ctf/cvt/ctf.c

1.1  darran /*
1.1  darran  * CDDL HEADER START
1.1  darran  *
1.1  darran  * The contents of this file are subject to the terms of the
1.1  darran  * Common Development and Distribution License (the "License").
1.1  darran  * You may not use this file except in compliance with the License.
1.1  darran  *
1.1  darran  * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
1.1  darran  * or http://www.opensolaris.org/os/licensing.
1.1  darran  * See the License for the specific language governing permissions
1.1  darran  * and limitations under the License.
1.1  darran  *
1.1  darran  * When distributing Covered Code, include this CDDL HEADER in each
1.1  darran  * file and include the License file at usr/src/OPENSOLARIS.LICENSE.
1.1  darran  * If applicable, add the following below this CDDL HEADER, with the
1.1  darran  * fields enclosed by brackets "[]" replaced with your own identifying
1.1  darran  * information: Portions Copyright [yyyy] [name of copyright owner]
1.1  darran  *
1.1  darran  * CDDL HEADER END
1.1  darran  */
1.1  darran /*
1.4    haad  * Copyright 2009 Sun Microsystems, Inc.  All rights reserved.
1.1  darran  * Use is subject to license terms.
1.1  darran  */
1.1  darran
1.1  darran /*
1.1  darran  * Create and parse buffers containing CTF data.
1.1  darran  */
1.1  darran
1.3  darran #if HAVE_NBTOOL_CONFIG_H
1.3  darran #include "nbtool_config.h"
1.3  darran #endif
1.3  darran
1.1  darran #include <sys/types.h>
1.1  darran #include <stdio.h>
1.1  darran #include <stdlib.h>
1.1  darran #include <strings.h>
1.1  darran #include <ctype.h>
1.1  darran #include <zlib.h>
1.1  darran #include <elf.h>
1.1  darran
1.1  darran #include "ctf_headers.h"
1.1  darran #include "ctftools.h"
1.1  darran #include "strtab.h"
1.1  darran #include "memory.h"
1.1  darran
1.1  darran /*
1.1  darran  * Name of the file currently being read, used to print error messages.  We
1.1  darran  * assume that only one file will be read at a time, and thus make no attempt
1.1  darran  * to allow curfile to be used simultaneously by multiple threads.
1.1  darran  *
1.1  darran  * The value is only valid during a call to ctf_load.
1.1  darran  */
1.1  darran char *curfile;
1.1  darran
1.1  darran #define	CTF_BUF_CHUNK_SIZE	(64 * 1024)
1.1  darran #define	RES_BUF_CHUNK_SIZE	(64 * 1024)
1.1  darran
1.1  darran struct ctf_buf {
1.1  darran 	strtab_t ctb_strtab;	/* string table */
1.1  darran 	caddr_t ctb_base;	/* pointer to base of buffer */
1.1  darran 	caddr_t ctb_end;	/* pointer to end of buffer */
1.1  darran 	caddr_t ctb_ptr;	/* pointer to empty buffer space */
1.1  darran 	size_t ctb_size;	/* size of buffer */
1.1  darran 	int nptent;		/* number of processed types */
1.1  darran 	int ntholes;		/* number of type holes */
1.1  darran };
1.1  darran
1.1  darran /*PRINTFLIKE1*/
1.1  darran static void
1.2  darran parseterminate(const char *fmt, ...)
1.1  darran {
1.1  darran 	static char msgbuf[1024]; /* sigh */
1.1  darran 	va_list ap;
1.1  darran
1.1  darran 	va_start(ap, fmt);
1.1  darran 	vsnprintf(msgbuf, sizeof (msgbuf), fmt, ap);
1.1  darran 	va_end(ap);
1.1  darran
1.1  darran 	terminate("%s: %s\n", curfile, msgbuf);
1.1  darran }
1.1  darran
1.2  darran static void
1.1  darran ctf_buf_grow(ctf_buf_t *b)
1.1  darran {
1.1  darran 	off_t ptroff = b->ctb_ptr - b->ctb_base;
1.1  darran
1.1  darran 	b->ctb_size += CTF_BUF_CHUNK_SIZE;
1.1  darran 	b->ctb_base = xrealloc(b->ctb_base, b->ctb_size);
1.1  darran 	b->ctb_end = b->ctb_base + b->ctb_size;
1.1  darran 	b->ctb_ptr = b->ctb_base + ptroff;
1.1  darran }
1.1  darran
1.2  darran static ctf_buf_t *
1.1  darran ctf_buf_new(void)
1.1  darran {
1.1  darran 	ctf_buf_t *b = xcalloc(sizeof (ctf_buf_t));
1.1  darran
1.1  darran 	strtab_create(&b->ctb_strtab);
1.1  darran 	ctf_buf_grow(b);
1.1  darran
1.1  darran 	return (b);
1.1  darran }
1.1  darran
1.2  darran static void
1.1  darran ctf_buf_free(ctf_buf_t *b)
1.1  darran {
1.1  darran 	strtab_destroy(&b->ctb_strtab);
1.1  darran 	free(b->ctb_base);
1.1  darran 	free(b);
1.1  darran }
1.1  darran
1.2  darran static uint_t
1.1  darran ctf_buf_cur(ctf_buf_t *b)
1.1  darran {
1.1  darran 	return (b->ctb_ptr - b->ctb_base);
1.1  darran }
1.1  darran
1.2  darran static void
1.2  darran ctf_buf_write(ctf_buf_t *b, void const *p, size_t n)
1.1  darran {
1.1  darran 	size_t len;
1.1  darran
1.1  darran 	while (n != 0) {
1.1  darran 		if (b->ctb_ptr == b->ctb_end)
1.1  darran 			ctf_buf_grow(b);
1.1  darran
1.1  darran 		len = MIN((size_t)(b->ctb_end - b->ctb_ptr), n);
1.1  darran 		bcopy(p, b->ctb_ptr, len);
1.1  darran 		b->ctb_ptr += len;
1.1  darran
1.2  darran 		p = (char const *)p + len;
1.1  darran 		n -= len;
1.1  darran 	}
1.1  darran }
1.1  darran
1.1  darran static int
1.2  darran write_label(void *arg1, void *arg2)
1.1  darran {
1.2  darran 	labelent_t *le = arg1;
1.2  darran 	ctf_buf_t *b = arg2;
1.1  darran 	ctf_lblent_t ctl;
1.1  darran
1.1  darran 	ctl.ctl_label = strtab_insert(&b->ctb_strtab, le->le_name);
1.1  darran 	ctl.ctl_typeidx = le->le_idx;
1.1  darran
1.1  darran 	ctf_buf_write(b, &ctl, sizeof (ctl));
1.1  darran
1.1  darran 	return (1);
1.1  darran }
1.1  darran
1.1  darran static void
1.1  darran write_objects(iidesc_t *idp, ctf_buf_t *b)
1.1  darran {
1.1  darran 	ushort_t id = (idp ? idp->ii_dtype->t_id : 0);
1.1  darran
1.1  darran 	ctf_buf_write(b, &id, sizeof (id));
1.1  darran
1.1  darran 	debug(3, "Wrote object %s (%d)\n", (idp ? idp->ii_name : "(null)"), id);
1.1  darran }
1.1  darran
1.1  darran static void
1.1  darran write_functions(iidesc_t *idp, ctf_buf_t *b)
1.1  darran {
1.1  darran 	ushort_t fdata[2];
1.1  darran 	ushort_t id;
1.1  darran 	int nargs;
1.1  darran 	int i;
1.1  darran
1.1  darran 	if (!idp) {
1.1  darran 		fdata[0] = 0;
1.1  darran 		ctf_buf_write(b, &fdata[0], sizeof (fdata[0]));
1.1  darran
1.1  darran 		debug(3, "Wrote function (null)\n");
1.1  darran 		return;
1.1  darran 	}
1.1  darran
1.1  darran 	nargs = idp->ii_nargs + (idp->ii_vargs != 0);
1.4    haad
1.4    haad 	if (nargs > CTF_MAX_VLEN) {
1.4    haad 		terminate("function %s has too many args: %d > %d\n",
1.4    haad 		    idp->ii_name, nargs, CTF_MAX_VLEN);
1.4    haad 	}
1.4    haad
1.1  darran 	fdata[0] = CTF_TYPE_INFO(CTF_K_FUNCTION, 1, nargs);
1.1  darran 	fdata[1] = idp->ii_dtype->t_id;
1.1  darran 	ctf_buf_write(b, fdata, sizeof (fdata));
1.1  darran
1.1  darran 	for (i = 0; i < idp->ii_nargs; i++) {
1.1  darran 		id = idp->ii_args[i]->t_id;
1.1  darran 		ctf_buf_write(b, &id, sizeof (id));
1.1  darran 	}
1.1  darran
1.1  darran 	if (idp->ii_vargs) {
1.1  darran 		id = 0;
1.1  darran 		ctf_buf_write(b, &id, sizeof (id));
1.1  darran 	}
1.1  darran
1.1  darran 	debug(3, "Wrote function %s (%d args)\n", idp->ii_name, nargs);
1.1  darran }
1.1  darran
1.1  darran /*
1.1  darran  * Depending on the size of the type being described, either a ctf_stype_t (for
1.1  darran  * types with size < CTF_LSTRUCT_THRESH) or a ctf_type_t (all others) will be
1.1  darran  * written.  We isolate the determination here so the rest of the writer code
1.1  darran  * doesn't need to care.
