src/common_device_name.c - chromiumos/third_party/libpciaccess - Git at Google

 /*
  * (C) Copyright IBM Corporation 2006
  * All Rights Reserved.
  *
  * Permission is hereby granted, free of charge, to any person obtaining a
  * copy of this software and associated documentation files (the "Software"),
  * to deal in the Software without restriction, including without limitation
  * on the rights to use, copy, modify, merge, publish, distribute, sub
  * license, and/or sell copies of the Software, and to permit persons to whom
  * the Software is furnished to do so, subject to the following conditions:
  *
  * The above copyright notice and this permission notice (including the next
  * paragraph) shall be included in all copies or substantial portions of the
  * Software.
  *
  * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
  * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
  * FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT.  IN NO EVENT SHALL
  * IBM AND/OR THEIR SUPPLIERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
  * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
  * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER
  * DEALINGS IN THE SOFTWARE.
  */

 /**
  * \file common_device_name.c
  * Support routines used to determine the vendor or device names associated
  * with a particular device or vendor.
  */

 #ifdef HAVE_CONFIG_H
 #include "config.h"
 #endif

 #include <stdio.h>
 #include <stdlib.h>
 #include <ctype.h>

 #if defined(HAVE_STRING_H)
 # include <string.h>
 #elif defined(HAVE_STRINGS_H)
 # include <strings.h>
 #endif

 #if defined(HAVE_INTTYPES_H)
 # include <inttypes.h>
 #elif defined(HAVE_STDINT_H)
 # include <stdint.h>
 #endif

 #include "pciaccess.h"
 #include "pciaccess_private.h"

 #define DO_MATCH(a,b)  (((a) == PCI_MATCH_ANY) || ((a) == (b)))

 #ifdef HAVE_ZLIB

 #include <zlib.h>
 typedef gzFile pci_id_file;

 static pci_id_file
 pci_id_file_open(void)
 {
     pci_id_file result;

     result = gzopen(PCIIDS_PATH "/pci.ids.gz", "rb");
     if (result)
         return result;

     return gzopen(PCIIDS_PATH "/pci.ids", "rb");
 }

 #define pci_id_file_gets(l, s, f)	gzgets(f, l, s)
 #define pci_id_file_close(f)		gzclose(f)

 #else /* not zlib */

 typedef FILE * pci_id_file;

 static pci_id_file
 pci_id_file_open(void)
 {
 #ifndef __sun
     pci_id_file result;

     result = fopen(PCIIDS_PATH "/pci.ids", "re");
     if (result)
         return result;
 #endif

     return fopen(PCIIDS_PATH "/pci.ids", "r");
 }

 #define pci_id_file_gets(l, s, f)	fgets(l, s, f)
 #define pci_id_file_close(f)		fclose(f)

 #endif

 /**
  * Node for sorting vendor IDs.
  *
  * Each structure forms an internal node of an n-way tree.  Each node selects
  * \c pci_id_node::bits number of bits from the vendor ID.  Starting from the
  * root of the tree, a slice of the low-order bits of the vendor ID are
  * selected and used as an index into the \c pci_id_node::children array.
  *
  * At the leaf nodes (i.e., the node entered when all 16 bits of the vendor ID
  * have been used), the \c pci_id_node::children is actually an array of
  * pointers to \c pci_id_leaf structures.
  *
  * \todo
  * Determine if there is a cleaner way (in the source code) to have the
  * \c children array change type based on whether the node is internal or
  * a leaf.
  *
  * \todo
  * Currently \c bits is always 4.  Decide if this value can ever change
  * (i.e., to pull-up levels of the n-way tree when all the children's children
  * are full).  If it can, rip it out and hard-code it to 4 everywhere.
  */
 struct pci_id_node {
     unsigned bits;
     struct pci_id_node * children[16];
 };

 struct pci_id_leaf {
     uint16_t     vendor;
     const char * vendor_name;

     size_t num_devices;
     struct pci_device_leaf * devices;
 };

 struct pci_device_leaf {
     struct pci_id_match   id;
     const char * device_name;
 };

 /**
  * Root of the PCI vendor ID search tree.
  */
 _pci_hidden struct pci_id_node * tree = NULL;

