com32/lib/pci/scan.c - platform/external/syslinux - Git at Google

 /* ----------------------------------------------------------------------- *
  *
  *   Copyright 2006-2007 Erwan Velu - 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 the rights to use,
  *   copy, modify, merge, publish, distribute, sublicense, 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 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
  *   NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT
  *   HOLDERS 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.
  *
  * ----------------------------------------------------------------------- */

 /*
  * pci.c
  *
  * A module to extract pci informations
  */

 #include <inttypes.h>
 #include <stdio.h>
 #include <stdlib.h>
 #include <string.h>
 #include <console.h>
 #include <sys/pci.h>
 #include <com32.h>
 #include <stdbool.h>
 #include <ctype.h>
 #include <syslinux/zio.h>
 #include <dprintf.h>

 #define MAX_LINE 512

 /* removing any \n found in a string */
 static void remove_eol(char *string)
 {
     int j = strlen(string);
     int i = 0;
     for (i = 0; i < j; i++)
 	if (string[i] == '\n')
 	    string[i] = 0;
 }

 /* converting a hexa string into its numerical value */
 static int hex_to_int(char *hexa)
 {
     return strtoul(hexa, NULL, 16);
 }

 /* Try to match any pci device to the appropriate kernel module */
 /* it uses the modules.pcimap from the boot device */
 int get_module_name_from_pcimap(struct pci_domain *domain,
 				char *modules_pcimap_path)
 {
   char line[MAX_LINE];
   char module_name[21]; // the module name field is 21 char long
   char delims[]=" ";    // colums are separated by spaces
   char vendor_id[16];
   char product_id[16];
   char sub_vendor_id[16];
   char sub_product_id[16];
   FILE *f;
   struct pci_device *dev=NULL;

   /* Intializing the linux_kernel_module for each pci device to "unknown" */
   /* adding a dev_info member if needed */
   for_each_pci_func(dev, domain) {
     /* initialize the dev_info structure if it doesn't exist yet. */
     if (! dev->dev_info) {
       dev->dev_info = zalloc(sizeof *dev->dev_info);
       if (!dev->dev_info)
 	return -1;
     }
     for (int i=0;i<MAX_KERNEL_MODULES_PER_PCI_DEVICE;i++) {
      if (strlen(dev->dev_info->linux_kernel_module[i])==0)
        strlcpy(dev->dev_info->linux_kernel_module[i], "unknown",7);
     }
   }

   /* Opening the modules.pcimap (of a linux kernel) from the boot device */
   f=zfopen(modules_pcimap_path, "r");
   if (!f)
     return -ENOMODULESPCIMAP;

   strcpy(vendor_id,"0000");
   strcpy(product_id,"0000");
   strcpy(sub_product_id,"0000");
   strcpy(sub_vendor_id,"0000");

   /* for each line we found in the modules.pcimap */
   while ( fgets(line, sizeof line, f) ) {
     /* skipping unecessary lines */
     if ((line[0] == '#') || (line[0] == ' ') || (line[0] == 10))
         continue;

     char *result = NULL;
     int field=0;

     /* looking for the next field */
     result = strtok(line, delims);
     while( result != NULL ) {
        /* if the column is larger than 1 char */
        /* multiple spaces generates some empty fields */
        if (strlen(result)>1) {
 	 switch (field) {
 	 /* About case 0, the kernel module name is featuring '_' or '-'
 	  * in the module name whereas modules.alias is only using '_'.
 	  * To avoid kernel modules duplication, let's rename all '-' in '_'
 	  * to match what modules.alias provides */
 	 case 0:chrreplace(result,'-','_');strcpy(module_name,result); break;
 	 case 1:strcpy(vendor_id,result); break;
 	 case 2:strcpy(product_id,result); break;
 	 case 3:strcpy(sub_vendor_id,result); break;
 	 case 4:strcpy(sub_product_id,result); break;
 	 }
 	 field++;
        }
        /* Searching the next field */
        result = strtok( NULL, delims );
    }
     int int_vendor_id=hex_to_int(vendor_id);
     int int_sub_vendor_id=hex_to_int(sub_vendor_id);
     int int_product_id=hex_to_int(product_id);
     int int_sub_product_id=hex_to_int(sub_product_id);
     /* if a pci_device matches an entry, fill the linux_kernel_module with
        the appropriate kernel module */
     for_each_pci_func(dev, domain) {
       if (int_vendor_id == dev->vendor &&
 	  int_product_id == dev->product &&
 	  (int_sub_product_id & dev->sub_product)
 	  == dev->sub_product &&
 	  (int_sub_vendor_id & dev->sub_vendor)
 	  == dev->sub_vendor) {
 	      bool found=false;

 	      /* Scan all known kernel modules for this pci device */
 	      for (int i=0; i<dev->dev_info->linux_kernel_module_count; i++) {

        	      /* Try to detect if we already knew the same kernel module*/
 	       if (strstr(dev->dev_info->linux_kernel_module[i], module_name)) {
 		      found=true;
 		      break;
 	       }
 	      }
 	      /* If we don't have this kernel module, let's add it */
 	      if (!found) {
 		strcpy(dev->dev_info->linux_kernel_module[dev->dev_info->linux_kernel_module_count], module_name);
 		dev->dev_info->linux_kernel_module_count++;
 	      }
       }
     }
   }
   fclose(f);
   return 0;
 }

 /* Try to match any pci device to the appropriate class name */
 /* it uses the pci.ids from the boot device */
 int get_class_name_from_pci_ids(struct pci_domain *domain, char *pciids_path)
 {
     char line[MAX_LINE];
     char class_name[PCI_CLASS_NAME_SIZE];
     char sub_class_name[PCI_CLASS_NAME_SIZE];
     char class_id_str[5];
     char sub_class_id_str[5];
     FILE *f;
     struct pci_device *dev;
     bool class_mode = false;

     /* Intializing the vendor/product name for each pci device to "unknown" */
     /* adding a dev_info member if needed */
     for_each_pci_func(dev, domain) {
 	/* initialize the dev_info structure if it doesn't exist yet. */
 	if (!dev->dev_info) {
 	    dev->dev_info = zalloc(sizeof *dev->dev_info);
 	    if (!dev->dev_info)
 		return -1;
 	}
 	strlcpy(dev->dev_info->class_name, "unknown", 7);
     }

     /* Opening the pci.ids from the boot device */
     f = zfopen(pciids_path, "r");
     if (!f)
 	return -ENOPCIIDS;