1.1  darran  */
1.1  darran static void
1.1  darran write_sized_type_rec(ctf_buf_t *b, ctf_type_t *ctt, size_t size)
1.1  darran {
1.1  darran 	if (size > CTF_MAX_SIZE) {
1.1  darran 		ctt->ctt_size = CTF_LSIZE_SENT;
1.1  darran 		ctt->ctt_lsizehi = CTF_SIZE_TO_LSIZE_HI(size);
1.1  darran 		ctt->ctt_lsizelo = CTF_SIZE_TO_LSIZE_LO(size);
1.1  darran 		ctf_buf_write(b, ctt, sizeof (*ctt));
1.1  darran 	} else {
1.1  darran 		ctf_stype_t *cts = (ctf_stype_t *)ctt;
1.1  darran
1.1  darran 		cts->ctt_size = (ushort_t)size;
1.1  darran 		ctf_buf_write(b, cts, sizeof (*cts));
1.1  darran 	}
1.1  darran }
1.1  darran
1.1  darran static void
1.1  darran write_unsized_type_rec(ctf_buf_t *b, ctf_type_t *ctt)
1.1  darran {
1.1  darran 	ctf_stype_t *cts = (ctf_stype_t *)ctt;
1.1  darran
1.1  darran 	ctf_buf_write(b, cts, sizeof (*cts));
1.1  darran }
1.1  darran
1.1  darran static int
1.2  darran write_type(void *arg1, void *arg2)
1.1  darran {
1.2  darran 	tdesc_t *tp = arg1;
1.2  darran 	ctf_buf_t *b = arg2;
1.1  darran 	elist_t *ep;
1.1  darran 	mlist_t *mp;
1.1  darran 	intr_t *ip;
1.1  darran
1.1  darran 	size_t offset;
1.1  darran 	uint_t encoding;
1.1  darran 	uint_t data;
1.1  darran 	int isroot = tp->t_flags & TDESC_F_ISROOT;
1.1  darran 	int i;
1.1  darran
1.1  darran 	ctf_type_t ctt;
1.1  darran 	ctf_array_t cta;
1.1  darran 	ctf_member_t ctm;
1.1  darran 	ctf_lmember_t ctlm;
1.1  darran 	ctf_enum_t cte;
1.1  darran 	ushort_t id;
1.1  darran
1.1  darran 	ctlm.ctlm_pad = 0;
1.1  darran
1.1  darran 	/*
1.1  darran 	 * There shouldn't be any holes in the type list (where a hole is
1.1  darran 	 * defined as two consecutive tdescs without consecutive ids), but
1.1  darran 	 * check for them just in case.  If we do find holes, we need to make
1.1  darran 	 * fake entries to fill the holes, or we won't be able to reconstruct
1.1  darran 	 * the tree from the written data.
1.1  darran 	 */
1.1  darran 	if (++b->nptent < CTF_TYPE_TO_INDEX(tp->t_id)) {
1.1  darran 		debug(2, "genctf: type hole from %d < x < %d\n",
1.1  darran 		    b->nptent - 1, CTF_TYPE_TO_INDEX(tp->t_id));
1.1  darran
1.1  darran 		ctt.ctt_name = CTF_TYPE_NAME(CTF_STRTAB_0, 0);
1.1  darran 		ctt.ctt_info = CTF_TYPE_INFO(0, 0, 0);
1.1  darran 		while (b->nptent < CTF_TYPE_TO_INDEX(tp->t_id)) {
1.1  darran 			write_sized_type_rec(b, &ctt, 0);
1.1  darran 			b->nptent++;
1.1  darran 		}
1.1  darran 	}
1.1  darran
1.1  darran 	offset = strtab_insert(&b->ctb_strtab, tp->t_name);
1.1  darran 	ctt.ctt_name = CTF_TYPE_NAME(CTF_STRTAB_0, offset);
1.1  darran
1.1  darran 	switch (tp->t_type) {
1.1  darran 	case INTRINSIC:
1.1  darran 		ip = tp->t_intr;
1.1  darran 		if (ip->intr_type == INTR_INT)
1.1  darran 			ctt.ctt_info = CTF_TYPE_INFO(CTF_K_INTEGER,
1.1  darran 			    isroot, 1);
1.1  darran 		else
1.1  darran 			ctt.ctt_info = CTF_TYPE_INFO(CTF_K_FLOAT, isroot, 1);
1.1  darran 		write_sized_type_rec(b, &ctt, tp->t_size);
1.1  darran
1.1  darran 		encoding = 0;
1.1  darran
1.1  darran 		if (ip->intr_type == INTR_INT) {
1.1  darran 			if (ip->intr_signed)
1.1  darran 				encoding |= CTF_INT_SIGNED;
1.1  darran 			if (ip->intr_iformat == 'c')
1.1  darran 				encoding |= CTF_INT_CHAR;
1.1  darran 			else if (ip->intr_iformat == 'b')
1.1  darran 				encoding |= CTF_INT_BOOL;
1.1  darran 			else if (ip->intr_iformat == 'v')
1.1  darran 				encoding |= CTF_INT_VARARGS;
1.1  darran 		} else
1.1  darran 			encoding = ip->intr_fformat;
1.1  darran
1.1  darran 		data = CTF_INT_DATA(encoding, ip->intr_offset, ip->intr_nbits);
1.1  darran 		ctf_buf_write(b, &data, sizeof (data));
1.1  darran 		break;
1.1  darran
1.1  darran 	case POINTER:
1.1  darran 		ctt.ctt_info = CTF_TYPE_INFO(CTF_K_POINTER, isroot, 0);
1.1  darran 		ctt.ctt_type = tp->t_tdesc->t_id;
1.1  darran 		write_unsized_type_rec(b, &ctt);
1.1  darran 		break;
1.1  darran
1.1  darran 	case ARRAY:
1.1  darran 		ctt.ctt_info = CTF_TYPE_INFO(CTF_K_ARRAY, isroot, 1);
1.1  darran 		write_sized_type_rec(b, &ctt, tp->t_size);
1.1  darran
1.1  darran 		cta.cta_contents = tp->t_ardef->ad_contents->t_id;
1.1  darran 		cta.cta_index = tp->t_ardef->ad_idxtype->t_id;
1.1  darran 		cta.cta_nelems = tp->t_ardef->ad_nelems;
1.1  darran 		ctf_buf_write(b, &cta, sizeof (cta));
1.1  darran 		break;
1.1  darran
1.1  darran 	case STRUCT:
1.1  darran 	case UNION:
1.1  darran 		for (i = 0, mp = tp->t_members; mp != NULL; mp = mp->ml_next)
1.1  darran 			i++; /* count up struct or union members */
1.1  darran
1.4    haad 		if (i > CTF_MAX_VLEN) {
1.4    haad 			terminate("sou %s has too many members: %d > %d\n",
1.4    haad 			    tdesc_name(tp), i, CTF_MAX_VLEN);
1.4    haad 		}
1.4    haad
1.1  darran 		if (tp->t_type == STRUCT)
1.1  darran 			ctt.ctt_info = CTF_TYPE_INFO(CTF_K_STRUCT, isroot, i);
1.1  darran 		else
1.1  darran 			ctt.ctt_info = CTF_TYPE_INFO(CTF_K_UNION, isroot, i);
1.1  darran
1.1  darran 		write_sized_type_rec(b, &ctt, tp->t_size);
1.1  darran
1.1  darran 		if (tp->t_size < CTF_LSTRUCT_THRESH) {
1.1  darran 			for (mp = tp->t_members; mp != NULL; mp = mp->ml_next) {
1.1  darran 				offset = strtab_insert(&b->ctb_strtab,
1.1  darran 				    mp->ml_name);
1.1  darran
1.1  darran 				ctm.ctm_name = CTF_TYPE_NAME(CTF_STRTAB_0,
1.1  darran 				    offset);
1.1  darran 				ctm.ctm_type = mp->ml_type->t_id;
1.1  darran 				ctm.ctm_offset = mp->ml_offset;
1.1  darran 				ctf_buf_write(b, &ctm, sizeof (ctm));
1.1  darran 			}
1.1  darran 		} else {
1.1  darran 			for (mp = tp->t_members; mp != NULL; mp = mp->ml_next) {
1.1  darran 				offset = strtab_insert(&b->ctb_strtab,
