/*************************************************************************** * This is a module which is used for counting packets. * * See http://www.intra2net.com/opensource/ipt_account * * for further information * * * * Copyright (C) 2004 by Intra2net AG * * opensource@intra2net.com * * * * This program is free software; you can redistribute it and/or modify * * it under the terms of the GNU General Public License * * version 2 as published by the Free Software Foundation; * * * ***************************************************************************/ #include #include #include #include #include #include #include #include struct in_device; #include #include #if 0 #define DEBUGP printk #else #define DEBUGP(format, args...) #endif #if (PAGE_SIZE < 4096) #error "ipt_ACCOUNT needs at least a PAGE_SIZE of 4096" #endif struct ipt_account_table *ipt_account_tables = NULL; struct ipt_account_handle *ipt_account_handles = NULL; void *ipt_account_tmpbuf = NULL; /* Spinlock used for manipulating the current accounting tables/data */ static spinlock_t ipt_account_lock = SPIN_LOCK_UNLOCKED; /* Spinlock used for manipulating userspace handles/snapshot data */ static spinlock_t ipt_account_userspace_lock = SPIN_LOCK_UNLOCKED; /* Recursive free of all data structures */ void ipt_account_data_free(void *data, unsigned char depth) { /* Empty data set */ if (!data) return; /* Free for 8 bit network */ if (depth == 0) { free_page((unsigned long)data); data = NULL; return; } /* Free for 16 bit network */ if (depth == 1) { struct ipt_account_mask_16 *mask_16 = (struct ipt_account_mask_16 *)data; unsigned int b; for (b=0; b <= 255; b++) { if (mask_16->mask_24[b] != 0) { free_page((unsigned long)mask_16->mask_24[b]); mask_16->mask_24[b] = NULL; } } free_page((unsigned long)data); data = NULL; return; } /* Free for 24 bit network */ if (depth == 3) { unsigned int a, b; for (a=0; a <= 255; a++) { if (((struct ipt_account_mask_8 *)data)->mask_16[a]) { struct ipt_account_mask_16 *mask_16 = (struct ipt_account_mask_16*)((struct ipt_account_mask_8 *)data)->mask_16[a]; for (b=0; b <= 255; b++) { if (mask_16->mask_24[b]) { free_page((unsigned long)mask_16->mask_24[b]); mask_16->mask_24[b] = NULL; } } free_page((unsigned long)mask_16); mask_16 = NULL; } } free_page((unsigned long)data); data = NULL; return; } printk("ACCOUNT: ipt_account_data_free called with unknown depth: %d\n", depth); return; } /* Look for existing table / insert new one. Return internal ID or -1 on error */ int ipt_account_table_insert(char *name, unsigned int ip, unsigned int netmask) { unsigned int i; DEBUGP("ACCOUNT: ipt_account_table_insert: %s, %u.%u.%u.%u/%u.%u.%u.%u\n", name, NIPQUAD(ip), NIPQUAD(netmask)); /* Look for existing table */ for (i = 0; i < ACCOUNT_MAX_TABLES; i++) { if (strncmp(ipt_account_tables[i].name, name, ACCOUNT_TABLE_NAME_LEN) == 0) { DEBUGP("ACCOUNT: Found existing slot: %d - %u.%u.%u.%u/%u.%u.%u.%u\n", i, NIPQUAD(ipt_account_tables[i].ip), NIPQUAD(ipt_account_tables[i].netmask)); if (ipt_account_tables[i].ip != ip || ipt_account_tables[i].netmask != netmask) { printk("ACCOUNT: Table %s found, but IP/netmask mismatch. IP/netmask found: %u.%u.%u.%u/%u.%u.%u.