     /* for each line we found in the pci.ids */
     while (fgets(line, sizeof line, f)) {
 	/* Skipping uncessary lines */
 	if ((line[0] == '#') || (line[0] == ' ') || (line[0] == 10))
 	    continue;

 	/* Until we found a line starting with a 'C', we are not parsing classes */
 	if (line[0] == 'C')
 	    class_mode = true;
 	if (class_mode == false)
 	    continue;
 	strlcpy(class_name, "unknown", 7);
 	/* If the line doesn't start with a tab, it means that's a class name */
 	if (line[0] != '\t') {

 	    /* ignore the two first char and then copy 2 chars (class id) */
 	    strlcpy(class_id_str, &line[2], 2);
 	    class_id_str[2] = 0;

 	    /* the class name is the next field */
 	    strlcpy(class_name, skipspace(strstr(line, " ")),
 		    PCI_CLASS_NAME_SIZE - 1);
 	    remove_eol(class_name);

 	    int int_class_id_str = hex_to_int(class_id_str);
 	    /* assign the class_name to any matching pci device */
 	    for_each_pci_func(dev, domain) {
 		if (int_class_id_str == dev->class[2]) {
 		    strlcpy(dev->dev_info->class_name, class_name,
 			    PCI_CLASS_NAME_SIZE - 1);
 		    /* This value is usually the main category */
 		    strlcpy(dev->dev_info->category_name, class_name + 4,
 			    PCI_CLASS_NAME_SIZE - 1);
 		}
 	    }
 	    /* if we have a tab + a char, it means this is a sub class name */
 	} else if ((line[0] == '\t') && (line[1] != '\t')) {

 	    /* the sub class name the second field */
 	    strlcpy(sub_class_name, skipspace(strstr(line, " ")),
 		    PCI_CLASS_NAME_SIZE - 1);
 	    remove_eol(sub_class_name);

 	    /* the sub class id is first field */
 	    strlcpy(sub_class_id_str, &line[1], 2);
 	    sub_class_id_str[2] = 0;

 	    int int_class_id_str = hex_to_int(class_id_str);
 	    int int_sub_class_id_str = hex_to_int(sub_class_id_str);
 	    /* assign the product_name to any matching pci device */
 	    for_each_pci_func(dev, domain) {
 		if (int_class_id_str == dev->class[2] &&
 		    int_sub_class_id_str == dev->class[1])
 		    strlcpy(dev->dev_info->class_name, sub_class_name,
 			    PCI_CLASS_NAME_SIZE - 1);
 	    }

 	}
     }
     fclose(f);
     return 0;
 }

 /* Try to match any pci device to the appropriate vendor and product name */
 /* it uses the pci.ids from the boot device */
 int get_name_from_pci_ids(struct pci_domain *domain, char *pciids_path)
 {
     char line[MAX_LINE];
     char vendor[PCI_VENDOR_NAME_SIZE];
     char vendor_id[5];
     char product[PCI_PRODUCT_NAME_SIZE];
     char product_id[5];
     char sub_product_id[5];
     char sub_vendor_id[5];
     FILE *f;
     struct pci_device *dev;
     bool skip_to_next_vendor = false;
     uint16_t int_vendor_id;
     uint16_t int_product_id;
     uint16_t int_sub_product_id;
     uint16_t int_sub_vendor_id;

     /* Intializing the vendor/product name for each pci device to "unknown" */
     /* adding a dev_info member if needed */
     for_each_pci_func(dev, domain) {
 	/* initialize the dev_info structure if it doesn't exist yet. */
 	if (!dev->dev_info) {
 	    dev->dev_info = zalloc(sizeof *dev->dev_info);
 	    if (!dev->dev_info)
 		return -1;
 	}
 	strlcpy(dev->dev_info->vendor_name, "unknown", 7);
 	strlcpy(dev->dev_info->product_name, "unknown", 7);
     }

     /* Opening the pci.ids from the boot device */
     f = zfopen(pciids_path, "r");
     if (!f)
 	return -ENOPCIIDS;

     strlcpy(vendor_id, "0000", 4);
     strlcpy(product_id, "0000", 4);
     strlcpy(sub_product_id, "0000", 4);
     strlcpy(sub_vendor_id, "0000", 4);

     /* for each line we found in the pci.ids */
     while (fgets(line, sizeof line, f)) {
 	/* Skipping uncessary lines */
 	if ((line[0] == '#') || (line[0] == ' ') || (line[0] == 'C') ||
 	    (line[0] == 10))
 	    continue;

 	/* If the line doesn't start with a tab, it means that's a vendor id */
 	if (line[0] != '\t') {

 	    /* the 4 first chars are the vendor_id */
 	    strlcpy(vendor_id, line, 4);

 	    /* the vendor name is the next field */
 	    vendor_id[4] = 0;
 	    strlcpy(vendor, skipspace(strstr(line, " ")),
 		    PCI_VENDOR_NAME_SIZE - 1);

 	    remove_eol(vendor);
 	    /* init product_id, sub_product and sub_vendor */
 	    strlcpy(product_id, "0000", 4);
 	    strlcpy(sub_product_id, "0000", 4);
 	    strlcpy(sub_vendor_id, "0000", 4);

 	    /* Unless we found a matching device, we have to skip to the next vendor */
 	    skip_to_next_vendor = true;

 	    int_vendor_id = hex_to_int(vendor_id);
 	    /* Iterate in all pci devices to find a matching vendor */
 	    for_each_pci_func(dev, domain) {
 		/* if one device that match this vendor */
 		if (int_vendor_id == dev->vendor) {
 		    /* copy the vendor name for this device */
 		    strlcpy(dev->dev_info->vendor_name, vendor,
 			    PCI_VENDOR_NAME_SIZE - 1);
 		    /* Some pci devices match this vendor, so we have to found them */
 		    skip_to_next_vendor = false;
 		    /* Let's loop on the other devices as some may have the same vendor */
 		}
 	    }
 	    /* if we have a tab + a char, it means this is a product id
 	     * but we only look at it if we own some pci devices of the current vendor*/
 	} else if ((line[0] == '\t') && (line[1] != '\t')
 		   && (skip_to_next_vendor == false)) {

 	    /* the product name the second field */
 	    strlcpy(product, skipspace(strstr(line, " ")),
 		    PCI_PRODUCT_NAME_SIZE - 1);
 	    remove_eol(product);

