/* Subroutines needed for unwinding IA-64 standard format stack frame info for exception handling. Copyright (C) 1997-2017 Free Software Foundation, Inc. Contributed by Andrew MacLeod Andrew Haley David Mosberger-Tang This file is part of GCC. GCC 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, or (at your option) any later version. GCC 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. Under Section 7 of GPL version 3, you are granted additional permissions described in the GCC Runtime Library Exception, version 3.1, as published by the Free Software Foundation. You should have received a copy of the GNU General Public License and a copy of the GCC Runtime Library Exception along with this program; see the files COPYING3 and COPYING.RUNTIME respectively. If not, see . */ #include "tconfig.h" #include "tsystem.h" #include "coretypes.h" #include "tm.h" #include "libgcc_tm.h" #include "unwind.h" #include "unwind-ia64.h" #include "unwind-compat.h" #include "ia64intrin.h" /* This isn't thread safe, but nice for occasional tests. */ #undef ENABLE_MALLOC_CHECKING #ifndef __USING_SJLJ_EXCEPTIONS__ enum unw_application_register { UNW_AR_BSP, UNW_AR_BSPSTORE, UNW_AR_PFS, UNW_AR_RNAT, UNW_AR_UNAT, UNW_AR_LC, UNW_AR_EC, UNW_AR_FPSR, UNW_AR_RSC, UNW_AR_CCV }; enum unw_register_index { /* Primary UNAT. */ UNW_REG_PRI_UNAT_GR, UNW_REG_PRI_UNAT_MEM, /* Memory Stack. */ UNW_REG_PSP, /* previous memory stack pointer */ /* Register Stack. */ UNW_REG_BSP, /* register stack pointer */ UNW_REG_BSPSTORE, UNW_REG_PFS, /* previous function state */ UNW_REG_RNAT, /* Return Pointer. */ UNW_REG_RP, /* Special preserved registers. */ UNW_REG_UNAT, UNW_REG_PR, UNW_REG_LC, UNW_REG_FPSR, /* Non-stacked general registers. */ UNW_REG_R2, UNW_REG_R4 = UNW_REG_R2 + 2, UNW_REG_R7 = UNW_REG_R2 + 5, UNW_REG_R31 = UNW_REG_R2 + 29, /* Non-stacked floating point registers. */ UNW_REG_F2, UNW_REG_F5 = UNW_REG_F2 + 3, UNW_REG_F16 = UNW_REG_F2 + 14, UNW_REG_F31 = UNW_REG_F2 + 29, /* Branch registers. */ UNW_REG_B0, UNW_REG_B1, UNW_REG_B5 = UNW_REG_B1 + 4, UNW_NUM_REGS }; enum unw_where { UNW_WHERE_NONE, /* register isn't saved at all */ UNW_WHERE_GR, /* register is saved in a general register */ UNW_WHERE_FR, /* register is saved in a floating-point register */ UNW_WHERE_BR, /* register is saved in a branch register */ UNW_WHERE_SPREL, /* register is saved on memstack (sp-relative) */ UNW_WHERE_PSPREL, /* register is saved on memstack (psp-relative) */ /* At the end of each prologue these locations get resolved to UNW_WHERE_PSPREL and UNW_WHERE_GR, respectively. */ UNW_WHERE_SPILL_HOME, /* register is saved in its spill home */ UNW_WHERE_GR_SAVE /* register is saved in next general register */ }; #define UNW_WHEN_NEVER 0x7fffffff struct unw_reg_info { unw_word val; /* save location: register number or offset */ enum unw_where where; /* where the register gets saved */ int when; /* when the register gets saved */ }; struct unw_reg_state { struct unw_reg_state *next; /* next (outer) element on state stack */ struct unw_reg_info reg[UNW_NUM_REGS]; /* register save locations */ }; struct unw_labeled_state { struct unw_labeled_state *next; /* next labeled state (or NULL) */ unw_word label; /* label for this state */ struct unw_reg_state saved_state; }; typedef struct unw_state_record { unsigned int first_region : 1; /* is this the first region? */ unsigned int done : 1; /* are we done scanning descriptors? */ unsigned int any_spills : 1; /* got any register spills? */ unsigned int in_body : 1; /* are we inside a body? */ unsigned int no_reg_stack_frame : 1; /* Don't adjust bsp for i&l regs */ unsigned char *imask; /* imask of spill_mask record or NULL */ unw_word pr_val; /* predicate values */ unw_word pr_mask; /* predicate mask */ unw_sword spill_offset; /* psp-relative offset for spill base */ int region_start; int region_len; int epilogue_start; int epilogue_count; int when_target; unsigned char gr_save_loc; /* next general register to use for saving */ unsigned char return_link_reg; /* branch register for return link */ unsigned short unwabi; struct unw_labeled_state *labeled_states; /* list of all labeled states */ struct unw_reg_state curr; /* current state */ _Unwind_Personality_Fn personality; } _Unwind_FrameState; enum unw_nat_type { UNW_NAT_NONE, /* NaT not represented */ UNW_NAT_VAL, /* NaT represented by NaT value (fp reg) */ UNW_NAT_MEMSTK, /* NaT value is in unat word at offset OFF */ UNW_NAT_REGSTK /* NaT is in rnat */ }; struct unw_stack { unw_word limit; unw_word top; }; struct _Unwind_Context { /* Initial frame info. */ unw_word rnat; /* rse nat collection */ unw_word regstk_top; /* lowest address of rbs stored register which uses context->rnat collection */ /* Current frame info. */ unw_word bsp; /* backing store pointer value corresponding to psp. */ unw_word sp; /* stack pointer value */ unw_word psp; /* previous sp value */ unw_word rp; /* return pointer */ unw_word pr; /* predicate collection */ unw_word region_start;/* start of unwind region */ unw_word gp; /* global pointer value */ void *lsda; /* language specific data area */ /* Preserved state. */ unw_word *bsp_loc; /* previous bsp save location Appears to be write-only? */ unw_word *bspstore_loc; unw_word *pfs_loc; /* Save location for pfs in current (corr. to sp) frame. Target contains cfm for caller. */ unw_word *signal_pfs_loc;/* Save location for pfs in current signal frame. Target contains pfs for caller. */ unw_word *pri_unat_loc; unw_word *unat_loc; unw_word *lc_loc; unw_word *fpsr_loc; unw_word eh_data[4]; struct unw_ireg { unw_word *loc; struct unw_ireg_nat { enum unw_nat_type type : 3; unw_sword off : 61; /* NaT word is at loc+nat.off */ } nat; } ireg[32 - 2]; /* Indexed by - 2 */ unw_word *br_loc[8]; void *fr_loc[32 - 2]; /* ??? We initially point pri_unat_loc here. The entire NAT bit logic needs work. */ unw_word initial_unat; }; /* Implicit register save order. See section 11.4.2.3 Rules for Using Unwind Descriptors, rule 3. */ static unsigned char const save_order[] = { UNW_REG_RP, UNW_REG_PFS, UNW_REG_PSP, UNW_REG_PR, UNW_REG_UNAT, UNW_REG_LC, UNW_REG_FPSR, UNW_REG_PRI_UNAT_GR }; #define MIN(X, Y) ((X) < (Y) ? (X) : (Y)) /* MASK is a bitmap describing the allocation state of emergency buffers, with bit set indicating free. Return >= 0 if allocation is successful; < 0 if failure. */ static inline int atomic_alloc (unsigned int *mask) { unsigned int old = *mask, ret, new; while (1) { if (old == 0) return -1; ret = old & -old; new = old & ~ret; new = __sync_val_compare_and_swap (mask, old, new); if (old == new) break; old = new; } return __builtin_ffs (ret) - 1; } /* Similarly, free an emergency buffer. */ static inline void atomic_free (unsigned int *mask, int bit) { __sync_xor_and_fetch (mask, 1 << bit); } #define SIZE(X) (sizeof(X) / sizeof(*(X))) #define MASK_FOR(X) ((2U << (SIZE (X) - 1)) - 1) #define PTR_IN(X, P) ((P) >= (X) && (P) < (X) + SIZE (X)) static struct unw_reg_state emergency_reg_state[32]; static unsigned int emergency_reg_state_free = MASK_FOR (emergency_reg_state); static struct unw_labeled_state emergency_labeled_state[8]; static unsigned int emergency_labeled_state_free = MASK_FOR (emergency_labeled_state); #ifdef ENABLE_MALLOC_CHECKING static int reg_state_alloced; static int labeled_state_alloced; #endif /* Allocation and deallocation of structures. */ static struct unw_reg_state * alloc_reg_state (void) { struct unw_reg_state *rs; #ifdef ENABLE_MALLOC_CHECKING reg_state_alloced++; #endif rs = malloc (sizeof (struct