 /**
  * Get a pointer to the leaf node for a vendor ID.
  *
  * If the vendor ID does not exist in the tree, it is added.
  */
 static struct pci_id_leaf *
 insert( uint16_t vendor )
 {
     struct pci_id_node * n;
     unsigned bits = 0;

     if ( tree == NULL ) {
 	tree = calloc( 1, sizeof( struct pci_id_node ) );
 	tree->bits = 4;
     }

     n = tree;
     while ( n != NULL ) {
 	const unsigned used_bits = n->bits;
 	const unsigned mask = (1 << used_bits) - 1;
 	const unsigned idx = (vendor & (mask << bits)) >> bits;


 	if ( bits >= 16 ) {
 	    break;
 	}

 	bits += used_bits;

 	if ( n->children[ idx ] == NULL ) {
 	    if ( bits < 16 ) {
 		struct pci_id_node * child =
 		    calloc( 1, sizeof( struct pci_id_node ) );

 		child->bits = 4;

 		n->children[ idx ] = child;
 	    }
 	    else {
 		struct pci_id_leaf * leaf =
 		    calloc( 1, sizeof( struct pci_id_leaf ) );

 		leaf->vendor = vendor;

 		n->children[ idx ] = (struct pci_id_node *) leaf;
 	    }
 	}

 	n = n->children[ idx ];
     }

     return (struct pci_id_leaf *) n;
 }


 /**
  * Populate a vendor node with all the devices associated with that vendor
  *
  * \param vend  Vendor node that is to be filled from the pci.ids file.
  *
  * \todo
  * The parsing in this function should be more rhobust.  There are some error
  * cases (i.e., a 0-tab line followed by a 2-tab line) that aren't handled
  * correctly.  I don't think there are any security problems with the code,
  * but it's not impossible.
  */
 static void
 populate_vendor( struct pci_id_leaf * vend, int fill_device_data )
 {
     pci_id_file f;
     char buf[128];
     unsigned vendor = PCI_MATCH_ANY;


     /* If the device tree for this vendor is already populated, don't do
      * anything.  This avoids wasted processing and potential memory leaks.
      */
     if (vend->num_devices != 0) {
 	return;
     }

     f = pci_id_file_open();

     /* If the pci.ids file could not be opened, there's nothing we can do.
      */
     if (f == NULL) {
 	return;
     }

     while( pci_id_file_gets( buf, sizeof( buf ), f ) != NULL ) {
 	unsigned num_tabs;
 	char * new_line;
 	size_t length;

 	/* Each line either starts with zero, one, or two tabs followed by
 	 * a series of 4 hex digits.  Any lines not matching that are ignored.
 	 */

 	for ( num_tabs = 0 ; num_tabs < 3 ; num_tabs++ ) {
 	    if ( buf[ num_tabs ] != '\t' ) {
 		break;
 	    }
 	}

 	if ( !isxdigit( buf[ num_tabs + 0 ] )
 	     || !isxdigit( buf[ num_tabs + 1 ] )
 	     || !isxdigit( buf[ num_tabs + 2 ] )
 	     || !isxdigit( buf[ num_tabs + 3 ] ) ) {
 	    continue;
 	}

 	new_line = strchr( buf, '\n' );
 	if ( new_line != NULL ) {
 	    *new_line = '\0';
 	}

 	length = strlen( buf );
 	(void) memset( buf + length, 0, sizeof( buf ) - length );


 	if ( num_tabs == 0 ) {
 	    vendor = (unsigned) strtoul( & buf[ num_tabs ], NULL, 16 );
 	    if ( vend->vendor == vendor ) {
 		/* vendor_name may already be set from a previous invocation
 		 * of this function with fill_device_data = 0.
 		 */
 		if (vend->vendor_name == NULL) {
 		    vend->vendor_name = strdup( & buf[ num_tabs + 6 ] );
 		}

