Mercurial > illumos > illumos-gate
view usr/src/cmd/mdb/common/mdb/mdb_ctf.c @ 14143:42d090a37218
3089 want ::typedef
3690 mdb on x86 should be able to print alternate register names
3688 Want mdb -e
3094 libctf should support removing a dynamic type
3095 libctf does not validate arrays correctly
3096 libctf does not validate function types correctly
3689 Want an mdb test suite driver
Reviewed by: Richard Lowe <richlowe@richlowe.net>
Reviewed by: Eric Schrock <eric.schrock@delphix.com>
Approved by: Gordon Ross <gwr@nexenta.com>
| author | Robert Mustacchi <rm@joyent.com> |
|---|---|
| date | Wed, 03 Apr 2013 15:25:37 -0700 |
| parents | 09f0146de94b |
| children |
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/* * 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 2009 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ /* * Copyright (c) 2013 by Delphix. All rights reserved. * Copyright (c) 2013, Joyent, Inc. All rights reserved. */ #include <mdb/mdb_ctf.h> #include <mdb/mdb_ctf_impl.h> #include <mdb/mdb_err.h> #include <mdb/mdb_modapi.h> #include <mdb/mdb_string.h> #include <mdb/mdb.h> #include <mdb/mdb_debug.h> #include <libctf.h> #include <string.h> typedef struct tnarg { mdb_tgt_t *tn_tgt; /* target to use for lookup */ const char *tn_name; /* query string to lookup */ ctf_file_t *tn_fp; /* CTF container from match */ ctf_id_t tn_id; /* CTF type ID from match */ } tnarg_t; typedef struct type_iter { mdb_ctf_type_f *ti_cb; void *ti_arg; ctf_file_t *ti_fp; } type_iter_t; typedef struct member_iter { mdb_ctf_member_f *mi_cb; void *mi_arg; ctf_file_t *mi_fp; } member_iter_t; typedef struct type_visit { mdb_ctf_visit_f *tv_cb; void *tv_arg; ctf_file_t *tv_fp; ulong_t tv_base_offset; /* used when recursing from type_cb() */ int tv_base_depth; /* used when recursing from type_cb() */ int tv_min_depth; } type_visit_t; typedef struct mbr_info { const char *mbr_member; ulong_t *mbr_offp; mdb_ctf_id_t *mbr_typep; } mbr_info_t; typedef struct synth_intrinsic { const char *syn_name; ctf_encoding_t syn_enc; uint_t syn_kind; } synth_intrinsic_t; typedef struct synth_typedef { const char *syt_src; const char *syt_targ; } synth_typedef_t; /* * As part of our support for synthetic types via ::typedef, we define a core * set of types. */ static const synth_intrinsic_t synth_builtins32[] = { { "void", { CTF_INT_SIGNED, 0, 0 }, CTF_K_INTEGER }, { "signed", { CTF_INT_SIGNED, 0, 32 }, CTF_K_INTEGER }, { "unsigned", { 0, 0, 32 }, CTF_K_INTEGER }, { "char", { CTF_INT_SIGNED | CTF_INT_CHAR, 0, 8 }, CTF_K_INTEGER }, { "short", { CTF_INT_SIGNED, 0, 16 }, CTF_K_INTEGER }, { "int", { CTF_INT_SIGNED, 0, 32 }, CTF_K_INTEGER }, { "long", { CTF_INT_SIGNED, 0, 32 }, CTF_K_INTEGER }, { "long long", { CTF_INT_SIGNED, 0, 64 }, CTF_K_INTEGER }, { "signed char", { CTF_INT_SIGNED | CTF_INT_CHAR, 0, 8 }, CTF_K_INTEGER }, { "signed short", { CTF_INT_SIGNED, 0, 16 }, CTF_K_INTEGER }, { "signed int", { CTF_INT_SIGNED, 0, 32 }, CTF_K_INTEGER }, { "signed long", { CTF_INT_SIGNED, 0, 32 }, CTF_K_INTEGER }, { "signed long long", { CTF_INT_SIGNED, 0, 64 }, CTF_K_INTEGER }, { "unsigned char", { CTF_INT_CHAR, 0, 8 }, CTF_K_INTEGER }, { "unsigned short", { 0, 0, 16 }, CTF_K_INTEGER }, { "unsigned int", { 0, 0, 32 }, CTF_K_INTEGER }, { "unsigned long", { 0, 0, 32 }, CTF_K_INTEGER }, { "unsigned long long", { 0, 0, 64 }, CTF_K_INTEGER }, { "_Bool", { CTF_INT_BOOL, 0, 8 }, CTF_K_INTEGER }, { "float", { CTF_FP_SINGLE, 0, 32 }, CTF_K_FLOAT }, { "double", { CTF_FP_DOUBLE, 0, 64 }, CTF_K_FLOAT }, { "long double", { CTF_FP_LDOUBLE, 0, 128 }, CTF_K_FLOAT }, { "float imaginary", { CTF_FP_IMAGRY, 0, 32 }, CTF_K_FLOAT }, { "double imaginary", { CTF_FP_DIMAGRY, 0, 64 }, CTF_K_FLOAT }, { "long double imaginary", { CTF_FP_LDIMAGRY, 0, 128 }, CTF_K_FLOAT }, { "float complex", { CTF_FP_CPLX, 0, 64 }, CTF_K_FLOAT }, { "double complex", { CTF_FP_DCPLX, 0, 128 }, CTF_K_FLOAT }, { "long double complex", { CTF_FP_LDCPLX, 0, 256 }, CTF_K_FLOAT }, { NULL, { 0, 0, 0}, 0 } }; static const synth_intrinsic_t synth_builtins64[] = { { "void", { CTF_INT_SIGNED, 0, 0 }, CTF_K_INTEGER }, { "signed", { CTF_INT_SIGNED, 0, 32 }, CTF_K_INTEGER }, { "unsigned", { 0, 0, 32 }, CTF_K_INTEGER }, { "char", { CTF_INT_SIGNED | CTF_INT_CHAR, 0, 8 }, CTF_K_INTEGER }, { "short", { CTF_INT_SIGNED, 0, 16 }, CTF_K_INTEGER }, { "int", { CTF_INT_SIGNED, 0, 32 }, CTF_K_INTEGER }, { "long", { CTF_INT_SIGNED, 0, 64 }, CTF_K_INTEGER }, { "long long", { CTF_INT_SIGNED, 0, 64 }, CTF_K_INTEGER }, { "signed char", { CTF_INT_SIGNED | CTF_INT_CHAR, 0, 8 }, CTF_K_INTEGER }, { "signed short", { CTF_INT_SIGNED, 0, 16 }, CTF_K_INTEGER }, { "signed int", { CTF_INT_SIGNED, 0, 32 }, CTF_K_INTEGER }, { "signed long", { CTF_INT_SIGNED, 0, 64 }, CTF_K_INTEGER }, { "signed long long", { CTF_INT_SIGNED, 0, 64 }, CTF_K_INTEGER }, { "unsigned char", { CTF_INT_CHAR, 0, 8 }, CTF_K_INTEGER }, { "unsigned short", { 0, 0, 16 }, CTF_K_INTEGER }, { "unsigned int", { 0, 0, 32 }, CTF_K_INTEGER }, { "unsigned long", { 0, 0, 64 }, CTF_K_INTEGER }, { "unsigned long long", { 0, 0, 64 }, CTF_K_INTEGER }, { "_Bool", { CTF_INT_BOOL, 0, 8 }, CTF_K_INTEGER }, { "float", { CTF_FP_SINGLE, 0, 32 }, CTF_K_FLOAT }, { "double", { CTF_FP_DOUBLE, 0, 64 }, CTF_K_FLOAT }, { "long double", { CTF_FP_LDOUBLE, 0, 128 }, CTF_K_FLOAT }, { "float imaginary", { CTF_FP_IMAGRY, 0, 32 }, CTF_K_FLOAT }, { "double imaginary", { CTF_FP_DIMAGRY, 0, 64 }, CTF_K_FLOAT }, { "long double imaginary", { CTF_FP_LDIMAGRY, 0, 128 }, CTF_K_FLOAT }, { "float complex", { CTF_FP_CPLX, 0, 64 }, CTF_K_FLOAT }, { "double complex", { CTF_FP_DCPLX, 0, 128 }, CTF_K_FLOAT }, { "long double complex", { CTF_FP_LDCPLX, 0, 256 }, CTF_K_FLOAT }, { NULL, { 0, 0, 0 }, 0 } }; static const synth_typedef_t synth_typedefs32[] = { { "char", "int8_t" }, { "short", "int16_t" }, { "int", "int32_t" }, { "long long", "int64_t" }, { "int", "intptr_t" }, { "unsigned char", "uint8_t" }, { "unsigned short", "uint16_t" }, { "unsigned", "uint32_t" }, { "unsigned long long", "uint64_t" }, { "unsigned char", "uchar_t" }, { "unsigned short", "ushort_t" }, { "unsigned", "uint_t" }, { "unsigned long", "ulong_t" }, { "unsigned long long", "u_longlong_t" }, { "int", "ptrdiff_t" }, { "unsigned", "uintptr_t" }, { NULL, NULL } }; static const synth_typedef_t synth_typedefs64[] = { { "char", "int8_t" }, { "short", "int16_t" }, { "int", "int32_t" }, { "long", "int64_t" }, { "long", "intptr_t" }, { "unsigned char", "uint8_t" }, { "unsigned