE)
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return _UVRSR_FAILED;
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/* Demand-save coprocessor registers for stage1. */
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if (start < 16 && (vrs->demand_save_flags & DEMAND_SAVE_VFP))
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{
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vrs->demand_save_flags &= ~DEMAND_SAVE_VFP;
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if (representation == _UVRSD_DOUBLE)
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{
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/* Save in FLDMD/FSTMD format. */
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vrs->demand_save_flags |= DEMAND_SAVE_VFP_D;
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__gnu_Unwind_Save_VFP_D (&vrs->vfp);
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}
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else
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{
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/* Save in FLDMX/FSTMX format. */
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vrs->demand_save_flags &= ~DEMAND_SAVE_VFP_D;
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__gnu_Unwind_Save_VFP (&vrs->vfp);
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}
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}
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if (num_vfpv3_regs > 0
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&& (vrs->demand_save_flags & DEMAND_SAVE_VFP_V3))
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{
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vrs->demand_save_flags &= ~DEMAND_SAVE_VFP_V3;
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__gnu_Unwind_Save_VFP_D_16_to_31 (&vrs->vfp_regs_16_to_31);
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}
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/* Restore the registers from the stack. Do this by saving the
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current VFP registers to a memory area, moving the in-memory
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values into that area, and restoring from the whole area.
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For _UVRSD_VFPX we assume FSTMX standard format 1. */
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if (representation == _UVRSD_VFPX)
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__gnu_Unwind_Save_VFP (&tmp);
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else
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{
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/* Save registers 0 .. 15 if required. */
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if (start < 16)
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__gnu_Unwind_Save_VFP_D (&tmp);
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/* Save VFPv3 registers 16 .. 31 if required. */
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if (num_vfpv3_regs)
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__gnu_Unwind_Save_VFP_D_16_to_31 (&tmp_16_to_31);
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}
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/* Work out how many registers below register 16 need popping. */
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tmp_count = num_vfpv3_regs > 0 ? 16 - start : count;
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/* Copy registers below 16, if needed.
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The stack address is only guaranteed to be word aligned, so
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we can't use doubleword copies. */
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sp = (_uw *) vrs->core.r[R_SP];
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if (tmp_count > 0)
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{
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tmp_count *= 2;
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dest = (_uw *) &tmp.d[start];
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while (tmp_count--)
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*(dest++) = *(sp++);
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}
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/* Copy VFPv3 registers numbered >= 16, if needed. */
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if (num_vfpv3_regs > 0)
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{
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/* num_vfpv3_regs is needed below, so copy it. */
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int tmp_count_2 = num_vfpv3_regs * 2;
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int vfpv3_start = start < 16 ? 16 : start;
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dest = (_uw *) &tmp_16_to_31.d[vfpv3_start - 16];
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while (tmp_count_2--)
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*(dest++) = *(sp++);
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}
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/* Skip the format word space if using FLDMX/FSTMX format. */
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if (representation == _UVRSD_VFPX)
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sp++;
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/* Set the new stack pointer. */
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vrs->core.r[R_SP] = (_uw) sp;
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/* Reload the registers. */
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if (representation == _UVRSD_VFPX)
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__gnu_Unwind_Restore_VFP (&tmp);
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else
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{
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/* Restore registers 0 .. 15 if required. */
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if (start < 16)
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__gnu_Unwind_Restore_VFP_D (&tmp);
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/* Restore VFPv3 registers 16 .. 31 if required. */
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if (num_vfpv3_regs > 0)
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__gnu_Unwind_Restore_VFP_D_16_to_31 (&tmp_16_to_31);
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}
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}
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return _UVRSR_OK;
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case _UVRSC_FPA:
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return _UVRSR_NOT_IMPLEMENTED;
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case _UVRSC_WMMXD:
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{
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_uw start = discriminator >> 16;
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_uw count = discriminator & 0xffff;
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struct wmmxd_regs tmp;
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_uw *sp;
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_uw *dest;
