/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2008 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" /* * Libkvm Kernel Target Intel 64-bit component * * This file provides the ISA-dependent portion of the libkvm kernel target. * For more details on the implementation refer to mdb_kvm.c. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /*ARGSUSED*/ int kt_regs(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { mdb_amd64_printregs((const mdb_tgt_gregset_t *)addr); return (DCMD_OK); } static int kt_stack_common(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv, mdb_tgt_stack_f *func) { kt_data_t *kt = mdb.m_target->t_data; void *arg = (void *)(uintptr_t)mdb.m_nargs; mdb_tgt_gregset_t gregs, *grp; if (flags & DCMD_ADDRSPEC) { bzero(&gregs, sizeof (gregs)); gregs.kregs[KREG_RBP] = addr; grp = &gregs; } else grp = kt->k_regs; if (argc != 0) { if (argv->a_type == MDB_TYPE_CHAR || argc > 1) return (DCMD_USAGE); if (argv->a_type == MDB_TYPE_STRING) arg = (void *)mdb_strtoull(argv->a_un.a_str); else arg = (void *)argv->a_un.a_val; } (void) mdb_amd64_kvm_stack_iter(mdb.m_target, grp, func, arg); return (DCMD_OK); } int kt_stack(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { return (kt_stack_common(addr, flags, argc, argv, mdb_amd64_kvm_frame)); } int kt_stackv(uintptr_t addr, uint_t flags, int argc, const mdb_arg_t *argv) { return (kt_stack_common(addr, flags, argc, argv, mdb_amd64_kvm_framev)); } const mdb_tgt_ops_t kt_amd64_ops = { kt_setflags, /* t_setflags */ kt_setcontext, /* t_setcontext */ kt_activate, /* t_activate */ kt_deactivate, /* t_deactivate */ (void (*)()) mdb_tgt_nop, /* t_periodic */ kt_destroy, /* t_destroy */ kt_name, /* t_name */ (const char *(*)()) mdb_conf_isa, /* t_isa */ kt_platform, /* t_platform */ kt_uname, /* t_uname */ kt_dmodel, /* t_dmodel */ kt_aread, /* t_aread */ kt_awrite, /* t_awrite */ kt_vread, /* t_vread */ kt_vwrite, /* t_vwrite */ kt_pread, /* t_pread */ kt_pwrite, /* t_pwrite */ kt_fread, /* t_fread */ kt_fwrite, /* t_fwrite */ (ssize_t (*)()) mdb_tgt_notsup, /* t_ioread */ (ssize_t (*)()) mdb_tgt_notsup, /* t_iowrite */ kt_vtop, /* t_vtop */ kt_lookup_by_name, /* t_lookup_by_name */ kt_lookup_by_addr, /* t_lookup_by_addr */ kt_symbol_iter, /* t_symbol_iter */ kt_mapping_iter, /* t_mapping_iter */ kt_object_iter, /* t_object_iter */ kt_addr_to_map, /* t_addr_to_map */ kt_name_to_map, /* t_name_to_map */ kt_addr_to_ctf, /* t_addr_to_ctf */ kt_name_to_ctf, /* t_name_to_ctf */ kt_status, /* t_status */ (int (*)()) mdb_tgt_notsup, /* t_run */ (int (*)()) mdb_tgt_notsup, /* t_step */ (int (*)()) mdb_tgt_notsup, /* t_step_out */ (int (*)()) mdb_tgt_notsup, /* t_step_branch */ (int (*)()) mdb_tgt_notsup, /* t_next */ (int (*)()) mdb_tgt_notsup, /* t_cont */ (int (*)()) mdb_tgt_notsup, /* t_signal */ (int (*)()) mdb_tgt_null, /* t_add_vbrkpt */ (int (*)()) mdb_tgt_null, /* t_add_sbrkpt */ (int (*)()) mdb_tgt_null, /* t_add_pwapt */ (int (*)()) mdb_tgt_null, /* t_add_vwapt */ (int (*)()) mdb_tgt_null, /* t_add_iowapt */ (int (*)()) mdb_tgt_null, /* t_add_sysenter */ (int (*)()) mdb_tgt_null, /* t_add_sysexit */ (int (*)()) mdb_tgt_null, /* t_add_signal */ (int (*)()) mdb_tgt_null, /* t_add_fault */ kt_getareg, /* t_getareg */ kt_putareg, /* t_putareg */ mdb_amd64_kvm_stack_iter, /* t_stack_iter */ (int (*)()) mdb_tgt_notsup /* t_auxv */ }; void kt_regs_to_kregs(struct regs *regs, mdb_tgt_gregset_t *gregs) { gregs->kregs[KREG_SAVFP] = regs->r_savfp; gregs->kregs[KREG_SAVPC] = regs->r_savpc; gregs->kregs[KREG_RDI] = regs->r_rdi; gregs->kregs[KREG_RSI] = regs->r_rsi; gregs->kregs[KREG_RDX] = regs->r_rdx; gregs->kregs[KREG_RCX] = regs->r_rcx; gregs->kregs[KREG_R8] = regs->r_r8; gregs->kregs[KREG_R9] = regs->r_r9; gregs->kregs[KREG_RAX] = regs->r_rax; gregs->kregs[KREG_RBX] = regs->r_rbx; gregs->kregs[KREG_RBP] = regs->r_rbp; gregs->kregs[KREG_R10] = regs->r_r10; gregs->kregs[KREG_R11] = regs->r_r11; gregs->kregs[KREG_R12] = regs->r_r12; gregs->kregs[KREG_R13] = regs->r_r13; gregs->kregs[KREG_R14] = regs->r_r14; gregs->kregs[KREG_R15] = regs->r_r15; gregs->kregs[KREG_DS] = regs->r_ds; gregs->kregs[KREG_ES] = regs->r_es; gregs->kregs[KREG_FS] = regs->r_fs; gregs->kregs[KREG_GS] = regs->r_gs; gregs->kregs[KREG_TRAPNO] = regs->r_trapno; gregs->kregs[KREG_ERR] = regs->r_err; gregs->kregs[KREG_RIP] = regs->r_rip; gregs->kregs[KREG_CS] = regs->r_cs; gregs->kregs[KREG_RFLAGS] = regs->r_rfl; gregs->kregs[KREG_RSP] = regs->r_rsp; gregs->kregs[KREG_SS] = regs->r_ss; } void kt_amd64_init(mdb_tgt_t *t) { kt_data_t *kt = t->t_data; panic_data_t pd; struct regs regs; uintptr_t addr; /* * Initialize the machine-dependent parts of the kernel target * structure. Once this is complete and we fill in the ops * vector, the target is now fully constructed and we can use * the target API itself to perform the rest of our initialization. */ kt->k_rds = mdb_amd64_kregs; kt->k_regs = mdb_zalloc(sizeof (mdb_tgt_gregset_t), UM_SLEEP); kt->k_regsize = sizeof (mdb_tgt_gregset_t); kt->k_dcmd_regs = kt_regs; kt->k_dcmd_stack = kt_stack; kt->k_dcmd_stackv = kt_stackv; kt->k_dcmd_stackr = kt_stackv; kt->k_dcmd_cpustack = kt_cpustack; kt->k_dcmd_cpuregs = kt_cpuregs; t->t_ops = &kt_amd64_ops; (void) mdb_dis_select("amd64"); /* * Lookup the symbols corresponding to subroutines in locore.s where * we expect a saved regs structure to be pushed on the stack. When * performing stack tracebacks we will attempt to detect interrupt * frames by comparing the %eip value to these symbols. */ (void) mdb_tgt_lookup_by_name(t, MDB_TGT_OBJ_EXEC, "cmnint", &kt->k_intr_sym, NULL); (void) mdb_tgt_lookup_by_name(t, MDB_TGT_OBJ_EXEC, "cmntrap", &kt->k_trap_sym, NULL); /* * Don't attempt to load any thread or register information if * we're examining the live operating system. */ if (kt->k_symfile != NULL && strcmp(kt->k_symfile, "/dev/ksyms") == 0) return; /* * If the panicbuf symbol is present and we can consume a panicbuf * header of the appropriate version from this address, then we can * initialize our current register set based on its contents. * Prior to the re-structuring of panicbuf, our only register data * was the panic_regs label_t, into which a setjmp() was performed, * or the panic_reg register pointer, which was only non-zero if * the system panicked as a result of a trap calling die(). */ if (mdb_tgt_readsym(t, MDB_TGT_AS_VIRT, &pd, sizeof (pd), MDB_TGT_OBJ_EXEC, "panicbuf") == sizeof (pd) && pd.pd_version == PANICBUFVERS) { size_t pd_size = MIN(PANICBUFSIZE, pd.pd_msgoff); panic_data_t *pdp = mdb_zalloc(pd_size, UM_SLEEP); uint_t i, n; (void) mdb_tgt_readsym(t, MDB_TGT_AS_VIRT, pdp, pd_size, MDB_TGT_OBJ_EXEC, "panicbuf"); n = (pd_size - (sizeof (panic_data_t) - sizeof (panic_nv_t))) / sizeof (panic_nv_t); for (i = 0; i < n; i++) { (void) kt_putareg(t, kt->k_tid, pdp->pd_nvdata[i].pnv_name, pdp->pd_nvdata[i].pnv_value); } mdb_free(pdp, pd_size); return; }; if (mdb_tgt_readsym(t, MDB_TGT_AS_VIRT, &addr, sizeof (addr), MDB_TGT_OBJ_EXEC, "panic_reg") == sizeof (addr) && addr != NULL && mdb_tgt_vread(t, ®s, sizeof (regs), addr) == sizeof (regs)) { kt_regs_to_kregs(®s, kt->k_regs); return; } /* * If we can't read any panic regs, then our final try is for any CPU * context that may have been stored (for example, in Xen core dumps). */ if (kt_kvmregs(t, 0, kt->k_regs) == 0) return; warn("failed to read panicbuf and panic_reg -- " "current register set will be unavailable\n"); }