%u\n", name, NIPQUAD(ipt_account_tables[i].ip), NIPQUAD(ipt_account_tables[i].netmask)); return -1; } ipt_account_tables[i].refcount++; DEBUGP("ACCOUNT: Refcount: %d\n", ipt_account_tables[i].refcount); return i; } } /* Insert new table */ for (i = 0; i < ACCOUNT_MAX_TABLES; i++) { /* Found free slot */ if (ipt_account_tables[i].name[0] == 0) { DEBUGP("ACCOUNT: Found free slot: %d\n", i); strncpy (ipt_account_tables[i].name, name, ACCOUNT_TABLE_NAME_LEN-1); ipt_account_tables[i].ip = ip; ipt_account_tables[i].netmask = netmask; /* Calculate netsize */ unsigned int j, calc_mask, netsize=0; calc_mask = htonl(netmask); for (j = 31; j > 0; j--) { if (calc_mask&(1<= 24) ipt_account_tables[i].depth = 0; else if (netsize >= 16) ipt_account_tables[i].depth = 1; else if(netsize >= 8) ipt_account_tables[i].depth = 2; printk("ACCOUNT: calculated netsize: %u -> ipt_account_table depth %u\n", netsize, ipt_account_tables[i].depth); ipt_account_tables[i].refcount++; if ((ipt_account_tables[i].data = (void *)get_zeroed_page(GFP_ATOMIC)) == NULL) { printk("ACCOUNT: out of memory for data of table: %s\n", name); memset(&ipt_account_tables[i], 0, sizeof(struct ipt_account_table)); return -1; } return i; } } /* No free slot found */ printk("ACCOUNT: No free table slot found (max: %d). Please increase ACCOUNT_MAX_TABLES.\n", ACCOUNT_MAX_TABLES); return -1; } static int ipt_account_checkentry(const char *tablename, const struct ipt_entry *e, void *targinfo, unsigned int targinfosize, unsigned int hook_mask) { struct ipt_account_info *info = targinfo; if (targinfosize != IPT_ALIGN(sizeof(struct ipt_account_info))) { DEBUGP("ACCOUNT: targinfosize %u != %u\n", targinfosize, IPT_ALIGN(sizeof(struct ipt_account_info))); return 0; } spin_lock_bh(&ipt_account_lock); int table_nr = ipt_account_table_insert(info->table_name, info->net_ip, info->net_mask); if (table_nr == -1) { printk("ACCOUNT: Table insert problem. Aborting\n"); spin_unlock_bh(&ipt_account_lock); return 0; } /* Table nr caching so we don't have to do an extra string compare for every packet */ info->table_nr = table_nr; spin_unlock_bh(&ipt_account_lock); return 1; } void ipt_account_deleteentry(void *targinfo, unsigned int targinfosize) { unsigned int i; struct ipt_account_info *info = targinfo; if (targinfosize != IPT_ALIGN(sizeof(struct ipt_account_info))) { DEBUGP("ACCOUNT: targinfosize %u != %u\n", targinfosize, IPT_ALIGN(sizeof(struct ipt_account_info))); } spin_lock_bh(&ipt_account_lock); DEBUGP("ACCOUNT: ipt_account_deleteentry called for table: %s (#%d)\n", info->table_name, info->table_nr); info->table_nr = -1; /* Set back to original state */ /* Look for table */ for (i = 0; i < ACCOUNT_MAX_TABLES; i++) { if (strncmp(ipt_account_tables[i].name, info->table_name, ACCOUNT_TABLE_NAME_LEN) == 0) { DEBUGP("ACCOUNT: Found table at slot: %d\n", i); ipt_account_tables[i].refcount--; DEBUGP("ACCOUNT: Refcount left: %d\n", ipt_account_tables[i].refcount); /* Table not needed anymore? */ if (ipt_account_tables[i].refcount == 0) { DEBUGP("ACCOUNT: Destroying table at slot: %d\n", i); ipt_account_data_free(ipt_account_tables[i].data, ipt_account_tables[i].depth); memset(&ipt_account_tables[i], 0, sizeof(struct ipt_account_table)); } spin_unlock_bh(&ipt_account_lock); return; } } /* Table not found */ printk("ACCOUNT: Table %s not found for destroy\n", info->table_name); spin_unlock_bh(&ipt_account_lock); } void ipt_account_depth0_insert(struct ipt_account_mask_24 *mask_24, unsigned int net_ip, unsigned int netmask, unsigned int src_ip, unsigned int dst_ip, unsigned int size, unsigned int *itemcount) { unsigned char is_src = 0, is_dst = 0; DEBUGP("ACCOUNT: ipt_account_depth0_insert: %u.