1.1  darran 				    mp->ml_name);
1.1  darran
1.1  darran 				ctlm.ctlm_name = CTF_TYPE_NAME(CTF_STRTAB_0,
1.1  darran 				    offset);
1.1  darran 				ctlm.ctlm_type = mp->ml_type->t_id;
1.1  darran 				ctlm.ctlm_offsethi =
1.1  darran 				    CTF_OFFSET_TO_LMEMHI(mp->ml_offset);
1.1  darran 				ctlm.ctlm_offsetlo =
1.1  darran 				    CTF_OFFSET_TO_LMEMLO(mp->ml_offset);
1.1  darran 				ctf_buf_write(b, &ctlm, sizeof (ctlm));
1.1  darran 			}
1.1  darran 		}
1.1  darran 		break;
1.1  darran
1.1  darran 	case ENUM:
1.1  darran 		for (i = 0, ep = tp->t_emem; ep != NULL; ep = ep->el_next)
1.1  darran 			i++; /* count up enum members */
1.1  darran
1.4    haad 		if (i > CTF_MAX_VLEN) {
1.4    haad 			terminate("enum %s has too many values: %d > %d\n",
1.4    haad 			    tdesc_name(tp), i, CTF_MAX_VLEN);
1.4    haad 		}
1.4    haad
1.1  darran 		ctt.ctt_info = CTF_TYPE_INFO(CTF_K_ENUM, isroot, i);
1.1  darran 		write_sized_type_rec(b, &ctt, tp->t_size);
1.1  darran
1.1  darran 		for (ep = tp->t_emem; ep != NULL; ep = ep->el_next) {
1.1  darran 			offset = strtab_insert(&b->ctb_strtab, ep->el_name);
1.1  darran 			cte.cte_name = CTF_TYPE_NAME(CTF_STRTAB_0, offset);
1.1  darran 			cte.cte_value = ep->el_number;
1.1  darran 			ctf_buf_write(b, &cte, sizeof (cte));
1.1  darran 		}
1.1  darran 		break;
1.1  darran
1.1  darran 	case FORWARD:
1.1  darran 		ctt.ctt_info = CTF_TYPE_INFO(CTF_K_FORWARD, isroot, 0);
1.1  darran 		ctt.ctt_type = 0;
1.1  darran 		write_unsized_type_rec(b, &ctt);
1.1  darran 		break;
1.1  darran
1.1  darran 	case TYPEDEF:
1.1  darran 		ctt.ctt_info = CTF_TYPE_INFO(CTF_K_TYPEDEF, isroot, 0);
1.1  darran 		ctt.ctt_type = tp->t_tdesc->t_id;
1.1  darran 		write_unsized_type_rec(b, &ctt);
1.1  darran 		break;
1.1  darran
1.1  darran 	case VOLATILE:
1.1  darran 		ctt.ctt_info = CTF_TYPE_INFO(CTF_K_VOLATILE, isroot, 0);
1.1  darran 		ctt.ctt_type = tp->t_tdesc->t_id;
1.1  darran 		write_unsized_type_rec(b, &ctt);
1.1  darran 		break;
1.1  darran
1.1  darran 	case CONST:
1.1  darran 		ctt.ctt_info = CTF_TYPE_INFO(CTF_K_CONST, isroot, 0);
1.1  darran 		ctt.ctt_type = tp->t_tdesc->t_id;
1.1  darran 		write_unsized_type_rec(b, &ctt);
1.1  darran 		break;
1.1  darran
1.1  darran 	case FUNCTION:
1.4    haad 		i = tp->t_fndef->fn_nargs + tp->t_fndef->fn_vargs;
1.4    haad
1.4    haad 		if (i > CTF_MAX_VLEN) {
1.4    haad 			terminate("function %s has too many args: %d > %d\n",
1.4    haad 			    i, CTF_MAX_VLEN);
1.4    haad 		}
1.4    haad
1.4    haad 		ctt.ctt_info = CTF_TYPE_INFO(CTF_K_FUNCTION, isroot, i);
1.1  darran 		ctt.ctt_type = tp->t_fndef->fn_ret->t_id;
1.1  darran 		write_unsized_type_rec(b, &ctt);
1.1  darran
1.2  darran 		for (i = 0; i < (int) tp->t_fndef->fn_nargs; i++) {
1.1  darran 			id = tp->t_fndef->fn_args[i]->t_id;
1.1  darran 			ctf_buf_write(b, &id, sizeof (id));
1.1  darran 		}
1.1  darran
1.1  darran 		if (tp->t_fndef->fn_vargs) {
1.1  darran 			id = 0;
1.1  darran 			ctf_buf_write(b, &id, sizeof (id));
1.1  darran 			i++;
1.1  darran 		}
1.1  darran
1.1  darran 		if (i & 1) {
1.1  darran 			id = 0;
1.1  darran 			ctf_buf_write(b, &id, sizeof (id));
1.1  darran 		}
1.1  darran 		break;
1.1  darran
1.1  darran 	case RESTRICT:
1.1  darran 		ctt.ctt_info = CTF_TYPE_INFO(CTF_K_RESTRICT, isroot, 0);
1.1  darran 		ctt.ctt_type = tp->t_tdesc->t_id;
1.1  darran 		write_unsized_type_rec(b, &ctt);
1.1  darran 		break;
1.1  darran
1.1  darran 	default:
1.1  darran 		warning("Can't write unknown type %d\n", tp->t_type);
1.1  darran 	}
1.1  darran
1.1  darran 	debug(3, "Wrote type %d %s\n", tp->t_id, tdesc_name(tp));
1.1  darran
1.1  darran 	return (1);
1.1  darran }
1.1  darran
1.1  darran typedef struct resbuf {
1.1  darran 	caddr_t rb_base;
1.1  darran 	caddr_t rb_ptr;
1.1  darran 	size_t rb_size;
1.1  darran 	z_stream rb_zstr;
1.1  darran } resbuf_t;
1.1  darran
1.1  darran static void
1.1  darran rbzs_grow(resbuf_t *rb)
1.1  darran {
1.1  darran 	off_t ptroff = (caddr_t)rb->rb_zstr.next_out - rb->rb_base;
1.1  darran
1.1  darran 	rb->rb_size += RES_BUF_CHUNK_SIZE;
1.1  darran 	rb->rb_base = xrealloc(rb->rb_base, rb->rb_size);
1.1  darran 	rb->rb_ptr = rb->rb_base + ptroff;
1.1  darran 	rb->rb_zstr.next_out = (Bytef *)(rb->rb_ptr);
1.1  darran 	rb->rb_zstr.avail_out += RES_BUF_CHUNK_SIZE;
1.1  darran }
1.1  darran
1.1  darran static void
1.1  darran compress_start(resbuf_t *rb)
1.1  darran {
1.1  darran 	int rc;
1.1  darran
1.1  darran 	rb->rb_zstr.zalloc = (alloc_func)0;
1.1  darran 	rb->rb_zstr.zfree = (free_func)0;
1.1  darran 	rb->rb_zstr.opaque = (voidpf)0;
1.1  darran
1.1  darran 	if ((rc = deflateInit(&rb->rb_zstr, Z_BEST_COMPRESSION)) != Z_OK)
1.1  darran 		parseterminate("zlib start failed: %s", zError(rc));
1.1  darran }
1.1  darran
1.1  darran static ssize_t
1.2  darran compress_buffer(void *buf, size_t n, void *data)
1.1  darran {
1.1  darran 	resbuf_t *rb = (resbuf_t *)data;
1.1  darran 	int rc;
1.1  darran
1.1  darran 	rb->rb_zstr.next_out = (Bytef *)rb->rb_ptr;
1.1  darran 	rb->rb_zstr.avail_out = rb->rb_size - (rb->rb_ptr - rb->rb_base);
1.2  darran 	rb->rb_zstr.next_in = buf;
1.1  darran 	rb->rb_zstr.avail_in = n;
1.1  darran
1.1  darran 	while (rb->rb_zstr.avail_in) {
1.1  darran 		if (rb->rb_zstr.avail_out == 0)
1.1  darran 			rbzs_grow(rb);
1.1  darran
1.1  darran 		if ((rc = deflate(&rb->rb_zstr, Z_NO_FLUSH)) != Z_OK)
1.1  darran 			parseterminate("zlib deflate failed: %s", zError(rc));
1.1  darran 	}
1.1  darran 	rb->rb_ptr = (caddr_t)rb->rb_zstr.next_out;
1.1  darran
1.1  darran 	return (n);
1.1  darran }
1.1  darran
1.1  darran static void