unw_reg_state)); if (!rs) { int n = atomic_alloc (&emergency_reg_state_free); if (n >= 0) rs = &emergency_reg_state[n]; } return rs; } static void free_reg_state (struct unw_reg_state *rs) { #ifdef ENABLE_MALLOC_CHECKING reg_state_alloced--; #endif if (PTR_IN (emergency_reg_state, rs)) atomic_free (&emergency_reg_state_free, rs - emergency_reg_state); else free (rs); } static struct unw_labeled_state * alloc_label_state (void) { struct unw_labeled_state *ls; #ifdef ENABLE_MALLOC_CHECKING labeled_state_alloced++; #endif ls = malloc(sizeof(struct unw_labeled_state)); if (!ls) { int n = atomic_alloc (&emergency_labeled_state_free); if (n >= 0) ls = &emergency_labeled_state[n]; } return ls; } static void free_label_state (struct unw_labeled_state *ls) { #ifdef ENABLE_MALLOC_CHECKING labeled_state_alloced--; #endif if (PTR_IN (emergency_labeled_state, ls)) atomic_free (&emergency_labeled_state_free, emergency_labeled_state - ls); else free (ls); } /* Routines to manipulate the state stack. */ static void push (struct unw_state_record *sr) { struct unw_reg_state *rs = alloc_reg_state (); memcpy (rs, &sr->curr, sizeof (*rs)); sr->curr.next = rs; } static void pop (struct unw_state_record *sr) { struct unw_reg_state *rs = sr->curr.next; if (!rs) abort (); memcpy (&sr->curr, rs, sizeof(*rs)); free_reg_state (rs); } /* Make a copy of the state stack. Non-recursive to avoid stack overflows. */ static struct unw_reg_state * dup_state_stack (struct unw_reg_state *rs) { struct unw_reg_state *copy, *prev = NULL, *first = NULL; while (rs) { copy = alloc_reg_state (); memcpy (copy, rs, sizeof(*copy)); if (first) prev->next = copy; else first = copy; rs = rs->next; prev = copy; } return first; } /* Free all stacked register states (but not RS itself). */ static void free_state_stack (struct unw_reg_state *rs) { struct unw_reg_state *p, *next; for (p = rs->next; p != NULL; p = next) { next = p->next; free_reg_state (p); } rs->next = NULL; } /* Free all labeled states. */ static void free_label_states (struct unw_labeled_state *ls) { struct unw_labeled_state *next; for (; ls ; ls = next) { next = ls->next; free_state_stack (&ls->saved_state); free_label_state (ls); } } /* Unwind decoder routines */ static enum unw_register_index __attribute__((const)) decode_abreg (unsigned char abreg, int memory) { switch (abreg) { #if TARGET_ABI_OPEN_VMS /* OpenVMS Calling Standard specifies R3 - R31. */ case 0x03 ... 0x1f: return UNW_REG_R2 + (abreg - 0x02); #else /* Standard Intel ABI specifies GR 4 - 7. */ case 0x04 ... 0x07: return UNW_REG_R4 + (abreg - 0x04); #endif case 0x22 ... 0x25: return UNW_REG_F2 + (abreg - 0x22); case 0x30 ... 0x3f: return UNW_REG_F16 + (abreg - 0x30); case 0x41 ... 0x45: return UNW_REG_B1 + (abreg - 0x41); case 0x60: return UNW_REG_PR; case 0x61: return UNW_REG_PSP; case 0x62: return memory ? UNW_REG_PRI_UNAT_MEM : UNW_REG_PRI_UNAT_GR; case 0x63: return UNW_REG_RP; case 0x64: return UNW_REG_BSP; case 0x65: return UNW_REG_BSPSTORE; case 0x66: return UNW_REG_RNAT; case 0x67: return UNW_REG_UNAT; case 0x68: return UNW_REG_FPSR; case 0x69: return UNW_REG_PFS; case 0x6a: return UNW_REG_LC; default: abort (); } } static void set_reg (struct unw_reg_info *reg, enum unw_where where, int when, unw_word val) { reg->val = val; reg->where = where; if (reg->when == UNW_WHEN_NEVER) reg->when = when; } static void alloc_spill_area (unw_word *offp, unw_word regsize, struct unw_reg_info *lo, struct unw_reg_info *hi) { struct unw_reg_info *reg; for (reg = hi; reg >= lo; --reg) { if (reg->where == UNW_WHERE_SPILL_HOME) { reg->where = UNW_WHERE_PSPREL; *offp -= regsize; reg->val = *offp; } } } static inline void spill_next_when (struct unw_reg_info **regp, struct unw_reg_info *lim, unw_word t) { struct unw_reg_info *reg; for (reg = *regp; reg <= lim; ++reg) { if (reg->where == UNW_WHERE_SPILL_HOME) { reg->when = t; *regp = reg + 1; return; } } /* Excess spill. */ abort (); } static void finish_prologue (struct unw_state_record *sr) { struct unw_reg_info *reg; unw_word off; int i; /* First, resolve implicit register save locations (see Section "11.4.2.3 Rules for Using Unwind Descriptors", rule 3). */ for (i = 0; i < (int) sizeof (save_order); ++i) { reg = sr->curr.reg + save_order[i]; if (reg->where == UNW_WHERE_GR_SAVE) { reg->where = UNW_WHERE_GR; reg->val = sr->gr_save_loc++; } } /* Next, compute when the fp, general, and branch registers get saved. This must come before alloc_spill_area() because we need to know which registers are spilled to their home locations. */ if (sr->imask) { static unsigned char const limit[3] = { UNW_REG_F31, UNW_REG_R7, UNW_REG_B5 }; unsigned char kind, mask = 0, *cp = sr->imask; int t; struct unw_reg_info *(regs[3]); regs[0] = sr->curr.reg + UNW_REG_F2; regs[1] = sr->curr.reg + UNW_REG_R4; regs[2] = sr->curr.reg + UNW_REG_B1; for (t = 0; t < sr->region_len; ++t) { if ((t & 3) == 0) mask = *cp++; kind = (mask >> 2*(3-(t & 3))) & 3; if (kind > 0) spill_next_when (®s[kind - 1], sr->curr.reg + limit[kind - 1], sr->region_start + t); } } /* Next, lay out the memory stack spill area. */ if (sr->any_spills) { off = sr->spill_offset; alloc_spill_area (&off, 16, sr->curr.reg + UNW_REG_F2, sr->curr.reg + UNW_REG_F31); alloc_spill_area (&off, 8, sr->curr.reg + UNW_REG_B1, sr->curr.reg + UNW_REG_B5); alloc_spill_area (&off, 8, sr->curr.reg + UNW_REG_R4, sr->curr.reg + UNW_REG_R7); } } /* * Region header descriptors. */ static void desc_prologue (int body, unw_word rlen, unsigned char mask, unsigned char grsave, struct unw_state_record *sr) { int i; if (!(sr->in_body || sr->first_region)) finish_prologue (sr); sr->first_region = 0; /* Check if we're done. */ if (sr->when_target < sr->region_start + sr->region_len) { sr->done = 1; return; } for (i = 0; i < sr->epilogue_count; ++i) pop (sr); sr->epilogue_count = 0; sr->epilogue_start = UNW_WHEN_NEVER; if (!body) push (sr); sr->region_start += sr->region_len; sr->region_len = rlen; sr->in_body = body; if (!body) { for (i = 0; i < 4; ++i) { if (mask & 0x8) set_reg (sr->curr.reg + save_order[i], UNW_WHERE_GR, sr->region_start + sr->region_len - 1, grsave++); mask <<= 1; } sr->gr_save_loc = grsave; sr->any_spills = 0; sr->imask = 0; sr->spill_offset = 0x10; /* default to psp+16 */ } } /* * Prologue descriptors. */ static inline void desc_abi (unsigned char abi, unsigned char context, struct unw_state_record *sr) { sr->unwabi = (abi << 8) | context; } static inline void desc_br_gr (unsigned char brmask, unsigned char gr, struct unw_state_record *sr) { int i; for (i = 0; i < 5; ++i) { if (brmask & 1) set_reg (sr->curr.reg + UNW_REG_B1 + i, UNW_WHERE_GR, sr->region_start + sr->region_len - 1, gr++); brmask >>= 1; } } static inline void desc_br_mem (unsigned char brmask, struct unw_state_record *sr) { int i; for (i = 0; i < 5; ++i) { if (brmask & 1) { set_reg (sr->curr.reg + UNW_REG_B1 + i, UNW_WHERE_SPILL_HOME, sr->region_start + sr->region_len - 1, 0); sr->any_spills = 1; } brmask >>= 1; } } static inline void desc_frgr_mem (unsigned char grmask, unw_word frmask, struct unw_state_record *sr) { int i; for (i = 0; i < 4; ++i) { if ((grmask & 1) != 0) { set_reg (sr->curr.reg + UNW_REG_R4 + i, UNW_WHERE_SPILL_HOME, sr->region_start + sr->region_len - 1, 0); sr->any_spills = 1; } grmask >>= 1; } for (i = 0; i < 20; ++i) { if ((frmask & 1) != 0) { enum unw_register_index base = i < 4 ? UNW_REG_F2 : UNW_REG_F16 - 4; set_reg (sr->curr.reg + base + i, UNW_WHERE_SPILL_HOME, sr->region_start + sr->region_len - 1, 0); sr->any_spills = 1; } frmask >>= 1; } } static inline