 	    /* the product id is first field */
 	    strlcpy(product_id, &line[1], 4);
 	    product_id[4] = 0;

 	    /* init sub_product and sub_vendor */
 	    strlcpy(sub_product_id, "0000", 4);
 	    strlcpy(sub_vendor_id, "0000", 4);

 	    int_vendor_id = hex_to_int(vendor_id);
 	    int_product_id = hex_to_int(product_id);
 	    /* assign the product_name to any matching pci device */
 	    for_each_pci_func(dev, domain) {
 		if (int_vendor_id == dev->vendor &&
 		    int_product_id == dev->product) {
 		    strlcpy(dev->dev_info->vendor_name, vendor,
 			    PCI_VENDOR_NAME_SIZE - 1);
 		    strlcpy(dev->dev_info->product_name, product,
 			    PCI_PRODUCT_NAME_SIZE - 1);
 		}
 	    }

 	    /* if we have two tabs, it means this is a sub product
 	     * but we only look at it if we own some pci devices of the current vendor*/
 	} else if ((line[0] == '\t') && (line[1] == '\t')
 		   && (skip_to_next_vendor == false)) {

 	    /* the product name is last field */
 	    strlcpy(product, skipspace(strstr(line, " ")),
 		    PCI_PRODUCT_NAME_SIZE - 1);
 	    strlcpy(product, skipspace(strstr(product, " ")),
 		    PCI_PRODUCT_NAME_SIZE - 1);
 	    remove_eol(product);

 	    /* the sub_vendor id is first field */
 	    strlcpy(sub_vendor_id, &line[2], 4);
 	    sub_vendor_id[4] = 0;

 	    /* the sub_vendor id is second field */
 	    strlcpy(sub_product_id, &line[7], 4);
 	    sub_product_id[4] = 0;

 	    int_vendor_id = hex_to_int(vendor_id);
 	    int_sub_vendor_id = hex_to_int(sub_vendor_id);
 	    int_product_id = hex_to_int(product_id);
 	    int_sub_product_id = hex_to_int(sub_product_id);
 	    /* assign the product_name to any matching pci device */
 	    for_each_pci_func(dev, domain) {
 		if (int_vendor_id == dev->vendor &&
 		    int_product_id == dev->product &&
 		    int_sub_product_id == dev->sub_product &&
 		    int_sub_vendor_id == dev->sub_vendor) {
 		    strlcpy(dev->dev_info->vendor_name, vendor,
 			    PCI_VENDOR_NAME_SIZE - 1);
 		    strlcpy(dev->dev_info->product_name, product,
 			    PCI_PRODUCT_NAME_SIZE - 1);
 		}
 	    }
 	}
     }
     fclose(f);
     return 0;
 }

 /* searching if any pcidevice match our query */
 struct match *find_pci_device(const struct pci_domain *domain,
 			      struct match *list)
 {
     uint32_t did, sid;
     struct match *m;
     const struct pci_device *dev;

     /* for all matches we have to search */
     for (m = list; m; m = m->next) {
 	/* for each pci device we know */
 	for_each_pci_func(dev, domain) {
 	    /* sid & did are the easiest way to compare devices */
 	    /* they are made of vendor/product subvendor/subproduct ids */
 	    sid = dev->svid_sdid;
 	    did = dev->vid_did;
 	    /* if the current device match */
 	    if (((did ^ m->did) & m->did_mask) == 0 &&
 		((sid ^ m->sid) & m->sid_mask) == 0 &&
 		dev->revision >= m->rid_min && dev->revision <= m->rid_max) {
 		dprintf
 		    ("PCI Match: Vendor=%04x Product=%04x Sub_vendor=%04x Sub_Product=%04x Release=%02x\n",
 		     dev->vendor, dev->product, dev->sub_vendor,
 		     dev->sub_product, dev->revision);
 		/* returning the matched pci device */
 		return m;
 	    }
 	}
     }
     return NULL;
 }

 /* scanning the pci bus to find pci devices */
 struct pci_domain *pci_scan(void)
 {
     struct pci_domain *domain = NULL;
     struct pci_bus *bus = NULL;
     struct pci_slot *slot = NULL;
     struct pci_device *func = NULL;
     unsigned int nbus, ndev, nfunc, maxfunc;
     uint32_t did, sid, rcid;
     uint8_t hdrtype;
     pciaddr_t a;
     int cfgtype;

     cfgtype = pci_set_config_type(PCI_CFG_AUTO);

     dprintf("PCI configuration type %d\n", cfgtype);

     if (cfgtype == PCI_CFG_NONE)
 	return NULL;

     dprintf("Scanning PCI Buses\n");

     for (nbus = 0; nbus < MAX_PCI_BUSES; nbus++) {
 	dprintf("Probing bus 0x%02x... \n", nbus);
 	bus = NULL;

 	for (ndev = 0; ndev < MAX_PCI_DEVICES; ndev++) {
 	    maxfunc = 1;	/* Assume a single-function device */
 	    slot = NULL;

 	    for (nfunc = 0; nfunc < maxfunc; nfunc++) {
 		a = pci_mkaddr(nbus, ndev, nfunc, 0);
 		did = pci_readl(a);

 		if (did == 0xffffffff || did == 0xffff0000 ||
 		    did == 0x0000ffff || did == 0x00000000)
 		    continue;

 		hdrtype = pci_readb(a + 0x0e);

 		if (hdrtype & 0x80)
 		    maxfunc = MAX_PCI_FUNC;	/* Multifunction device */

 		rcid = pci_readl(a + 0x08);
 		sid = pci_readl(a + 0x2c);

 		if (!domain) {
 		    domain = zalloc(sizeof *domain);
 		    if (!domain)
 			goto bail;
 		}
 		if (!bus) {
 		    bus = zalloc(sizeof *bus);
 		    if (!bus)
 			goto bail;
 		    domain->bus[nbus] = bus;
 		}
 		if (!slot) {
 		    slot = zalloc(sizeof *slot);
 		    if (!slot)
 			goto bail;
 		    bus->slot[ndev] = slot;
 		}
 		func = zalloc(sizeof *func);
 		if (!func)
 		    goto bail;

 		slot->func[nfunc] = func;

 		func->vid_did = did;
 		func->svid_sdid = sid;
 		func->rid_class = rcid;