 		/* If we're not going to fill in all of the device data as
 		 * well, then bail out now.  We have all the information that
 		 * we need.
 		 */
 		if ( ! fill_device_data ) {
 		    break;
 		}
 	    }
 	}
 	else if ( vendor == vend->vendor ) {
 	    struct pci_device_leaf * d;
 	    struct pci_device_leaf * dev;
 	    struct pci_device_leaf * last_dev;


 	    d = realloc( vend->devices, (vend->num_devices + 1)
 			 * sizeof( struct pci_device_leaf ) );
 	    if ( d == NULL ) {
 		goto cleanup;
 	    }

 	    last_dev = & d[ vend->num_devices - 1 ];
 	    dev = & d[ vend->num_devices ];
 	    vend->num_devices++;
 	    vend->devices = d;

 	    if ( num_tabs == 1 ) {
 		dev->id.vendor_id = vend->vendor;
 		dev->id.device_id = (unsigned) strtoul( & buf[ num_tabs ],
 							NULL, 16 );
 		dev->id.subvendor_id = PCI_MATCH_ANY;
 		dev->id.subdevice_id = PCI_MATCH_ANY;

 		dev->id.device_class = 0;
 		dev->id.device_class_mask = 0;
 		dev->id.match_data = 0;

 		dev->device_name = strdup( & buf[ num_tabs + 6 ] );
 	    }
 	    else {
 		dev->id = last_dev->id;

 		dev->id.subvendor_id= (unsigned) strtoul( & buf[ num_tabs ],
 							  NULL, 16 );
 		dev->id.subdevice_id = (unsigned) strtoul( & buf[ num_tabs + 5 ],
 							   NULL, 16 );
 		dev->device_name = strdup( & buf[ num_tabs + 5 + 6 ] );
 	    }
 	}
     }

   cleanup:
     pci_id_file_close( f );
 }


 /**
  * Find the name of the specified device.
  *
  * Finds the actual product name of the specified device.  If a subvendor ID
  * and subdevice ID are specified in \c m, the returned name will be the name
  * of the subdevice.
  */
 static const char *
 find_device_name( const struct pci_id_match * m )
 {
     struct pci_id_leaf * vend;
     unsigned i;


     if ( m->vendor_id == PCI_MATCH_ANY ) {
 	return NULL;
     }


     vend = insert( m->vendor_id );
     if ( vend == NULL ) {
 	return NULL;
     }

     if ( vend->num_devices == 0 ) {
 	populate_vendor( vend, 1 );
     }


     for ( i = 0 ; i < vend->num_devices ; i++ ) {
 	struct pci_device_leaf * d = & vend->devices[ i ];

 	if ( DO_MATCH( m->vendor_id, d->id.vendor_id )
 	     && DO_MATCH( m->device_id, d->id.device_id )
 	     && DO_MATCH( m->subvendor_id, d->id.subvendor_id )
 	     && DO_MATCH( m->subdevice_id, d->id.subdevice_id ) ) {
 	    return d->device_name;
 	}
     }

     return NULL;
 }


 /**
  * Find the vendor name of the specified device.
  *
  * Finds the actual vendor name of the specified device.  If a subvendor ID
  * and subdevice ID are specified in \c m, the returned name will be the name
  * associated with the subvendor.
  */
 static const char *
 find_vendor_name( const struct pci_id_match * m )
 {
     struct pci_id_leaf * vend;


     if ( m->vendor_id == PCI_MATCH_ANY ) {
 	return NULL;
     }


     vend = insert( m->vendor_id );
     if ( vend == NULL ) {
 	return NULL;
     }

     if ( vend->vendor_name == NULL ) {
 	populate_vendor( vend, 0 );
     }


     return vend->vendor_name;
 }


 /**
  * Get a name based on an arbitrary PCI search structure.
  */
 void
 pci_get_strings( const struct pci_id_match * m,
 		 const char ** device_name,
 		 const char ** vendor_name,
 		 const char ** subdevice_name,
 		 const char ** subvendor_name )
 {
     struct pci_id_match  temp;


     temp = *m;
     temp.subvendor_id = PCI_MATCH_ANY;
     temp.subdevice_id = PCI_MATCH_ANY;

     if ( device_name != NULL ) {
 	*device_name = find_device_name( & temp );
     }

     if ( vendor_name != NULL ) {
 	*vendor_name = find_vendor_name( & temp );
     }

     if ( subdevice_name != NULL ) {
 	*subdevice_name = find_device_name( m );
     }

     if ( subvendor_name != NULL ) {
 	*subvendor_name = find_vendor_name( m );
     }
 }