void desc_fr_mem (unsigned char frmask, struct unw_state_record *sr) { int i; for (i = 0; i < 4; ++i) { if ((frmask & 1) != 0) { set_reg (sr->curr.reg + UNW_REG_F2 + i, UNW_WHERE_SPILL_HOME, sr->region_start + sr->region_len - 1, 0); sr->any_spills = 1; } frmask >>= 1; } } static inline void desc_gr_gr (unsigned char grmask, unsigned char gr, struct unw_state_record *sr) { int i; for (i = 0; i < 4; ++i) { if ((grmask & 1) != 0) set_reg (sr->curr.reg + UNW_REG_R4 + i, UNW_WHERE_GR, sr->region_start + sr->region_len - 1, gr++); grmask >>= 1; } } static inline void desc_gr_mem (unsigned char grmask, struct unw_state_record *sr) { int i; for (i = 0; i < 4; ++i) { if ((grmask & 1) != 0) { set_reg (sr->curr.reg + UNW_REG_R4 + i, UNW_WHERE_SPILL_HOME, sr->region_start + sr->region_len - 1, 0); sr->any_spills = 1; } grmask >>= 1; } } static inline void desc_mem_stack_f (unw_word t, unw_word size, struct unw_state_record *sr) { set_reg (sr->curr.reg + UNW_REG_PSP, UNW_WHERE_NONE, sr->region_start + MIN ((int)t, sr->region_len - 1), 16*size); } static inline void desc_mem_stack_v (unw_word t, struct unw_state_record *sr) { sr->curr.reg[UNW_REG_PSP].when = sr->region_start + MIN ((int)t, sr->region_len - 1); } static inline void desc_reg_gr (unsigned char reg, unsigned char dst, struct unw_state_record *sr) { set_reg (sr->curr.reg + reg, UNW_WHERE_GR, sr->region_start + sr->region_len - 1, dst); } static inline void desc_reg_psprel (unsigned char reg, unw_word pspoff, struct unw_state_record *sr) { set_reg (sr->curr.reg + reg, UNW_WHERE_PSPREL, sr->region_start + sr->region_len - 1, 0x10 - 4*pspoff); } static inline void desc_reg_sprel (unsigned char reg, unw_word spoff, struct unw_state_record *sr) { set_reg (sr->curr.reg + reg, UNW_WHERE_SPREL, sr->region_start + sr->region_len - 1, 4*spoff); } static inline void desc_rp_br (unsigned char dst, struct unw_state_record *sr) { sr->return_link_reg = dst; } static inline void desc_reg_when (unsigned char regnum, unw_word t, struct unw_state_record *sr) { struct unw_reg_info *reg = sr->curr.reg + regnum; if (reg->where == UNW_WHERE_NONE) reg->where = UNW_WHERE_GR_SAVE; reg->when = sr->region_start + MIN ((int)t, sr->region_len - 1); } static inline void desc_spill_base (unw_word pspoff, struct unw_state_record *sr) { sr->spill_offset = 0x10 - 4*pspoff; } static inline unsigned char * desc_spill_mask (unsigned char *imaskp, struct unw_state_record *sr) { sr->imask = imaskp; return imaskp + (2*sr->region_len + 7)/8; } /* * Body descriptors. */ static inline void desc_epilogue (unw_word t, unw_word ecount, struct unw_state_record *sr) { sr->epilogue_start = sr->region_start + sr->region_len - 1 - t; sr->epilogue_count = ecount + 1; } static inline void desc_copy_state (unw_word label, struct unw_state_record *sr) { struct unw_labeled_state *ls; for (ls = sr->labeled_states; ls; ls = ls->next) { if (ls->label == label) { free_state_stack (&sr->curr); memcpy (&sr->curr, &ls->saved_state, sizeof (sr->curr)); sr->curr.next = dup_state_stack (ls->saved_state.next); return; } } abort (); } static inline void desc_label_state (unw_word label, struct unw_state_record *sr) { struct unw_labeled_state *ls = alloc_label_state (); ls->label = label; memcpy (&ls->saved_state, &sr->curr, sizeof (ls->saved_state)); ls->saved_state.next = dup_state_stack (sr->curr.next); /* Insert into list of labeled states. */ ls->next = sr->labeled_states; sr->labeled_states = ls; } /* * General descriptors. */ static inline int desc_is_active (unsigned char qp, unw_word t, struct unw_state_record *sr) { if (sr->when_target <= sr->region_start + MIN ((int)t, sr->region_len - 1)) return 0; if (qp > 0) { if ((sr->pr_val & (1UL << qp)) == 0) return 0; sr->pr_mask |= (1UL << qp); } return 1; } static inline void desc_restore_p (unsigned char qp, unw_word t, unsigned char abreg, struct unw_state_record *sr) { struct unw_reg_info *r; if (! desc_is_active (qp, t, sr)) return; r = sr->curr.reg + decode_abreg (abreg, 0); r->where = UNW_WHERE_NONE; r->when = sr->region_start + MIN ((int)t, sr->region_len - 1); r->val = 0; } static inline void desc_spill_reg_p (unsigned char qp, unw_word t, unsigned char abreg, unsigned char x, unsigned char ytreg, struct unw_state_record *sr) { enum unw_where where = UNW_WHERE_GR; struct unw_reg_info *r; if (! desc_is_active (qp, t, sr)) return; if (x) where = UNW_WHERE_BR; else if (ytreg & 0x80) where = UNW_WHERE_FR; r = sr->curr.reg + decode_abreg (abreg, 0); r->where = where; r->when = sr->region_start + MIN ((int)t, sr->region_len - 1); r->val = ytreg & 0x7f; } static inline void desc_spill_psprel_p (unsigned char qp, unw_word t, unsigned char abreg, unw_word pspoff, struct unw_state_record *sr) { struct unw_reg_info *r; if (! desc_is_active (qp, t, sr)) return; r = sr->curr.reg + decode_abreg (abreg, 1); r->where = UNW_WHERE_PSPREL; r->when = sr->region_start + MIN((int)t, sr->region_len - 1); r->val = 0x10 - 4*pspoff; } static inline void desc_spill_sprel_p (unsigned char qp, unw_word t, unsigned char abreg, unw_word spoff, struct unw_state_record *sr) { struct unw_reg_info *r; if (! desc_is_active (qp, t, sr)) return; r = sr->curr.reg + decode_abreg (abreg, 1); r->where = UNW_WHERE_SPREL; r->when = sr->region_start + MIN ((int)t, sr->region_len - 1); r->val = 4*spoff; } #define UNW_DEC_BAD_CODE(code) abort (); /* Region headers. */ #define UNW_DEC_PROLOGUE_GR(fmt,r,m,gr,arg) desc_prologue(0,r,m,gr,arg) #define UNW_DEC_PROLOGUE(fmt,b,r,arg) desc_prologue(b,r,0,32,arg) /* Prologue descriptors. */ #define UNW_DEC_ABI(fmt,a,c,arg) desc_abi(a,c,arg) #define UNW_DEC_BR_GR(fmt,b,g,arg) desc_br_gr(b,g,arg) #define UNW_DEC_BR_MEM(fmt,b,arg) desc_br_mem(b,arg) #define UNW_DEC_FRGR_MEM(fmt,g,f,arg) desc_frgr_mem(g,f,arg) #define UNW_DEC_FR_MEM(fmt,f,arg) desc_fr_mem(f,arg) #define UNW_DEC_GR_GR(fmt,m,g,arg) desc_gr_gr(m,g,arg) #define UNW_DEC_GR_MEM(fmt,m,arg) desc_gr_mem(m,arg) #define UNW_DEC_MEM_STACK_F(fmt,t,s,arg) desc_mem_stack_f(t,s,arg) #define UNW_DEC_MEM_STACK_V(fmt,t,arg) desc_mem_stack_v(t,arg) #define UNW_DEC_REG_GR(fmt,r,d,arg) desc_reg_gr(r,d,arg) #define UNW_DEC_REG_PSPREL(fmt,r,o,arg) desc_reg_psprel(r,o,arg) #define UNW_DEC_REG_SPREL(fmt,r,o,arg) desc_reg_sprel(r,o,arg) #define UNW_DEC_REG_WHEN(fmt,r,t,arg) desc_reg_when(r,t,arg) #define UNW_DEC_PRIUNAT_WHEN_GR(fmt,t,arg) desc_reg_when(UNW_REG_PRI_UNAT_GR,t,arg) #define UNW_DEC_PRIUNAT_WHEN_MEM(fmt,t,arg) desc_reg_when(UNW_REG_PRI_UNAT_MEM,t,arg) #define UNW_DEC_PRIUNAT_GR(fmt,r,arg) desc_reg_gr(UNW_REG_PRI_UNAT_GR,r,arg) #define UNW_DEC_PRIUNAT_PSPREL(fmt,o,arg) desc_reg_psprel(UNW_REG_PRI_UNAT_MEM,o,arg) #define UNW_DEC_PRIUNAT_SPREL(fmt,o,arg) desc_reg_sprel(UNW_REG_PRI_UNAT_MEM,o,arg) #define UNW_DEC_RP_BR(fmt,d,arg) desc_rp_br(d,arg) #define UNW_DEC_SPILL_BASE(fmt,o,arg) desc_spill_base(o,arg) #define UNW_DEC_SPILL_MASK(fmt,m,arg) (m = desc_spill_mask(m,arg)) /* Body descriptors. */ #define UNW_DEC_EPILOGUE(fmt,t,c,arg) desc_epilogue(t,c,arg) #define UNW_DEC_COPY_STATE(fmt,l,arg) desc_copy_state(l,arg) #define UNW_DEC_LABEL_STATE(fmt,l,arg) desc_label_state(l,arg) /* General unwind descriptors. */ #define UNW_DEC_SPILL_REG_P(f,p,t,a,x,y,arg) desc_spill_reg_p(p,t,a,x,y,arg) #define UNW_DEC_SPILL_REG(f,t,a,x,y,arg) desc_spill_reg_p(0,t,a,x,y,arg) #define UNW_DEC_SPILL_PSPREL_P(f,p,t,a,o,arg) desc_spill_psprel_p(p,t,a,o,arg) #define UNW_DEC_SPILL_PSPREL(f,t,a,o,arg) desc_spill_psprel_p(0,t,a,o,arg) #define UNW_DEC_SPILL_SPREL_P(f,p,t,a,o,arg) desc_spill_sprel_p(p,t,a,o,arg) #define