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      1 /*
      2  * CDDL HEADER START
      3  *
      4  * The contents of this file are subject to the terms of the
      5  * Common Development and Distribution License (the "License").
      6  * You may not use this file except in compliance with the License.
      7  *
      8  * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
      9  * or http://www.opensolaris.org/os/licensing.
     10  * See the License for the specific language governing permissions
     11  * and limitations under the License.
     12  *
     13  * When distributing Covered Code, include this CDDL HEADER in each
     14  * file and include the License file at usr/src/OPENSOLARIS.LICENSE.
     15  * If applicable, add the following below this CDDL HEADER, with the
     16  * fields enclosed by brackets "[]" replaced with your own identifying
     17  * information: Portions Copyright [yyyy] [name of copyright owner]
     18  *
     19  * CDDL HEADER END
     20  */
     21 /*
     22  * Copyright 2009 Sun Microsystems, Inc.  All rights reserved.
     23  * Use is subject to license terms.
     24  */
     25 
     26 /*
     27  * NDR heap management. The heap is used for temporary storage by
     28  * both the client and server side library routines.  In order to
     29  * support the different requirements of the various RPCs, the heap
     30  * can grow dynamically if required.  We start with a single block
     31  * and perform sub-allocations from it.  If an RPC requires more space
     32  * we will continue to add it a block at a time.  This means that we
     33  * don't hog lots of memory on every call to support the few times
     34  * that we actually need a lot heap space.
     35  *
     36  * Note that there is no individual free function.  Once space has been
     37  * allocated, it remains allocated until the heap is destroyed.  This
     38  * shouldn't be an issue because the heap is being filled with data to
     39  * be marshalled or unmarshalled and we need it all to be there until
     40  * the point that the entire heap is no longer required.
     41  */
     42 
     43 #include <sys/errno.h>
     44 #include <stdlib.h>
     45 #include <string.h>
     46 #include <strings.h>
     47 #include <sys/uio.h>
     48 
     49 #include <smbsrv/libsmb.h>
     50 #include <smbsrv/libmlrpc.h>
     51 #include <smbsrv/smb_sid.h>
     52 
     53 /*
     54  * Allocate a heap structure and the first heap block.  For many RPC
     55  * operations this will be the only time we need to malloc memory
     56  * in this instance of the heap.  The only point of note here is that
     57  * we put the heap management data in the first block to avoid a
     58  * second malloc. Make sure that sizeof(ndr_heap_t) is smaller
     59  * than NDR_HEAP_BLKSZ.
     60  *
     61  * Note that the heap management data is at the start of the first block.
     62  *
     63  * Returns a pointer to the newly created heap, which is used like an
     64  * opaque handle with the rest of the heap management interface..
     65  */
     66 ndr_heap_t *
     67 ndr_heap_create(void)
     68 {
     69 	ndr_heap_t *heap;
     70 	char *base;
     71 	size_t allocsize = sizeof (ndr_heap_t) + NDR_HEAP_BLKSZ;
     72 
     73 	if ((heap = malloc(allocsize)) == NULL)
     74 		return (NULL);
     75 
     76 	base = (char *)heap;
     77 	bzero(heap, sizeof (ndr_heap_t));
     78 
     79 	heap->iovcnt = NDR_HEAP_MAXIOV;
     80 	heap->iov = heap->iovec;
     81 	heap->iov->iov_base = base;
     82 	heap->iov->iov_len = sizeof (ndr_heap_t);
     83 	heap->top = base + allocsize;
     84 	heap->next = base + sizeof (ndr_heap_t);
     85 
     86 	return (heap);
     87 }
     88 
     89 /*
     90  * Deallocate all of the memory associated with a heap.  This is the
     91  * only way to deallocate heap memory, it isn't possible to free the
     92  * space obtained by individual malloc calls.
     93  *
     94  * Note that the first block contains the heap management data, which
     95  * is deleted last.
     96  */
     97 void
     98 ndr_heap_destroy(ndr_heap_t *heap)
     99 {
    100 	int i;
    101 	char *p;
    102 
    103 	if (heap) {
    104 		for (i = 1; i < NDR_HEAP_MAXIOV; ++i) {
    105 			if ((p = heap->iovec[i].iov_base) != NULL)
    106 				free(p);
    107 		}
    108 
    109 		free(heap);
    110 	}
    111 }
    112 
    113 /*
    114  * Allocate space in the specified heap.  All requests are padded, if
    115  * required, to ensure dword alignment.  If the current iov will be
    116  * exceeded, we allocate a new block and setup the next iov.  Otherwise
    117  * all we have to do is move the next pointer and update the current
    118  * iov length.
    119  *
    120  * On success, a pointer to the allocated (dword aligned) area is
    121  * returned.  Otherwise a null pointer is returned.
    122  */
    123 void *
    124 ndr_heap_malloc(ndr_heap_t *heap, unsigned size)
    125 {
    126 	char *p;
    127 	int incr_size;
    128 
    129 	size += NDR_ALIGN4(size);
    130 
    131 	if (heap == NULL || size == 0)
    132 		return (NULL);
    133 
    134 	p = heap->next;
    135 
    136 	if (p + size > heap->top) {
    137 		if ((heap->iovcnt == 0) || ((--heap->iovcnt) == 0))
    138 			return (NULL);
    139 
    140 		incr_size = (size < NDR_HEAP_BLKSZ) ? NDR_HEAP_BLKSZ : size;
    141 
    142 		if ((p = (char *)malloc(incr_size)) == NULL)
    143 			return (NULL);
    144 
    145 		++heap->iov;
    146 		heap->iov->iov_base = p;
    147 		heap->iov->iov_len = 0;
    148 		heap->top = p + incr_size;
    149 	}
    150 
    151 	heap->next = p + size;
    152 	heap->iov->iov_len += size;
    153 	return ((void *)p);
    154 }
    155 
    156 /*
    157  * Convenience function to do heap strdup.
