/* libunwind - a platform-independent unwind library Copyright (C) 2001-2005 Hewlett-Packard Co Contributed by David Mosberger-Tang <davidm@hpl.hp.com> This file is part of libunwind. Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ #include "offsets.h" #include "unwind_i.h" static inline int linux_sigtramp (struct cursor *c, ia64_loc_t prev_cfm_loc, unw_word_t *num_regsp) { #if defined(UNW_LOCAL_ONLY) && !defined(__linux) return -UNW_EINVAL; #else unw_word_t sc_addr; int ret; if ((ret = ia64_get (c, IA64_LOC_ADDR (c->sp + 0x10 + LINUX_SIGFRAME_ARG2_OFF, 0), &sc_addr)) < 0) return ret; c->sigcontext_addr = sc_addr; if (!IA64_IS_REG_LOC (c->loc[IA64_REG_IP]) && IA64_GET_ADDR (c->loc[IA64_REG_IP]) == sc_addr + LINUX_SC_BR_OFF + 8) { /* Linux kernels before 2.4.19 and 2.5.10 had buggy unwind info for sigtramp. Fix it up here. */ c->loc[IA64_REG_IP] = IA64_LOC_ADDR (sc_addr + LINUX_SC_IP_OFF, 0); c->cfm_loc = IA64_LOC_ADDR (sc_addr + LINUX_SC_CFM_OFF, 0); } /* do what can't be described by unwind directives: */ c->loc[IA64_REG_PFS] = IA64_LOC_ADDR (sc_addr + LINUX_SC_AR_PFS_OFF, 0); c->ec_loc = prev_cfm_loc; *num_regsp = c->cfm & 0x7f; /* size of frame */ return 0; #endif } static inline int linux_interrupt (struct cursor *c, ia64_loc_t prev_cfm_loc, unw_word_t *num_regsp, int marker) { #if defined(UNW_LOCAL_ONLY) && !(defined(__linux) && defined(__KERNEL__)) return -UNW_EINVAL; #else unw_word_t sc_addr, num_regs; ia64_loc_t pfs_loc; sc_addr = c->sigcontext_addr = c->sp + 0x10; if ((c->pr & (1UL << LINUX_PT_P_NONSYS)) != 0) num_regs = c->cfm & 0x7f; else num_regs = 0; /* do what can't be described by unwind directives: */ if (marker == ABI_MARKER_OLD_LINUX_INTERRUPT) pfs_loc = IA64_LOC_ADDR (sc_addr + LINUX_OLD_PT_PFS_OFF, 0); else pfs_loc = IA64_LOC_ADDR (sc_addr + LINUX_PT_PFS_OFF, 0); c->loc[IA64_REG_PFS] = pfs_loc; c->ec_loc = prev_cfm_loc; *num_regsp = num_regs; /* size of frame */ return 0; #endif } static inline int hpux_sigtramp (struct cursor *c, ia64_loc_t prev_cfm_loc, unw_word_t *num_regsp) { #if defined(UNW_LOCAL_ONLY) && !defined(__hpux) return -UNW_EINVAL; #else unw_word_t sc_addr, bsp, bspstore; ia64_loc_t sc_loc; int ret, i; /* HP-UX passes the address of ucontext_t in r32: */ if ((ret = ia64_get_stacked (c, 32, &sc_loc, NULL)) < 0) return ret; if ((ret = ia64_get (c, sc_loc, &sc_addr)) < 0) return ret; c->sigcontext_addr = sc_addr; /* Now mark all (preserved) registers as coming from the signal context: */ c->cfm_loc = IA64_LOC_UC_REG (UNW_IA64_CFM, sc_addr); c->loc[IA64_REG_PRI_UNAT_MEM] = IA64_NULL_LOC; c->loc[IA64_REG_PSP] = IA64_LOC_UC_REG (UNW_IA64_GR + 12, sc_addr); c->loc[IA64_REG_BSP] = IA64_LOC_UC_REG (UNW_IA64_AR_BSP, sc_addr); c->loc[IA64_REG_BSPSTORE] = IA64_LOC_UC_REG (UNW_IA64_AR_BSPSTORE, sc_addr); c->loc[IA64_REG_PFS] = IA64_LOC_UC_REG (UNW_IA64_AR_PFS, sc_addr); c->loc[IA64_REG_RNAT] = IA64_LOC_UC_REG (UNW_IA64_AR_RNAT, sc_addr); c->loc[IA64_REG_IP] = IA64_LOC_UC_REG (UNW_IA64_IP, sc_addr); c->loc[IA64_REG_R4] = IA64_LOC_UC_REG (UNW_IA64_GR + 4, sc_addr); c->loc[IA64_REG_R5] = IA64_LOC_UC_REG (UNW_IA64_GR + 5, sc_addr); c->loc[IA64_REG_R6] = IA64_LOC_UC_REG (UNW_IA64_GR + 6, sc_addr); c->loc[IA64_REG_R7] = IA64_LOC_UC_REG (UNW_IA64_GR + 7, sc_addr); c->loc[IA64_REG_NAT4] = IA64_LOC_UC_REG (UNW_IA64_NAT + 4, sc_addr); c->loc[IA64_REG_NAT5] = IA64_LOC_UC_REG (UNW_IA64_NAT + 5, sc_addr); c->loc[IA64_REG_NAT6] = IA64_LOC_UC_REG (UNW_IA64_NAT + 6, sc_addr); c->loc[IA64_REG_NAT7] = IA64_LOC_UC_REG (UNW_IA64_NAT + 7, sc_addr); c->loc[IA64_REG_UNAT] = IA64_LOC_UC_REG (UNW_IA64_AR_UNAT, sc_addr); c->loc[IA64_REG_PR] = IA64_LOC_UC_REG (UNW_IA64_PR, sc_addr); c->loc[IA64_REG_LC] = IA64_LOC_UC_REG (UNW_IA64_AR_LC, sc_addr); c->loc[IA64_REG_FPSR] = IA64_LOC_UC_REG (UNW_IA64_AR_FPSR, sc_addr); c->loc[IA64_REG_B1] = IA64_LOC_UC_REG (UNW_IA64_BR + 1, sc_addr); c->loc[IA64_REG_B2] = IA64_LOC_UC_REG (UNW_IA64_BR + 2, sc_addr); c->loc[IA64_REG_B3] = IA64_LOC_UC_REG (UNW_IA64_BR + 3, sc_addr); c->loc[IA64_REG_B4] = IA64_LOC_UC_REG (UNW_IA64_BR + 4, sc_addr); c->loc[IA64_REG_B5] = IA64_LOC_UC_REG (UNW_IA64_BR + 5, sc_addr); c->loc[IA64_REG_F2] = IA64_LOC_UC_REG (UNW_IA64_FR + 2, sc_addr); c->loc[IA64_REG_F3] = IA64_LOC_UC_REG (UNW_IA64_FR + 3, sc_addr); c->loc[IA64_REG_F4] = IA64_LOC_UC_REG (UNW_IA64_FR + 4, sc_addr); c->loc[IA64_REG_F5] = IA64_LOC_UC_REG (UNW_IA64_FR + 5, sc_addr); for (i = 0; i < 16; ++i) c->loc[IA64_REG_F16 + i] = IA64_LOC_UC_REG (UNW_IA64_FR + 16 + i, sc_addr); c->pi.flags |= UNW_PI_FLAG_IA64_RBS_SWITCH; /* update the CFM cache: */ if ((ret = ia64_get (c, c->cfm_loc, &c->cfm)) < 0) return ret; /* update the PSP cache: */ if ((ret = ia64_get (c, c->loc[IA64_REG_PSP], &c->psp)) < 0) return ret; if ((ret = ia64_get (c, c->loc[IA64_REG_BSP], &bsp)) < 0 || (ret = ia64_get (c, c->loc[IA64_REG_BSPSTORE], &bspstore)) < 0) return ret; if (bspstore < bsp) /* Dirty partition got spilled into the ucontext_t structure itself. We'll need to access it via uc_access(3). */ rbs_switch (c, bsp, bspstore, IA64_LOC_UC_ADDR (bsp | 0x1f8, 0)); c->ec_loc = prev_cfm_loc; *num_regsp = 0; return 0; #endif } static inline int check_rbs_switch (struct cursor *c) { unw_word_t saved_bsp, saved_bspstore, loadrs, ndirty; int ret = 0; saved_bsp = c->bsp; if (c->pi.flags & UNW_PI_FLAG_IA64_RBS_SWITCH) { /* Got ourselves a frame that has saved ar.bspstore, ar.bsp, and ar.rnat, so we're all set for rbs-switching: */ if ((ret = ia64_get (c, c->loc[IA64_REG_BSP], &saved_bsp)) < 0 || (ret = ia64_get (c, c->loc[IA64_REG_BSPSTORE], &saved_bspstore))) return ret; } else if ((c->abi_marker == ABI_MARKER_LINUX_SIGTRAMP || c->abi_marker == ABI_MARKER_OLD_LINUX_SIGTRAMP) && !IA64_IS_REG_LOC (c->loc[IA64_REG_BSP]) && (IA64_GET_ADDR (c->loc[IA64_REG_BSP]) == c->sigcontext_addr + LINUX_SC_AR_BSP_OFF)) { /* When Linux delivers a signal on an alternate stack, it does things a bit differently from what the unwind conventions allow us to describe: instead of saving ar.rnat, ar.bsp, and ar.bspstore, it saves the former two plus the "loadrs" value. Because of this, we need to detect & record a potential rbs-area switch manually... */ /* If ar.bsp has been saved already AND the current bsp is not equal to the saved value, then we know for sure that we're past the point where the backing store has been switched (and before the point where it's restored). */ if ((ret = ia64_get (c, IA64_LOC_ADDR (c->sigcontext_addr + LINUX_SC_AR_BSP_OFF, 0), &saved_bsp) < 0) || (ret = ia64_get (c, IA64_LOC_ADDR (c->sigcontext_addr + LINUX_SC_LOADRS_OFF, 0), &loadrs) < 0)) return ret; loadrs >>= 16; ndirty = rse_num_regs (c->bsp - loadrs, c->bsp); saved_bspstore = rse_skip_regs (saved_bsp, -ndirty); } if (saved_bsp == c->bsp) return 0; return rbs_switch (c, saved_bsp, saved_bspstore, c->loc[IA64_REG_RNAT]); } static