UNW_DEC_SPILL_SPREL(f,t,a,o,arg) desc_spill_sprel_p(0,t,a,o,arg) #define UNW_DEC_RESTORE_P(f,p,t,a,arg) desc_restore_p(p,t,a,arg) #define UNW_DEC_RESTORE(f,t,a,arg) desc_restore_p(0,t,a,arg) /* * Generic IA-64 unwind info decoder. * * This file is used both by the Linux kernel and objdump. Please keep * the copies of this file in sync. * * You need to customize the decoder by defining the following * macros/constants before including this file: * * Types: * unw_word Unsigned integer type with at least 64 bits * * Register names: * UNW_REG_BSP * UNW_REG_BSPSTORE * UNW_REG_FPSR * UNW_REG_LC * UNW_REG_PFS * UNW_REG_PR * UNW_REG_RNAT * UNW_REG_PSP * UNW_REG_RP * UNW_REG_UNAT * * Decoder action macros: * UNW_DEC_BAD_CODE(code) * UNW_DEC_ABI(fmt,abi,context,arg) * UNW_DEC_BR_GR(fmt,brmask,gr,arg) * UNW_DEC_BR_MEM(fmt,brmask,arg) * UNW_DEC_COPY_STATE(fmt,label,arg) * UNW_DEC_EPILOGUE(fmt,t,ecount,arg) * UNW_DEC_FRGR_MEM(fmt,grmask,frmask,arg) * UNW_DEC_FR_MEM(fmt,frmask,arg) * UNW_DEC_GR_GR(fmt,grmask,gr,arg) * UNW_DEC_GR_MEM(fmt,grmask,arg) * UNW_DEC_LABEL_STATE(fmt,label,arg) * UNW_DEC_MEM_STACK_F(fmt,t,size,arg) * UNW_DEC_MEM_STACK_V(fmt,t,arg) * UNW_DEC_PRIUNAT_GR(fmt,r,arg) * UNW_DEC_PRIUNAT_WHEN_GR(fmt,t,arg) * UNW_DEC_PRIUNAT_WHEN_MEM(fmt,t,arg) * UNW_DEC_PRIUNAT_WHEN_PSPREL(fmt,pspoff,arg) * UNW_DEC_PRIUNAT_WHEN_SPREL(fmt,spoff,arg) * UNW_DEC_PROLOGUE(fmt,body,rlen,arg) * UNW_DEC_PROLOGUE_GR(fmt,rlen,mask,grsave,arg) * UNW_DEC_REG_PSPREL(fmt,reg,pspoff,arg) * UNW_DEC_REG_REG(fmt,src,dst,arg) * UNW_DEC_REG_SPREL(fmt,reg,spoff,arg) * UNW_DEC_REG_WHEN(fmt,reg,t,arg) * UNW_DEC_RESTORE(fmt,t,abreg,arg) * UNW_DEC_RESTORE_P(fmt,qp,t,abreg,arg) * UNW_DEC_SPILL_BASE(fmt,pspoff,arg) * UNW_DEC_SPILL_MASK(fmt,imaskp,arg) * UNW_DEC_SPILL_PSPREL(fmt,t,abreg,pspoff,arg) * UNW_DEC_SPILL_PSPREL_P(fmt,qp,t,abreg,pspoff,arg) * UNW_DEC_SPILL_REG(fmt,t,abreg,x,ytreg,arg) * UNW_DEC_SPILL_REG_P(fmt,qp,t,abreg,x,ytreg,arg) * UNW_DEC_SPILL_SPREL(fmt,t,abreg,spoff,arg) * UNW_DEC_SPILL_SPREL_P(fmt,qp,t,abreg,pspoff,arg) */ static unw_word unw_decode_uleb128 (unsigned char **dpp) { unsigned shift = 0; unw_word byte, result = 0; unsigned char *bp = *dpp; while (1) { byte = *bp++; result |= (byte & 0x7f) << shift; if ((byte & 0x80) == 0) break; shift += 7; } *dpp = bp; return result; } static unsigned char * unw_decode_x1 (unsigned char *dp, unsigned char code __attribute__((unused)), void *arg) { unsigned char byte1, abreg; unw_word t, off; byte1 = *dp++; t = unw_decode_uleb128 (&dp); off = unw_decode_uleb128 (&dp); abreg = (byte1 & 0x7f); if (byte1 & 0x80) UNW_DEC_SPILL_SPREL(X1, t, abreg, off, arg); else UNW_DEC_SPILL_PSPREL(X1, t, abreg, off, arg); return dp; } static unsigned char * unw_decode_x2 (unsigned char *dp, unsigned char code __attribute__((unused)), void *arg) { unsigned char byte1, byte2, abreg, x, ytreg; unw_word t; byte1 = *dp++; byte2 = *dp++; t = unw_decode_uleb128 (&dp); abreg = (byte1 & 0x7f); ytreg = byte2; x = (byte1 >> 7) & 1; if ((byte1 & 0x80) == 0 && ytreg == 0) UNW_DEC_RESTORE(X2, t, abreg, arg); else UNW_DEC_SPILL_REG(X2, t, abreg, x, ytreg, arg); return dp; } static unsigned char * unw_decode_x3 (unsigned char *dp, unsigned char code __attribute__((unused)), void *arg) { unsigned char byte1, byte2, abreg, qp; unw_word t, off; byte1 = *dp++; byte2 = *dp++; t = unw_decode_uleb128 (&dp); off = unw_decode_uleb128 (&dp); qp = (byte1 & 0x3f); abreg = (byte2 & 0x7f); if (byte1 & 0x80) UNW_DEC_SPILL_SPREL_P(X3, qp, t, abreg, off, arg); else UNW_DEC_SPILL_PSPREL_P(X3, qp, t, abreg, off, arg); return dp; } static unsigned char * unw_decode_x4 (unsigned char *dp, unsigned char code __attribute__((unused)), void *arg) { unsigned char byte1, byte2, byte3, qp, abreg, x, ytreg; unw_word t; byte1 = *dp++; byte2 = *dp++; byte3 = *dp++; t = unw_decode_uleb128 (&dp); qp = (byte1 & 0x3f); abreg = (byte2 & 0x7f); x = (byte2 >> 7) & 1; ytreg = byte3; if ((byte2 & 0x80) == 0 && byte3 == 0) UNW_DEC_RESTORE_P(X4, qp, t, abreg, arg); else UNW_DEC_SPILL_REG_P(X4, qp, t, abreg, x, ytreg, arg); return dp; } static unsigned char * unw_decode_r1 (unsigned char *dp, unsigned char code, void *arg) { int body = (code & 0x20) != 0; unw_word rlen; rlen = (code & 0x1f); UNW_DEC_PROLOGUE(R1, body, rlen, arg); return dp; } static unsigned char * unw_decode_r2 (unsigned char *dp, unsigned char code, void *arg) { unsigned char byte1, mask, grsave; unw_word rlen; byte1 = *dp++; mask = ((code & 0x7) << 1) | ((byte1 >> 7) & 1); grsave = (byte1 & 0x7f); rlen = unw_decode_uleb128 (&dp); UNW_DEC_PROLOGUE_GR(R2, rlen, mask, grsave, arg); return dp; } static unsigned char * unw_decode_r3 (unsigned char *dp, unsigned char code, void *arg) { unw_word rlen; rlen = unw_decode_uleb128 (&dp); UNW_DEC_PROLOGUE(R3, ((code & 0x3) == 1), rlen, arg); return dp; } static unsigned char * unw_decode_p1 (unsigned char *dp, unsigned char code, void *arg) { unsigned char brmask = (code & 0x1f); UNW_DEC_BR_MEM(P1, brmask, arg); return dp; } static unsigned char * unw_decode_p2_p5 (unsigned char *dp, unsigned char code, void *arg) { if ((code & 0x10) == 0) { unsigned char byte1 = *dp++; UNW_DEC_BR_GR(P2, ((code & 0xf) << 1) | ((byte1 >> 7) & 1), (byte1 & 0x7f), arg); } else if ((code & 0x08) == 0) { unsigned char byte1 = *dp++, r, dst; r = ((code & 0x7) << 1) | ((byte1 >> 7) & 1); dst = (byte1 & 0x7f); switch (r) { case 0: UNW_DEC_REG_GR(P3, UNW_REG_PSP, dst, arg); break; case 1: UNW_DEC_REG_GR(P3, UNW_REG_RP, dst, arg); break; case 2: UNW_DEC_REG_GR(P3, UNW_REG_PFS, dst, arg); break; case 3: UNW_DEC_REG_GR(P3, UNW_REG_PR, dst, arg); break; case 4: UNW_DEC_REG_GR(P3, UNW_REG_UNAT, dst, arg); break; case 5: UNW_DEC_REG_GR(P3, UNW_REG_LC, dst, arg); break; case 6: UNW_DEC_RP_BR(P3, dst, arg); break; case 7: UNW_DEC_REG_GR(P3, UNW_REG_RNAT, dst, arg); break; case 8: UNW_DEC_REG_GR(P3, UNW_REG_BSP, dst, arg); break; case 9: UNW_DEC_REG_GR(P3, UNW_REG_BSPSTORE, dst, arg); break; case 10: UNW_DEC_REG_GR(P3, UNW_REG_FPSR, dst, arg); break; case 11: UNW_DEC_PRIUNAT_GR(P3, dst, arg); break; default: UNW_DEC_BAD_CODE(r); break; } } else if ((code & 0x7) == 0) UNW_DEC_SPILL_MASK(P4, dp, arg); else if ((code & 0x7) == 1) { unw_word grmask, frmask, byte1, byte2, byte3; byte1 = *dp++; byte2 = *dp++; byte3 = *dp++; grmask = ((byte1 >> 4) & 0xf); frmask = ((byte1 & 0xf) << 16) | (byte2 << 8) | byte3; UNW_DEC_FRGR_MEM(P5, grmask, frmask, arg); } else UNW_DEC_BAD_CODE(code); return dp; } static unsigned char * unw_decode_p6 (unsigned char *dp, unsigned char code, void *arg) { int gregs = (code & 0x10) != 0; unsigned char mask = (code & 0x0f); if (gregs) UNW_DEC_GR_MEM(P6, mask, arg); else UNW_DEC_FR_MEM(P6, mask, arg); return dp; } static unsigned char * unw_decode_p7_p10 (unsigned char *dp, unsigned char code, void *arg) { unsigned char r, byte1, byte2; unw_word t, size; if ((code & 0x10) == 0) { r = (code & 0xf); t = unw_decode_uleb128 (&dp); switch (r) { case 0: size = unw_decode_uleb128 (&dp); UNW_DEC_MEM_STACK_F(P7, t, size, arg); break; case 1: UNW_DEC_MEM_STACK_V(P7, t, arg); break; case 2: UNW_DEC_SPILL_BASE(P7, t, arg); break; case 3: UNW_DEC_REG_SPREL(P7, UNW_REG_PSP, t, arg); break; case 4: UNW_DEC_REG_WHEN(P7, UNW_REG_RP, t, arg); break; case 5: UNW_DEC_REG_PSPREL(P7, UNW_REG_RP, t, arg); break; case 6: UNW_DEC_REG_WHEN(P7, UNW_REG_PFS, t, arg); break; case 7: UNW_DEC_REG_PSPREL(P7, UNW_REG_PFS, t, arg); break; case 8: UNW_DEC_REG_WHEN(P7, UNW_REG_PR, t, arg); break; case 9: UNW_DEC_REG_PSPREL(P7, UNW_REG_PR, t, arg); break; case 10: UNW_DEC_REG_WHEN(P7, UNW_REG_LC, t, arg); break; case 