%u.%u.%u/%u.%u.%u.%u for net %u.%u.%u.%u/%u.%u.%u.%u, size: %u\n", NIPQUAD(src_ip), NIPQUAD(dst_ip), NIPQUAD(net_ip), NIPQUAD(netmask), size); /* Check if src/dst is inside our network. */ /* Special: net_ip = 0.0.0.0/0 gets stored as src in slot 0 */ if (!netmask) src_ip = 0; if ((net_ip&netmask) == (src_ip&netmask)) is_src = 1; if ((net_ip&netmask) == (dst_ip&netmask) && netmask) is_dst = 1; if (!is_src && !is_dst) { DEBUGP("ACCOUNT: Skipping packet %u.%u.%u.%u/%u.%u.%u.%u for net %u.%u.%u.%u/%u.%u.%u.%u\n", NIPQUAD(src_ip), NIPQUAD(dst_ip), NIPQUAD(net_ip), NIPQUAD(netmask)); return; } /* Check if this entry is new */ char is_src_new_ip = 0, is_dst_new_ip = 0; /* Calculate array positions */ unsigned char src_slot = (unsigned char)((src_ip&0xFF000000) >> 24); unsigned char dst_slot = (unsigned char)((dst_ip&0xFF000000) >> 24); /* Increase size counters */ if (is_src) { /* Calculate network slot */ DEBUGP("ACCOUNT: Calculated SRC 8 bit network slot: %d\n", src_slot); if (!mask_24->ip[src_slot].src_packets && !mask_24->ip[src_slot].dst_packets) is_src_new_ip = 1; mask_24->ip[src_slot].src_packets++; mask_24->ip[src_slot].src_bytes+=size; } if (is_dst) { DEBUGP("ACCOUNT: Calculated DST 8 bit network slot: %d\n", dst_slot); if (!mask_24->ip[dst_slot].src_packets && !mask_24->ip[dst_slot].dst_packets) is_dst_new_ip = 1; mask_24->ip[dst_slot].dst_packets++; mask_24->ip[dst_slot].dst_bytes+=size; } /* Increase itemcounter */ DEBUGP("ACCOUNT: Itemcounter before: %d\n", *itemcount); if (src_slot == dst_slot) { if (is_src_new_ip || is_dst_new_ip) { DEBUGP("ACCOUNT: src_slot == dst_slot: %d, %d\n", is_src_new_ip, is_dst_new_ip); (*itemcount)++; } } else { if (is_src_new_ip) { DEBUGP("ACCOUNT: New src_ip: %u.%u.%u.%u\n", NIPQUAD(src_ip)); (*itemcount)++; } if (is_dst_new_ip) { DEBUGP("ACCOUNT: New dst_ip: %u.%u.%u.%u\n", NIPQUAD(dst_ip)); (*itemcount)++; } } DEBUGP("ACCOUNT: Itemcounter after: %d\n", *itemcount); } void ipt_account_depth1_insert(struct ipt_account_mask_16 *mask_16, unsigned int net_ip, unsigned int netmask, unsigned int src_ip, unsigned int dst_ip, unsigned int size, unsigned int *itemcount) { /* Do we need to process src IP? */ if ((net_ip&netmask) == (src_ip&netmask)) { unsigned char slot = (unsigned char)((src_ip&0x00FF0000) >> 16); DEBUGP("ACCOUNT: Calculated SRC 16 bit network slot: %d\n", slot); /* Do we need to create a new mask_24 bucket? */ if (!mask_16->mask_24[slot] && (mask_16->mask_24[slot] = (void *)get_zeroed_page(GFP_ATOMIC)) == NULL) { printk("ACCOUNT: Can't process packet because out of memory!\n"); return; } ipt_account_depth0_insert((struct ipt_account_mask_24 *)mask_16->mask_24[slot], net_ip, netmask, src_ip, 0, size, itemcount); } /* Do we need to process dst IP? */ if ((net_ip&netmask) == (dst_ip&netmask)) { unsigned char slot = (unsigned char)((dst_ip&0x00FF0000) >> 16); DEBUGP("ACCOUNT: Calculated DST 16 bit network slot: %d\n", slot); /* Do we need to create a new mask_24 bucket? */ if (!mask_16->mask_24[slot] && (mask_16->mask_24[slot] = (void *)get_zeroed_page(GFP_ATOMIC)) == NULL) { printk("ACCOUT: Can't process packet because out of memory!