1.1  darran compress_flush(resbuf_t *rb, int type)
1.1  darran {
1.1  darran 	int rc;
1.1  darran
1.1  darran 	for (;;) {
1.1  darran 		if (rb->rb_zstr.avail_out == 0)
1.1  darran 			rbzs_grow(rb);
1.1  darran
1.1  darran 		rc = deflate(&rb->rb_zstr, type);
1.1  darran 		if ((type == Z_FULL_FLUSH && rc == Z_BUF_ERROR) ||
1.1  darran 		    (type == Z_FINISH && rc == Z_STREAM_END))
1.1  darran 			break;
1.1  darran 		else if (rc != Z_OK)
1.1  darran 			parseterminate("zlib finish failed: %s", zError(rc));
1.1  darran 	}
1.1  darran 	rb->rb_ptr = (caddr_t)rb->rb_zstr.next_out;
1.1  darran }
1.1  darran
1.1  darran static void
1.1  darran compress_end(resbuf_t *rb)
1.1  darran {
1.1  darran 	int rc;
1.1  darran
1.1  darran 	compress_flush(rb, Z_FINISH);
1.1  darran
1.1  darran 	if ((rc = deflateEnd(&rb->rb_zstr)) != Z_OK)
1.1  darran 		parseterminate("zlib end failed: %s", zError(rc));
1.1  darran }
1.1  darran
1.1  darran /*
1.1  darran  * Pad the buffer to a power-of-2 boundary
1.1  darran  */
1.1  darran static void
1.1  darran pad_buffer(ctf_buf_t *buf, int align)
1.1  darran {
1.1  darran 	uint_t cur = ctf_buf_cur(buf);
1.1  darran 	ssize_t topad = (align - (cur % align)) % align;
1.1  darran 	static const char pad[8] = { 0 };
1.1  darran
1.1  darran 	while (topad > 0) {
1.1  darran 		ctf_buf_write(buf, pad, (topad > 8 ? 8 : topad));
1.1  darran 		topad -= 8;
1.1  darran 	}
1.1  darran }
1.1  darran
1.1  darran static ssize_t
1.2  darran bcopy_data(void *buf, size_t n, void *data)
1.1  darran {
1.1  darran 	caddr_t *posp = (caddr_t *)data;
1.1  darran 	bcopy(buf, *posp, n);
1.1  darran 	*posp += n;
1.1  darran 	return (n);
1.1  darran }
1.1  darran
1.1  darran static caddr_t
1.1  darran write_buffer(ctf_header_t *h, ctf_buf_t *buf, size_t *resszp)
1.1  darran {
1.1  darran 	caddr_t outbuf;
1.1  darran 	caddr_t bufpos;
1.1  darran
1.1  darran 	outbuf = xmalloc(sizeof (ctf_header_t) + (buf->ctb_ptr - buf->ctb_base)
1.1  darran 	    + buf->ctb_strtab.str_size);
1.1  darran
1.1  darran 	bufpos = outbuf;
1.1  darran 	(void) bcopy_data(h, sizeof (ctf_header_t), &bufpos);
1.1  darran 	(void) bcopy_data(buf->ctb_base, buf->ctb_ptr - buf->ctb_base,
1.1  darran 	    &bufpos);
1.1  darran 	(void) strtab_write(&buf->ctb_strtab, bcopy_data, &bufpos);
1.1  darran 	*resszp = bufpos - outbuf;
1.1  darran 	return (outbuf);
1.1  darran }
1.1  darran
1.1  darran /*
1.1  darran  * Create the compression buffer, and fill it with the CTF and string
1.1  darran  * table data.  We flush the compression state between the two so the
1.1  darran  * dictionary used for the string tables won't be polluted with values
1.1  darran  * that made sense for the CTF data.
1.1  darran  */
1.1  darran static caddr_t
1.1  darran write_compressed_buffer(ctf_header_t *h, ctf_buf_t *buf, size_t *resszp)
1.1  darran {
1.1  darran 	resbuf_t resbuf;
1.1  darran 	resbuf.rb_size = RES_BUF_CHUNK_SIZE;
1.1  darran 	resbuf.rb_base = xmalloc(resbuf.rb_size);
1.1  darran 	bcopy(h, resbuf.rb_base, sizeof (ctf_header_t));
1.1  darran 	resbuf.rb_ptr = resbuf.rb_base + sizeof (ctf_header_t);
1.1  darran
1.1  darran 	compress_start(&resbuf);
1.1  darran 	(void) compress_buffer(buf->ctb_base, buf->ctb_ptr - buf->ctb_base,
1.1  darran 	    &resbuf);
1.1  darran 	compress_flush(&resbuf, Z_FULL_FLUSH);
1.1  darran 	(void) strtab_write(&buf->ctb_strtab, compress_buffer, &resbuf);
1.1  darran 	compress_end(&resbuf);
1.1  darran
1.1  darran 	*resszp = (resbuf.rb_ptr - resbuf.rb_base);
1.1  darran 	return (resbuf.rb_base);
1.1  darran }
1.1  darran
1.1  darran caddr_t
1.1  darran ctf_gen(iiburst_t *iiburst, size_t *resszp, int do_compress)
1.1  darran {
1.1  darran 	ctf_buf_t *buf = ctf_buf_new();
1.1  darran 	ctf_header_t h;
1.1  darran 	caddr_t outbuf;
1.1  darran
1.1  darran 	int i;
1.1  darran
1.1  darran 	/*
1.1  darran 	 * Prepare the header, and create the CTF output buffers.  The data
1.1  darran 	 * object section and function section are both lists of 2-byte
1.1  darran 	 * integers; we pad these out to the next 4-byte boundary if needed.
1.1  darran 	 */
1.1  darran 	h.cth_magic = CTF_MAGIC;
1.1  darran 	h.cth_version = CTF_VERSION;
1.1  darran 	h.cth_flags = do_compress ? CTF_F_COMPRESS : 0;
1.1  darran 	h.cth_parlabel = strtab_insert(&buf->ctb_strtab,
1.1  darran 	    iiburst->iib_td->td_parlabel);
1.1  darran 	h.cth_parname = strtab_insert(&buf->ctb_strtab,
1.1  darran 	    iiburst->iib_td->td_parname);
1.1  darran
1.1  darran 	h.cth_lbloff = 0;
1.2  darran 	(void) list_iter(iiburst->iib_td->td_labels, write_label,
1.1  darran 	    buf);
1.1  darran
1.1  darran 	pad_buffer(buf, 2);
1.1  darran 	h.cth_objtoff = ctf_buf_cur(buf);
1.1  darran 	for (i = 0; i < iiburst->iib_nobjts; i++)
1.1  darran 		write_objects(iiburst->iib_objts[i], buf);
1.1  darran
1.1  darran 	pad_buffer(buf, 2);
1.1  darran 	h.cth_funcoff = ctf_buf_cur(buf);
1.1  darran 	for (i = 0; i < iiburst->iib_nfuncs; i++)
1.1  darran 		write_functions(iiburst->iib_funcs[i], buf);
1.1  darran
1.1  darran 	pad_buffer(buf, 4);
1.1  darran 	h.cth_typeoff = ctf_buf_cur(buf);
1.2  darran 	(void) list_iter(iiburst->iib_types, write_type, buf);
1.1  darran
1.1  darran 	debug(2, "CTF wrote %d types\n", list_count(iiburst->iib_types));
1.1  darran
1.1  darran 	h.cth_stroff = ctf_buf_cur(buf);
1.1  darran 	h.cth_strlen = strtab_size(&buf->ctb_strtab);
1.1  darran
1.1  darran 	/*
1.1  darran 	 * We only do compression for ctfmerge, as ctfconvert is only
1.1  darran 	 * supposed to be used on intermediary build objects. This is
1.1  darran 	 * significantly faster.