11: UNW_DEC_REG_PSPREL(P7, UNW_REG_LC, t, arg); break; case 12: UNW_DEC_REG_WHEN(P7, UNW_REG_UNAT, t, arg); break; case 13: UNW_DEC_REG_PSPREL(P7, UNW_REG_UNAT, t, arg); break; case 14: UNW_DEC_REG_WHEN(P7, UNW_REG_FPSR, t, arg); break; case 15: UNW_DEC_REG_PSPREL(P7, UNW_REG_FPSR, t, arg); break; default: UNW_DEC_BAD_CODE(r); break; } } else { switch (code & 0xf) { case 0x0: /* p8 */ { r = *dp++; t = unw_decode_uleb128 (&dp); switch (r) { case 1: UNW_DEC_REG_SPREL(P8, UNW_REG_RP, t, arg); break; case 2: UNW_DEC_REG_SPREL(P8, UNW_REG_PFS, t, arg); break; case 3: UNW_DEC_REG_SPREL(P8, UNW_REG_PR, t, arg); break; case 4: UNW_DEC_REG_SPREL(P8, UNW_REG_LC, t, arg); break; case 5: UNW_DEC_REG_SPREL(P8, UNW_REG_UNAT, t, arg); break; case 6: UNW_DEC_REG_SPREL(P8, UNW_REG_FPSR, t, arg); break; case 7: UNW_DEC_REG_WHEN(P8, UNW_REG_BSP, t, arg); break; case 8: UNW_DEC_REG_PSPREL(P8, UNW_REG_BSP, t, arg); break; case 9: UNW_DEC_REG_SPREL(P8, UNW_REG_BSP, t, arg); break; case 10: UNW_DEC_REG_WHEN(P8, UNW_REG_BSPSTORE, t, arg); break; case 11: UNW_DEC_REG_PSPREL(P8, UNW_REG_BSPSTORE, t, arg); break; case 12: UNW_DEC_REG_SPREL(P8, UNW_REG_BSPSTORE, t, arg); break; case 13: UNW_DEC_REG_WHEN(P8, UNW_REG_RNAT, t, arg); break; case 14: UNW_DEC_REG_PSPREL(P8, UNW_REG_RNAT, t, arg); break; case 15: UNW_DEC_REG_SPREL(P8, UNW_REG_RNAT, t, arg); break; case 16: UNW_DEC_PRIUNAT_WHEN_GR(P8, t, arg); break; case 17: UNW_DEC_PRIUNAT_PSPREL(P8, t, arg); break; case 18: UNW_DEC_PRIUNAT_SPREL(P8, t, arg); break; case 19: UNW_DEC_PRIUNAT_WHEN_MEM(P8, t, arg); break; default: UNW_DEC_BAD_CODE(r); break; } } break; case 0x1: byte1 = *dp++; byte2 = *dp++; UNW_DEC_GR_GR(P9, (byte1 & 0xf), (byte2 & 0x7f), arg); break; case 0xf: /* p10 */ byte1 = *dp++; byte2 = *dp++; UNW_DEC_ABI(P10, byte1, byte2, arg); break; case 0x9: return unw_decode_x1 (dp, code, arg); case 0xa: return unw_decode_x2 (dp, code, arg); case 0xb: return unw_decode_x3 (dp, code, arg); case 0xc: return unw_decode_x4 (dp, code, arg); default: UNW_DEC_BAD_CODE(code); break; } } return dp; } static unsigned char * unw_decode_b1 (unsigned char *dp, unsigned char code, void *arg) { unw_word label = (code & 0x1f); if ((code & 0x20) != 0) UNW_DEC_COPY_STATE(B1, label, arg); else UNW_DEC_LABEL_STATE(B1, label, arg); return dp; } static unsigned char * unw_decode_b2 (unsigned char *dp, unsigned char code, void *arg) { unw_word t; t = unw_decode_uleb128 (&dp); UNW_DEC_EPILOGUE(B2, t, (code & 0x1f), arg); return dp; } static unsigned char * unw_decode_b3_x4 (unsigned char *dp, unsigned char code, void *arg) { unw_word t, ecount, label; if ((code & 0x10) == 0) { t = unw_decode_uleb128 (&dp); ecount = unw_decode_uleb128 (&dp); UNW_DEC_EPILOGUE(B3, t, ecount, arg); } else if ((code & 0x07) == 0) { label = unw_decode_uleb128 (&dp); if ((code & 0x08) != 0) UNW_DEC_COPY_STATE(B4, label, arg); else UNW_DEC_LABEL_STATE(B4, label, arg); } else switch (code & 0x7) { case 1: return unw_decode_x1 (dp, code, arg); case 2: return unw_decode_x2 (dp, code, arg); case 3: return unw_decode_x3 (dp, code, arg); case 4: return unw_decode_x4 (dp, code, arg); default: UNW_DEC_BAD_CODE(code); break; } return dp; } typedef unsigned char *(*unw_decoder) (unsigned char *, unsigned char, void *); static const unw_decoder unw_decode_table[2][8] = { /* prologue table: */ { unw_decode_r1, /* 0 */ unw_decode_r1, unw_decode_r2, unw_decode_r3, unw_decode_p1, /* 4 */ unw_decode_p2_p5, unw_decode_p6, unw_decode_p7_p10 }, { unw_decode_r1, /* 0 */ unw_decode_r1, unw_decode_r2, unw_decode_r3, unw_decode_b1, /* 4 */ unw_decode_b1, unw_decode_b2, unw_decode_b3_x4 } }; /* * Decode one descriptor and return address of next descriptor. */ static inline unsigned char * unw_decode (unsigned char *dp, int inside_body, void *arg) { unw_decoder decoder; unsigned char code; code = *dp++; decoder = unw_decode_table[inside_body][code >> 5]; dp = (*decoder) (dp, code, arg); return dp; } /* RSE helper functions. */ static inline unw_word ia64_rse_slot_num (unw_word *addr) { return (((unw_word) addr) >> 3) & 0x3f; } /* Return TRUE if ADDR is the address of an RNAT slot. */ static inline unw_word ia64_rse_is_rnat_slot (unw_word *addr) { return ia64_rse_slot_num (addr) == 0x3f; } /* Returns the address of the RNAT slot that covers the slot at address SLOT_ADDR. */ static inline unw_word * ia64_rse_rnat_addr (unw_word *slot_addr) { return (unw_word *) ((unw_word) slot_addr | (0x3f << 3)); } /* Calculate the number of registers in the dirty partition starting at BSPSTORE with a size of DIRTY bytes. This isn't simply DIRTY divided by eight because the 64th slot is used to store ar.rnat. */ static inline unw_word ia64_rse_num_regs (unw_word *bspstore, unw_word *bsp) { unw_word slots = (bsp - bspstore); return slots - (ia64_rse_slot_num (bspstore) + slots)/0x40; } /* The inverse of the above: given bspstore and the number of registers, calculate ar.bsp. */ static inline unw_word * ia64_rse_skip_regs (unw_word *addr, int num_regs) { int delta = ia64_rse_slot_num (addr) + num_regs; if (num_regs < 0) delta -= 0x3e; return addr + num_regs + delta/0x3f; } /* Copy register backing store from SRC to DST, LEN words (which include both saved registers and nat collections). DST_RNAT is a partial nat collection for DST. SRC and DST don't have to be equal modulo 64 slots, so it cannot be done with a simple memcpy as the nat collections will be at different relative offsets and need to be combined together. */ static void ia64_copy_rbs (struct _Unwind_Context *info, unw_word dst, unw_word src, unw_word len, unw_word dst_rnat) { unw_word count; unw_word src_rnat; unw_word shift1, shift2; len <<= 3; dst_rnat &= (1ULL << ((dst >> 3) & 0x3f)) - 1; src_rnat = src >= info->regstk_top ? info->rnat : *(unw_word *) (src | 0x1f8); src_rnat &= ~((1ULL << ((src >> 3) & 0x3f)) - 1); /* Just to make sure. */ src_rnat &= ~(1ULL << 63); shift1 = ((dst - src) >> 3) & 0x3f; if ((dst & 0x1f8) < (src & 0x1f8)) shift1--; shift2 = 0x3f - shift1; if ((dst & 0x1f8) >= (src & 0x1f8)) { count = ~dst & 0x1f8; goto first; } count = ~src & 0x1f8; goto second; while (len > 0) { src_rnat = src >= info->regstk_top ? info->rnat : *(unw_word *) (src | 0x1f8); /* Just to make sure. */ src_rnat &= ~(1ULL << 63); count = shift2 << 3; first: if (count > len) count = len; memcpy ((char *) dst, (char *) src, count); dst += count; src += count; len -= count; dst_rnat |= (src_rnat << shift1) & ~(1ULL << 63); if (len <= 0) break; *(unw_word *) dst = dst_rnat; dst += 8; dst_rnat = 0; count = shift1 << 3; second: if (count > len) count = len; memcpy ((char *) dst, (char *) src, count); dst += count; src += count + 8; len -= count + 8; dst_rnat |= (src_rnat >> shift2); } if ((dst & 0x1f8) == 0x1f8) { *(unw_word *) dst = dst_rnat; dst += 8; dst_rnat = 0; } /* Set info->regstk_top to lowest rbs address which will use info->rnat collection. */ info->regstk_top = dst & ~0x1ffULL; info->rnat = dst_rnat; } /* Unwind accessors. */ static void unw_access_gr (struct _Unwind_Context *info, int regnum, unw_word *val, char *nat, int write) { unw_word *addr, *nat_addr = 0, nat_mask = 0, dummy_nat; struct unw_ireg *ireg; if ((unsigned) regnum - 1 >= 127) abort (); if (regnum < 1) { nat_addr = addr = &dummy_nat; dummy_nat = 0; } else if (regnum < 32) { /* Access a non-stacked register. */ ireg = &info->ireg[regnum - 2]; addr = ireg->loc; if (addr) { nat_addr = addr + ireg->nat.off; switch (ireg->nat.type) { case UNW_NAT_VAL: /* Simulate getf.sig/setf.sig. */ if (write) { if (*nat) { /* Write NaTVal and be done