 		dprintf
 		    ("Scanning: BUS %02x DID %08x (%04x:%04x) SID %08x RID %02x\n",
 		     nbus, did, did >> 16, (did << 16) >> 16, sid, rcid & 0xff);
 	    }
 	}
     }

     return domain;

 bail:
     free_pci_domain(domain);
     return NULL;
 }

 /* gathering additional configuration*/
 void gather_additional_pci_config(struct pci_domain *domain)
 {
     struct pci_device *dev;
     pciaddr_t pci_addr;
     int cfgtype;

     cfgtype = pci_set_config_type(PCI_CFG_AUTO);
     if (cfgtype == PCI_CFG_NONE)
 	return;

     for_each_pci_func3(dev, domain, pci_addr) {
 	if (!dev->dev_info) {
 	    dev->dev_info = zalloc(sizeof *dev->dev_info);
 	    if (!dev->dev_info) {
 		return;
 	    }
 	}
 	dev->dev_info->irq = pci_readb(pci_addr + 0x3c);
 	dev->dev_info->latency = pci_readb(pci_addr + 0x0d);
     }
 }

 void free_pci_domain(struct pci_domain *domain)
 {
     struct pci_bus *bus;
     struct pci_slot *slot;
     struct pci_device *func;
     unsigned int nbus, ndev, nfunc;

     if (domain) {
 	for (nbus = 0; nbus < MAX_PCI_BUSES; nbus++) {
 	    bus = domain->bus[nbus];
 	    if (bus) {
 		for (ndev = 0; ndev < MAX_PCI_DEVICES; ndev++) {
 		    slot = bus->slot[ndev];
 		    if (slot) {
 			for (nfunc = 0; nfunc < MAX_PCI_FUNC; nfunc++) {
 			    func = slot->func[nfunc];
 			    if (func) {
 				if (func->dev_info)
 				    free(func->dev_info);
 				free(func);
 			    }
 			}
 			free(slot);
 		    }
 		}
 		free(bus);
 	    }
 	}
 	free(domain);
     }
 }

 /* Try to match any pci device to the appropriate kernel module */
 /* it uses the modules.alias from the boot device */
 int get_module_name_from_alias(struct pci_domain *domain, char *modules_alias_path)
 {
   char line[MAX_LINE];
   char module_name[21]; // the module name field is 21 char long
   char delims[]="*";    // colums are separated by spaces
   char vendor_id[16];
   char product_id[16];
   char sub_vendor_id[16];
   char sub_product_id[16];
   FILE *f;
   struct pci_device *dev=NULL;

   /* Intializing the linux_kernel_module for each pci device to "unknown" */
   /* adding a dev_info member if needed */
   for_each_pci_func(dev, domain) {
     /* initialize the dev_info structure if it doesn't exist yet. */
     if (! dev->dev_info) {
       dev->dev_info = zalloc(sizeof *dev->dev_info);
       if (!dev->dev_info)
 	return -1;
     }
     for (int i=0;i<MAX_KERNEL_MODULES_PER_PCI_DEVICE;i++) {
      if (strlen(dev->dev_info->linux_kernel_module[i])==0)
        strlcpy(dev->dev_info->linux_kernel_module[i], "unknown",7);
     }
   }

   /* Opening the modules.pcimap (of a linux kernel) from the boot device */
   f=zfopen(modules_alias_path, "r");
   if (!f)
     return -ENOMODULESALIAS;

   /* for each line we found in the modules.pcimap */
   while ( fgets(line, sizeof line, f) ) {
     /* skipping unecessary lines */
     if ((line[0] == '#') || (strstr(line,"alias pci:v")==NULL))
         continue;

     /* Resetting temp buffer*/
     memset(module_name,0,sizeof(module_name));
     memset(vendor_id,0,sizeof(vendor_id));
     memset(sub_vendor_id,0,sizeof(sub_vendor_id));
     memset(product_id,0,sizeof(product_id));
     memset(sub_product_id,0,sizeof(sub_product_id));
     strcpy(vendor_id,"0000");
     strcpy(product_id,"0000");
     /* ffff will be used to match any device as in modules.alias
      * a missing subvendor/product have to be considered as  0xFFFF*/
     strcpy(sub_product_id,"ffff");
     strcpy(sub_vendor_id,"ffff");

     char *result = NULL;
     int field=0;

     /* looking for the next field */
     result = strtok(line+strlen("alias pci:v"), delims);
     while( result != NULL ) {
 	if (field==0) {

 		/* Searching for the vendor separator*/
 		char *temp = strstr(result,"d");
 		if (temp != NULL) {
 			strlcpy(vendor_id,result,temp-result);
 			result+=strlen(vendor_id)+1;
 		}

 		/* Searching for the product separator*/
 		temp = strstr(result,"sv");
 		if (temp != NULL) {
 			strlcpy(product_id,result,temp-result);
 			result+=strlen(product_id)+1;
 		}

 		/* Searching for the sub vendor separator*/
 		temp = strstr(result,"sd");
 		if (temp != NULL) {
 			strlcpy(sub_vendor_id,result,temp-result);
 			result+=strlen(sub_vendor_id)+1;
 		}

 		/* Searching for the sub product separator*/
 		temp = strstr(result,"bc");
 		if (temp != NULL) {
 			strlcpy(sub_product_id,result,temp-result);
 			result+=strlen(sub_product_id)+1;
 		}
 	/* That's the module name */
 	} else if ((strlen(result)>2) &&
 			(result[0]==0x20))
 		strcpy(module_name,result+1);
 		/* We have to replace \n by \0*/
 		module_name[strlen(module_name)-1]='\0';
 	field++;

 	/* Searching the next field */
         result = strtok( NULL, delims );
     }

     /* Now we have extracted informations from the modules.alias
      * Let's compare it with the devices we know*/
     int int_vendor_id=hex_to_int(vendor_id);
     int int_sub_vendor_id=hex_to_int(sub_vendor_id);
     int int_product_id=hex_to_int(product_id);
     int int_sub_product_id=hex_to_int(sub_product_id);
     /* if a pci_device matches an entry, fill the linux_kernel_module with
        the appropriate kernel module */
     for_each_pci_func(dev, domain) {
       if (int_vendor_id == dev->vendor &&
 	  int_product_id == dev->product &&
 	  (int_sub_product_id & dev->sub_product)
 	  == dev->sub_product &&
 	  (int_sub_vendor_id & dev->sub_vendor)
 	  == dev->sub_vendor) {
 	      bool found=false;