 /**
  * Get the name associated with the device's primary device ID.
  */
 const char *
 pci_device_get_device_name( const struct pci_device * dev )
 {
     struct pci_id_match m;


     m.vendor_id = dev->vendor_id;
     m.device_id = dev->device_id;
     m.subvendor_id = PCI_MATCH_ANY;
     m.subdevice_id = PCI_MATCH_ANY;
     m.device_class = 0;
     m.device_class_mask = 0;
     m.match_data = 0;

     return find_device_name( & m );
 }


 /**
  * Get the name associated with the device's subdevice ID.
  */
 const char *
 pci_device_get_subdevice_name( const struct pci_device * dev )
 {
     struct pci_id_match m;


     if ( (dev->subvendor_id == 0) || (dev->subdevice_id == 0) ) {
 	return NULL;
     }

     m.vendor_id = dev->vendor_id;
     m.device_id = dev->device_id;
     m.subvendor_id = dev->subvendor_id;
     m.subdevice_id = dev->subdevice_id;
     m.device_class = 0;
     m.device_class_mask = 0;
     m.match_data = 0;

     return find_device_name( & m );
 }


 /**
  * Get the name associated with the device's primary vendor ID.
  */
 const char *
 pci_device_get_vendor_name( const struct pci_device * dev )
 {
     struct pci_id_match m;


     m.vendor_id = dev->vendor_id;
     m.device_id = PCI_MATCH_ANY;
     m.subvendor_id = PCI_MATCH_ANY;
     m.subdevice_id = PCI_MATCH_ANY;
     m.device_class = 0;
     m.device_class_mask = 0;
     m.match_data = 0;

     return find_vendor_name( & m );
 }


 /**
  * Get the name associated with the device's subvendor ID.
  */
 const char *
 pci_device_get_subvendor_name( const struct pci_device * dev )
 {
     struct pci_id_match m;


     if ( dev->subvendor_id == 0 ) {
 	return NULL;
     }


     m.vendor_id = dev->subvendor_id;
     m.device_id = PCI_MATCH_ANY;
     m.subvendor_id = PCI_MATCH_ANY;
     m.subdevice_id = PCI_MATCH_ANY;
     m.device_class = 0;
     m.device_class_mask = 0;
     m.match_data = 0;

     return find_vendor_name( & m );
 }
	/*
	* (C) Copyright IBM Corporation 2006
	* All Rights Reserved.
	*
	* Permission is hereby granted, free of charge, to any person obtaining a
	* copy of this software and associated documentation files (the "Software"),
	* to deal in the Software without restriction, including without limitation
	* on the rights to use, copy, modify, merge, publish, distribute, sub
	* license, and/or sell copies of the Software, and to permit persons to whom
	* the Software is furnished to do so, subject to the following conditions:
	*
	* The above copyright notice and this permission notice (including the next
	* paragraph) shall be included in all copies or substantial portions of the
	* Software.
	*
	* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
	* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
	* FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT. IN NO EVENT SHALL
	* IBM AND/OR THEIR SUPPLIERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
	* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
	* FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER
	* DEALINGS IN THE SOFTWARE.
	*/

	/**
	* \file common_device_name.c
	* Support routines used to determine the vendor or device names associated
	* with a particular device or vendor.
	*/

	#ifdef HAVE_CONFIG_H
	#include "config.h"
	#endif

	#include <stdio.h>
	#include <stdlib.h>
	#include <ctype.h>

	#if defined(HAVE_STRING_H)
	# include <string.h>
	#elif defined(HAVE_STRINGS_H)
	# include <strings.h>
	#endif

	#if defined(HAVE_INTTYPES_H)
	# include <inttypes.h>
	#elif defined(HAVE_STDINT_H)
	# include <stdint.h>
	#endif

	#include "pciaccess.h"
	#include "pciaccess_private.h"

	#define DO_MATCH(a,b) (((a) == PCI_MATCH_ANY) \|\| ((a) == (b)))