\n"); return; } ipt_account_depth0_insert((struct ipt_account_mask_24 *)mask_16->mask_24[slot], net_ip, netmask, 0, dst_ip, size, itemcount); } } void ipt_account_depth2_insert(struct ipt_account_mask_8 *mask_8, unsigned int net_ip, unsigned int netmask, unsigned int src_ip, unsigned int dst_ip, unsigned int size, unsigned int *itemcount) { /* Do we need to process src IP? */ if ((net_ip&netmask) == (src_ip&netmask)) { unsigned char slot = (unsigned char)((src_ip&0x0000FF00) >> 8); DEBUGP("ACCOUNT: Calculated SRC 24 bit network slot: %d\n", slot); /* Do we need to create a new mask_24 bucket? */ if (!mask_8->mask_16[slot] && (mask_8->mask_16[slot] = (void *)get_zeroed_page(GFP_ATOMIC)) == NULL) { printk("ACCOUNT: Can't process packet because out of memory!\n"); return; } ipt_account_depth1_insert((struct ipt_account_mask_16 *)mask_8->mask_16[slot], net_ip, netmask, src_ip, 0, size, itemcount); } /* Do we need to process dst IP? */ if ((net_ip&netmask) == (dst_ip&netmask)) { unsigned char slot = (unsigned char)((dst_ip&0x0000FF00) >> 8); DEBUGP("ACCOUNT: Calculated DST 24 bit network slot: %d\n", slot); /* Do we need to create a new mask_24 bucket? */ if (!mask_8->mask_16[slot] && (mask_8->mask_16[slot] = (void *)get_zeroed_page(GFP_ATOMIC)) == NULL) { printk("ACCOUNT: Can't process packet because out of memory!\n"); return; } ipt_account_depth1_insert((struct ipt_account_mask_16 *)mask_8->mask_16[slot], net_ip, netmask, 0, dst_ip, size, itemcount); } } static unsigned int ipt_account_target(struct sk_buff **pskb, unsigned int hooknum, const struct net_device *in, const struct net_device *out, const void *targinfo, void *userinfo) { const struct ipt_account_info *info = (const struct ipt_account_info *)targinfo; unsigned int src_ip = (*pskb)->nh.iph->saddr; unsigned int dst_ip = (*pskb)->nh.iph->daddr; unsigned int size = ntohs((*pskb)->nh.iph->tot_len); spin_lock_bh(&ipt_account_lock); if (ipt_account_tables[info->table_nr].name[0] == 0) { printk("ACCOUNT: ipt_account_target: Invalid table id %u. IPs %u.%u.%u.%u/%u.%u.%u.%u\n", info->table_nr, NIPQUAD(src_ip), NIPQUAD(dst_ip)); spin_unlock_bh(&ipt_account_lock); return IPT_CONTINUE; } /* 8 bit network or "any" network */ if (ipt_account_tables[info->table_nr].depth == 0) { /* Count packet and check if the IP is new */ ipt_account_depth0_insert((struct ipt_account_mask_24 *)ipt_account_tables[info->table_nr].data, ipt_account_tables[info->table_nr].ip, ipt_account_tables[info->table_nr].netmask, src_ip, dst_ip, size, &ipt_account_tables[info->table_nr].itemcount); spin_unlock_bh(&ipt_account_lock); return IPT_CONTINUE; } /* 16 bit network */ if (ipt_account_tables[info->table_nr].depth == 1) { ipt_account_depth1_insert((struct ipt_account_mask_16 *)ipt_account_tables[info->table_nr].data, ipt_account_tables[info->table_nr].ip, ipt_account_tables[info->table_nr].netmask, src_ip, dst_ip, size, &ipt_account_tables[info->table_nr].itemcount); spin_unlock_bh(&ipt_account_lock); return IPT_CONTINUE; } /* 24 bit network */ if (ipt_account_tables[info->table_nr].depth == 2) { ipt_account_depth2_insert((struct ipt_account_mask_8 *)ipt_account_tables[info->table_nr].data, ipt_account_tables[info->table_nr].ip, ipt_account_tables[info->table_nr].netmask, src_ip, dst_ip, size, &ipt_account_tables[info->table_nr].itemcount); spin_unlock_bh(&ipt_account_lock); return IPT_CONTINUE; } printk("ACCOUNT: ipt_account_target: Unable to process packet. Table id %u. IPs %u.