 	      /* Scan all known kernel modules for this pci device */
 	      for (int i=0; i<dev->dev_info->linux_kernel_module_count; i++) {

        	      /* Try to detect if we already knew the same kernel module*/
 	       if (strstr(dev->dev_info->linux_kernel_module[i], module_name)) {
 		      found=true;
 		      break;
 	       }
 	      }
 	      /* If we don't have this kernel module, let's add it */
 	      if (!found) {
 		strcpy(dev->dev_info->linux_kernel_module[dev->dev_info->linux_kernel_module_count], module_name);
 		dev->dev_info->linux_kernel_module_count++;
 	      }
       }
     }
   }
   fclose(f);
   return 0;
 }
	/* ----------------------------------------------------------------------- *
	*
	* Copyright 2006-2007 Erwan Velu - 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 the rights to use,
	* copy, modify, merge, publish, distribute, sublicense, 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 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
	* NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT
	* HOLDERS 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.
	*
	* ----------------------------------------------------------------------- */

	/*
	* pci.c
	*
	* A module to extract pci informations
	*/

	#include <inttypes.h>
	#include <stdio.h>
	#include <stdlib.h>
	#include <string.h>
	#include <console.h>
	#include <sys/pci.h>
	#include <com32.h>
	#include <stdbool.h>
	#include <ctype.h>
	#include <syslinux/zio.h>
	#include <dprintf.h>

	#define MAX_LINE 512

	/* removing any \n found in a string */
	static void remove_eol(char *string)
	{
	int j = strlen(string);
	int i = 0;
	for (i = 0; i < j; i++)
	if (string[i] == '\n')
	string[i] = 0;
	}

	/* converting a hexa string into its numerical value */
	static int hex_to_int(char *hexa)
	{
	return strtoul(hexa, NULL, 16);
	}

	/* Try to match any pci device to the appropriate kernel module */
	/* it uses the modules.pcimap from the boot device */
	int get_module_name_from_pcimap(struct pci_domain *domain,
	char *modules_pcimap_path)
	{
	char line[MAX_LINE];
	char module_name[21]; // the module name field is 21 char long
	char delims[]=" "; // colums are separated by spaces
	char vendor_id[16];
	char product_id[16];
	char sub_vendor_id[16];
	char sub_product_id[16];
	FILE *f;
	struct pci_device *dev=NULL;

	/* Intializing the linux_kernel_module for each pci device to "unknown" */
	/* adding a dev_info member if needed */
	for_each_pci_func(dev, domain) {
	/* initialize the dev_info structure if it doesn't exist yet. */
	if (! dev->dev_info) {
	dev->dev_info = zalloc(sizeof *dev->dev_info);
	if (!dev->dev_info)
	return -1;
	}
	for (int i=0;i<MAX_KERNEL_MODULES_PER_PCI_DEVICE;i++) {
	if (strlen(dev->dev_info->linux_kernel_module[i])==0)
	strlcpy(dev->dev_info->linux_kernel_module[i], "unknown",7);
	}
	}

	/* Opening the modules.pcimap (of a linux kernel) from the boot device */
	f=zfopen(modules_pcimap_path, "r");
	if (!f)
	return -ENOMODULESPCIMAP;

	strcpy(vendor_id,"0000");
	strcpy(product_id,"0000");
	strcpy(sub_product_id,"0000");
	strcpy(sub_vendor_id,"0000");

	/* for each line we found in the modules.pcimap */
	while ( fgets(line, sizeof line, f) ) {
	/* skipping unecessary lines */
	if ((line[0] == '#') \|\| (line[0] == ' ') \|\| (line[0] == 10))
	continue;

	char *result = NULL;
	int field=0;

	/* looking for the next field */
	result = strtok(line, delims);
	while( result != NULL ) {
	/* if the column is larger than 1 char */
	/* multiple spaces generates some empty fields */
	if (strlen(result)>1) {
	switch (field) {
	/* About case 0, the kernel module name is featuring '_' or '-'
	* in the module name whereas modules.alias is only using '_'.
	* To avoid kernel modules duplication, let's rename all '-' in '_'
	* to match what modules.alias provides */
	case 0:chrreplace(result,'-','_');strcpy(module_name,result); break;
	case 1:strcpy(vendor_id,result); break;
	case 2:strcpy(product_id,result); break;
	case 3:strcpy(sub_vendor_id,result); break;
	case 4:strcpy(sub_product_id,result); break;
	}
	field++;
	}
	/* Searching the next field */
	result = strtok( NULL, delims );
	}
	int int_vendor_id=hex_to_int(vendor_id);
	int int_sub_vendor_id=hex_to_int(sub_vendor_id);
	int int_product_id=hex_to_int(product_id);
	int int_sub_product_id=hex_to_int(sub_product_id);
	/* if a pci_device matches an entry, fill the linux_kernel_module with
	the appropriate kernel module */
	for_each_pci_func(dev, domain) {
	if (int_vendor_id == dev->vendor &&
	int_product_id == dev->product &&
	(int_sub_product_id & dev->sub_product)
	== dev->sub_product &&
	(int_sub_vendor_id & dev->sub_vendor)
	== dev->sub_vendor) {
	bool found=false;

	/* Scan all known kernel modules for this pci device */
	for (int i=0; i<dev->dev_info->linux_kernel_module_count; i++) {

	/* Try to detect if we already knew the same kernel module*/
	if (strstr(dev->dev_info->linux_kernel_module[i], module_name)) {
	found=true;
	break;
	}
	}
	/* If we don't have this kernel module, let's add it */
	if (!found) {
	strcpy(dev->dev_info->linux_kernel_module[dev->dev_info->linux_kernel_module_count], module_name);
	dev->dev_info->linux_kernel_module_count++;
	}
	}
	}
	}
	fclose(f);
	return 0;
	}

	/* Try to match any pci device to the appropriate class name */
	/* it uses the pci.ids from the boot device */
	int get_class_name_from_pci_ids(struct pci_domain domain, char pciids_path)
	{
	char line[MAX_LINE];
	char class_name[PCI_CLASS_NAME_SIZE];
	char sub_class_name[PCI_CLASS_NAME_SIZE];
	char class_id_str[5];
	char sub_class_id_str[5];
	FILE *f;
	struct pci_device *dev;
	bool class_mode = false;