short", "uint16_t" }, { "unsigned", "uint32_t" }, { "unsigned long", "uint64_t" }, { "unsigned char", "uchar_t" }, { "unsigned short", "ushort_t" }, { "unsigned", "uint_t" }, { "unsigned long", "ulong_t" }, { "unsigned long long", "u_longlong_t" }, { "long", "ptrdiff_t" }, { "unsigned long", "uintptr_t" }, { NULL, NULL } }; static void set_ctf_id(mdb_ctf_id_t *p, ctf_file_t *fp, ctf_id_t id) { mdb_ctf_impl_t *mcip = (mdb_ctf_impl_t *)p; mcip->mci_fp = fp; mcip->mci_id = id; } /* * Callback function for mdb_tgt_object_iter used from name_to_type, below, * to search the CTF namespace of each object file for a particular name. */ /*ARGSUSED*/ static int obj_lookup(void *data, const mdb_map_t *mp, const char *name) { tnarg_t *tnp = data; ctf_file_t *fp; ctf_id_t id; if ((fp = mdb_tgt_name_to_ctf(tnp->tn_tgt, name)) != NULL && (id = ctf_lookup_by_name(fp, tnp->tn_name)) != CTF_ERR) { tnp->tn_fp = fp; tnp->tn_id = id; /* * We may have found a forward declaration. If we did, we'll * note the ID and file pointer, but we'll keep searching in * an attempt to find the real thing. If we found something * real (i.e. not a forward), we stop the iteration. */ return (ctf_type_kind(fp, id) == CTF_K_FORWARD ? 0 : -1); } return (0); } /* * Convert a string type name with an optional leading object specifier into * the corresponding CTF file container and type ID. If an error occurs, we * print an appropriate message and return NULL. */ static ctf_file_t * name_to_type(mdb_tgt_t *t, const char *cname, ctf_id_t *idp) { const char *object = MDB_TGT_OBJ_EXEC; ctf_file_t *fp = NULL; ctf_id_t id; tnarg_t arg; char *p, *s; char buf[MDB_SYM_NAMLEN]; char *name = &buf[0]; (void) mdb_snprintf(buf, sizeof (buf), "%s", cname); if ((p = strrsplit(name, '`')) != NULL) { /* * We need to shuffle things around a little to support * type names of the form "struct module`name". */ if ((s = strsplit(name, ' ')) != NULL) { bcopy(cname + (s - name), name, (p - s) - 1); name[(p - s) - 1] = '\0'; bcopy(cname, name + (p - s), s - name); p = name + (p - s); } if (*name != '\0') object = name; name = p; } /* * Attempt to look up the name in the primary object file. If this * fails and the name was unscoped, search all remaining object files. * Finally, search the synthetic types. */ if (((fp = mdb_tgt_name_to_ctf(t, object)) == NULL || (id = ctf_lookup_by_name(fp, name)) == CTF_ERR || ctf_type_kind(fp, id) == CTF_K_FORWARD) && object == MDB_TGT_OBJ_EXEC) { arg.tn_tgt = t; arg.tn_name = name; arg.tn_fp = NULL; arg.tn_id = CTF_ERR; (void) mdb_tgt_object_iter(t, obj_lookup, &arg); if (arg.tn_id != CTF_ERR) { fp = arg.tn_fp; id = arg.tn_id; } else if (mdb.m_synth != NULL) { if ((id = ctf_lookup_by_name(mdb.m_synth, name)) != CTF_ERR) fp = mdb.m_synth; } } if (fp == NULL) return (NULL); /* errno is set for us */ if (id == CTF_ERR) { (void) set_errno(ctf_to_errno(ctf_errno(fp))); return (NULL); } *idp = id; return (fp); } /* * Check to see if there is ctf data in the given object. This is useful * so that we don't enter some loop where every call to lookup fails. */ int mdb_ctf_enabled_by_object(const char *object) { mdb_tgt_t *t = mdb.m_target; return (mdb_tgt_name_to_ctf(t, object) != NULL); } int mdb_ctf_lookup_by_name(const char *name, mdb_ctf_id_t *p) { ctf_file_t *fp = NULL; mdb_ctf_impl_t *mcip = (mdb_ctf_impl_t *)p; mdb_tgt_t *t = mdb.m_target; if (mcip == NULL) return (set_errno(EINVAL)); if ((fp = name_to_type(t, name, &mcip->mci_id)) == NULL) { mdb_ctf_type_invalidate(p); return (-1); /* errno is set for us */ } mcip->mci_fp = fp; return (0); } int mdb_ctf_lookup_by_symbol(const GElf_Sym *symp, const mdb_syminfo_t *sip, mdb_ctf_id_t *p) { ctf_file_t *fp = NULL; mdb_ctf_impl_t *mcip = (mdb_ctf_impl_t *)p; mdb_tgt_t *t = mdb.m_target; if (mcip == NULL) return (set_errno(EINVAL)); if (symp == NULL || sip == NULL) { mdb_ctf_type_invalidate(p); return (set_errno(EINVAL)); } if ((fp = mdb_tgt_addr_to_ctf(t, symp->st_value)) == NULL) { mdb_ctf_type_invalidate(p); return (-1); /* errno is set for us */ } if ((mcip->mci_id = ctf_lookup_by_symbol(fp, sip->sym_id)) == CTF_ERR) { mdb_ctf_type_invalidate(p); return (set_errno(ctf_to_errno(ctf_errno(fp)))); } mcip->mci_fp = fp; return (0); } int mdb_ctf_lookup_by_addr(uintptr_t addr, mdb_ctf_id_t *p) { GElf_Sym sym; mdb_syminfo_t si; char name[MDB_SYM_NAMLEN]; const mdb_map_t *mp; mdb_tgt_t *t = mdb.m_target; const char *obj, *c; if (p == NULL) return (set_errno(EINVAL)); if (mdb_tgt_lookup_by_addr(t, addr, MDB_TGT_SYM_EXACT, name, sizeof (name), NULL, NULL) == -1) { mdb_ctf_type_invalidate(p); return (-1); /* errno is set for us */ } if ((c = strrsplit(name, '`')) != NULL) { obj = name; } else { if ((mp = mdb_tgt_addr_to_map(t, addr)) == NULL) { mdb_ctf_type_invalidate(p); return (-1); /* errno is set for us */ } obj = mp->map_name; c = name; } if (mdb_tgt_lookup_by_name(t, obj, c, &sym, &si) == -1) { mdb_ctf_type_invalidate(p); return (-1); /* errno is set for us */ } return (mdb_ctf_lookup_by_symbol(&sym, &si, p)); } int mdb_ctf_module_lookup(const char *name, mdb_ctf_id_t *p) { ctf_file_t *fp; ctf_id_t id; mdb_module_t *mod; if ((mod = mdb_get_module()) == NULL) return (set_errno(EMDB_CTX)); if ((fp = mod->mod_ctfp) == NULL) return (set_errno(EMDB_NOCTF)); if ((id = ctf_lookup_by_name(fp, name)) == CTF_ERR) return (set_errno(ctf_to_errno(ctf_errno(fp)))); set_ctf_id(p, fp, id); return (0); } /*ARGSUSED*/ int mdb_ctf_func_info(const GElf_Sym *symp, const mdb_syminfo_t *sip, mdb_ctf_funcinfo_t *mfp) { ctf_file_t *fp = NULL; ctf_funcinfo_t f; mdb_tgt_t *t = mdb.m_target; char name[MDB_SYM_NAMLEN]; const mdb_map_t *mp; mdb_syminfo_t si; int err; if (symp == NULL || mfp == NULL) return (set_errno(EINVAL)); /* * In case the input symbol came from a merged or private symbol table, * re-lookup the address as a symbol, and then perform a fully scoped * lookup of that symbol name to get the mdb_syminfo_t for its CTF. */ if ((fp = mdb_tgt_addr_to_ctf(t, symp->st_value)) == NULL || (mp = mdb_tgt_addr_to_map(t, symp->st_value)) == NULL || mdb_tgt_lookup_by_addr(t, symp->st_value, MDB_TGT_SYM_FUZZY, name, sizeof (name), NULL, NULL) != 0) return (-1); /* errno is set for us */ if (strchr(name, '`') != NULL) err = mdb_tgt_lookup_by_scope(t, name, NULL, &si); else err = mdb_tgt_lookup_by_name(t, mp->map_name, name, NULL, &si); if (err != 0) return (-1); /* errno is set for us */ if (ctf_func_info(fp, si.sym_id, &f) == CTF_ERR) return (set_errno(ctf_to_errno(ctf_errno(fp)))); set_ctf_id(&mfp->mtf_return, fp, f.ctc_return); mfp->mtf_argc = f.ctc_argc; mfp->mtf_flags = f.ctc_flags; mfp->mtf_symidx = si.sym_id; return (0); } int mdb_ctf_func_args(const mdb_ctf_funcinfo_t *funcp, uint_t len, mdb_ctf_id_t *argv) { ctf_file_t *fp; ctf_id_t cargv[32]; int i; if (len > (sizeof (cargv) / sizeof (cargv[0]))) return (set_errno(EINVAL)); if (funcp == NULL || argv == NULL) return (set_errno(EINVAL)); fp = mdb_ctf_type_file(funcp->mtf_return); if (ctf_func_args(fp, funcp->mtf_symidx, len, cargv) == CTF_ERR) return (set_errno(ctf_to_errno(ctf_errno(fp)))); for (i = MIN(len, funcp->mtf_argc) - 1; i >= 0; i--) { set_ctf_id(&argv[i], fp, cargv[i]); } return (0); } void mdb_ctf_type_invalidate(mdb_ctf_id_t *idp) { set_ctf_id(idp, NULL, CTF_ERR); } int mdb_ctf_type_valid(mdb_ctf_id_t id) { return (((mdb_ctf_impl_t *)&id)->mci_id != CTF_ERR); } int mdb_ctf_type_cmp(mdb_ctf_id_t aid, mdb_ctf_id_t bid) { mdb_ctf_impl_t *aidp = (mdb_ctf_impl_t *)&aid; mdb_ctf_impl_t *bidp = (mdb_ctf_impl_t *)&bid; return (ctf_type_cmp(aidp->mci_fp, aidp->mci_id, bidp->mci_fp, bidp->mci_id)); } int mdb_ctf_type_resolve(mdb_ctf_id_t mid, mdb_ctf_id_t *outp) { ctf_id_t id; mdb_ctf_impl_t *idp = (mdb_ctf_impl_t *)∣ if ((id = ctf_type_resolve(idp->mci_fp, idp->mci_id)) == CTF_ERR) { if (outp) mdb_ctf_type_invalidate(outp); return (set_errno(ctf_to_errno(ctf_errno(idp->mci_fp)))); } if (ctf_type_kind(idp->mci_fp, id) == CTF_K_FORWARD) { char name[MDB_SYM_NAMLEN]; mdb_ctf_id_t lookup_id; if (ctf_type_name(idp->mci_fp, id, name, sizeof (name)) != NULL && mdb_ctf_lookup_by_name(name, &lookup_id) == 0 && outp != NULL) { *outp = lookup_id; return (0); } } if (outp != NULL) set_ctf_id(outp, idp->mci_fp, id); return (0); } char * mdb_ctf_type_name(mdb_ctf_id_t id, char *buf, size_t len) { mdb_ctf_impl_t *idp = (mdb_ctf_impl_t *)&id; char *ret; if (!mdb_ctf_type_valid(id)) { (void) set_errno(EINVAL); return (NULL); } ret = ctf_type_name(idp->mci_fp, idp->mci_id, buf, len); if (ret == NULL) (void) set_errno(ctf_to_errno(ctf_errno(idp->mci_fp))); return (ret); } ssize_t mdb_ctf_type_size(mdb_ctf_id_t id) { mdb_ctf_impl_t *idp = (mdb_ctf_impl_t *)&id; ssize_t ret; /* resolve the type in case there's a forward declaration */ if ((ret = mdb_ctf_type_resolve(id, &id)) != 0) return (ret); if ((ret = ctf_type_size(idp->mci_fp, idp->mci_id)) == CTF_ERR) return (set_errno(ctf_to_errno(ctf_errno(idp->mci_fp)))); return (ret); } int mdb_ctf_type_kind(mdb_ctf_id_t id) { mdb_ctf_impl_t *idp = (mdb_ctf_impl_t *)&id; int ret; if ((ret = ctf_type_kind(idp->mci_fp, idp->mci_id)) == CTF_ERR) return (set_errno(ctf_to_errno(ctf_errno(idp->mci_fp)))); return (ret); } int mdb_ctf_type_reference(mdb_ctf_id_t mid, mdb_ctf_id_t *outp) { mdb_ctf_impl_t *idp = (mdb_ctf_impl_t *)∣ ctf_id_t id; if ((id = ctf_type_reference(idp->mci_fp, idp->mci_id)) == CTF_ERR) { if (outp) mdb_ctf_type_invalidate(outp); return (set_errno(ctf_to_errno(ctf_errno(idp->mci_fp)))); } if (outp != NULL) set_ctf_id(outp, idp->mci_fp, id); return (0); } int mdb_ctf_type_encoding(mdb_ctf_id_t id, ctf_encoding_t *ep) { mdb_ctf_impl_t *idp = (mdb_ctf_impl_t *)&id; if (ctf_type_encoding(idp->mci_fp, idp->mci_id, ep) == CTF_ERR) return (set_errno(ctf_to_errno(ctf_errno(idp->mci_fp)))); return (0); } /* * callback proxy for mdb_ctf_type_visit */ static int type_cb(const char *name, ctf_id_t type, ulong_t off, int depth, void *arg) { type_visit_t *tvp = arg; mdb_ctf_id_t id; mdb_ctf_id_t base; mdb_ctf_impl_t *basep = (mdb_ctf_impl_t *)&base; int ret; if (depth < tvp->tv_min_depth) return (0); off += tvp->tv_base_offset; depth += tvp->tv_base_depth; set_ctf_id(&id, tvp->tv_fp, type); (void) mdb_ctf_type_resolve(id, &base); if ((ret = tvp->tv_cb(name, id, base, off, depth, tvp->tv_arg)) != 0) return (ret); /* * If the type resolves to a type in a different file, we must have * followed a forward declaration. We need to recurse into the * new type. */ if (basep->mci_fp != tvp->tv_fp && mdb_ctf_type_valid(base)) { type_visit_t tv; tv.tv_cb = tvp->tv_cb; tv.tv_arg = tvp->tv_arg; tv.tv_fp = basep->mci_fp; tv.tv_base_offset = off; tv.tv_base_depth = depth; tv.tv_min_depth = 1; /* depth = 0 has already been done */ ret = ctf_type_visit(basep->mci_fp, basep->mci_id, type_cb, &tv); } return (ret); } int mdb_ctf_type_visit(mdb_ctf_id_t id, mdb_ctf_visit_f *func, void *arg) { mdb_ctf_impl_t *idp = (mdb_ctf_impl_t *)&id; type_visit_t tv; int ret; tv.tv_cb = func; tv.tv_arg = arg; tv.tv_fp = idp->mci_fp; tv.tv_base_offset = 0; tv.tv_base_depth = 0; tv.tv_min_depth = 0; ret = ctf_type_visit(idp->mci_fp, idp->mci_id, type_cb, &tv); if (ret == CTF_ERR) return (set_errno(ctf_to_errno(ctf_errno(idp->mci_fp)))); return (ret); } int mdb_ctf_array_info(mdb_ctf_id_t id, mdb_ctf_arinfo_t *arp) { mdb_ctf_impl_t *idp = (mdb_ctf_impl_t *)&id; ctf_arinfo_t car; if (ctf_array_info(idp->mci_fp, idp->mci_id, &car) == CTF_ERR) return (set_errno(ctf_to_errno(ctf_errno(idp->mci_fp)))); set_ctf_id(&arp->mta_contents, idp->mci_fp, car.ctr_contents); set_ctf_id(&arp->mta_index, idp->mci_fp, car.ctr_index); arp->mta_nelems = car.ctr_nelems; return (0); } const char * mdb_ctf_enum_name(mdb_ctf_id_t id, int value) { mdb_ctf_impl_t *idp = (mdb_ctf_impl_t *)&id; const char *ret; /* resolve the type in case there's a forward declaration */ if (mdb_ctf_type_resolve(id, &id) != 0) return (NULL); if ((ret = ctf_enum_name(idp->mci_fp, idp->mci_id, value)) == NULL) (void) set_errno(ctf_to_errno(ctf_errno(idp->mci_fp))); return (ret); } /* * callback proxy for mdb_ctf_member_iter */ static int member_iter_cb(const char *name, ctf_id_t type, ulong_t off, void *data) { member_iter_t *mip = data; mdb_ctf_id_t id; set_ctf_id(&id, mip->mi_fp, type); return (mip->mi_cb(name, id, off, mip->mi_arg)); } int mdb_ctf_member_iter(mdb_ctf_id_t id, mdb_ctf_member_f *cb, void *data) { mdb_ctf_impl_t *idp = (mdb_ctf_impl_t *)&id; member_iter_t mi; int ret; /* resolve the type in case there's a forward declaration */ if ((ret = mdb_ctf_type_resolve(id, &id)) != 0) return (ret); mi.mi_cb = cb; mi.mi_arg = data; mi.mi_fp = idp->mci_fp; ret = ctf_member_iter(idp->mci_fp, idp->mci_id, member_iter_cb, &mi); if (ret == CTF_ERR) return (set_errno(ctf_to_errno(ctf_errno(idp->mci_fp)))); return (ret); } int mdb_ctf_enum_iter(mdb_ctf_id_t id, mdb_ctf_enum_f *cb, void *data) { mdb_ctf_impl_t *idp = (mdb_ctf_impl_t *)&id; int ret; /* resolve the type in case there's a forward declaration */ if ((ret = mdb_ctf_type_resolve(id, &id)) != 0) return (ret); return (ctf_enum_iter(idp->mci_fp, idp->mci_id, cb, data)); } /* * callback proxy for mdb_ctf_type_iter */ static int type_iter_cb(ctf_id_t type, void *data) { type_iter_t *tip = data; mdb_ctf_id_t id; set_ctf_id(&id, tip->ti_fp, type); return (tip->ti_cb(id, tip->ti_arg)); } int mdb_ctf_type_iter(const char *object, mdb_ctf_type_f *cb, void *data) { ctf_file_t *fp; mdb_tgt_t *t = mdb.m_target; int ret; type_iter_t ti; if (object == MDB_CTF_SYNTHETIC_ITER) fp = mdb.m_synth; else fp = mdb_tgt_name_to_ctf(t, object); if (fp == NULL) return (-1); ti.ti_cb = cb; ti.ti_arg = data; ti.ti_fp = fp; if ((ret = ctf_type_iter(fp, type_iter_cb, &ti)) == CTF_ERR) return (set_errno(ctf_to_errno(ctf_errno(fp)))); return (ret); } /* utility functions */ ctf_id_t mdb_ctf_type_id(mdb_ctf_id_t id) { return (((mdb_ctf_impl_t *)&id)->mci_id); } ctf_file_t * mdb_ctf_type_file(mdb_ctf_id_t id) { return (((mdb_ctf_impl_t *)&id)->mci_fp); } static int member_info_cb(const char *name, mdb_ctf_id_t id, ulong_t off, void *data) { mbr_info_t *mbrp = data; if (strcmp(name, mbrp->mbr_member) == 0) { if (mbrp->mbr_offp != NULL) *(mbrp->mbr_offp) = off; if (mbrp->mbr_typep != NULL) *(mbrp->mbr_typep) = id; return (1); } return (0); } int mdb_ctf_member_info(mdb_ctf_id_t id, const char *member, ulong_t *offp, mdb_ctf_id_t *typep) { mbr_info_t mbr; int rc; mbr.mbr_member = member; mbr.mbr_offp = offp; mbr.mbr_typep = typep; rc = mdb_ctf_member_iter(id, member_info_cb, &mbr); /* couldn't get member list */ if (rc == -1) return (-1); /* errno is set for us */ /* not a member */ if (rc == 0) return (set_errno(EMDB_CTFNOMEMB)); return (0); } /* * Returns offset in _bits_ in *retp. */ int mdb_ctf_offsetof(mdb_ctf_id_t id, const char *member, ulong_t *retp) { return (mdb_ctf_member_info(id, member, retp, NULL)); } /* * Returns offset in _bytes_, or -1 on failure. */ int mdb_ctf_offsetof_by_name(const char *type, const char *member) { mdb_ctf_id_t id; ulong_t off; if (mdb_ctf_lookup_by_name(type, &id) == -1) { mdb_warn("couldn't find type %s", type); return (-1); } if (mdb_ctf_offsetof(id, member, &off) == -1) { mdb_warn("couldn't find member %s of type %s", member, type); return (-1); } if (off % 8 != 0) { mdb_warn("member %s of type %s is an unsupported bitfield\n", member, type); return (-1); } off /= 8; return (off); } /*ARGSUSED*/ static int num_members_cb(const char *name, mdb_ctf_id_t id, ulong_t off, void *data) { int *count = data; *count = *count + 1; return (0); } int mdb_ctf_num_members(mdb_ctf_id_t id) { int count = 0; if (mdb_ctf_member_iter(id, num_members_cb, &count) != 0) return (-1); /* errno is set for us */ return (count); } typedef struct mbr_contains { char **mbc_bufp; size_t *mbc_lenp; ulong_t *mbc_offp; mdb_ctf_id_t *mbc_idp; ssize_t mbc_total; } mbr_contains_t; static int offset_to_name_cb(const char *name, mdb_ctf_id_t id, ulong_t off, void *data) { mbr_contains_t *mbc = data; ulong_t size; ctf_encoding_t e; size_t n; if (*mbc->mbc_offp < off) return (0); if (mdb_ctf_type_encoding(id, &e) == -1) size = mdb_ctf_type_size(id) * NBBY; else size = e.cte_bits; if (off + size <= *mbc->mbc_offp) return (0); n = mdb_snprintf(*mbc->mbc_bufp, *mbc->mbc_lenp, "%s", name); mbc->mbc_total += n; if (n > *mbc->mbc_lenp) n = *mbc->mbc_lenp; *mbc->mbc_lenp -= n; *mbc->mbc_bufp += n; *mbc->mbc_offp -= off; *mbc->mbc_idp = id; return (1); } ssize_t mdb_ctf_offset_to_name(mdb_ctf_id_t id, ulong_t off, char *buf, size_t len, int dot, mdb_ctf_id_t *midp, ulong_t *moffp) { size_t size; size_t n; mbr_contains_t mbc; if (!mdb_ctf_type_valid(id)) return (set_errno(EINVAL)); /* * Quick sanity check to make sure the given offset is within * this scope of this type. */ if (mdb_ctf_type_size(id) * NBBY <= off) return (set_errno(EINVAL)); mbc.mbc_bufp = &buf; mbc.mbc_lenp = &len; mbc.mbc_offp = &off; mbc.mbc_idp = &id; mbc.mbc_total = 0; *buf = '\0'; for (;;) { /* * Check for an exact match. */ if (off == 0) break; (void) mdb_ctf_type_resolve(id, &id); /* * Find the member that contains this offset. */ switch (mdb_ctf_type_kind(id)) { case CTF_K_ARRAY: { mdb_ctf_arinfo_t ar; uint_t index; (void) mdb_ctf_array_info(id, &ar); size = mdb_ctf_type_size(ar.mta_contents) * NBBY; index = off / size; id = ar.mta_contents; off %= size; n = mdb_snprintf(buf, len, "[%u]", index); mbc.mbc_total += n; if (n > len) n = len; buf += n; len -= n; break; } case CTF_K_STRUCT: { int ret; /* * Find the member that contains this offset * and continue. */ if (dot) { mbc.mbc_total++; if (len != 0) { *buf++ = '.'; *buf = '\0'; len--; } } ret = mdb_ctf_member_iter(id, offset_to_name_cb, &mbc); if (ret == -1) return (-1); /* errno is set for us */ /* * If we did not find a member containing this offset * (due to holes in the structure), return EINVAL. */ if (ret == 0) return (set_errno(EINVAL)); break; } case CTF_K_UNION: /* * Treat unions like atomic entities since we can't * do more than guess which member of the union * might be the intended one. */ goto done; case CTF_K_INTEGER: case CTF_K_FLOAT: case CTF_K_POINTER: case CTF_K_ENUM: goto done; default: return (set_errno(EINVAL)); } dot = 1; } done: if (midp != NULL) *midp = id; if (moffp != NULL) *moffp = off; return (mbc.mbc_total); } static void mdb_ctf_warn(uint_t flags, const char *format, ...) { va_list alist; if (flags & MDB_CTF_VREAD_QUIET) return; va_start(alist, format); vwarn(format, alist); va_end(alist); } /* * Check if two types are structurally the same rather than logically * the same. That is to say that two types are equal if they have the * same logical structure rather than having the same ids in CTF-land. */ static int type_equals(mdb_ctf_id_t, mdb_ctf_id_t); static int type_equals_cb(const char *name, mdb_ctf_id_t amem, ulong_t aoff, void *data) { mdb_ctf_id_t b = *(mdb_ctf_id_t *)data; ulong_t boff; mdb_ctf_id_t bmem; /* * Look up the corresponding member in the other composite type. */ if (mdb_ctf_member_info(b, name, &boff, &bmem) != 0) return (1); /* * We don't allow members to be shuffled around. */ if (aoff != boff) return (1); return (type_equals(amem, bmem) ? 