    158  */
    159 void *
    160 ndr_heap_strdup(ndr_heap_t *heap, const char *s)
    161 {
    162 	int len;
    163 	void *p;
    164 
    165 	if (s == NULL)
    166 		return (NULL);
    167 
    168 	/*
    169 	 * We don't need to clutter the heap with empty strings.
    170 	 */
    171 	if ((len = strlen(s)) == 0)
    172 		return ("");
    173 
    174 	if ((p = ndr_heap_malloc(heap, len+1)) != NULL)
    175 		(void) strcpy((char *)p, s);
    176 
    177 	return (p);
    178 }
    179 
    180 /*
    181  * Make an ndr_mstring_t from a regular string.
    182  */
    183 int
    184 ndr_heap_mstring(ndr_heap_t *heap, const char *s, ndr_mstring_t *out)
    185 {
    186 	if (s == NULL || out == NULL)
    187 		return (-1);
    188 
    189 	out->length = smb_wcequiv_strlen(s);
    190 	out->allosize = out->length + sizeof (smb_wchar_t);
    191 
    192 	if ((out->str = ndr_heap_strdup(heap, s)) == NULL)
    193 		return (-1);
    194 
    195 	return (0);
    196 }
    197 
    198 /*
    199  * Our regular string marshalling always creates null terminated strings
    200  * but some Windows clients and servers are pedantic about the string
    201  * formats they will accept and require non-null terminated strings.
    202  * This function can be used to build a wide-char, non-null terminated
    203  * string in the heap as a varying/conformant array.  We need to do the
    204  * wide-char conversion here because the marshalling code won't be
    205  * aware that this is really a string.
    206  */
    207 void
    208 ndr_heap_mkvcs(ndr_heap_t *heap, char *s, ndr_vcstr_t *vc)
    209 {
    210 	int mlen;
    211 
    212 	vc->wclen = smb_wcequiv_strlen(s);
    213 	vc->wcsize = vc->wclen;
    214 
    215 	mlen = sizeof (ndr_vcs_t) + vc->wcsize + sizeof (smb_wchar_t);
    216 
    217 	vc->vcs = ndr_heap_malloc(heap, mlen);
    218 
    219 	if (vc->vcs) {
    220 		vc->vcs->vc_first_is = 0;
    221 		vc->vcs->vc_length_is = vc->wclen / sizeof (smb_wchar_t);
    222 		(void) smb_mbstowcs((smb_wchar_t *)vc->vcs->buffer, s,
    223 		    vc->vcs->vc_length_is);
    224 	}
    225 }
    226 
    227 void
    228 ndr_heap_mkvcb(ndr_heap_t *heap, uint8_t *data, uint32_t datalen,
    229     ndr_vcbuf_t *vcbuf)
    230 {
    231 	int mlen;
    232 
    233 	if (data == NULL || datalen == 0) {
    234 		bzero(vcbuf, sizeof (ndr_vcbuf_t));
    235 		return;
    236 	}
    237 
    238 	vcbuf->len = datalen;
    239 	vcbuf->size = datalen;
    240 
    241 	mlen = sizeof (ndr_vcbuf_t) + datalen;
    242 
    243 	vcbuf->vcb = ndr_heap_malloc(heap, mlen);
    244 
    245 	if (vcbuf->vcb) {
    246 		vcbuf->vcb->vc_first_is = 0;
    247 		vcbuf->vcb->vc_length_is = datalen;
    248 		bcopy(data, vcbuf->vcb->buffer, datalen);
    249 	}
    250 }
    251 
    252 /*
    253  * Duplcate a SID in the heap.
    254  */
    255 smb_sid_t *
    256 ndr_heap_siddup(ndr_heap_t *heap, smb_sid_t *sid)
    257 {
    258 	smb_sid_t *new_sid;
    259 	unsigned size;
    260 
    261 	if (sid == NULL)
    262 		return (NULL);
    263 
    264 	size = smb_sid_len(sid);
    265 
    266 	if ((new_sid = ndr_heap_malloc(heap, size)) == NULL)
    267 		return (NULL);
    268 
    269 	bcopy(sid, new_sid, size);
    270 	return (new_sid);
    271 }
    272 
    273 int
    274 ndr_heap_used(ndr_heap_t *heap)
    275 {
    276 	int used = 0;
    277 	int i;
    278 
    279 	for (i = 0; i < NDR_HEAP_MAXIOV; ++i)
    280 		used += heap->iovec[i].iov_len;
    281 
    282 	return (used);
    283 }
    284 
    285 int
    286 ndr_heap_avail(ndr_heap_t *heap)
    287 {
    288 	int avail;
    289 	int count;
    290 
    291 	count = (heap->iovcnt == 0) ? 0 : (heap->iovcnt - 1);
    292 
    293 	avail = count * NDR_HEAP_BLKSZ;
    294 	avail += (heap->top - heap->next);
    295 
    296 	return (avail);
    297 }
    298