%u.%u.%u/%u.%u.%u.%u\n", info->table_nr, NIPQUAD(src_ip), NIPQUAD(dst_ip)); spin_unlock_bh(&ipt_account_lock); return IPT_CONTINUE; } /* Functions dealing with "handles": Handles are snapshots of a accounting state. read snapshots are only for debugging the code and are very expensive concerning speed/memory compared to read_and_flush. The functions aren't protected by spinlocks themselves as this is done in the ioctl part of the code. */ /* Find a free handle slot. Normally only one should be used, but there could be two or more applications accessing the data at the same time. */ int ipt_account_handle_find_slot(void) { unsigned int i; /* Insert new table */ for (i = 0; i < ACCOUNT_MAX_HANDLES; i++) { /* Found free slot */ if (ipt_account_handles[i].data == NULL) { /* Don't "mark" data as used as we are protected by a spinlock by the calling function. */ /* handle_find_slot() is only a function to prevent code duplication. */ return i; } } /* No free slot found */ printk("ACCOUNT: No free handle slot found (max: %u). Please increase ACCOUNT_MAX_HANDLES.\n", ACCOUNT_MAX_HANDLES); return -1; } int ipt_account_handle_free(unsigned int handle) { if (handle >= ACCOUNT_MAX_HANDLES) { printk("ACCOUNT: Invalid handle for ipt_account_handle_free() specified: %u\n", handle); return -EINVAL; } ipt_account_data_free(ipt_account_handles[handle].data, ipt_account_handles[handle].depth); memset (&ipt_account_handles[handle], 0, sizeof (struct ipt_account_handle)); return 0; } /* Prepare data for read without flush. Use only for debugging! Real applications should use read&flush as it's way more efficent */ int ipt_account_handle_prepare_read(char *tablename, unsigned int *count) { int handle, i, table_nr=-1; for (i = 0; i < ACCOUNT_MAX_TABLES; i++) if (strncmp(ipt_account_tables[i].name, tablename, ACCOUNT_TABLE_NAME_LEN) == 0) { table_nr = i; break; } if (table_nr == -1) { printk("ACCOUNT: ipt_account_handle_prepare_read(): Table %s not found\n", tablename); return -1; } /* Can't find a free handle slot? */ if ((handle = ipt_account_handle_find_slot()) == -1) return -1; /* Fill up handle structure */ ipt_account_handles[handle].ip = ipt_account_tables[table_nr].ip; ipt_account_handles[handle].depth = ipt_account_tables[table_nr].depth; ipt_account_handles[handle].itemcount = ipt_account_tables[table_nr].itemcount; /* allocate "root" table */ if ((ipt_account_handles[handle].data = (void*)get_zeroed_page(GFP_ATOMIC)) == NULL) { printk("ACCOUNT: out of memory for root table in ipt_account_handle_prepare_read()\n"); memset (&ipt_account_handles[handle], 0, sizeof(struct ipt_account_handle)); return -1; } /* Recursive copy of complete data structure */ unsigned int depth = ipt_account_handles[handle].depth; if (depth == 0) { memcpy(ipt_account_handles[handle].data, ipt_account_tables[table_nr].data, sizeof(struct ipt_account_mask_24)); } else if (depth == 1) { struct ipt_account_mask_16 *src_16 = (struct ipt_account_mask_16 *)ipt_account_tables[table_nr].data; struct ipt_account_mask_16 *network_16 = (struct ipt_account_mask_16 *)ipt_account_handles[handle].data; unsigned int b; for (b = 0; b <= 255; b++) { if (src_16->mask_24[b]) { if ((network_16->mask_24[b] = (void*)get_zeroed_page(GFP_ATOMIC)) == NULL) { printk("ACCOUNT: out of memory during copy of 16 bit network in ipt_account_handle_prepare_read()\n"); ipt_account_data_free(ipt_account_handles[handle].data, depth); memset (&ipt_account_handles[handle], 0, sizeof(struct ipt_account_handle)); return -1; } memcpy(network_16->mask_24[b], src_16->mask_24[b], sizeof(struct ipt_account_mask_24)); } } } else if(depth == 2) { struct ipt_account_mask_8 *src_8 = (struct ipt_account_mask_8 *)ipt_account_tables[table_nr].data; struct ipt_account_mask_8 *network_8 = (struct ipt_account_mask_8 *)ipt_account_handles[handle].data; unsigned int a; for (a = 0; a <= 255; a++) { if (src_8->mask_16[a]) { if ((network_8->mask_16[a] = (void*)get_zeroed_page(GFP_ATOMIC)) == NULL) { printk("ACCOUNT: out of memory during copy of 24 bit network in ipt_account_handle_prepare_read()\n"); ipt_account_data_free(ipt_account_handles[handle].data, depth); memset (&ipt_account_handles[handle], 0, sizeof(struct ipt_account_handle)); return -1; } memcpy(network_8->mask_16[a], src_8->mask_16[a], sizeof(struct ipt_account_mask_16)); struct ipt_account_mask_16 *src_16 = src_8->mask_16[a]; struct ipt_account_mask_16 *network_16 = network_8->mask_16[a]; unsigned int b; for (b = 0; b <= 255; b++) { if (src_16->mask_24[b]) { if ((network_16->mask_24[b] = (void*)get_zeroed_page(GFP_ATOMIC)) == NULL) { printk("ACCOUNT: out of memory during copy of 16 bit network in ipt_account_handle_prepare_read()\n"); ipt_account_data_free(ipt_account_handles[handle].data, depth); memset (&ipt_account_handles[handle], 0, sizeof(struct ipt_account_handle)); return -1; } memcpy(network_16->mask_24[b], src_16->mask_24[b], sizeof(struct ipt_account_mask_24)); } } } } } *count = ipt_account_tables[table_nr].itemcount; return handle; } /* Prepare data for read and flush it */ int ipt_account_handle_prepare_read_flush(char *tablename, unsigned int *count) { int handle, i, table_nr=-1; for (i = 0; i < ACCOUNT_MAX_TABLES; i++) if (strncmp(ipt_account_tables[i].name, tablename, ACCOUNT_TABLE_NAME_LEN) == 0) { table_nr = i; break; } if (table_nr == -1) { printk("ACCOUNT: ipt_account_handle_prepare_read_flush(): Table %s not found\n", tablename); return -1; } /* Can't find a free handle slot? */ if ((handle = ipt_account_handle_find_slot()) == -1) return -1; /* Try to allocate memory */ void *new_data_page = (void*)get_zeroed_page(GFP_ATOMIC); if (!new_data_page) { printk("ACCOUNT: ipt_account_handle_prepare_read_flush(): Out of memory!\n"); return -1; } /* Fill up handle structure */ ipt_account_handles[handle].ip = ipt_account_tables[table_nr].ip; ipt_account_handles[handle].depth = ipt_account_tables[table_nr].depth; ipt_account_handles[handle].itemcount = ipt_account_tables[table_nr].itemcount; ipt_account_handles[handle].data = ipt_account_tables[table_nr].data; *count = ipt_account_tables[table_nr].itemcount; /* "Flush" table data */ ipt_account_tables[table_nr].data = new_data_page; ipt_account_tables[table_nr].itemcount = 0; return handle; } /* Copy the actual that into a prepared buffer. We only copy entries != 0 to increase performance. The memory gets freed again in ipt_account_handle_free(). */ int ipt_account_handle_get_data(unsigned int handle, void *buffer) { struct