inline int update_frame_state (struct cursor *c) { unw_word_t prev_ip, prev_sp, prev_bsp, ip, num_regs; ia64_loc_t prev_cfm_loc; int ret; prev_cfm_loc = c->cfm_loc; prev_ip = c->ip; prev_sp = c->sp; prev_bsp = c->bsp; /* Update the IP cache (do this first: if we reach the end of the frame-chain, the rest of the info may not be valid/useful anymore. */ ret = ia64_get (c, c->loc[IA64_REG_IP], &ip); if (ret < 0) return ret; c->ip = ip; if ((ip & 0xc) != 0) { /* don't let obviously bad addresses pollute the cache */ Debug (1, "rejecting bad ip=0x%lx\n", (long) c->ip); return -UNW_EINVALIDIP; } c->cfm_loc = c->loc[IA64_REG_PFS]; /* update the CFM cache: */ ret = ia64_get (c, c->cfm_loc, &c->cfm); if (ret < 0) return ret; /* Normally, AR.EC is stored in the CFM save-location. That save-location contains the full function-state as defined by AR.PFS. However, interruptions only save the frame-marker, not any other info in CFM. Instead, AR.EC gets saved on the first call by the interruption-handler. Thus, interruption-related frames need to track the _previous_ CFM save-location since that's were AR.EC is saved. We support this by setting ec_loc to cfm_loc by default and giving frames marked with an ABI-marker the chance to override this value with prev_cfm_loc. */ c->ec_loc = c->cfm_loc; num_regs = 0; if (unlikely (c->abi_marker)) { c->last_abi_marker = c->abi_marker; switch (ia64_get_abi_marker (c)) { case ABI_MARKER_LINUX_SIGTRAMP: case ABI_MARKER_OLD_LINUX_SIGTRAMP: ia64_set_abi (c, ABI_LINUX); if ((ret = linux_sigtramp (c, prev_cfm_loc, &num_regs)) < 0) return ret; break; case ABI_MARKER_OLD_LINUX_INTERRUPT: case ABI_MARKER_LINUX_INTERRUPT: ia64_set_abi (c, ABI_LINUX); if ((ret = linux_interrupt (c, prev_cfm_loc, &num_regs, c->abi_marker)) < 0) return ret; break; case ABI_MARKER_HP_UX_SIGTRAMP: ia64_set_abi (c, ABI_HPUX); if ((ret = hpux_sigtramp (c, prev_cfm_loc, &num_regs)) < 0) return ret; break; default: Debug (1, "unknown ABI marker: ABI=%u, context=%u\n", c->abi_marker >> 8, c->abi_marker & 0xff); return -UNW_EINVAL; } Debug (12, "sigcontext_addr=%lx (ret=%d)\n", (unsigned long) c->sigcontext_addr, ret); c->sigcontext_off = c->sigcontext_addr - c->sp; /* update the IP cache: */ if ((ret = ia64_get (c, c->loc[IA64_REG_IP], &ip)) < 0) return ret; c->ip = ip; if (ip == 0) /* end of frame-chain reached */ return 0; } else num_regs = (c->cfm >> 7) & 0x7f; /* size of locals */ if (!IA64_IS_NULL_LOC (c->loc[IA64_REG_BSP])) { ret = check_rbs_switch (c); if (ret < 0) return ret; } c->bsp = rse_skip_regs (c->bsp, -num_regs); c->sp = c->psp; c->abi_marker = 0; if (c->ip == prev_ip && c->sp == prev_sp && c->bsp == prev_bsp) { Dprintf ("%s: ip, sp, and bsp unchanged; stopping here (ip=0x%lx)\n", __FUNCTION__, (long) ip); return -UNW_EBADFRAME; } /* as we unwind, the saved ar.unat becomes the primary unat: */ c->loc[IA64_REG_PRI_UNAT_MEM] = c->loc[IA64_REG_UNAT]; /* restore the predicates: */ ret = ia64_get (c, c->loc[IA64_REG_PR], &c->pr); if (ret < 0) return ret; c->pi_valid = 0; return 0; } PROTECTED int unw_step (unw_cursor_t *cursor) { struct cursor *c = (struct cursor *) cursor; int ret; Debug (1, "(cursor=%p, ip=0x%016lx)\n", c, (unsigned long) c->ip); if ((ret = ia64_find_save_locs (c)) >= 0 && (ret = update_frame_state (c)) >= 0) ret = (c->ip == 0) ? 0 : 1; Debug (2, "returning %d (ip=0x%016lx)\n", ret, (unsigned long) c->ip); return ret; }