	#ifdef HAVE_ZLIB

	#include <zlib.h>
	typedef gzFile pci_id_file;

	static pci_id_file
	pci_id_file_open(void)
	{
	pci_id_file result;

	result = gzopen(PCIIDS_PATH "/pci.ids.gz", "rb");
	if (result)
	return result;

	return gzopen(PCIIDS_PATH "/pci.ids", "rb");
	}

	#define pci_id_file_gets(l, s, f) gzgets(f, l, s)
	#define pci_id_file_close(f) gzclose(f)

	#else /* not zlib */

	typedef FILE * pci_id_file;

	static pci_id_file
	pci_id_file_open(void)
	{
	#ifndef __sun
	pci_id_file result;

	result = fopen(PCIIDS_PATH "/pci.ids", "re");
	if (result)
	return result;
	#endif

	return fopen(PCIIDS_PATH "/pci.ids", "r");
	}

	#define pci_id_file_gets(l, s, f) fgets(l, s, f)
	#define pci_id_file_close(f) fclose(f)

	#endif

	/**
	* Node for sorting vendor IDs.
	*
	* Each structure forms an internal node of an n-way tree. Each node selects
	* \c pci_id_node::bits number of bits from the vendor ID. Starting from the
	* root of the tree, a slice of the low-order bits of the vendor ID are
	* selected and used as an index into the \c pci_id_node::children array.
	*
	* At the leaf nodes (i.e., the node entered when all 16 bits of the vendor ID
	* have been used), the \c pci_id_node::children is actually an array of
	* pointers to \c pci_id_leaf structures.
	*
	* \todo
	* Determine if there is a cleaner way (in the source code) to have the
	* \c children array change type based on whether the node is internal or
	* a leaf.
	*
	* \todo
	* Currently \c bits is always 4. Decide if this value can ever change
	* (i.e., to pull-up levels of the n-way tree when all the children's children
	* are full). If it can, rip it out and hard-code it to 4 everywhere.
	*/
	struct pci_id_node {
	unsigned bits;
	struct pci_id_node * children[16];
	};

	struct pci_id_leaf {
	uint16_t vendor;
	const char * vendor_name;

	size_t num_devices;
	struct pci_device_leaf * devices;
	};

	struct pci_device_leaf {
	struct pci_id_match id;
	const char * device_name;
	};

	/**
	* Root of the PCI vendor ID search tree.
	*/
	_pci_hidden struct pci_id_node * tree = NULL;

	/**
	* Get a pointer to the leaf node for a vendor ID.
	*
	* If the vendor ID does not exist in the tree, it is added.
	*/
	static struct pci_id_leaf *
	insert( uint16_t vendor )
	{
	struct pci_id_node * n;
	unsigned bits = 0;

	if ( tree == NULL ) {
	tree = calloc( 1, sizeof( struct pci_id_node ) );
	tree->bits = 4;
	}

	n = tree;
	while ( n != NULL ) {
	const unsigned used_bits = n->bits;
	const unsigned mask = (1 << used_bits) - 1;
	const unsigned idx = (vendor & (mask << bits)) >> bits;


	if ( bits >= 16 ) {
	break;
	}

	bits += used_bits;

	if ( n->children[ idx ] == NULL ) {
	if ( bits < 16 ) {
	struct pci_id_node * child =
	calloc( 1, sizeof( struct pci_id_node ) );

	child->bits = 4;

	n->children[ idx ] = child;
	}
	else {
	struct pci_id_leaf * leaf =
	calloc( 1, sizeof( struct pci_id_leaf ) );

	leaf->vendor = vendor;

	n->children[ idx ] = (struct pci_id_node *) leaf;
	}
	}

	n = n->children[ idx ];
	}

	return (struct pci_id_leaf *) n;
	}


	/**
	* Populate a vendor node with all the devices associated with that vendor
	*
	* \param vend Vendor node that is to be filled from the pci.ids file.
	*
	* \todo
	* The parsing in this function should be more rhobust. There are some error
	* cases (i.e., a 0-tab line followed by a 2-tab line) that aren't handled
	* correctly. I don't think there are any security problems with the code,
	* but it's not impossible.
	*/
	static void
	populate_vendor( struct pci_id_leaf * vend, int fill_device_data )
	{
	pci_id_file f;
	char buf[128];
	unsigned vendor = PCI_MATCH_ANY;