with it. */ addr[0] = 0; addr[1] = 0x1fffe; return; } addr[1] = 0x1003e; } else if (addr[0] == 0 && addr[1] == 0x1ffe) { /* Return NaT and be done with it. */ *val = 0; *nat = 1; return; } /* FALLTHRU */ case UNW_NAT_NONE: dummy_nat = 0; nat_addr = &dummy_nat; break; case UNW_NAT_MEMSTK: nat_mask = 1UL << ((unw_word) addr & 0x1f8)/8; break; case UNW_NAT_REGSTK: if ((unw_word) addr >= info->regstk_top) nat_addr = &info->rnat; else nat_addr = ia64_rse_rnat_addr (addr); nat_mask = 1ULL << ia64_rse_slot_num (addr); break; } } } else { /* Access a stacked register. */ addr = ia64_rse_skip_regs ((unw_word *) info->bsp, regnum - 32); if ((unw_word) addr >= info->regstk_top) nat_addr = &info->rnat; else nat_addr = ia64_rse_rnat_addr (addr); nat_mask = 1UL << ia64_rse_slot_num (addr); } if (write) { *addr = *val; if (*nat) *nat_addr |= nat_mask; else *nat_addr &= ~nat_mask; } else { *val = *addr; *nat = (*nat_addr & nat_mask) != 0; } } /* Get the value of register REG as saved in CONTEXT. */ _Unwind_Word _Unwind_GetGR (struct _Unwind_Context *context, int index) { _Unwind_Word ret; char nat; if (index == 1) return context->gp; else if (index >= 15 && index <= 18) return context->eh_data[index - 15]; else unw_access_gr (context, index, &ret, &nat, 0); return ret; } /* Overwrite the saved value for register REG in CONTEXT with VAL. */ void _Unwind_SetGR (struct _Unwind_Context *context, int index, _Unwind_Word val) { char nat = 0; if (index == 1) context->gp = val; else if (index >= 15 && index <= 18) context->eh_data[index - 15] = val; else unw_access_gr (context, index, &val, &nat, 1); } /* Retrieve the return address for CONTEXT. */ inline _Unwind_Ptr _Unwind_GetIP (struct _Unwind_Context *context) { return context->rp; } inline _Unwind_Ptr _Unwind_GetIPInfo (struct _Unwind_Context *context, int *ip_before_insn) { *ip_before_insn = 0; return context->rp; } /* Overwrite the return address for CONTEXT with VAL. */ inline void _Unwind_SetIP (struct _Unwind_Context *context, _Unwind_Ptr val) { context->rp = val; } _Unwind_Ptr _Unwind_GetLanguageSpecificData (struct _Unwind_Context *context) { return (_Unwind_Ptr)context->lsda; } _Unwind_Ptr _Unwind_GetRegionStart (struct _Unwind_Context *context) { return context->region_start; } void * _Unwind_FindEnclosingFunction (void *pc) { struct unw_table_entry *entp, ent; unw_word segment_base, gp; entp = _Unwind_FindTableEntry (pc, &segment_base, &gp, &ent); if (entp == NULL) return NULL; else return (void *)(segment_base + entp->start_offset); } /* Get the value of the CFA as saved in CONTEXT. In GCC/Dwarf2 parlance, the CFA is the value of the stack pointer on entry; In IA-64 unwind parlance, this is the PSP. */ _Unwind_Word _Unwind_GetCFA (struct _Unwind_Context *context) { return (_Unwind_Ptr) context->psp; } /* Get the value of the Backing Store Pointer as saved in CONTEXT. */ _Unwind_Word _Unwind_GetBSP (struct _Unwind_Context *context) { return (_Unwind_Ptr) context->bsp; } #include "md-unwind-support.h" /* By default, assume personality routine interface compatibility with our expectations. */ #ifndef MD_UNW_COMPATIBLE_PERSONALITY_P #define MD_UNW_COMPATIBLE_PERSONALITY_P(HEADER) 1 #endif static _Unwind_Reason_Code uw_frame_state_for (struct _Unwind_Context *context, _Unwind_FrameState *fs) { struct unw_table_entry *entp, ent; unw_word *unw, header, length; unsigned char *insn, *insn_end; unw_word segment_base; struct unw_reg_info *r; memset (fs, 0, sizeof (*fs)); for (r = fs->curr.reg; r < fs->curr.reg + UNW_NUM_REGS; ++r) r->when = UNW_WHEN_NEVER; context->lsda = 0; entp = _Unwind_FindTableEntry ((void *) context->rp, &segment_base, &context->gp, &ent); if (entp == NULL) { /* Couldn't find unwind info for this function. Try an os-specific fallback mechanism. This will necessarily not provide a personality routine or LSDA. */ #ifdef MD_FALLBACK_FRAME_STATE_FOR if (MD_FALLBACK_FRAME_STATE_FOR (context, fs) == _URC_NO_REASON) return _URC_NO_REASON; #endif /* [SCRA 11.4.1] A leaf function with no memory stack, no exception handlers, and which keeps the return value in B0 does not need an unwind table entry. This can only happen in the frame after unwinding through a signal handler. Avoid infinite looping by requiring that B0 != RP. RP == 0 terminates the chain. */ if (context->br_loc[0] && *context->br_loc[0] != context->rp && context->rp != 0) goto skip_unwind_info; return _URC_END_OF_STACK; } context->region_start = entp->start_offset + segment_base; fs->when_target = ((context->rp & -16) - context->region_start) / 16 * 3 + (context->rp & 15); unw = (unw_word *) (entp->info_offset + segment_base); header = *unw; length = UNW_LENGTH (header); /* Some operating systems use the personality routine slot in way not compatible with what we expect. For instance, OpenVMS uses this slot to designate "condition handlers" with very different arguments than what we would be providing. Such cases are typically identified from OS specific bits in the unwind information block header, and checked by the target MD_UNW_COMPATIBLE_PERSONALITY_P macro. We just pretend there is no personality from our standpoint in such situations, and expect GCC not to set the identifying bits itself so that compatible personalities for GCC compiled code are called. Of course, this raises the question of what combinations of native/GCC calls can be expected to behave properly exception handling-wise. We are not to provide a magic answer here, merely to prevent crashes assuming users know what they are doing. ??? Perhaps check UNW_VER / UNW_FLAG_OSMASK as well. */ if (MD_UNW_COMPATIBLE_PERSONALITY_P (header) && (UNW_FLAG_EHANDLER (header) | UNW_FLAG_UHANDLER (header))) { fs->personality = *(_Unwind_Personality_Fn *) (unw[length + 1] + context->gp); context->lsda = unw + length + 2; } insn = (unsigned char *) (unw + 1); insn_end = (unsigned char *) (unw + 1 + length); while (!fs->done && insn < insn_end) insn = unw_decode (insn, fs->in_body, fs); free_label_states (fs->labeled_states); free_state_stack (&fs->curr); #ifdef ENABLE_MALLOC_CHECKING if (reg_state_alloced || labeled_state_alloced) abort (); #endif /* If we're in the epilogue, sp has been restored and all values on the memory stack below psp also have been restored. */ if (fs->when_target > fs->epilogue_start) { struct unw_reg_info *r; fs->curr.reg[UNW_REG_PSP].where = UNW_WHERE_NONE; fs->curr.reg[UNW_REG_PSP].val = 0; for (r = fs->curr.reg; r < fs->curr.reg + UNW_NUM_REGS; ++r) if ((r->where == UNW_WHERE_PSPREL && r->val <= 0x10) || r->where == UNW_WHERE_SPREL) r->where = UNW_WHERE_NONE; } skip_unwind_info: /* If RP didn't get saved, generate entry for the return link register. */ if (fs->curr.reg[UNW_REG_RP].when >= fs->when_target) { fs->curr.reg[UNW_REG_RP].where = UNW_WHERE_BR; fs->curr.reg[UNW_REG_RP].when = -1; fs->curr.reg[UNW_REG_RP].val = fs->return_link_reg; } /* There is a subtlety for the frame after unwinding through a signal handler: should we restore the cfm as usual or the pfs? We can't restore both because we use br.ret to resume execution of user code. For other frames the procedure is by definition non-leaf so the pfs is saved and restored and thus effectively dead in the body; only the cfm need therefore be restored. Here we have 2 cases: - either the pfs is saved and restored and thus effectively dead like in regular frames; then we do nothing special and restore the cfm. - or the pfs is not saved and thus live; but in that case the procedure is necessarily leaf so the cfm is effectively dead and we restore the