1.1  darran 	 */
1.1  darran 	if (do_compress)
1.1  darran 		outbuf = write_compressed_buffer(&h, buf, resszp);
1.1  darran 	else
1.1  darran 		outbuf = write_buffer(&h, buf, resszp);
1.1  darran
1.1  darran 	ctf_buf_free(buf);
1.1  darran 	return (outbuf);
1.1  darran }
1.1  darran
1.2  darran static void
1.1  darran get_ctt_size(ctf_type_t *ctt, size_t *sizep, size_t *incrementp)
1.1  darran {
1.1  darran 	if (ctt->ctt_size == CTF_LSIZE_SENT) {
1.1  darran 		*sizep = (size_t)CTF_TYPE_LSIZE(ctt);
1.1  darran 		*incrementp = sizeof (ctf_type_t);
1.1  darran 	} else {
1.1  darran 		*sizep = ctt->ctt_size;
1.1  darran 		*incrementp = sizeof (ctf_stype_t);
1.1  darran 	}
1.1  darran }
1.1  darran
1.1  darran static int
1.1  darran count_types(ctf_header_t *h, caddr_t data)
1.1  darran {
1.1  darran 	caddr_t dptr = data + h->cth_typeoff;
1.1  darran 	int count = 0;
1.1  darran
1.1  darran 	dptr = data + h->cth_typeoff;
1.1  darran 	while (dptr < data + h->cth_stroff) {
1.2  darran 		void *v = (void *) dptr;
1.2  darran 		ctf_type_t *ctt = v;
1.1  darran 		size_t vlen = CTF_INFO_VLEN(ctt->ctt_info);
1.1  darran 		size_t size, increment;
1.1  darran
1.1  darran 		get_ctt_size(ctt, &size, &increment);
1.1  darran
1.1  darran 		switch (CTF_INFO_KIND(ctt->ctt_info)) {
1.1  darran 		case CTF_K_INTEGER:
1.1  darran 		case CTF_K_FLOAT:
1.1  darran 			dptr += 4;
1.1  darran 			break;
1.1  darran 		case CTF_K_POINTER:
1.1  darran 		case CTF_K_FORWARD:
1.1  darran 		case CTF_K_TYPEDEF:
1.1  darran 		case CTF_K_VOLATILE:
1.1  darran 		case CTF_K_CONST:
1.1  darran 		case CTF_K_RESTRICT:
1.1  darran 		case CTF_K_FUNCTION:
1.1  darran 			dptr += sizeof (ushort_t) * (vlen + (vlen & 1));
1.1  darran 			break;
1.1  darran 		case CTF_K_ARRAY:
1.1  darran 			dptr += sizeof (ctf_array_t);
1.1  darran 			break;
1.1  darran 		case CTF_K_STRUCT:
1.1  darran 		case CTF_K_UNION:
1.1  darran 			if (size < CTF_LSTRUCT_THRESH)
1.1  darran 				dptr += sizeof (ctf_member_t) * vlen;
1.1  darran 			else
1.1  darran 				dptr += sizeof (ctf_lmember_t) * vlen;
1.1  darran 			break;
1.1  darran 		case CTF_K_ENUM:
1.1  darran 			dptr += sizeof (ctf_enum_t) * vlen;
1.1  darran 			break;
1.1  darran 		case CTF_K_UNKNOWN:
1.1  darran 			break;
1.1  darran 		default:
1.1  darran 			parseterminate("Unknown CTF type %d (#%d) at %#x",
1.1  darran 			    CTF_INFO_KIND(ctt->ctt_info), count, dptr - data);
1.1  darran 		}
1.1  darran
1.1  darran 		dptr += increment;
1.1  darran 		count++;
1.1  darran 	}
1.1  darran
1.1  darran 	debug(3, "CTF read %d types\n", count);
1.1  darran
1.1  darran 	return (count);
1.1  darran }
1.1  darran
1.1  darran /*
1.1  darran  * Resurrect the labels stored in the CTF data, returning the index associated
1.1  darran  * with a label provided by the caller.  There are several cases, outlined
1.1  darran  * below.  Note that, given two labels, the one associated with the lesser type
1.1  darran  * index is considered to be older than the other.
1.1  darran  *
1.1  darran  *  1. matchlbl == NULL - return the index of the most recent label.
1.1  darran  *  2. matchlbl == "BASE" - return the index of the oldest label.
1.1  darran  *  3. matchlbl != NULL, but doesn't match any labels in the section - warn
1.1  darran  *	the user, and proceed as if matchlbl == "BASE" (for safety).
1.1  darran  *  4. matchlbl != NULL, and matches one of the labels in the section - return
1.1  darran  *	the type index associated with the label.
1.1  darran  */
1.1  darran static int
1.1  darran resurrect_labels(ctf_header_t *h, tdata_t *td, caddr_t ctfdata, char *matchlbl)
1.1  darran {
1.1  darran 	caddr_t buf = ctfdata + h->cth_lbloff;
1.1  darran 	caddr_t sbuf = ctfdata + h->cth_stroff;
1.1  darran 	size_t bufsz = h->cth_objtoff - h->cth_lbloff;
1.1  darran 	int lastidx = 0, baseidx = -1;
1.2  darran 	char *baselabel = NULL;
1.1  darran 	ctf_lblent_t *ctl;
1.2  darran 	void *v = (void *) buf;
1.1  darran
1.2  darran 	for (ctl = v; (caddr_t)ctl < buf + bufsz; ctl++) {
1.1  darran 		char *label = sbuf + ctl->ctl_label;
1.1  darran
1.1  darran 		lastidx = ctl->ctl_typeidx;
1.1  darran
1.1  darran 		debug(3, "Resurrected label %s type idx %d\n", label, lastidx);
1.1  darran
1.1  darran 		tdata_label_add(td, label, lastidx);
1.1  darran
1.1  darran 		if (baseidx == -1) {
1.1  darran 			baseidx = lastidx;
1.1  darran 			baselabel = label;
1.1  darran 			if (matchlbl != NULL && streq(matchlbl, "BASE"))
1.1  darran 				return (lastidx);
1.1  darran 		}
1.1  darran
1.1  darran 		if (matchlbl != NULL && streq(label, matchlbl))
1.1  darran 			return (lastidx);
1.1  darran 	}
1.1  darran
1.1  darran 	if (matchlbl != NULL) {
1.1  darran 		/* User provided a label that didn't match */
1.1  darran 		warning("%s: Cannot find label `%s' - using base (%s)\n",
1.1  darran 		    curfile, matchlbl, (baselabel ? baselabel : "NONE"));
1.1  darran
1.1  darran 		tdata_label_free(td);
1.1  darran 		tdata_label_add(td, baselabel, baseidx);
1.1  darran
1.1  darran 		return (baseidx);
1.1  darran 	}
1.1  darran
1.1  darran 	return (lastidx);
1.1  darran }
1.1  darran
1.1  darran static void