	/* Intializing the vendor/product name for each pci device to "unknown" */
	/* adding a dev_info member if needed */
	for_each_pci_func(dev, domain) {
	/* initialize the dev_info structure if it doesn't exist yet. */
	if (!dev->dev_info) {
	dev->dev_info = zalloc(sizeof *dev->dev_info);
	if (!dev->dev_info)
	return -1;
	}
	strlcpy(dev->dev_info->class_name, "unknown", 7);
	}

	/* Opening the pci.ids from the boot device */
	f = zfopen(pciids_path, "r");
	if (!f)
	return -ENOPCIIDS;

	/* for each line we found in the pci.ids */
	while (fgets(line, sizeof line, f)) {
	/* Skipping uncessary lines */
	if ((line[0] == '#') \|\| (line[0] == ' ') \|\| (line[0] == 10))
	continue;

	/* Until we found a line starting with a 'C', we are not parsing classes */
	if (line[0] == 'C')
	class_mode = true;
	if (class_mode == false)
	continue;
	strlcpy(class_name, "unknown", 7);
	/* If the line doesn't start with a tab, it means that's a class name */
	if (line[0] != '\t') {

	/* ignore the two first char and then copy 2 chars (class id) */
	strlcpy(class_id_str, &line[2], 2);
	class_id_str[2] = 0;

	/* the class name is the next field */
	strlcpy(class_name, skipspace(strstr(line, " ")),
	PCI_CLASS_NAME_SIZE - 1);
	remove_eol(class_name);

	int int_class_id_str = hex_to_int(class_id_str);
	/* assign the class_name to any matching pci device */
	for_each_pci_func(dev, domain) {
	if (int_class_id_str == dev->class[2]) {
	strlcpy(dev->dev_info->class_name, class_name,
	PCI_CLASS_NAME_SIZE - 1);
	/* This value is usually the main category */
	strlcpy(dev->dev_info->category_name, class_name + 4,
	PCI_CLASS_NAME_SIZE - 1);
	}
	}
	/* if we have a tab + a char, it means this is a sub class name */
	} else if ((line[0] == '\t') && (line[1] != '\t')) {

	/* the sub class name the second field */
	strlcpy(sub_class_name, skipspace(strstr(line, " ")),
	PCI_CLASS_NAME_SIZE - 1);
	remove_eol(sub_class_name);

	/* the sub class id is first field */
	strlcpy(sub_class_id_str, &line[1], 2);
	sub_class_id_str[2] = 0;

	int int_class_id_str = hex_to_int(class_id_str);
	int int_sub_class_id_str = hex_to_int(sub_class_id_str);
	/* assign the product_name to any matching pci device */
	for_each_pci_func(dev, domain) {
	if (int_class_id_str == dev->class[2] &&
	int_sub_class_id_str == dev->class[1])
	strlcpy(dev->dev_info->class_name, sub_class_name,
	PCI_CLASS_NAME_SIZE - 1);
	}

	}
	}
	fclose(f);
	return 0;
	}

	/* Try to match any pci device to the appropriate vendor and product name */
	/* it uses the pci.ids from the boot device */
	int get_name_from_pci_ids(struct pci_domain domain, char pciids_path)
	{
	char line[MAX_LINE];
	char vendor[PCI_VENDOR_NAME_SIZE];
	char vendor_id[5];
	char product[PCI_PRODUCT_NAME_SIZE];
	char product_id[5];
	char sub_product_id[5];
	char sub_vendor_id[5];
	FILE *f;
	struct pci_device *dev;
	bool skip_to_next_vendor = false;
	uint16_t int_vendor_id;
	uint16_t int_product_id;
	uint16_t int_sub_product_id;
	uint16_t int_sub_vendor_id;

	/* Intializing the vendor/product name for each pci device to "unknown" */
	/* adding a dev_info member if needed */
	for_each_pci_func(dev, domain) {
	/* initialize the dev_info structure if it doesn't exist yet. */
	if (!dev->dev_info) {
	dev->dev_info = zalloc(sizeof *dev->dev_info);
	if (!dev->dev_info)
	return -1;
	}
	strlcpy(dev->dev_info->vendor_name, "unknown", 7);
	strlcpy(dev->dev_info->product_name, "unknown", 7);
	}

	/* Opening the pci.ids from the boot device */
	f = zfopen(pciids_path, "r");
	if (!f)
	return -ENOPCIIDS;

	strlcpy(vendor_id, "0000", 4);
	strlcpy(product_id, "0000", 4);
	strlcpy(sub_product_id, "0000", 4);
	strlcpy(sub_vendor_id, "0000", 4);

	/* for each line we found in the pci.ids */
	while (fgets(line, sizeof line, f)) {
	/* Skipping uncessary lines */
	if ((line[0] == '#') \|\| (line[0] == ' ') \|\| (line[0] == 'C') \|\|
	(line[0] == 10))
	continue;

	/* If the line doesn't start with a tab, it means that's a vendor id */
	if (line[0] != '\t') {

	/* the 4 first chars are the vendor_id */
	strlcpy(vendor_id, line, 4);

	/* the vendor name is the next field */
	vendor_id[4] = 0;
	strlcpy(vendor, skipspace(strstr(line, " ")),
	PCI_VENDOR_NAME_SIZE - 1);

	remove_eol(vendor);
	/* init product_id, sub_product and sub_vendor */
	strlcpy(product_id, "0000", 4);
	strlcpy(sub_product_id, "0000", 4);
	strlcpy(sub_vendor_id, "0000", 4);

	/* Unless we found a matching device, we have to skip to the next vendor */
	skip_to_next_vendor = true;

	int_vendor_id = hex_to_int(vendor_id);
	/* Iterate in all pci devices to find a matching vendor */
	for_each_pci_func(dev, domain) {
	/* if one device that match this vendor */
	if (int_vendor_id == dev->vendor) {
	/* copy the vendor name for this device */
	strlcpy(dev->dev_info->vendor_name, vendor,
	PCI_VENDOR_NAME_SIZE - 1);
	/* Some pci devices match this vendor, so we have to found them */
	skip_to_next_vendor = false;
	/* Let's loop on the other devices as some may have the same vendor */
	}
	}
	/* if we have a tab + a char, it means this is a product id
	* but we only look at it if we own some pci devices of the current vendor*/
	} else if ((line[0] == '\t') && (line[1] != '\t')
	&& (skip_to_next_vendor == false)) {