pfs. */ if (context->signal_pfs_loc) { if (fs->curr.reg[UNW_REG_PFS].when >= fs->when_target) context->pfs_loc = context->signal_pfs_loc; context->signal_pfs_loc = NULL; } return _URC_NO_REASON; } static void uw_update_reg_address (struct _Unwind_Context *context, _Unwind_FrameState *fs, enum unw_register_index regno) { struct unw_reg_info *r = fs->curr.reg + regno; void *addr; unw_word rval; if (r->where == UNW_WHERE_NONE || r->when >= fs->when_target) return; rval = r->val; switch (r->where) { case UNW_WHERE_GR: if (rval >= 32) addr = ia64_rse_skip_regs ((unw_word *) context->bsp, rval - 32); else if (rval >= 2) addr = context->ireg[rval - 2].loc; else if (rval == 0) { static const unw_word dummy; addr = (void *) &dummy; } else abort (); break; case UNW_WHERE_FR: if (rval >= 2 && rval < 32) addr = context->fr_loc[rval - 2]; else abort (); break; case UNW_WHERE_BR: /* Note that while RVAL can only be 1-5 from normal descriptors, we can want to look at B0, B6 and B7 due to having manually unwound a signal frame. */ if (rval < 8) addr = context->br_loc[rval]; else abort (); break; case UNW_WHERE_SPREL: addr = (void *)(context->sp + rval); break; case UNW_WHERE_PSPREL: addr = (void *)(context->psp + rval); break; default: abort (); } switch (regno) { case UNW_REG_R2 ... UNW_REG_R31: context->ireg[regno - UNW_REG_R2].loc = addr; switch (r->where) { case UNW_WHERE_GR: if (rval >= 32) { context->ireg[regno - UNW_REG_R2].nat.type = UNW_NAT_MEMSTK; context->ireg[regno - UNW_REG_R2].nat.off = context->pri_unat_loc - (unw_word *) addr; } else if (rval >= 2) { context->ireg[regno - UNW_REG_R2].nat = context->ireg[rval - 2].nat; } else if (rval == 0) { context->ireg[regno - UNW_REG_R2].nat.type = UNW_NAT_NONE; context->ireg[regno - UNW_REG_R2].nat.off = 0; } else abort (); break; case UNW_WHERE_FR: context->ireg[regno - UNW_REG_R2].nat.type = UNW_NAT_VAL; context->ireg[regno - UNW_REG_R2].nat.off = 0; break; case UNW_WHERE_BR: context->ireg[regno - UNW_REG_R2].nat.type = UNW_NAT_NONE; context->ireg[regno - UNW_REG_R2].nat.off = 0; break; case UNW_WHERE_PSPREL: case UNW_WHERE_SPREL: context->ireg[regno - UNW_REG_R2].nat.type = UNW_NAT_MEMSTK; context->ireg[regno - UNW_REG_R2].nat.off = context->pri_unat_loc - (unw_word *) addr; break; default: abort (); } break; case UNW_REG_F2 ... UNW_REG_F31: context->fr_loc[regno - UNW_REG_F2] = addr; break; case UNW_REG_B1 ... UNW_REG_B5: context->br_loc[regno - UNW_REG_B0] = addr; break; case UNW_REG_BSP: context->bsp_loc = addr; break; case UNW_REG_BSPSTORE: context->bspstore_loc = addr; break; case UNW_REG_PFS: context->pfs_loc = addr; break; case UNW_REG_RP: context->rp = *(unw_word *)addr; break; case UNW_REG_UNAT: context->unat_loc = addr; break; case UNW_REG_PR: context->pr = *(unw_word *) addr; break; case UNW_REG_LC: context->lc_loc = addr; break; case UNW_REG_FPSR: context->fpsr_loc = addr; break; case UNW_REG_PSP: context->psp = *(unw_word *)addr; break; default: abort (); } } static void uw_update_context (struct _Unwind_Context *context, _Unwind_FrameState *fs) { int i; #ifdef MD_HANDLE_UNWABI MD_HANDLE_UNWABI (context, fs); #endif context->sp = context->psp; /* First, set PSP. Subsequent instructions may depend on this value. */ if (fs->when_target > fs->curr.reg[UNW_REG_PSP].when) { if (fs->curr.reg[UNW_REG_PSP].where == UNW_WHERE_NONE) context->psp = context->psp + fs->curr.reg[UNW_REG_PSP].val; else uw_update_reg_address (context, fs, UNW_REG_PSP); } /* Determine the location of the primary UNaT. */ { int i; if (fs->when_target < fs->curr.reg[UNW_REG_PRI_UNAT_GR].when) i = UNW_REG_PRI_UNAT_MEM; else if (fs->when_target < fs->curr.reg[UNW_REG_PRI_UNAT_MEM].when) i = UNW_REG_PRI_UNAT_GR; else if (fs->curr.reg[UNW_REG_PRI_UNAT_MEM].when > fs->curr.reg[UNW_REG_PRI_UNAT_GR].when) i = UNW_REG_PRI_UNAT_MEM; else i = UNW_REG_PRI_UNAT_GR; uw_update_reg_address (context, fs, i); } /* Compute the addresses of all registers saved in this frame. */ for (i = UNW_REG_BSP; i < UNW_NUM_REGS; ++i) uw_update_reg_address (context, fs, i); /* Unwind BSP for the local registers allocated this frame. */ /* ??? What to do with stored BSP or BSPSTORE registers. */ /* We assert that we are either at a call site, or we have just unwound through a signal frame. In either case pfs_loc is valid. */ if (!(fs -> no_reg_stack_frame)) { unw_word pfs = *context->pfs_loc; unw_word sol = (pfs >> 7) & 0x7f; context->bsp = (unw_word) ia64_rse_skip_regs ((unw_word *) context->bsp, -sol); } } static void uw_advance_context (struct _Unwind_Context *context, _Unwind_FrameState *fs) { uw_update_context (context, fs); } /* Fill in CONTEXT for top-of-stack. The only valid registers at this level will be the return address and the CFA. Note that CFA = SP+16. */ #define uw_init_context(CONTEXT) \ do { \ /* ??? There is a whole lot o code in uw_install_context that \ tries to avoid spilling the entire machine state here. We \ should try to make that work again. */ \ __builtin_unwind_init(); \ uw_init_context_1 (CONTEXT, __builtin_ia64_bsp ()); \ } while (0) static void __attribute__((noinline)) uw_init_context_1 (struct _Unwind_Context *context, void *bsp) { void *rp = __builtin_extract_return_addr (__builtin_return_address (0)); /* Set psp to the caller's stack pointer. */ void *psp = __builtin_dwarf_cfa () - 16; _Unwind_FrameState fs; unw_word rnat, tmp1, tmp2; /* Flush the register stack to memory so that we can access it. Get rse nat collection for the last incomplete rbs chunk of registers at the same time. For this RSE needs to be turned into the mandatory only mode. */ asm ("mov.m %1 = ar.rsc;;\n\t" "and %2 = 0x1c, %1;;\n\t" "mov.m ar.rsc = %2;;\n\t" "flushrs;;\n\t" "mov.m %0 = ar.rnat;;\n\t" "mov.m ar.rsc = %1\n\t" : "=r" (rnat), "=r" (tmp1), "=r" (tmp2)); memset (context, 0, sizeof (struct _Unwind_Context)); context->bsp = (unw_word) bsp; /* Set context->regstk_top to lowest rbs address which will use context->rnat collection. */ context->regstk_top = context->bsp & ~0x1ffULL; context->rnat = rnat; context->psp = (unw_word) psp; context->rp = (unw_word) rp; asm ("mov %0 = sp" : "=r" (context->sp)); asm ("mov %0 = pr" : "=r" (context->pr)); context->pri_unat_loc = &context->initial_unat; /* ??? */ if (uw_frame_state_for (context, &fs) != _URC_NO_REASON) abort (); uw_update_context (context, &fs); } /* Install (i.e. longjmp to) the contents of TARGET. */ static void __attribute__((noreturn)) uw_install_context (struct _Unwind_Context *current __attribute__((unused)), struct _Unwind_Context *target) { unw_word ireg_buf[4], ireg_nat = 0, ireg_pr = 0; unw_word saved_lc; int i; /* ??? LC is a fixed register so the call to __builtin_unwind_init in uw_init_context doesn't cause it to be saved. In case it isn't in the user frames either, we need to manually do so here, lest it be clobbered by the loop just below. */ if (target->lc_loc == NULL) { register unw_word lc asm ("ar.lc"); saved_lc = lc; target->lc_loc = &saved_lc; } /* Copy integer register data from the target context to a temporary buffer. Do this so that we can frob AR.UNAT to get the NaT bits for these registers set properly. */ for (i = 4; i <= 7; ++i) { char nat; void *t = target->ireg[i - 2].loc; if (t) { unw_access_gr (target, i, &ireg_buf[i - 4], &nat, 0); ireg_nat |= (unw_word)nat << (((size_t)&ireg_buf[i - 4] >> 3) & 0x3f); /* Set p6 - p9. */ ireg_pr |= 4L << i; } } /* The value in uc_bsp that we've computed is that for the target function. The value that we install below will be adjusted by the BR.RET instruction based on the