1.1  darran resurrect_objects(ctf_header_t *h, tdata_t *td, tdesc_t **tdarr, int tdsize,
1.1  darran     caddr_t ctfdata, symit_data_t *si)
1.1  darran {
1.1  darran 	caddr_t buf = ctfdata + h->cth_objtoff;
1.1  darran 	size_t bufsz = h->cth_funcoff - h->cth_objtoff;
1.1  darran 	caddr_t dptr;
1.1  darran
1.1  darran 	symit_reset(si);
1.1  darran 	for (dptr = buf; dptr < buf + bufsz; dptr += 2) {
1.2  darran 		void *v = (void *) dptr;
1.2  darran 		ushort_t id = *((ushort_t *)v);
1.1  darran 		iidesc_t *ii;
1.1  darran 		GElf_Sym *sym;
1.1  darran
1.1  darran 		if (!(sym = symit_next(si, STT_OBJECT)) && id != 0) {
1.1  darran 			parseterminate(
1.1  darran 			    "Unexpected end of object symbols at %x of %x",
1.1  darran 			    dptr - buf, bufsz);
1.1  darran 		}
1.1  darran
1.1  darran 		if (id == 0) {
1.1  darran 			debug(3, "Skipping null object\n");
1.1  darran 			continue;
1.1  darran 		} else if (id >= tdsize) {
1.1  darran 			parseterminate("Reference to invalid type %d", id);
1.1  darran 		}
1.1  darran
1.1  darran 		ii = iidesc_new(symit_name(si));
1.1  darran 		ii->ii_dtype = tdarr[id];
1.1  darran 		if (GELF_ST_BIND(sym->st_info) == STB_LOCAL) {
1.1  darran 			ii->ii_type = II_SVAR;
1.1  darran 			ii->ii_owner = xstrdup(symit_curfile(si));
1.1  darran 		} else
1.1  darran 			ii->ii_type = II_GVAR;
1.1  darran 		hash_add(td->td_iihash, ii);
1.1  darran
1.1  darran 		debug(3, "Resurrected %s object %s (%d) from %s\n",
1.1  darran 		    (ii->ii_type == II_GVAR ? "global" : "static"),
1.1  darran 		    ii->ii_name, id, (ii->ii_owner ? ii->ii_owner : "(none)"));
1.1  darran 	}
1.1  darran }
1.1  darran
1.1  darran static void
1.1  darran resurrect_functions(ctf_header_t *h, tdata_t *td, tdesc_t **tdarr, int tdsize,
1.1  darran     caddr_t ctfdata, symit_data_t *si)
1.1  darran {
1.1  darran 	caddr_t buf = ctfdata + h->cth_funcoff;
1.1  darran 	size_t bufsz = h->cth_typeoff - h->cth_funcoff;
1.1  darran 	caddr_t dptr = buf;
1.1  darran 	iidesc_t *ii;
1.1  darran 	ushort_t info;
1.1  darran 	ushort_t retid;
1.1  darran 	GElf_Sym *sym;
1.1  darran 	int i;
1.1  darran
1.1  darran 	symit_reset(si);
1.1  darran 	while (dptr < buf + bufsz) {
1.2  darran 		void *v = (void *) dptr;
1.2  darran 		info = *((ushort_t *)v);
1.1  darran 		dptr += 2;
1.1  darran
1.1  darran 		if (!(sym = symit_next(si, STT_FUNC)) && info != 0)
1.1  darran 			parseterminate("Unexpected end of function symbols");
1.1  darran
1.1  darran 		if (info == 0) {
1.1  darran 			debug(3, "Skipping null function (%s)\n",
1.1  darran 			    symit_name(si));
1.1  darran 			continue;
1.1  darran 		}
1.1  darran
1.2  darran 		v = (void *) dptr;
1.2  darran 		retid = *((ushort_t *)v);
1.1  darran 		dptr += 2;
1.1  darran
1.1  darran 		if (retid >= tdsize)
1.1  darran 			parseterminate("Reference to invalid type %d", retid);
1.1  darran
1.1  darran 		ii = iidesc_new(symit_name(si));
1.1  darran 		ii->ii_dtype = tdarr[retid];
1.1  darran 		if (GELF_ST_BIND(sym->st_info) == STB_LOCAL) {
1.1  darran 			ii->ii_type = II_SFUN;
1.1  darran 			ii->ii_owner = xstrdup(symit_curfile(si));
1.1  darran 		} else
1.1  darran 			ii->ii_type = II_GFUN;
1.1  darran 		ii->ii_nargs = CTF_INFO_VLEN(info);
1.1  darran 		if (ii->ii_nargs)
1.1  darran 			ii->ii_args =
1.1  darran 			    xmalloc(sizeof (tdesc_t *) * ii->ii_nargs);
1.1  darran
1.1  darran 		for (i = 0; i < ii->ii_nargs; i++, dptr += 2) {
1.2  darran 			v = (void *) dptr;
1.2  darran 			ushort_t id = *((ushort_t *)v);
1.1  darran 			if (id >= tdsize)
1.1  darran 				parseterminate("Reference to invalid type %d",
1.1  darran 				    id);
1.1  darran 			ii->ii_args[i] = tdarr[id];
1.1  darran 		}
1.1  darran
1.1  darran 		if (ii->ii_nargs && ii->ii_args[ii->ii_nargs - 1] == NULL) {
1.1  darran 			ii->ii_nargs--;
1.1  darran 			ii->ii_vargs = 1;
1.1  darran 		}
1.1  darran
1.1  darran 		hash_add(td->td_iihash, ii);
1.1  darran
1.1  darran 		debug(3, "Resurrected %s function %s (%d, %d args)\n",
1.1  darran 		    (ii->ii_type == II_GFUN ? "global" : "static"),
1.1  darran 		    ii->ii_name, retid, ii->ii_nargs);
1.1  darran 	}
1.1  darran }
1.1  darran
1.1  darran static void
1.1  darran resurrect_types(ctf_header_t *h, tdata_t *td, tdesc_t **tdarr, int tdsize,
1.1  darran     caddr_t ctfdata, int maxid)
1.1  darran {
1.1  darran 	caddr_t buf = ctfdata + h->cth_typeoff;
1.1  darran 	size_t bufsz = h->cth_stroff - h->cth_typeoff;
1.1  darran 	caddr_t sbuf = ctfdata + h->cth_stroff;
1.1  darran 	caddr_t dptr = buf;
1.1  darran 	tdesc_t *tdp;
1.1  darran 	uint_t data;
1.1  darran 	uint_t encoding;
1.1  darran 	size_t size, increment;
1.1  darran 	int tcnt;
1.1  darran 	int iicnt = 0;
1.1  darran 	tid_t tid, argid;
1.1  darran 	int kind, vlen;
1.1  darran 	int i;
1.1  darran
1.1  darran 	elist_t **epp;
1.1  darran 	mlist_t **mpp;
1.1  darran 	intr_t *ip;
1.1  darran
1.1  darran 	ctf_type_t *ctt;
1.1  darran 	ctf_array_t *cta;
1.1  darran 	ctf_enum_t *cte;
1.1  darran
1.1  darran 	/*
1.1  darran 	 * A maxid of zero indicates a request to resurrect all types, so reset
1.1  darran 	 * maxid to the maximum type id.