	/* the product name the second field */
	strlcpy(product, skipspace(strstr(line, " ")),
	PCI_PRODUCT_NAME_SIZE - 1);
	remove_eol(product);

	/* the product id is first field */
	strlcpy(product_id, &line[1], 4);
	product_id[4] = 0;

	/* init sub_product and sub_vendor */
	strlcpy(sub_product_id, "0000", 4);
	strlcpy(sub_vendor_id, "0000", 4);

	int_vendor_id = hex_to_int(vendor_id);
	int_product_id = hex_to_int(product_id);
	/* assign the product_name to any matching pci device */
	for_each_pci_func(dev, domain) {
	if (int_vendor_id == dev->vendor &&
	int_product_id == dev->product) {
	strlcpy(dev->dev_info->vendor_name, vendor,
	PCI_VENDOR_NAME_SIZE - 1);
	strlcpy(dev->dev_info->product_name, product,
	PCI_PRODUCT_NAME_SIZE - 1);
	}
	}

	/* if we have two tabs, it means this is a sub product
	* but we only look at it if we own some pci devices of the current vendor*/
	} else if ((line[0] == '\t') && (line[1] == '\t')
	&& (skip_to_next_vendor == false)) {

	/* the product name is last field */
	strlcpy(product, skipspace(strstr(line, " ")),
	PCI_PRODUCT_NAME_SIZE - 1);
	strlcpy(product, skipspace(strstr(product, " ")),
	PCI_PRODUCT_NAME_SIZE - 1);
	remove_eol(product);

	/* the sub_vendor id is first field */
	strlcpy(sub_vendor_id, &line[2], 4);
	sub_vendor_id[4] = 0;

	/* the sub_vendor id is second field */
	strlcpy(sub_product_id, &line[7], 4);
	sub_product_id[4] = 0;

	int_vendor_id = hex_to_int(vendor_id);
	int_sub_vendor_id = hex_to_int(sub_vendor_id);
	int_product_id = hex_to_int(product_id);
	int_sub_product_id = hex_to_int(sub_product_id);
	/* assign the product_name to any matching pci device */
	for_each_pci_func(dev, domain) {
	if (int_vendor_id == dev->vendor &&
	int_product_id == dev->product &&
	int_sub_product_id == dev->sub_product &&
	int_sub_vendor_id == dev->sub_vendor) {
	strlcpy(dev->dev_info->vendor_name, vendor,
	PCI_VENDOR_NAME_SIZE - 1);
	strlcpy(dev->dev_info->product_name, product,
	PCI_PRODUCT_NAME_SIZE - 1);
	}
	}
	}
	}
	fclose(f);
	return 0;
	}

	/* searching if any pcidevice match our query */
	struct match find_pci_device(const struct pci_domain domain,
	struct match *list)
	{
	uint32_t did, sid;
	struct match *m;
	const struct pci_device *dev;

	/* for all matches we have to search */
	for (m = list; m; m = m->next) {
	/* for each pci device we know */
	for_each_pci_func(dev, domain) {
	/* sid & did are the easiest way to compare devices */
	/* they are made of vendor/product subvendor/subproduct ids */
	sid = dev->svid_sdid;
	did = dev->vid_did;
	/* if the current device match */
	if (((did ^ m->did) & m->did_mask) == 0 &&
	((sid ^ m->sid) & m->sid_mask) == 0 &&
	dev->revision >= m->rid_min && dev->revision <= m->rid_max) {
	dprintf
	("PCI Match: Vendor=%04x Product=%04x Sub_vendor=%04x Sub_Product=%04x Release=%02x\n",
	dev->vendor, dev->product, dev->sub_vendor,
	dev->sub_product, dev->revision);
	/* returning the matched pci device */
	return m;
	}
	}
	}
	return NULL;
	}

	/* scanning the pci bus to find pci devices */
	struct pci_domain *pci_scan(void)
	{
	struct pci_domain *domain = NULL;
	struct pci_bus *bus = NULL;
	struct pci_slot *slot = NULL;
	struct pci_device *func = NULL;
	unsigned int nbus, ndev, nfunc, maxfunc;
	uint32_t did, sid, rcid;
	uint8_t hdrtype;
	pciaddr_t a;
	int cfgtype;

	cfgtype = pci_set_config_type(PCI_CFG_AUTO);

	dprintf("PCI configuration type %d\n", cfgtype);

	if (cfgtype == PCI_CFG_NONE)
	return NULL;

	dprintf("Scanning PCI Buses\n");

	for (nbus = 0; nbus < MAX_PCI_BUSES; nbus++) {
	dprintf("Probing bus 0x%02x... \n", nbus);
	bus = NULL;

	for (ndev = 0; ndev < MAX_PCI_DEVICES; ndev++) {
	maxfunc = 1; /* Assume a single-function device */
	slot = NULL;

	for (nfunc = 0; nfunc < maxfunc; nfunc++) {
	a = pci_mkaddr(nbus, ndev, nfunc, 0);
	did = pci_readl(a);

	if (did == 0xffffffff \|\| did == 0xffff0000 \|\|
	did == 0x0000ffff \|\| did == 0x00000000)
	continue;

	hdrtype = pci_readb(a + 0x0e);

	if (hdrtype & 0x80)
	maxfunc = MAX_PCI_FUNC; /* Multifunction device */

	rcid = pci_readl(a + 0x08);
	sid = pci_readl(a + 0x2c);

	if (!domain) {
	domain = zalloc(sizeof *domain);
	if (!domain)
	goto bail;
	}
	if (!bus) {
	bus = zalloc(sizeof *bus);
	if (!bus)
	goto bail;
	domain->bus[nbus] = bus;
	}
	if (!slot) {
	slot = zalloc(sizeof *slot);
	if (!slot)
	goto bail;
	bus->slot[ndev] = slot;
	}
	func = zalloc(sizeof *func);
	if (!func)
	goto bail;

	slot->func[nfunc] = func;

	func->vid_did = did;
	func->svid_sdid = sid;
	func->rid_class = rcid;

	dprintf
	("Scanning: BUS %02x DID %08x (%04x:%04x) SID %08x RID %02x\n",
	nbus, did, did >> 16, (did << 16) >> 16, sid, rcid & 0xff);
	}
	}
	}

	return domain;

	bail:
	free_pci_domain(domain);
	return NULL;
	}

	/* gathering additional configuration*/
	void gather_additional_pci_config(struct pci_domain *domain)
	{
	struct pci_device *dev;
	pciaddr_t pci_addr;
	int cfgtype;