	/* If the device tree for this vendor is already populated, don't do
	* anything. This avoids wasted processing and potential memory leaks.
	*/
	if (vend->num_devices != 0) {
	return;
	}

	f = pci_id_file_open();

	/* If the pci.ids file could not be opened, there's nothing we can do.
	*/
	if (f == NULL) {
	return;
	}

	while( pci_id_file_gets( buf, sizeof( buf ), f ) != NULL ) {
	unsigned num_tabs;
	char * new_line;
	size_t length;

	/* Each line either starts with zero, one, or two tabs followed by
	* a series of 4 hex digits. Any lines not matching that are ignored.
	*/

	for ( num_tabs = 0 ; num_tabs < 3 ; num_tabs++ ) {
	if ( buf[ num_tabs ] != '\t' ) {
	break;
	}
	}

	if ( !isxdigit( buf[ num_tabs + 0 ] )
	\|\| !isxdigit( buf[ num_tabs + 1 ] )
	\|\| !isxdigit( buf[ num_tabs + 2 ] )
	\|\| !isxdigit( buf[ num_tabs + 3 ] ) ) {
	continue;
	}

	new_line = strchr( buf, '\n' );
	if ( new_line != NULL ) {
	*new_line = '\0';
	}

	length = strlen( buf );
	(void) memset( buf + length, 0, sizeof( buf ) - length );


	if ( num_tabs == 0 ) {
	vendor = (unsigned) strtoul( & buf[ num_tabs ], NULL, 16 );
	if ( vend->vendor == vendor ) {
	/* vendor_name may already be set from a previous invocation
	* of this function with fill_device_data = 0.
	*/
	if (vend->vendor_name == NULL) {
	vend->vendor_name = strdup( & buf[ num_tabs + 6 ] );
	}

	/* If we're not going to fill in all of the device data as
	* well, then bail out now. We have all the information that
	* we need.
	*/
	if ( ! fill_device_data ) {
	break;
	}
	}
	}
	else if ( vendor == vend->vendor ) {
	struct pci_device_leaf * d;
	struct pci_device_leaf * dev;
	struct pci_device_leaf * last_dev;



	d = realloc( vend->devices, (vend->num_devices + 1)
	* sizeof( struct pci_device_leaf ) );
	if ( d == NULL ) {
	goto cleanup;
	}

	last_dev = & d[ vend->num_devices - 1 ];
	dev = & d[ vend->num_devices ];
	vend->num_devices++;
	vend->devices = d;

	if ( num_tabs == 1 ) {
	dev->id.vendor_id = vend->vendor;
	dev->id.device_id = (unsigned) strtoul( & buf[ num_tabs ],
	NULL, 16 );
	dev->id.subvendor_id = PCI_MATCH_ANY;
	dev->id.subdevice_id = PCI_MATCH_ANY;

	dev->id.device_class = 0;
	dev->id.device_class_mask = 0;
	dev->id.match_data = 0;

	dev->device_name = strdup( & buf[ num_tabs + 6 ] );
	}
	else {
	dev->id = last_dev->id;

	dev->id.subvendor_id= (unsigned) strtoul( & buf[ num_tabs ],
	NULL, 16 );
	dev->id.subdevice_id = (unsigned) strtoul( & buf[ num_tabs + 5 ],
	NULL, 16 );
	dev->device_name = strdup( & buf[ num_tabs + 5 + 6 ] );
	}
	}
	}

	cleanup:
	pci_id_file_close( f );
	}


	/**
	* Find the name of the specified device.
	*
	* Finds the actual product name of the specified device. If a subvendor ID
	* and subdevice ID are specified in \c m, the returned name will be the name
	* of the subdevice.
	*/
	static const char *
	find_device_name( const struct pci_id_match * m )
	{
	struct pci_id_leaf * vend;
	unsigned i;


	if ( m->vendor_id == PCI_MATCH_ANY ) {
	return NULL;
	}


	vend = insert( m->vendor_id );
	if ( vend == NULL ) {
	return NULL;
	}

	if ( vend->num_devices == 0 ) {
	populate_vendor( vend, 1 );
	}


	for ( i = 0 ; i < vend->num_devices ; i++ ) {
	struct pci_device_leaf * d = & vend->devices[ i ];