1.1  darran 	 */
1.1  darran 	if (maxid == 0)
1.1  darran 		maxid = CTF_MAX_TYPE;
1.1  darran
1.1  darran 	for (dptr = buf, tcnt = 0, tid = 1; dptr < buf + bufsz; tcnt++, tid++) {
1.1  darran 		if (tid > maxid)
1.1  darran 			break;
1.1  darran
1.1  darran 		if (tid >= tdsize)
1.1  darran 			parseterminate("Reference to invalid type %d", tid);
1.1  darran
1.2  darran 		void *v = (void *) dptr;
1.2  darran 		ctt = v;
1.1  darran
1.1  darran 		get_ctt_size(ctt, &size, &increment);
1.1  darran 		dptr += increment;
1.1  darran
1.1  darran 		tdp = tdarr[tid];
1.1  darran
1.1  darran 		if (CTF_NAME_STID(ctt->ctt_name) != CTF_STRTAB_0)
1.1  darran 			parseterminate(
1.4    haad 			    "Unable to cope with non-zero strtab id");
1.1  darran 		if (CTF_NAME_OFFSET(ctt->ctt_name) != 0) {
1.1  darran 			tdp->t_name =
1.1  darran 			    xstrdup(sbuf + CTF_NAME_OFFSET(ctt->ctt_name));
1.1  darran 		} else
1.1  darran 			tdp->t_name = NULL;
1.1  darran
1.1  darran 		kind = CTF_INFO_KIND(ctt->ctt_info);
1.1  darran 		vlen = CTF_INFO_VLEN(ctt->ctt_info);
1.1  darran
1.1  darran 		switch (kind) {
1.1  darran 		case CTF_K_INTEGER:
1.1  darran 			tdp->t_type = INTRINSIC;
1.1  darran 			tdp->t_size = size;
1.1  darran
1.2  darran 			v = (void *) dptr;
1.2  darran 			data = *((uint_t *)v);
1.1  darran 			dptr += sizeof (uint_t);
1.1  darran 			encoding = CTF_INT_ENCODING(data);
1.1  darran
1.1  darran 			ip = xmalloc(sizeof (intr_t));
1.1  darran 			ip->intr_type = INTR_INT;
1.1  darran 			ip->intr_signed = (encoding & CTF_INT_SIGNED) ? 1 : 0;
1.1  darran
1.1  darran 			if (encoding & CTF_INT_CHAR)
1.1  darran 				ip->intr_iformat = 'c';
1.1  darran 			else if (encoding & CTF_INT_BOOL)
1.1  darran 				ip->intr_iformat = 'b';
1.1  darran 			else if (encoding & CTF_INT_VARARGS)
1.1  darran 				ip->intr_iformat = 'v';
1.1  darran 			else
1.1  darran 				ip->intr_iformat = '\0';
1.1  darran
1.1  darran 			ip->intr_offset = CTF_INT_OFFSET(data);
1.1  darran 			ip->intr_nbits = CTF_INT_BITS(data);
1.1  darran 			tdp->t_intr = ip;
1.1  darran 			break;
1.1  darran
1.1  darran 		case CTF_K_FLOAT:
1.1  darran 			tdp->t_type = INTRINSIC;
1.1  darran 			tdp->t_size = size;
1.1  darran
1.2  darran 			v = (void *) dptr;
1.2  darran 			data = *((uint_t *)v);
1.1  darran 			dptr += sizeof (uint_t);
1.1  darran
1.1  darran 			ip = xcalloc(sizeof (intr_t));
1.1  darran 			ip->intr_type = INTR_REAL;
1.1  darran 			ip->intr_fformat = CTF_FP_ENCODING(data);
1.1  darran 			ip->intr_offset = CTF_FP_OFFSET(data);
1.1  darran 			ip->intr_nbits = CTF_FP_BITS(data);
1.1  darran 			tdp->t_intr = ip;
1.1  darran 			break;
1.1  darran
1.1  darran 		case CTF_K_POINTER:
1.1  darran 			tdp->t_type = POINTER;
1.1  darran 			tdp->t_tdesc = tdarr[ctt->ctt_type];
1.1  darran 			break;
1.1  darran
1.1  darran 		case CTF_K_ARRAY:
1.1  darran 			tdp->t_type = ARRAY;
1.1  darran 			tdp->t_size = size;
1.1  darran
1.2  darran 			v = (void *) dptr;
1.2  darran 			cta = v;
1.1  darran 			dptr += sizeof (ctf_array_t);
1.1  darran
1.1  darran 			tdp->t_ardef = xmalloc(sizeof (ardef_t));
1.1  darran 			tdp->t_ardef->ad_contents = tdarr[cta->cta_contents];
1.1  darran 			tdp->t_ardef->ad_idxtype = tdarr[cta->cta_index];
1.1  darran 			tdp->t_ardef->ad_nelems = cta->cta_nelems;
1.1  darran 			break;
1.1  darran
1.1  darran 		case CTF_K_STRUCT:
1.1  darran 		case CTF_K_UNION:
1.1  darran 			tdp->t_type = (kind == CTF_K_STRUCT ? STRUCT : UNION);
1.1  darran 			tdp->t_size = size;
1.1  darran
1.1  darran 			if (size < CTF_LSTRUCT_THRESH) {
1.1  darran 				for (i = 0, mpp = &tdp->t_members; i < vlen;
1.1  darran 				    i++, mpp = &((*mpp)->ml_next)) {
1.2  darran 					v = (void *) dptr;
1.2  darran 					ctf_member_t *ctm = v;
1.1  darran 					dptr += sizeof (ctf_member_t);
1.1  darran
1.1  darran 					*mpp = xmalloc(sizeof (mlist_t));
1.1  darran 					(*mpp)->ml_name = xstrdup(sbuf +
1.1  darran 					    ctm->ctm_name);
1.1  darran 					(*mpp)->ml_type = tdarr[ctm->ctm_type];
1.1  darran 					(*mpp)->ml_offset = ctm->ctm_offset;
1.1  darran 					(*mpp)->ml_size = 0;
1.1  darran 				}
1.1  darran 			} else {
1.1  darran 				for (i = 0, mpp = &tdp->t_members; i < vlen;
1.1  darran 				    i++, mpp = &((*mpp)->ml_next)) {
1.2  darran 					v = (void *) dptr;
1.2  darran 					ctf_lmember_t *ctlm = v;
1.1  darran 					dptr += sizeof (ctf_lmember_t);
1.1  darran
1.1  darran 					*mpp = xmalloc(sizeof (mlist_t));
1.1  darran 					(*mpp)->ml_name = xstrdup(sbuf +
1.1  darran 					    ctlm->ctlm_name);
1.1  darran 					(*mpp)->ml_type =
1.1  darran 					    tdarr[ctlm->ctlm_type];
1.1  darran 					(*mpp)->ml_offset =
1.1  darran 					    (int)CTF_LMEM_OFFSET(ctlm);
1.1  darran 					(*mpp)->ml_size = 0;
1.1  darran 				}
1.1  darran 			}
1.1  darran
1.1  darran 			*mpp = NULL;
1.1  darran 			break;
1.1  darran
1.1  darran 		case CTF_K_ENUM:
1.1  darran 			tdp->t_type = ENUM;
1.1  darran 			tdp->t_size = size;
1.1  darran
1.1  darran 			for (i = 0, epp = &tdp->t_emem; i < vlen;
1.1  darran 			    i++, epp = &((*epp)->el_next)) {
1.2  darran 				v = (void *) dptr;
1.2  darran 				cte = v;
1.1  darran 				dptr += sizeof (ctf_enum_t);
1.1  darran
1.1  darran 				*epp = xmalloc(sizeof (elist_t));
1.1  darran 				(*epp)->el_name = xstrdup(sbuf + cte->cte_name);
1.1  darran 				(*epp)->el_number = cte->cte_value;
1.1  darran 			}
1.1  darran 			*epp = NULL;
1.1  darran 			break;
1.1  darran
1.1  darran 		case CTF_K_FORWARD:
1.1  darran 			tdp->t_type = FORWARD;
1.1  darran 			list_add(&td->td_fwdlist, tdp);
1.1  darran 			break;
1.1  darran
1.1  darran 		case CTF_K_TYPEDEF:
1.1  darran 			tdp->t_type = TYPEDEF;
1.1  darran 			tdp->t_tdesc = tdarr[ctt->ctt_type];
1.1  darran 			break;
1.1  darran
1.1  darran 		case CTF_K_VOLATILE:
1.1  darran 			tdp->t_type = VOLATILE;
1.1  darran 			tdp->t_tdesc = tdarr[ctt->ctt_type];
1.1  darran 			break;
1.1  darran
1.1  darran 		case CTF_K_CONST:
1.1  darran 			tdp->t_type = CONST;
1.1  darran 			tdp->t_tdesc = tdarr[ctt->ctt_type];
1.1  darran 			break;
1.1  darran
1.1  darran 		case CTF_K_FUNCTION:
1.1  darran 			tdp->t_type = FUNCTION;
1.1  darran 			tdp->t_fndef = xcalloc(sizeof (fndef_t));
1.1  darran 			tdp->t_fndef->fn_ret = tdarr[ctt->ctt_type];
1.1  darran
1.2  darran 			v = (void *) (dptr + (sizeof (ushort_t) * (vlen - 1)));
1.2  darran 			if (vlen > 0 && *(ushort_t *)v == 0)
1.1  darran 				tdp->t_fndef->fn_vargs = 1;
1.1  darran
1.1  darran 			tdp->t_fndef->fn_nargs = vlen - tdp->t_fndef->fn_vargs;
1.1  darran 			tdp->t_fndef->fn_args = xcalloc(sizeof (tdesc_t) *
1.1  darran 			    vlen - tdp->t_fndef->fn_vargs);
1.1  darran
1.1  darran 			for (i = 0; i < vlen; i++) {
1.2  darran 				v = (void *) dptr;
1.2  darran 				argid = *(ushort_t *)v;
1.1  darran 				dptr += sizeof (ushort_t);
1.1  darran
1.1  darran 				if (argid != 0)
1.1  darran 					tdp->t_fndef->fn_args[i] = tdarr[argid];
1.1  darran 			}
1.1  darran
1.1  darran 			if (vlen & 1)
1.1  darran 				dptr += sizeof (ushort_t);
1.1  darran 			break;
1.1  darran
1.1  darran 		case CTF_K_RESTRICT:
1.1  darran 			tdp->t_type = RESTRICT;
1.1  darran 			tdp->t_tdesc = tdarr[ctt->ctt_type];
1.1  darran 			break;
1.1  darran
1.1  darran 		case CTF_K_UNKNOWN:
1.1  darran 			break;
1.1  darran
1.1  darran 		default:
1.1  darran 			warning("Can't parse unknown CTF type %d\n", kind);
1.1  darran 		}
1.1  darran
1.1  darran 		if (CTF_INFO_ISROOT(ctt->ctt_info)) {
1.1  darran 			iidesc_t *ii = iidesc_new(tdp->t_name);
1.1  darran 			if (tdp->t_type == STRUCT || tdp->t_type == UNION ||
1.1  darran 			    tdp->t_type == ENUM)
1.1  darran 				ii->ii_type = II_SOU;
1.1  darran 			else
1.1  darran 				ii->ii_type = II_TYPE;
1.1  darran 			ii->ii_dtype = tdp;
1.1  darran 			hash_add(td->td_iihash, ii);
1.1  darran
1.1  darran 			iicnt++;
1.1  darran 		}
1.1  darran
1.1  darran 		debug(3, "Resurrected %d %stype %s (%d)\n", tdp->t_type,
1.1  darran 		    (CTF_INFO_ISROOT(ctt->ctt_info) ? "root " : ""),
1.1  darran 		    tdesc_name(tdp), tdp->t_id);
1.1  darran 	}
1.1  darran
1.1  darran 	debug(3, "Resurrected %d types (%d were roots)\n", tcnt, iicnt);
1.1  darran }
1.1  darran
1.1  darran /*
1.1  darran  * For lack of other inspiration, we're going to take the boring route.  We
1.1  darran  * count the number of types.  This lets us malloc that many tdesc structs
1.1  darran  * before we start filling them in.  This has the advantage of allowing us to
1.1  darran  * avoid a merge-esque remap step.
