/* * 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 2006 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" /* * Workarounds for stabs generation bugs in the compiler and general needed * fixups. */ #include #include #include "ctf_headers.h" #include "ctftools.h" #include "hash.h" #include "memory.h" /* * Due to 4432619, the 6.1 compiler will sometimes incorrectly generate pointer * stabs. Given a struct foo, and a corresponding typedef struct foo foo_t. * In some cases, when faced with a pointer to a foo_t, the compiler will * sometimes generate a stab that describes a pointer to a struct foo. * Regardless of correctness, this breaks merges, as it occurs inconsistently * by file. The following two routines know how to recognize and repair foo_t * * and foo_t ** bugs in a specific set of cases. There is no general way to * solve this problem without a fix to the compiler. In general, cases should * only be added to these routines to fix merging problems in genunix. */ static void fix_ptrptr_to_struct(tdata_t *td) { char *strs[2] = { "as", "fdbuffer" }; char *mems[2] = { "a_objectdir", "fd_shadow" }; char *acts[2] = { "vnode", "page" }; char *tgts[2] = { "vnode_t", "page_t" }; tdesc_t *str; tdesc_t *act, *tgt; tdesc_t *p1, *p2; mlist_t *ml; int i; for (i = 0; i < sizeof (strs) / sizeof (strs[0]); i++) { if (!(str = lookupname(strs[i])) || str->t_type != STRUCT) continue; for (ml = str->t_members; ml; ml = ml->ml_next) { if (streq(ml->ml_name, mems[i])) break; } if (!ml) continue; if (ml->ml_type->t_type != POINTER || ml->ml_type->t_name || ml->ml_type->t_tdesc->t_type != POINTER || ml->ml_type->t_tdesc->t_name) continue; act = ml->ml_type->t_tdesc->t_tdesc; if (act->t_type != STRUCT || !streq(act->t_name, acts[i])) continue; if (!(tgt = lookupname(tgts[i])) || tgt->t_type != TYPEDEF) continue; /* We have an instance of the bug */ p2 = xcalloc(sizeof (*p2)); p2->t_type = POINTER; p2->t_id = td->td_nextid++; p2->t_tdesc = tgt; p1 = xcalloc(sizeof (*p1)); p1->t_type = POINTER; p1->t_id = td->td_nextid++; p1->t_tdesc = p2; ml->ml_type = p1; debug(3, "Fixed %s->%s => ptrptr struct %s bug\n", strs[i], mems[i], acts[i]); } } static void fix_ptr_to_struct(tdata_t *td) { char *strs[2] = { "vmem", "id_space" }; char *mems[2] = { NULL, "is_vmem" }; tdesc_t *ptr = NULL; tdesc_t *str, *vmt; mlist_t *ml; int i; if ((vmt = lookupname("vmem_t")) == NULL || vmt->t_type != TYPEDEF) return; for (i = 0; i < sizeof (strs) / sizeof (strs[0]); i++) { if (!(str = lookupname(strs[i])) || str->t_type != STRUCT) continue; for (ml = str->t_members; ml; ml = ml->ml_next) { if (mems[i] && !streq(ml->ml_name, mems[i])) continue; if (ml->ml_type->t_type != POINTER || ml->ml_type->t_name || (ml->ml_type->t_tdesc->t_type != STRUCT && ml->ml_type->t_tdesc->t_type != FORWARD) || !streq(ml->ml_type->t_tdesc->t_name, "vmem")) continue; debug(3, "Fixed %s->%s => ptr struct vmem bug\n", strs[i], ml->ml_name); if (!ptr) { ptr = xcalloc(sizeof (*ptr)); ptr->t_type = POINTER; ptr->t_id = td->td_nextid++; ptr->t_tdesc = vmt; } ml->ml_type = ptr; } } } /* * Fix stabs generation bugs. These routines must be run before the * post-conversion merge */ void cvt_fixstabs(tdata_t *td) { fix_ptrptr_to_struct(td); fix_ptr_to_struct(td); } struct match { tdesc_t *m_ret; const char *m_name; }; static int matching_iidesc(iidesc_t *iidesc, struct match *match) { if (!streq(iidesc->ii_name, match->m_name)) return (0); if (iidesc->ii_type != II_TYPE && iidesc->ii_type != II_SOU) return (0); match->m_ret = iidesc->ii_dtype; return (-1); } static tdesc_t * lookup_tdesc(tdata_t *td, const char *name) { struct match match = { NULL, name }; iter_iidescs_by_name(td, name, (int (*)())matching_iidesc, &match); return (match.m_ret); } /* * The cpu structure grows, with the addition of a machcpu member, if * _MACHDEP is defined. This means that, for example, the cpu structure * in unix is different from the cpu structure in genunix. As one might * expect, this causes merges to fail. Since everyone indirectly contains * a pointer to a CPU structure, the failed merges can cause massive amounts * of duplication. In the case of unix uniquifying against genunix, upwards * of 50% of the structures were unmerged due to this problem. We fix this * by adding a cpu_m member. If machcpu hasn't been defined in our module, * we make a forward node for it. */ static void fix_small_cpu_struct(tdata_t *td, size_t ptrsize) { tdesc_t *cput, *cpu; tdesc_t *machcpu; mlist_t *ml, *lml; mlist_t *cpum; int foundcpucyc = 0; /* * We're going to take the circuitous route finding the cpu structure, * because we want to make sure that we find the right one. It would * be nice if we could verify the header name too. DWARF might not * have the cpu_t, so we let this pass. */ if ((cput = lookup_tdesc(td, "cpu_t")) != NULL) { if (cput->t_type != TYPEDEF) return; cpu = cput->t_tdesc; } else { cpu = lookup_tdesc(td, "cpu"); } if (cpu == NULL) return; if (!streq(cpu->t_name, "cpu") || cpu->t_type != STRUCT) return; for (ml = cpu->t_members, lml = NULL; ml; lml = ml, ml = ml->ml_next) { if (strcmp(ml->ml_name, "cpu_cyclic") == 0) foundcpucyc = 1; } if (foundcpucyc == 0 || lml == NULL || strcmp(lml->ml_name, "cpu_m") == 0) return; /* * We need to derive the right offset for the fake cpu_m member. To do * that, we require a special unused member to be the last member * before the 'cpu_m', that we encode knowledge of here. ABI alignment * on all platforms is such that we only need to add a pointer-size * number of bits to get the right offset for cpu_m. This would most * likely break if gcc's -malign-double were ever used, but that option * breaks the ABI anyway. */ if (!streq(lml->ml_name, "cpu_m_pad") && getenv("CTFCONVERT_PERMISSIVE") == NULL) { terminate("last cpu_t member before cpu_m is %s; " "it must be cpu_m_pad.\n", lml->ml_name); } if ((machcpu = lookup_tdesc(td, "machcpu")) == NULL) { machcpu = xcalloc(sizeof (*machcpu)); machcpu->t_name = xstrdup("machcpu"); machcpu->t_id = td->td_nextid++; machcpu->t_type = FORWARD; } else if (machcpu->t_type != STRUCT) { return; } debug(3, "Adding cpu_m machcpu %s to cpu struct\n", (machcpu->t_type == FORWARD ? "forward" : "struct")); cpum = xmalloc(sizeof (*cpum)); cpum->ml_offset = lml->ml_offset + (ptrsize * NBBY); cpum->ml_size = 0; cpum->ml_name = xstrdup("cpu_m"); cpum->ml_type = machcpu; cpum->ml_next = NULL; lml->ml_next = cpum; } void cvt_fixups(tdata_t *td, size_t ptrsize) { fix_small_cpu_struct(td, ptrsize); }