	cfgtype = pci_set_config_type(PCI_CFG_AUTO);
	if (cfgtype == PCI_CFG_NONE)
	return;

	for_each_pci_func3(dev, domain, pci_addr) {
	if (!dev->dev_info) {
	dev->dev_info = zalloc(sizeof *dev->dev_info);
	if (!dev->dev_info) {
	return;
	}
	}
	dev->dev_info->irq = pci_readb(pci_addr + 0x3c);
	dev->dev_info->latency = pci_readb(pci_addr + 0x0d);
	}
	}

	void free_pci_domain(struct pci_domain *domain)
	{
	struct pci_bus *bus;
	struct pci_slot *slot;
	struct pci_device *func;
	unsigned int nbus, ndev, nfunc;

	if (domain) {
	for (nbus = 0; nbus < MAX_PCI_BUSES; nbus++) {
	bus = domain->bus[nbus];
	if (bus) {
	for (ndev = 0; ndev < MAX_PCI_DEVICES; ndev++) {
	slot = bus->slot[ndev];
	if (slot) {
	for (nfunc = 0; nfunc < MAX_PCI_FUNC; nfunc++) {
	func = slot->func[nfunc];
	if (func) {
	if (func->dev_info)
	free(func->dev_info);
	free(func);
	}
	}
	free(slot);
	}
	}
	free(bus);
	}
	}
	free(domain);
	}
	}

	/* Try to match any pci device to the appropriate kernel module */
	/* it uses the modules.alias from the boot device */
	int get_module_name_from_alias(struct pci_domain domain, char modules_alias_path)
	{
	char line[MAX_LINE];
	char module_name[21]; // the module name field is 21 char long
	char delims[]="*"; // colums are separated by spaces
	char vendor_id[16];
	char product_id[16];
	char sub_vendor_id[16];
	char sub_product_id[16];
	FILE *f;
	struct pci_device *dev=NULL;

	/* Intializing the linux_kernel_module for each pci device to "unknown" */
	/* adding a dev_info member if needed */
	for_each_pci_func(dev, domain) {
	/* initialize the dev_info structure if it doesn't exist yet. */
	if (! dev->dev_info) {
	dev->dev_info = zalloc(sizeof *dev->dev_info);
	if (!dev->dev_info)
	return -1;
	}
	for (int i=0;i<MAX_KERNEL_MODULES_PER_PCI_DEVICE;i++) {
	if (strlen(dev->dev_info->linux_kernel_module[i])==0)
	strlcpy(dev->dev_info->linux_kernel_module[i], "unknown",7);
	}
	}

	/* Opening the modules.pcimap (of a linux kernel) from the boot device */
	f=zfopen(modules_alias_path, "r");
	if (!f)
	return -ENOMODULESALIAS;

	/* for each line we found in the modules.pcimap */
	while ( fgets(line, sizeof line, f) ) {
	/* skipping unecessary lines */
	if ((line[0] == '#') \|\| (strstr(line,"alias pci:v")==NULL))
	continue;

	/* Resetting temp buffer*/
	memset(module_name,0,sizeof(module_name));
	memset(vendor_id,0,sizeof(vendor_id));
	memset(sub_vendor_id,0,sizeof(sub_vendor_id));
	memset(product_id,0,sizeof(product_id));
	memset(sub_product_id,0,sizeof(sub_product_id));
	strcpy(vendor_id,"0000");
	strcpy(product_id,"0000");
	/* ffff will be used to match any device as in modules.alias
	* a missing subvendor/product have to be considered as 0xFFFF*/
	strcpy(sub_product_id,"ffff");
	strcpy(sub_vendor_id,"ffff");

	char *result = NULL;
	int field=0;

	/* looking for the next field */
	result = strtok(line+strlen("alias pci:v"), delims);
	while( result != NULL ) {
	if (field==0) {

	/* Searching for the vendor separator*/
	char *temp = strstr(result,"d");
	if (temp != NULL) {
	strlcpy(vendor_id,result,temp-result);
	result+=strlen(vendor_id)+1;
	}

	/* Searching for the product separator*/
	temp = strstr(result,"sv");
	if (temp != NULL) {
	strlcpy(product_id,result,temp-result);
	result+=strlen(product_id)+1;
	}

	/* Searching for the sub vendor separator*/
	temp = strstr(result,"sd");
	if (temp != NULL) {
	strlcpy(sub_vendor_id,result,temp-result);
	result+=strlen(sub_vendor_id)+1;
	}

	/* Searching for the sub product separator*/
	temp = strstr(result,"bc");
	if (temp != NULL) {
	strlcpy(sub_product_id,result,temp-result);
	result+=strlen(sub_product_id)+1;
	}
	/* That's the module name */
	} else if ((strlen(result)>2) &&
	(result[0]==0x20))
	strcpy(module_name,result+1);
	/* We have to replace \n by \0*/
	module_name[strlen(module_name)-1]='\0';
	field++;

	/* Searching the next field */
	result = strtok( NULL, delims );
	}

	/* Now we have extracted informations from the modules.alias
	* Let's compare it with the devices we know*/
	int int_vendor_id=hex_to_int(vendor_id);
	int int_sub_vendor_id=hex_to_int(sub_vendor_id);
	int int_product_id=hex_to_int(product_id);
	int int_sub_product_id=hex_to_int(sub_product_id);
	/* if a pci_device matches an entry, fill the linux_kernel_module with
	the appropriate kernel module */
	for_each_pci_func(dev, domain) {
	if (int_vendor_id == dev->vendor &&
	int_product_id == dev->product &&
	(int_sub_product_id & dev->sub_product)
	== dev->sub_product &&
	(int_sub_vendor_id & dev->sub_vendor)
	== dev->sub_vendor) {
	bool found=false;

	/* Scan all known kernel modules for this pci device */
	for (int i=0; i<dev->dev_info->linux_kernel_module_count; i++) {

	/* Try to detect if we already knew the same kernel module*/
	if (strstr(dev->dev_info->linux_kernel_module[i], module_name)) {
	found=true;
	break;
	}
	}
	/* If we don't have this kernel module, let's add it */
	if (!found) {
	strcpy(dev->dev_info->linux_kernel_module[dev->dev_info->linux_kernel_module_count], module_name);
	dev->dev_info->linux_kernel_module_count++;
	}
	}
	}
	}
	fclose(f);
	return 0;
	}