1.1  darran  */
1.1  darran static tdata_t *
1.1  darran ctf_parse(ctf_header_t *h, caddr_t buf, symit_data_t *si, char *label)
1.1  darran {
1.1  darran 	tdata_t *td = tdata_new();
1.1  darran 	tdesc_t **tdarr;
1.1  darran 	int ntypes = count_types(h, buf);
1.1  darran 	int idx, i;
1.1  darran
1.1  darran 	/* shudder */
1.1  darran 	tdarr = xcalloc(sizeof (tdesc_t *) * (ntypes + 1));
1.1  darran 	tdarr[0] = NULL;
1.1  darran 	for (i = 1; i <= ntypes; i++) {
1.1  darran 		tdarr[i] = xcalloc(sizeof (tdesc_t));
1.1  darran 		tdarr[i]->t_id = i;
1.1  darran 	}
1.1  darran
1.1  darran 	td->td_parlabel = xstrdup(buf + h->cth_stroff + h->cth_parlabel);
1.1  darran
1.1  darran 	/* we have the technology - we can rebuild them */
1.1  darran 	idx = resurrect_labels(h, td, buf, label);
1.1  darran
1.1  darran 	resurrect_objects(h, td, tdarr, ntypes + 1, buf, si);
1.1  darran 	resurrect_functions(h, td, tdarr, ntypes + 1, buf, si);
1.1  darran 	resurrect_types(h, td, tdarr, ntypes + 1, buf, idx);
1.1  darran
1.1  darran 	free(tdarr);
1.1  darran
1.1  darran 	td->td_nextid = ntypes + 1;
1.1  darran
1.1  darran 	return (td);
1.1  darran }
1.1  darran
1.1  darran static size_t
1.1  darran decompress_ctf(caddr_t cbuf, size_t cbufsz, caddr_t dbuf, size_t dbufsz)
1.1  darran {
1.1  darran 	z_stream zstr;
1.1  darran 	int rc;
1.1  darran
1.1  darran 	zstr.zalloc = (alloc_func)0;
1.1  darran 	zstr.zfree = (free_func)0;
1.1  darran 	zstr.opaque = (voidpf)0;
1.1  darran
1.1  darran 	zstr.next_in = (Bytef *)cbuf;
1.1  darran 	zstr.avail_in = cbufsz;
1.1  darran 	zstr.next_out = (Bytef *)dbuf;
1.1  darran 	zstr.avail_out = dbufsz;
1.1  darran
1.1  darran 	if ((rc = inflateInit(&zstr)) != Z_OK ||
1.1  darran 	    (rc = inflate(&zstr, Z_NO_FLUSH)) != Z_STREAM_END ||
1.1  darran 	    (rc = inflateEnd(&zstr)) != Z_OK) {
1.1  darran 		warning("CTF decompress zlib error %s\n", zError(rc));
1.2  darran 		return (0);
1.1  darran 	}
1.1  darran
1.1  darran 	debug(3, "reflated %lu bytes to %lu, pointer at %d\n",
1.1  darran 	    zstr.total_in, zstr.total_out, (caddr_t)zstr.next_in - cbuf);
1.1  darran
1.1  darran 	return (zstr.total_out);
1.1  darran }
1.1  darran
1.1  darran /*
1.1  darran  * Reconstruct the type tree from a given buffer of CTF data.  Only the types
1.1  darran  * up to the type associated with the provided label, inclusive, will be
1.1  darran  * reconstructed.  If a NULL label is provided, all types will be reconstructed.
1.1  darran  *
1.1  darran  * This function won't work on files that have been uniquified.
1.1  darran  */
1.1  darran tdata_t *
1.1  darran ctf_load(char *file, caddr_t buf, size_t bufsz, symit_data_t *si, char *label)
1.1  darran {
1.1  darran 	ctf_header_t *h;
1.1  darran 	caddr_t ctfdata;
1.1  darran 	size_t ctfdatasz;
1.1  darran 	tdata_t *td;
1.1  darran
1.1  darran 	curfile = file;
1.1  darran
1.1  darran 	if (bufsz < sizeof (ctf_header_t))
1.1  darran 		parseterminate("Corrupt CTF - short header");
1.1  darran
1.2  darran 	void *v = (void *) buf;
1.2  darran 	h = v;
1.1  darran 	buf += sizeof (ctf_header_t);
1.1  darran 	bufsz -= sizeof (ctf_header_t);
1.1  darran
1.1  darran 	if (h->cth_magic != CTF_MAGIC)
1.1  darran 		parseterminate("Corrupt CTF - bad magic 0x%x", h->cth_magic);
1.1  darran
1.1  darran 	if (h->cth_version != CTF_VERSION)
1.1  darran 		parseterminate("Unknown CTF version %d", h->cth_version);
1.1  darran
1.1  darran 	ctfdatasz = h->cth_stroff + h->cth_strlen;
1.1  darran 	if (h->cth_flags & CTF_F_COMPRESS) {
1.1  darran 		size_t actual;
1.1  darran
1.1  darran 		ctfdata = xmalloc(ctfdatasz);
1.1  darran 		if ((actual = decompress_ctf(buf, bufsz, ctfdata, ctfdatasz)) !=
1.1  darran 		    ctfdatasz) {
1.1  darran 			parseterminate("Corrupt CTF - short decompression "
1.1  darran 			    "(was %d, expecting %d)", actual, ctfdatasz);
1.1  darran 		}
1.1  darran 	} else {
1.1  darran 		ctfdata = buf;
1.1  darran 		ctfdatasz = bufsz;
1.1  darran 	}
1.1  darran
1.1  darran 	td = ctf_parse(h, ctfdata, si, label);
1.1  darran
1.1  darran 	if (h->cth_flags & CTF_F_COMPRESS)
1.1  darran 		free(ctfdata);
1.1  darran
1.1  darran 	curfile = NULL;
1.1  darran
1.1  darran 	return (td);
1.1  darran }