0 : 1); } static int type_equals(mdb_ctf_id_t a, mdb_ctf_id_t b) { size_t asz, bsz; int akind, bkind; mdb_ctf_arinfo_t aar, bar; /* * Resolve both types down to their fundamental types, and make * sure their sizes and kinds match. */ if (mdb_ctf_type_resolve(a, &a) != 0 || mdb_ctf_type_resolve(b, &b) != 0 || (asz = mdb_ctf_type_size(a)) == -1UL || (bsz = mdb_ctf_type_size(b)) == -1UL || (akind = mdb_ctf_type_kind(a)) == -1 || (bkind = mdb_ctf_type_kind(b)) == -1 || asz != bsz || akind != bkind) { return (0); } switch (akind) { case CTF_K_INTEGER: case CTF_K_FLOAT: case CTF_K_POINTER: /* * For pointers we could be a little stricter and require * both pointers to reference types which look vaguely * similar (for example, we could insist that the two types * have the same name). However, all we really care about * here is that the structure of the two types are the same, * and, in that regard, one pointer is as good as another. */ return (1); case CTF_K_UNION: case CTF_K_STRUCT: /* * The test for the number of members is only strictly * necessary for unions since we'll find other problems with * structs. However, the extra check will do no harm. */ return (mdb_ctf_num_members(a) == mdb_ctf_num_members(b) && mdb_ctf_member_iter(a, type_equals_cb, &b) == 0); case CTF_K_ARRAY: return (mdb_ctf_array_info(a, &aar) == 0 && mdb_ctf_array_info(b, &bar) == 0 && aar.mta_nelems == bar.mta_nelems && type_equals(aar.mta_index, bar.mta_index) && type_equals(aar.mta_contents, bar.mta_contents)); } return (0); } typedef struct member { char *m_modbuf; char *m_tgtbuf; const char *m_tgtname; mdb_ctf_id_t m_tgtid; uint_t m_flags; } member_t; static int vread_helper(mdb_ctf_id_t, char *, mdb_ctf_id_t, char *, const char *, uint_t); static int member_cb(const char *name, mdb_ctf_id_t modmid, ulong_t modoff, void *data) { member_t *mp = data; char *modbuf = mp->m_modbuf; mdb_ctf_id_t tgtmid; char *tgtbuf = mp->m_tgtbuf; ulong_t tgtoff; char tgtname[128]; (void) mdb_snprintf(tgtname, sizeof (tgtname), "member %s of type %s", name, mp->m_tgtname); if (mdb_ctf_member_info(mp->m_tgtid, name, &tgtoff, &tgtmid) != 0) { mdb_ctf_warn(mp->m_flags, "could not find %s\n", tgtname); return (set_errno(EMDB_CTFNOMEMB)); } return (vread_helper(modmid, modbuf + modoff / NBBY, tgtmid, tgtbuf + tgtoff / NBBY, tgtname, mp->m_flags)); } typedef struct enum_value { int *ev_modbuf; const char *ev_name; } enum_value_t; static int enum_cb(const char *name, int value, void *data) { enum_value_t *ev = data; if (strcmp(name, ev->ev_name) == 0) { *ev->ev_modbuf = value; return (1); } return (0); } static int vread_helper(mdb_ctf_id_t modid, char *modbuf, mdb_ctf_id_t tgtid, char *tgtbuf, const char *tgtname, uint_t flags) { size_t modsz, tgtsz; int modkind, tgtkind; member_t mbr; enum_value_t ev; int ret; mdb_ctf_arinfo_t tar, mar; int i; char typename[128]; char mdbtypename[128]; ctf_encoding_t tgt_encoding, mod_encoding; boolean_t signed_int = B_FALSE; if (mdb_ctf_type_name(tgtid, typename, sizeof (typename)) == NULL) { (void) mdb_snprintf(typename, sizeof (typename), "#%ul", mdb_ctf_type_id(tgtid)); } if (mdb_ctf_type_name(modid, mdbtypename, sizeof (mdbtypename)) == NULL) { (void) mdb_snprintf(mdbtypename, sizeof (mdbtypename), "#%ul", mdb_ctf_type_id(modid)); } if (tgtname == NULL) tgtname = ""; /* * Resolve the types to their canonical form. */ (void) mdb_ctf_type_resolve(modid, &modid); (void) mdb_ctf_type_resolve(tgtid, &tgtid); if ((modkind = mdb_ctf_type_kind(modid)) == -1) { mdb_ctf_warn(flags, "couldn't determine type kind of mdb module type %s\n", mdbtypename); return (-1); /* errno is set for us */ } if ((tgtkind = mdb_ctf_type_kind(tgtid)) == -1) { mdb_ctf_warn(flags, "couldn't determine type kind of %s\n", typename); return (-1); /* errno is set for us */ } if ((modsz = mdb_ctf_type_size(modid)) == -1UL) { mdb_ctf_warn(flags, "couldn't determine type size of " "mdb module type %s\n", mdbtypename); return (-1); /* errno is set for us */ } if ((tgtsz = mdb_ctf_type_size(tgtid)) == -1UL) { mdb_ctf_warn(flags, "couldn't determine size of %s (%s)\n", typename, tgtname); return (-1); /* errno is set for us */ } if (tgtkind == CTF_K_POINTER && modkind == CTF_K_INTEGER && strcmp(mdbtypename, "uintptr_t") == 0) { /* allow them to convert a pointer to a uintptr_t */ ASSERT(modsz == tgtsz); } else if (tgtkind != modkind) { mdb_ctf_warn(flags, "unexpected kind for type %s (%s)\n", typename, tgtname); return (set_errno(EMDB_INCOMPAT)); } switch (tgtkind) { case CTF_K_INTEGER: case CTF_K_FLOAT: /* * Must determine if the target and module types have the same * encoding before we can copy them. */ if (mdb_ctf_type_encoding(tgtid, &tgt_encoding) != 0) { mdb_ctf_warn(flags, "couldn't determine encoding of type %s (%s)\n", typename, tgtname); return (-1); /* errno is set for us */ } if (mdb_ctf_type_encoding(modid, &mod_encoding) != 0) { mdb_ctf_warn(flags, "couldn't determine encoding of " "mdb module type %s\n", mdbtypename); return (-1); /* errno is set for us */ } if (modkind == CTF_K_INTEGER) { if ((tgt_encoding.cte_format & CTF_INT_SIGNED) != (mod_encoding.cte_format & CTF_INT_SIGNED)) { mdb_ctf_warn(flags, "signedness mismatch between type " "%s (%s) and mdb module type %s\n", typename, tgtname, mdbtypename); return (set_errno(EMDB_INCOMPAT)); } signed_int = ((tgt_encoding.cte_format & CTF_INT_SIGNED) != 0); } else if (tgt_encoding.cte_format != mod_encoding.cte_format) { mdb_ctf_warn(flags, "encoding mismatch (%#x != %#x) between type " "%s (%s) and mdb module type %s\n", tgt_encoding.cte_format, mod_encoding.cte_format, typename, tgtname, mdbtypename); return (set_errno(EMDB_INCOMPAT)); } /* FALLTHROUGH */ case CTF_K_POINTER: /* * If the sizes don't match we need to be tricky to make * sure that the caller gets the correct data. */ if (modsz < tgtsz) { mdb_ctf_warn(flags, "size of type %s (%s) is too " "large for mdb module type %s\n", typename, tgtname, mdbtypename); return (set_errno(EMDB_INCOMPAT)); } else if (modsz > tgtsz) { /* BEGIN CSTYLED */ /* * Fill modbuf with 1's for sign extension if target * buf is a signed integer and its value is negative. * * S = sign bit (in most-significant byte) * * BIG ENDIAN DATA * +--------+--------+--------+--------+ * |S | | | | * +--------+--------+--------+--------+ * 0 1 ... sz-1 sz * * LITTLE ENDIAN DATA * +--------+--------+--------+--------+ * | | | |S | * +--------+--------+--------+--------+ * 0 1 ... sz-1 sz */ /* END CSTYLED */ #ifdef _BIG_ENDIAN if (signed_int && (tgtbuf[0] & 0x80) != 0) #else if (signed_int && (tgtbuf[tgtsz - 1] & 0x80) != 0) #endif (void) memset(modbuf, 0xFF, modsz); else bzero(modbuf, modsz); #ifdef _BIG_ENDIAN bcopy(tgtbuf, modbuf + modsz - tgtsz, tgtsz); #else bcopy(tgtbuf, modbuf, tgtsz); #endif } else { bcopy(tgtbuf, modbuf, modsz); } return (0); case CTF_K_ENUM: if (modsz != tgtsz || modsz != sizeof (int)) { mdb_ctf_warn(flags, "unexpected size of type %s (%s)\n", typename, tgtname); return (set_errno(EMDB_INCOMPAT)); } /* * Default to the same value as in the target. */ bcopy(tgtbuf, modbuf, sizeof (int)); /* LINTED */ i = *(int *)tgtbuf; /* LINTED */ ev.ev_modbuf = (int *)modbuf; ev.ev_name = mdb_ctf_enum_name(tgtid, i); if (ev.ev_name == NULL) { mdb_ctf_warn(flags, "unexpected value %u of enum type %s (%s)\n", i, typename, tgtname); return (set_errno(EMDB_INCOMPAT)); } ret = mdb_ctf_enum_iter(modid, enum_cb, &ev); if (ret == 0) { /* value not found */ mdb_ctf_warn(flags, "unexpected value %s (%u) of enum type %s (%s)\n", ev.ev_name, i, typename, tgtname); return (set_errno(EMDB_INCOMPAT)); } else if (ret == 1) { /* value found */ return (0); } else if (ret == -1) { mdb_ctf_warn(flags, "could not iterate enum %s (%s)\n", typename, tgtname); } return (ret); case CTF_K_STRUCT: mbr.m_modbuf = modbuf; mbr.m_tgtbuf = tgtbuf; mbr.m_tgtid = tgtid; mbr.m_flags = flags; mbr.m_tgtname = typename; return (mdb_ctf_member_iter(modid, member_cb, &mbr)); case CTF_K_UNION: /* * Unions are a little tricky. The only time it's truly * safe to read in a union is if no part of the union or * any of its component types have changed. The correct * use of this feature is to read the containing structure, * figure out which component of the union is valid, compute * the location of that in the target and then read in * that part of the structure. */ if (!type_equals(modid, tgtid)) { mdb_ctf_warn(flags, "inexact match for union %s (%s)\n", typename, tgtname); return (set_errno(EMDB_INCOMPAT)); } ASSERT(modsz == tgtsz); bcopy(tgtbuf, modbuf, modsz); return (0); case CTF_K_ARRAY: if (mdb_ctf_array_info(tgtid, &tar) != 0) { mdb_ctf_warn(flags, "couldn't get array info for %s (%s)\n", typename, tgtname); return (-1); /* errno is set for us */ } if (mdb_ctf_array_info(modid, &mar) != 0) { mdb_ctf_warn(flags, "couldn't get array info for mdb module type %s\n", mdbtypename); return (-1); /* errno is set for us */ } if (tar.mta_nelems != mar.mta_nelems) { mdb_ctf_warn(flags, "unexpected array size (%u) for type %s (%s)\n", tar.mta_nelems, typename, tgtname); return (set_errno(EMDB_INCOMPAT)); } if ((modsz = mdb_ctf_type_size(mar.mta_contents)) == -1UL) { mdb_ctf_warn(flags, "couldn't determine type size of " "mdb module type %s\n", mdbtypename); return (-1); /* errno is set for us */ } if ((tgtsz = mdb_ctf_type_size(tar.mta_contents)) == -1UL) { mdb_ctf_warn(flags, "couldn't determine size of %s (%s)\n", typename, tgtname); return (-1); /* errno is set for us */ } for (i = 0; i < tar.mta_nelems; i++) { ret = vread_helper(mar.mta_contents, modbuf + i * modsz, tar.mta_contents, tgtbuf + i * tgtsz, tgtname, flags); if (ret != 0) return (ret); } return (0); } mdb_ctf_warn(flags, "unsupported kind %d for type %s (%s)\n", modkind, typename, tgtname); return (set_errno(EMDB_INCOMPAT)); } /* * Like mdb_vread(), mdb_ctf_vread() is used to read from the target's * virtual address space. However, mdb_ctf_vread() can be used to safely * read a complex type (e.g. a struct) from the target, even if MDB was compiled * against a different definition of that type (e.g. when debugging a crash * dump from an older release). * * Callers can achieve this by defining their own type which corresponds to the * type in the target, but contains only the members that the caller requires. * Using the CTF type information embedded in the target, mdb_ctf_vread will * find the required members in the target and fill in the caller's structure. * The members are located by name, and their types are verified to be * compatible. * * By convention, the caller will declare a type with the name "mdb_<type>", * where <type> is the name of the type in the target (e.g. mdb_zio_t). This * type will contain the members that the caller is interested in. For example: * * typedef struct mdb_zio { * enum zio_type io_type; * void *io_waiter; * struct { * struct { * void *list_next; * } list_head; * } io_parent_list; * int io_error; * } mdb_zio_t; * * mdb_zio_t zio; * error = mdb_ctf_vread(&zio, "zio_t", "mdb_zio_t", zio_target_addr, 0); * * If a given MDB module has different dcmds or walkers that need to read * different members from the same struct, then different "mdb_" types * should be declared for each caller. By convention, these types should * be named "mdb_<dcmd or walker>_<type>", e.g. mdb_findstack_kthread_t * for ::findstack. If the MDB module is compiled from several source files, * one must be especially careful to not define different types with the * same name in different source files, because the compiler can not detect * this error. * * Enums will also be translated by name, so the mdb module will receive * the enum value it expects even if the target has renumbered the enum. * Warning: it will therefore only work with enums are only used to store * legitimate enum values (not several values or-ed together). * * By default, if mdb_ctf_vread() can not find any members or enum values, * it will print a descriptive message (with mdb_warn()) and fail. * Passing MDB_CTF_VREAD_QUIET in 'flags' will suppress the warning message. * Additional flags can be used to ignore specific types of translation * failure, but should be used with caution, because they will silently leave * the caller's buffer uninitialized. */ int mdb_ctf_vread(void *modbuf, const char *target_typename, const char *mdb_typename, uintptr_t addr, uint_t flags) { ctf_file_t *mfp; ctf_id_t mid; void *tgtbuf; size_t size; mdb_ctf_id_t tgtid; mdb_ctf_id_t modid; mdb_module_t *mod; if ((mod = mdb_get_module()) == NULL || (mfp = mod->mod_ctfp) == NULL) { mdb_ctf_warn(flags, "no ctf data found for mdb module %s\n", mod->mod_name); return (set_errno(EMDB_NOCTF)); } if ((mid = ctf_lookup_by_name(mfp, mdb_typename)) == CTF_ERR) { mdb_ctf_warn(flags, "couldn't find ctf data for " "type %s in mdb module %s\n", mdb_typename, mod->mod_name); return (set_errno(ctf_to_errno(ctf_errno(mfp)))); } set_ctf_id(&modid, mfp, mid); if (mdb_ctf_lookup_by_name(target_typename, &tgtid) != 0) { mdb_ctf_warn(flags, "couldn't find type %s in target's ctf data\n", target_typename); return (set_errno(EMDB_NOCTF)); } /* * Read the data out of the target's address space. */ if ((size = mdb_ctf_type_size(tgtid)) == -1UL) { mdb_ctf_warn(flags, "couldn't determine size of type %s\n", target_typename); return (-1); /* errno is set for us */ } tgtbuf = mdb_alloc(size, UM_SLEEP | UM_GC); if (mdb_vread(tgtbuf, size, addr) < 0) { mdb_ctf_warn(flags, "couldn't read %s from %p\n", target_typename, addr); return (-1); /* errno is set for us */ } return (vread_helper(modid, modbuf, tgtid, tgtbuf, NULL, flags)); } /* * Note: mdb_ctf_readsym() doesn't take separate parameters for the name * of the target's type vs the mdb module's type. Use with complicated * types (e.g. structs) may result in unnecessary failure if a member of * the struct has been changed in the target, but is not actually needed * by the mdb module. Use mdb_lookup_by_name() + mdb_ctf_vread() to * avoid this problem. */ int mdb_ctf_readsym(void *buf, const char *typename, const char *name, uint_t flags) { GElf_Sym sym; if (mdb_lookup_by_obj(MDB_TGT_OBJ_EVERY, name, &sym) != 0) { mdb_ctf_warn(flags, "couldn't find symbol %s\n", name); return (-1); /* errno is set for us */ } return (mdb_ctf_vread(buf, typename, typename, sym.st_value, flags)); } ctf_file_t * mdb_ctf_bufopen(const void *ctf_va, size_t ctf_size, const void *sym_va, Shdr *symhdr, const void *str_va, Shdr *strhdr, int *errp) { ctf_sect_t ctdata, symtab, strtab; ctdata.cts_name = ".SUNW_ctf"; ctdata.cts_type = SHT_PROGBITS; ctdata.cts_flags = 0; ctdata.cts_data = ctf_va; ctdata.cts_size = ctf_size; ctdata.cts_entsize = 1; ctdata.cts_offset = 0; symtab.cts_name = ".symtab"; symtab.cts_type = symhdr->sh_type; symtab.cts_flags = symhdr->sh_flags; symtab.cts_data = sym_va; symtab.cts_size = symhdr->sh_size; symtab.cts_entsize = symhdr->sh_entsize; symtab.cts_offset = symhdr->sh_offset; strtab.cts_name = ".strtab"; strtab.cts_type = strhdr->sh_type; strtab.cts_flags = strhdr->sh_flags; strtab.cts_data = str_va; strtab.cts_size = strhdr->sh_size; strtab.cts_entsize = strhdr->sh_entsize; strtab.cts_offset = strhdr->sh_offset; return (ctf_bufopen(&ctdata, &symtab, &strtab, errp)); } int mdb_ctf_synthetics_init(void) { int err; if ((mdb.m_synth = ctf_create(&err)) == NULL) return (set_errno(ctf_to_errno(err))); return (0); } void mdb_ctf_synthetics_fini(void) { if (mdb.m_synth == NULL) return; ctf_close(mdb.m_synth); mdb.m_synth = NULL; } int mdb_ctf_synthetics_create_base(int kind) { const synth_intrinsic_t *synp; const synth_typedef_t *sytp; int err; ctf_id_t id; ctf_file_t *cp = mdb.m_synth; if (mdb.m_synth == NULL) { mdb_printf("synthetic types disabled: ctf create failed\n"); return (1); } switch (kind) { case SYNTHETIC_ILP32: synp = synth_builtins32; sytp = synth_typedefs32; break; case SYNTHETIC_LP64: synp = synth_builtins64; sytp = synth_typedefs64; break; default: mdb_dprintf(MDB_DBG_CTF, "invalid type of intrinsic: %d\n", kind); return (1); } err = 0; for (; synp->syn_name != NULL; synp++) { if (synp->syn_kind == CTF_K_INTEGER) { err = ctf_add_integer(cp, CTF_ADD_ROOT, synp->syn_name, &synp->syn_enc); } else { err = ctf_add_float(cp, CTF_ADD_ROOT, synp->syn_name, &synp->syn_enc); } if (err == CTF_ERR) { mdb_dprintf(MDB_DBG_CTF, "couldn't add synthetic " "type: %s\n", synp->syn_name); goto discard; } } if (ctf_update(cp) == CTF_ERR) { mdb_dprintf(MDB_DBG_CTF, "failed to update synthetic types\n"); goto discard; } for (; sytp->syt_src != NULL; sytp++) { id = ctf_lookup_by_name(cp, sytp->syt_src); if (id == CTF_ERR) { mdb_dprintf(MDB_DBG_CTF, "cailed to lookup %s: %s\n", sytp->syt_src, ctf_errmsg(ctf_errno(cp))); goto discard; } if (ctf_add_typedef(cp, CTF_ADD_ROOT, sytp->syt_targ, id) == CTF_ERR) { mdb_dprintf(MDB_DBG_CTF, "couldn't add typedef %s " "%s: %s\n", sytp->syt_targ, sytp->syt_src, ctf_errmsg(ctf_errno(cp))); goto discard; } } if (ctf_update(cp) == CTF_ERR) { mdb_dprintf(MDB_DBG_CTF, "failed to update synthetic types\n"); goto discard; } return (0); discard: err = set_errno(ctf_to_errno(ctf_errno(cp))); (void) ctf_discard(cp); return (err); } int mdb_ctf_synthetics_reset(void) { mdb_ctf_synthetics_fini(); return (mdb_ctf_synthetics_init()); } int mdb_ctf_add_typedef(const char *name, const mdb_ctf_id_t *p, mdb_ctf_id_t *new) { ctf_id_t rid; mdb_ctf_id_t tid; mdb_ctf_impl_t *mcip = (mdb_ctf_impl_t *)p; if (mdb.m_synth == NULL) { mdb_printf("synthetic types disabled: ctf create failed\n"); return (1); } if (mdb_ctf_lookup_by_name(name, &tid) == 0) { mdb_dprintf(MDB_DBG_CTF, "failed to add type %s: a type " "with that name already exists\n", name); return (set_errno(EEXIST)); } rid = ctf_add_type(mdb.m_synth, mcip->mci_fp, mcip->mci_id); if (rid == CTF_ERR) { mdb_dprintf(MDB_DBG_CTF, "failed to add reference type: %s\n", ctf_errmsg(ctf_errno(mdb.m_synth))); return (set_errno(ctf_to_errno(ctf_errno(mdb.m_synth)))); } rid = ctf_add_typedef(mdb.m_synth, CTF_ADD_ROOT, name, rid); if (rid == CTF_ERR) { mdb_dprintf(MDB_DBG_CTF, "failed to add typedef: %s", ctf_errmsg(ctf_errno(mdb.m_synth))); return (set_errno(ctf_to_errno(ctf_errno(mdb.m_synth)))); } if (ctf_update(mdb.m_synth) == CTF_ERR) { mdb_dprintf(MDB_DBG_CTF, "failed to update synthetic types: %s", ctf_errmsg(ctf_errno(mdb.m_synth))); return (set_errno(ctf_to_errno(ctf_errno(mdb.m_synth)))); } if (new != NULL) set_ctf_id(new, mdb.m_synth, rid); return (0); } int mdb_ctf_add_struct(const char *name, mdb_ctf_id_t *rid) { mdb_ctf_id_t tid; ctf_id_t id; if (mdb.m_synth == NULL) { mdb_printf("synthetic types disabled: ctf create failed\n"); return (1); } if (name != NULL && mdb_ctf_lookup_by_name(name, &tid) == 0) { mdb_dprintf(MDB_DBG_CTF, "failed to add type %s: a type " "with that name already exists\n", name); return (set_errno(EEXIST)); } if ((id = ctf_add_struct(mdb.m_synth, CTF_ADD_ROOT, name)) == CTF_ERR) { mdb_dprintf(MDB_DBG_CTF, "failed to add struct: %s\n", ctf_errmsg(ctf_errno(mdb.m_synth))); return (set_errno(ctf_to_errno(ctf_errno(mdb.m_synth)))); } if (ctf_update(mdb.m_synth) == CTF_ERR) { mdb_dprintf(MDB_DBG_CTF, "failed to update synthetic types: %s", ctf_errmsg(ctf_errno(mdb.m_synth))); return (set_errno(ctf_to_errno(ctf_errno(mdb.m_synth)))); } if (rid != NULL) set_ctf_id(rid, mdb.m_synth, id); return (0); } int mdb_ctf_add_union(const char *name, mdb_ctf_id_t *rid) { mdb_ctf_id_t tid; ctf_id_t id; if (mdb.m_synth == NULL) { mdb_printf("synthetic types disabled: ctf create failed\n"); return (1); } if (name != NULL && mdb_ctf_lookup_by_name(name, &tid) == 0) { mdb_dprintf(MDB_DBG_CTF, "failed to add type %s: a type " "with that name already exists\n", name); return (set_errno(EEXIST)); } if ((id = ctf_add_union(mdb.m_synth, CTF_ADD_ROOT, name)) == CTF_ERR) { mdb_dprintf(MDB_DBG_CTF, "failed to add union: %s\n", ctf_errmsg(ctf_errno(mdb.m_synth))); return (set_errno(ctf_to_errno(ctf_errno(mdb.m_synth)))); } if (ctf_update(mdb.m_synth) == CTF_ERR) { mdb_dprintf(MDB_DBG_CTF, "failed to update synthetic types: %s", ctf_errmsg(ctf_errno(mdb.m_synth))); return (set_errno(ctf_to_errno(ctf_errno(mdb.m_synth)))); } if (rid != NULL) set_ctf_id(rid, mdb.m_synth, id); return (0); } int mdb_ctf_add_member(const mdb_ctf_id_t *p, const char *name, const mdb_ctf_id_t *mtype, mdb_ctf_id_t *rid) { ctf_id_t id, mtid; mdb_ctf_impl_t *mcip = (mdb_ctf_impl_t *)p; mdb_ctf_impl_t *mcim = (mdb_ctf_impl_t *)mtype; if (mdb.m_synth == NULL) { mdb_printf("synthetic types disabled: ctf create failed\n"); return (DCMD_ERR); } if (mcip->mci_fp != mdb.m_synth) { mdb_dprintf(MDB_DBG_CTF, "requested to add member to a type " "that wasn't created from a synthetic\n"); return (set_errno(EINVAL)); } mtid = ctf_add_type(mdb.m_synth, mcim->mci_fp, mcim->mci_id); if (mtid == CTF_ERR) { mdb_dprintf(MDB_DBG_CTF, "failed to add member type: %s\n", ctf_errmsg(ctf_errno(mdb.m_synth))); return (set_errno(ctf_to_errno(ctf_errno(mdb.m_synth)))); } if (ctf_update(mdb.m_synth) == CTF_ERR) { mdb_dprintf(MDB_DBG_CTF, "failed to update synthetic types: %s", ctf_errmsg(ctf_errno(mdb.m_synth))); return (set_errno(ctf_to_errno(ctf_errno(mdb.m_synth)))); } id = ctf_add_member(mdb.m_synth, mcip->mci_id, name, mtid); if (id == CTF_ERR) { mdb_dprintf(MDB_DBG_CTF, "failed to add member %s: %s\n", name, ctf_errmsg(ctf_errno(mdb.m_synth))); return (set_errno(ctf_to_errno(ctf_errno(mdb.m_synth)))); } if (ctf_update(mdb.m_synth) == CTF_ERR) { mdb_dprintf(MDB_DBG_CTF, "failed to update synthetic types: %s", ctf_errmsg(ctf_errno(mdb.m_synth))); return (set_errno(ctf_to_errno(ctf_errno(mdb.m_synth)))); } if (rid != NULL) set_ctf_id(rid, mdb.m_synth, id); return (0); } int mdb_ctf_add_array(const mdb_ctf_arinfo_t *marp, mdb_ctf_id_t *rid) { mdb_ctf_impl_t *mcip; ctf_arinfo_t car; ctf_id_t id; if (mdb.m_synth == NULL) { mdb_printf("synthetic types disabled: ctf create failed\n"); return (1); } car.ctr_nelems = marp->mta_nelems; mcip = (mdb_ctf_impl_t *)&marp->mta_contents; id = ctf_add_type(mdb.m_synth, mcip->mci_fp, mcip->mci_id); if (id == CTF_ERR) { mdb_dprintf(MDB_DBG_CTF, "failed to add member type: %s\n", ctf_errmsg(ctf_errno(mdb.m_synth))); return (set_errno(ctf_to_errno(ctf_errno(mdb.m_synth)))); } car.ctr_contents = id; mcip = (mdb_ctf_impl_t *)&marp->mta_index; id = ctf_add_type(mdb.m_synth, mcip->mci_fp, mcip->mci_id); if (id == CTF_ERR) { mdb_dprintf(MDB_DBG_CTF, "failed to add member type: %s\n", ctf_errmsg(ctf_errno(mdb.m_synth))); return (set_errno(ctf_to_errno(ctf_errno(mdb.m_synth)))); } car.ctr_index = id; if (ctf_update(mdb.m_synth) == CTF_ERR) { mdb_dprintf(MDB_DBG_CTF, "failed to update synthetic types: %s", ctf_errmsg(ctf_errno(mdb.m_synth))); return (set_errno(ctf_to_errno(ctf_errno(mdb.m_synth)))); } id = ctf_add_array(mdb.m_synth, CTF_ADD_ROOT, &car); if (id == CTF_ERR) { mdb_dprintf(MDB_DBG_CTF, "failed to update synthetic types: %s", ctf_errmsg(ctf_errno(mdb.m_synth))); return (set_errno(ctf_to_errno(ctf_errno(mdb.m_synth)))); } if (ctf_update(mdb.m_synth) == CTF_ERR) { mdb_dprintf(MDB_DBG_CTF, "failed to update synthetic types: %s", ctf_errmsg(ctf_errno(mdb.m_synth))); return (set_errno(ctf_to_errno(ctf_errno(mdb.m_synth)))); } if (rid != NULL) set_ctf_id(rid, mdb.m_synth, id); return (0); } int mdb_ctf_add_pointer(const mdb_ctf_id_t *p, mdb_ctf_id_t *rid) { ctf_id_t id; mdb_ctf_impl_t *mcip = (mdb_ctf_impl_t *)p; if (mdb.m_synth == NULL) { mdb_printf("synthetic types disabled: ctf create failed\n"); return (1); } id = ctf_add_type(mdb.m_synth, mcip->mci_fp, mcip->mci_id); if (id == CTF_ERR) { mdb_dprintf(MDB_DBG_CTF, "failed to add pointer type: %s\n", ctf_errmsg(ctf_errno(mdb.m_synth))); return (set_errno(ctf_to_errno(ctf_errno(mdb.m_synth)))); } if (ctf_update(mdb.m_synth) == CTF_ERR) { mdb_dprintf(MDB_DBG_CTF, "failed to update synthetic types: %s", ctf_errmsg(ctf_errno(mdb.m_synth))); return (set_errno(ctf_to_errno(ctf_errno(mdb.m_synth)))); } id = ctf_add_pointer(mdb.m_synth, CTF_ADD_ROOT, id); if (id == CTF_ERR) { mdb_dprintf(MDB_DBG_CTF, "failed to add pointer: %s\n", ctf_errmsg(ctf_errno(mdb.m_synth))); return (set_errno(ctf_to_errno(ctf_errno(mdb.m_synth)))); } if (ctf_update(mdb.m_synth) == CTF_ERR) { mdb_dprintf(MDB_DBG_CTF, "failed to update synthetic types: %s", ctf_errmsg(ctf_errno(mdb.m_synth))); return (set_errno(ctf_to_errno(ctf_errno(mdb.m_synth)))); } if (rid != NULL) set_ctf_id(rid, mdb.m_synth, id); return (0); } int mdb_ctf_type_delete(const mdb_ctf_id_t *id) { int ret; mdb_ctf_impl_t *mcip = (mdb_ctf_impl_t *)id; if (mcip->mci_fp != mdb.m_synth) { mdb_warn("bad ctf_file_t, expected synth container\n"); return (1); } ret = ctf_delete_type(mcip->mci_fp, mcip->mci_id); if (ret != 0) { mdb_dprintf(MDB_DBG_CTF, "failed to delete synthetic type: %s", ctf_errmsg(ctf_errno(mdb.m_synth))); return (set_errno(ctf_to_errno(ctf_errno(mdb.m_synth)))); } if (ctf_update(mdb.m_synth) == CTF_ERR) { mdb_dprintf(MDB_DBG_CTF, "failed to update synthetic types: %s", ctf_errmsg(ctf_errno(mdb.m_synth))); return (set_errno(ctf_to_errno(ctf_errno(mdb.m_synth)))); } return (0); } static int mdb_ctf_synthetics_file_cb(mdb_ctf_id_t id, void *arg) { ctf_file_t *targ = arg; mdb_ctf_impl_t *mcip = (mdb_ctf_impl_t *)&id; if (ctf_add_type(targ, mcip->mci_fp, mcip->mci_id) == CTF_ERR) { mdb_dprintf(MDB_DBG_CTF, "failed to add type %d: %s\n", mcip->mci_id, ctf_errmsg(ctf_errno(mcip->mci_fp))); return (set_errno(ctf_to_errno(ctf_errno(mcip->mci_fp)))); } return (0); } int mdb_ctf_synthetics_from_file(const char *file) { ctf_file_t *fp, *syn = mdb.m_synth; int ret; type_iter_t ti; if (syn == NULL) { mdb_warn("synthetic types disabled: ctf create failed\n"); return (1); } if ((fp = mdb_ctf_open(file, &ret)) == NULL) { mdb_warn("failed to parse ctf data in %s", file); return (1); } ret = DCMD_OK; ti.ti_fp = fp; ti.ti_arg = syn; ti.ti_cb = mdb_ctf_synthetics_file_cb; if (ctf_type_iter(fp, type_iter_cb, &ti) == CTF_ERR) { ret = set_errno(ctf_to_errno(ctf_errno(fp))); mdb_warn("failed to add types"); goto cleanup; } if (ctf_update(syn) == CTF_ERR) { mdb_dprintf(MDB_DBG_CTF, "failed to update synthetic types\n"); ret = set_errno(ctf_to_errno(ctf_errno(fp))); } cleanup: ctf_close(fp); if (ret != 0) (void) ctf_discard(syn); return (ret); }