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if ((representation != _UVRSD_UINT64) || start + count > 16)
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return _UVRSR_FAILED;
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if (vrs->demand_save_flags & DEMAND_SAVE_WMMXD)
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{
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/* Demand-save resisters for stage1. */
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vrs->demand_save_flags &= ~DEMAND_SAVE_WMMXD;
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__gnu_Unwind_Save_WMMXD (&vrs->wmmxd);
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}
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/* Restore the registers from the stack. Do this by saving the
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current WMMXD registers to a memory area, moving the in-memory
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values into that area, and restoring from the whole area. */
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__gnu_Unwind_Save_WMMXD (&tmp);
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/* The stack address is only guaranteed to be word aligned, so
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we can't use doubleword copies. */
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sp = (_uw *) vrs->core.r[R_SP];
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dest = (_uw *) &tmp.wd[start];
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count *= 2;
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while (count--)
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*(dest++) = *(sp++);
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/* Set the new stack pointer. */
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vrs->core.r[R_SP] = (_uw) sp;
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/* Reload the registers. */
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__gnu_Unwind_Restore_WMMXD (&tmp);
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}
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return _UVRSR_OK;
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case _UVRSC_WMMXC:
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{
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int i;
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struct wmmxc_regs tmp;
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_uw *sp;
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if ((representation != _UVRSD_UINT32) || discriminator > 16)
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return _UVRSR_FAILED;
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if (vrs->demand_save_flags & DEMAND_SAVE_WMMXC)
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{
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/* Demand-save resisters for stage1. */
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vrs->demand_save_flags &= ~DEMAND_SAVE_WMMXC;
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__gnu_Unwind_Save_WMMXC (&vrs->wmmxc);
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}
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/* Restore the registers from the stack. Do this by saving the
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current WMMXC registers to a memory area, moving the in-memory
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values into that area, and restoring from the whole area. */
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__gnu_Unwind_Save_WMMXC (&tmp);
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sp = (_uw *) vrs->core.r[R_SP];
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for (i = 0; i < 4; i++)
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if (discriminator & (1 << i))
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tmp.wc[i] = *(sp++);
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/* Set the new stack pointer. */
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vrs->core.r[R_SP] = (_uw) sp;
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/* Reload the registers. */
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__gnu_Unwind_Restore_WMMXC (&tmp);
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}
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return _UVRSR_OK;
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default:
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return _UVRSR_FAILED;
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}
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}
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/* Core unwinding functions. */
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/* Calculate the address encoded by a 31-bit self-relative offset at address
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P. */
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static inline _uw
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selfrel_offset31 (const _uw *p)
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{
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_uw offset;
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offset = *p;
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/* Sign extend to 32 bits. */
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if (offset & (1 << 30))
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offset |= 1u << 31;
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else
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offset &= ~(1u << 31);
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return offset + (_uw) p;
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}
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static _uw
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__gnu_unwind_get_pr_addr (int idx)
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{
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switch (idx)
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{
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case 0:
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return (_uw) &__aeabi_unwind_cpp_pr0;
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case 1:
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return (_uw) &__aeabi_unwind_cpp_pr1;
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case 2:
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return (_uw) &__aeabi_unwind_cpp_pr2;
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default:
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return 0;
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}
|
|
}
|
|
|
|
/* ABI defined personality routine entry points. */
|
|
|
|
_Unwind_Reason_Code
|
|
__aeabi_unwind_cpp_pr0 (_Unwind_State state,
|
|
_Unwind_Control_Block *ucbp,
|
|
_Unwind_Context *context)
|
|
{
|
|
return __gnu_unwind_pr_common (state, ucbp, context, 0);
|
|
}
|
|
|
|
_Unwind_Reason_Code
|
|
__aeabi_unwind_cpp_pr1 (_Unwind_State state,
|
|
_Unwind_Control_Block *ucbp,
|
|
_Unwind_Context *context)
|
|
{
|
|
return __gnu_unwind_pr_common (state, ucbp, context, 1);
|
|
}
|
|
|
|
_Unwind_Reason_Code
|
|
__aeabi_unwind_cpp_pr2 (_Unwind_State state,
|
|
_Unwind_Control_Block *ucbp,
|
|
_Unwind_Context *context)
|
|
{
|
|
return __gnu_unwind_pr_common (state, ucbp, context, 2);
|
|
}
|