	if ( DO_MATCH( m->vendor_id, d->id.vendor_id )
	&& DO_MATCH( m->device_id, d->id.device_id )
	&& DO_MATCH( m->subvendor_id, d->id.subvendor_id )
	&& DO_MATCH( m->subdevice_id, d->id.subdevice_id ) ) {
	return d->device_name;
	}
	}

	return NULL;
	}


	/**
	* Find the vendor name of the specified device.
	*
	* Finds the actual vendor name of the specified device. If a subvendor ID
	* and subdevice ID are specified in \c m, the returned name will be the name
	* associated with the subvendor.
	*/
	static const char *
	find_vendor_name( const struct pci_id_match * m )
	{
	struct pci_id_leaf * vend;


	if ( m->vendor_id == PCI_MATCH_ANY ) {
	return NULL;
	}


	vend = insert( m->vendor_id );
	if ( vend == NULL ) {
	return NULL;
	}

	if ( vend->vendor_name == NULL ) {
	populate_vendor( vend, 0 );
	}


	return vend->vendor_name;
	}


	/**
	* Get a name based on an arbitrary PCI search structure.
	*/
	void
	pci_get_strings( const struct pci_id_match * m,
	const char ** device_name,
	const char ** vendor_name,
	const char ** subdevice_name,
	const char ** subvendor_name )
	{
	struct pci_id_match temp;


	temp = *m;
	temp.subvendor_id = PCI_MATCH_ANY;
	temp.subdevice_id = PCI_MATCH_ANY;

	if ( device_name != NULL ) {
	*device_name = find_device_name( & temp );
	}

	if ( vendor_name != NULL ) {
	*vendor_name = find_vendor_name( & temp );
	}

	if ( subdevice_name != NULL ) {
	*subdevice_name = find_device_name( m );
	}

	if ( subvendor_name != NULL ) {
	*subvendor_name = find_vendor_name( m );
	}
	}


	/**
	* Get the name associated with the device's primary device ID.
	*/
	const char *
	pci_device_get_device_name( const struct pci_device * dev )
	{
	struct pci_id_match m;


	m.vendor_id = dev->vendor_id;
	m.device_id = dev->device_id;
	m.subvendor_id = PCI_MATCH_ANY;
	m.subdevice_id = PCI_MATCH_ANY;
	m.device_class = 0;
	m.device_class_mask = 0;
	m.match_data = 0;

	return find_device_name( & m );
	}


	/**
	* Get the name associated with the device's subdevice ID.
	*/
	const char *
	pci_device_get_subdevice_name( const struct pci_device * dev )
	{
	struct pci_id_match m;


	if ( (dev->subvendor_id == 0) \|\| (dev->subdevice_id == 0) ) {
	return NULL;
	}

	m.vendor_id = dev->vendor_id;
	m.device_id = dev->device_id;
	m.subvendor_id = dev->subvendor_id;
	m.subdevice_id = dev->subdevice_id;
	m.device_class = 0;
	m.device_class_mask = 0;
	m.match_data = 0;

	return find_device_name( & m );
	}


	/**
	* Get the name associated with the device's primary vendor ID.
	*/
	const char *
	pci_device_get_vendor_name( const struct pci_device * dev )
	{
	struct pci_id_match m;


	m.vendor_id = dev->vendor_id;
	m.device_id = PCI_MATCH_ANY;
	m.subvendor_id = PCI_MATCH_ANY;
	m.subdevice_id = PCI_MATCH_ANY;
	m.device_class = 0;
	m.device_class_mask = 0;
	m.match_data = 0;

	return find_vendor_name( & m );
	}


	/**
	* Get the name associated with the device's subvendor ID.
	*/
	const char *
	pci_device_get_subvendor_name( const struct pci_device * dev )
	{
	struct pci_id_match m;


	if ( dev->subvendor_id == 0 ) {
	return NULL;
	}


	m.vendor_id = dev->subvendor_id;
	m.device_id = PCI_MATCH_ANY;
	m.subvendor_id = PCI_MATCH_ANY;
	m.subdevice_id = PCI_MATCH_ANY;
	m.device_class = 0;
	m.device_class_mask = 0;
	m.match_data = 0;

	return find_vendor_name( & m );
	}