contents of AR.PFS. So we must unadjust that here. */ target->bsp = (unw_word) ia64_rse_skip_regs ((unw_word *)target->bsp, (*target->pfs_loc >> 7) & 0x7f); if (target->bsp < target->regstk_top) target->rnat = *ia64_rse_rnat_addr ((unw_word *) target->bsp); /* Provide assembly with the offsets into the _Unwind_Context. */ asm volatile ("uc_rnat = %0" : : "i"(offsetof (struct _Unwind_Context, rnat))); asm volatile ("uc_bsp = %0" : : "i"(offsetof (struct _Unwind_Context, bsp))); asm volatile ("uc_psp = %0" : : "i"(offsetof (struct _Unwind_Context, psp))); asm volatile ("uc_rp = %0" : : "i"(offsetof (struct _Unwind_Context, rp))); asm volatile ("uc_pr = %0" : : "i"(offsetof (struct _Unwind_Context, pr))); asm volatile ("uc_gp = %0" : : "i"(offsetof (struct _Unwind_Context, gp))); asm volatile ("uc_pfs_loc = %0" : : "i"(offsetof (struct _Unwind_Context, pfs_loc))); asm volatile ("uc_unat_loc = %0" : : "i"(offsetof (struct _Unwind_Context, unat_loc))); asm volatile ("uc_lc_loc = %0" : : "i"(offsetof (struct _Unwind_Context, lc_loc))); asm volatile ("uc_fpsr_loc = %0" : : "i"(offsetof (struct _Unwind_Context, fpsr_loc))); asm volatile ("uc_eh_data = %0" : : "i"(offsetof (struct _Unwind_Context, eh_data))); asm volatile ("uc_br_loc = %0" : : "i"(offsetof (struct _Unwind_Context, br_loc))); asm volatile ("uc_fr_loc = %0" : : "i"(offsetof (struct _Unwind_Context, fr_loc))); asm volatile ( /* Load up call-saved non-window integer registers from ireg_buf. */ "add r20 = 8, %1 \n\t" "mov ar.unat = %2 \n\t" "mov pr = %3, 0x3c0 \n\t" ";; \n\t" "(p6) ld8.fill r4 = [%1] \n\t" "(p7) ld8.fill r5 = [r20] \n\t" "add r21 = uc_br_loc + 16, %0 \n\t" "adds %1 = 16, %1 \n\t" "adds r20 = 16, r20 \n\t" ";; \n\t" "(p8) ld8.fill r6 = [%1] \n\t" "(p9) ld8.fill r7 = [r20] \n\t" "add r20 = uc_br_loc + 8, %0 \n\t" ";; \n\t" /* Load up call-saved branch registers. */ "ld8 r22 = [r20], 16 \n\t" "ld8 r23 = [r21], 16 \n\t" ";; \n\t" "ld8 r24 = [r20], 16 \n\t" "ld8 r25 = [r21], uc_fr_loc - (uc_br_loc + 32)\n\t" ";; \n\t" "ld8 r26 = [r20], uc_fr_loc + 8 - (uc_br_loc + 40)\n\t" "ld8 r27 = [r21], 24 \n\t" "cmp.ne p6, p0 = r0, r22 \n\t" ";; \n\t" "ld8 r28 = [r20], 8 \n\t" "(p6) ld8 r22 = [r22] \n\t" "cmp.ne p7, p0 = r0, r23 \n\t" ";; \n\t" "(p7) ld8 r23 = [r23] \n\t" "cmp.ne p8, p0 = r0, r24 \n\t" ";; \n\t" "(p8) ld8 r24 = [r24] \n\t" "(p6) mov b1 = r22 \n\t" "cmp.ne p9, p0 = r0, r25 \n\t" ";; \n\t" "(p9) ld8 r25 = [r25] \n\t" "(p7) mov b2 = r23 \n\t" "cmp.ne p6, p0 = r0, r26 \n\t" ";; \n\t" "(p6) ld8 r26 = [r26] \n\t" "(p8) mov b3 = r24 \n\t" "cmp.ne p7, p0 = r0, r27 \n\t" ";; \n\t" /* Load up call-saved fp registers. */ "(p7) ldf.fill f2 = [r27] \n\t" "(p9) mov b4 = r25 \n\t" "cmp.ne p8, p0 = r0, r28 \n\t" ";; \n\t" "(p8) ldf.fill f3 = [r28] \n\t" "(p6) mov b5 = r26 \n\t" ";; \n\t" "ld8 r29 = [r20], 16*8 - 4*8 \n\t" "ld8 r30 = [r21], 17*8 - 5*8 \n\t" ";; \n\t" "ld8 r22 = [r20], 16 \n\t" "ld8 r23 = [r21], 16 \n\t" ";; \n\t" "ld8 r24 = [r20], 16 \n\t" "ld8 r25 = [r21] \n\t" "cmp.ne p6, p0 = r0, r29 \n\t" ";; \n\t" "ld8 r26 = [r20], 8 \n\t" "(p6) ldf.fill f4 = [r29] \n\t" "cmp.ne p7, p0 = r0, r30 \n\t" ";; \n\t" "ld8 r27 = [r20], 8 \n\t" "(p7) ldf.fill f5 = [r30] \n\t" "cmp.ne p6, p0 = r0, r22 \n\t" ";; \n\t" "ld8 r28 = [r20], 8 \n\t" "(p6) ldf.fill f16 = [r22] \n\t" "cmp.ne p7, p0 = r0, r23 \n\t" ";; \n\t" "ld8 r29 = [r20], 8 \n\t" "(p7) ldf.fill f17 = [r23] \n\t" "cmp.ne p6, p0 = r0, r24 \n\t" ";; \n\t" "ld8 r22 = [r20], 8 \n\t" "(p6) ldf.fill f18 = [r24] \n\t" "cmp.ne p7, p0 = r0, r25 \n\t" ";; \n\t" "ld8 r23 = [r20], 8 \n\t" "(p7) ldf.fill f19 = [r25] \n\t" "cmp.ne p6, p0 = r0, r26 \n\t" ";; \n\t" "ld8 r24 = [r20], 8 \n\t" "(p6) ldf.fill f20 = [r26] \n\t" "cmp.ne p7, p0 = r0, r27 \n\t" ";; \n\t" "ld8 r25 = [r20], 8 \n\t" "(p7) ldf.fill f21 = [r27] \n\t" "cmp.ne p6, p0 = r0, r28 \n\t" ";; \n\t" "ld8 r26 = [r20], 8 \n\t" "(p6) ldf.fill f22 = [r28] \n\t" "cmp.ne p7, p0 = r0, r29 \n\t" ";; \n\t" "ld8 r27 = [r20], 8 \n\t" ";; \n\t" "ld8 r28 = [r20], 8 \n\t" "(p7) ldf.fill f23 = [r29] \n\t" "cmp.ne p6, p0 = r0, r22 \n\t" ";; \n\t" "ld8 r29 = [r20], 8 \n\t" "(p6) ldf.fill f24 = [r22] \n\t" "cmp.ne p7, p0 = r0, r23 \n\t" ";; \n\t" "(p7) ldf.fill f25 = [r23] \n\t" "cmp.ne p6, p0 = r0, r24 \n\t" "cmp.ne p7, p0 = r0, r25 \n\t" ";; \n\t" "(p6) ldf.fill f26 = [r24] \n\t" "(p7) ldf.fill f27 = [r25] \n\t" "cmp.ne p6, p0 = r0, r26 \n\t" ";; \n\t" "(p6) ldf.fill f28 = [r26] \n\t" "cmp.ne p7, p0 = r0, r27 \n\t" "cmp.ne p6, p0 = r0, r28 \n\t" ";; \n\t" "(p7) ldf.fill f29 = [r27] \n\t" "(p6) ldf.fill f30 = [r28] \n\t" "cmp.ne p7, p0 = r0, r29 \n\t" ";; \n\t" "(p7) ldf.fill f31 = [r29] \n\t" "add r20 = uc_rnat, %0 \n\t" "add r21 = uc_bsp, %0 \n\t" ";; \n\t" /* Load the balance of the thread state from the context. */ "ld8 r22 = [r20], uc_psp - uc_rnat \n\t" "ld8 r23 = [r21], uc_gp - uc_bsp \n\t" ";; \n\t" "ld8 r24 = [r20], uc_pfs_loc - uc_psp \n\t" "ld8 r1 = [r21], uc_rp - uc_gp \n\t" ";; \n\t" "ld8 r25 = [r20], uc_unat_loc - uc_pfs_loc\n\t" "ld8 r26 = [r21], uc_pr - uc_rp \n\t" ";; \n\t" "ld8 r27 = [r20], uc_lc_loc - uc_unat_loc\n\t" "ld8 r28 = [r21], uc_fpsr_loc - uc_pr \n\t" ";; \n\t" "ld8 r29 = [r20], uc_eh_data - uc_lc_loc\n\t" "ld8 r30 = [r21], uc_eh_data + 8 - uc_fpsr_loc\n\t" ";; \n\t" /* Load data for the exception handler. */ "ld8 r15 = [r20], 16 \n\t" "ld8 r16 = [r21], 16 \n\t" ";; \n\t" "ld8 r17 = [r20] \n\t" "ld8 r18 = [r21] \n\t" ";; \n\t" /* Install the balance of the thread state loaded above. */ "cmp.ne p6, p0 = r0, r25 \n\t" "cmp.ne p7, p0 = r0, r27 \n\t" ";; \n\t" "(p6) ld8 r25 = [r25] \n\t" "(p7) ld8 r27 = [r27] \n\t" ";; \n\t" "(p7) mov.m ar.unat = r27 \n\t" "(p6) mov.i ar.pfs = r25 \n\t" "cmp.ne p9, p0 = r0, r29 \n\t" ";; \n\t" "(p9) ld8 r29 = [r29] \n\t" "cmp.ne p6, p0 = r0, r30 \n\t" ";; \n\t" "(p6) ld8 r30 = [r30] \n\t" /* Don't clobber p6-p9, which are in use at present. */ "mov pr = r28, ~0x3c0 \n\t" "(p9) mov.i ar.lc = r29 \n\t" ";; \n\t" "mov.m r25 = ar.rsc \n\t" "(p6) mov.m ar.fpsr = r30 \n\t" ";; \n\t" "and r29 = 0x1c, r25 \n\t" "mov b0 = r26 \n\t" ";; \n\t" "mov.m ar.rsc = r29 \n\t" ";; \n\t" /* This must be done before setting AR.BSPSTORE, otherwise AR.BSP will be initialized with a random displacement below the value we want, based on the current number of dirty stacked registers. */ "loadrs \n\t" "invala \n\t" ";; \n\t" "mov.m ar.bspstore = r23 \n\t" ";; \n\t" "mov.m ar.rnat = r22 \n\t" ";; \n\t" "mov.m ar.rsc = r25 \n\t" "mov sp = r24 \n\t" "br.ret.sptk.few b0" : : "r"(target), "r"(ireg_buf), "r"(ireg_nat), "r"(ireg_pr) : "r15", "r16", "r17", "r18", "r20", "r21", "r22", "r23", "r24", "r25", "r26", "r27", "r28", "r29", "r30", "r31"); /* NOTREACHED */ while (1); } static inline _Unwind_Ptr uw_identify_context (struct _Unwind_Context *context) { return _Unwind_GetIP (context); } #ifdef __NetBSD__ /* dummy for bootstrapping purposes */ struct unw_table_entry * _Unwind_FindTableEntry (void *pc, unw_word *segment_base, unw_word *gp, struct unw_table_entry *ent) { return NULL; } #endif #include "unwind.inc" #if defined (USE_GAS_SYMVER) && defined (SHARED) && defined (USE_LIBUNWIND_EXCEPTIONS) alias (_Unwind_Backtrace); alias (_Unwind_DeleteException); alias (_Unwind_FindEnclosingFunction); alias (_Unwind_ForcedUnwind); alias (_Unwind_GetBSP); alias (_Unwind_GetCFA); alias (_Unwind_GetGR); alias (_Unwind_GetIP); alias (_Unwind_GetLanguageSpecificData); alias (_Unwind_GetRegionStart); alias (_Unwind_RaiseException); alias (_Unwind_Resume); alias (_Unwind_Resume_or_Rethrow); alias (_Unwind_SetGR); alias (_Unwind_SetIP); #endif #endif