ipt_account_handle_ip handle_ip; unsigned int handle_ip_size = sizeof (struct ipt_account_handle_ip); unsigned int i, tmpbuf_pos=0; if (handle >= ACCOUNT_MAX_HANDLES) { printk("ACCOUNT: invalid handle for ipt_account_handle_get_data() specified: %u\n", handle); return -1; } if (ipt_account_handles[handle].data == NULL) { printk("ACCOUNT: handle %u is BROKEN: Contains no data\n", handle); return -1; } unsigned int net_ip = ipt_account_handles[handle].ip; unsigned int depth = ipt_account_handles[handle].depth; /* 8 bit network */ if (depth == 0) { struct ipt_account_mask_24 *network = (struct ipt_account_mask_24*)ipt_account_handles[handle].data; for (i = 0; i <= 255; i++) { if (network->ip[i].src_packets || network->ip[i].dst_packets) { handle_ip.ip = net_ip | (i<<24); handle_ip.src_packets = network->ip[i].src_packets; handle_ip.src_bytes = network->ip[i].src_bytes; handle_ip.dst_packets = network->ip[i].dst_packets; handle_ip.dst_bytes = network->ip[i].dst_bytes; /* Temporary buffer full? Flush to userspace */ if (tmpbuf_pos+handle_ip_size >= PAGE_SIZE) { copy_to_user(buffer, ipt_account_tmpbuf, tmpbuf_pos); tmpbuf_pos = 0; } memcpy(ipt_account_tmpbuf+tmpbuf_pos, &handle_ip, handle_ip_size); tmpbuf_pos += handle_ip_size; } } /* Flush remaining data to userspace */ if (tmpbuf_pos) copy_to_user(buffer, ipt_account_tmpbuf, tmpbuf_pos); return 0; } /* 16 bit network */ if (depth == 1) { struct ipt_account_mask_16 *network_16 = (struct ipt_account_mask_16*)ipt_account_handles[handle].data; unsigned int b; for (b = 0; b <= 255; b++) { if (network_16->mask_24[b]) { struct ipt_account_mask_24 *network = (struct ipt_account_mask_24*)network_16->mask_24[b]; for (i = 0; i <= 255; i++) { if (network->ip[i].src_packets || network->ip[i].dst_packets) { handle_ip.ip = net_ip | (b << 16) | (i<<24); handle_ip.src_packets = network->ip[i].src_packets; handle_ip.src_bytes = network->ip[i].src_bytes; handle_ip.dst_packets = network->ip[i].dst_packets; handle_ip.dst_bytes = network->ip[i].dst_bytes; /* Temporary buffer full? Flush to userspace */ if (tmpbuf_pos+handle_ip_size >= PAGE_SIZE) { copy_to_user(buffer, ipt_account_tmpbuf, tmpbuf_pos); tmpbuf_pos = 0; } memcpy(ipt_account_tmpbuf+tmpbuf_pos, &handle_ip, handle_ip_size); tmpbuf_pos += handle_ip_size; } } } } /* Flush remaining data to userspace */ if (tmpbuf_pos) copy_to_user(buffer, ipt_account_tmpbuf, tmpbuf_pos); return 0; } /* 24 bit network */ if (depth == 2) { struct ipt_account_mask_8 *network_8 = (struct ipt_account_mask_8*)ipt_account_handles[handle].data; unsigned int a, b; for (a = 0; a <= 255; a++) { if (network_8->mask_16[a]) { struct ipt_account_mask_16 *network_16 = (struct ipt_account_mask_16*)network_8->mask_16[a]; for (b = 0; b <= 255; b++) { if (network_16->mask_24[b]) { struct ipt_account_mask_24 *network = (struct ipt_account_mask_24*)network_16->mask_24[b]; for (i = 0; i <= 255; i++) { if (network->ip[i].src_packets || network->ip[i].dst_packets) { handle_ip.ip = net_ip | (a << 8) | (b << 16) | (i<<24); handle_ip.src_packets = network->ip[i].src_packets; handle_ip.src_bytes = network->ip[i].src_bytes; handle_ip.dst_packets = network->ip[i].dst_packets; handle_ip.dst_bytes = network->ip[i].dst_bytes; /* Temporary buffer full? Flush to userspace */ if (tmpbuf_pos+handle_ip_size >= PAGE_SIZE) { copy_to_user(buffer, ipt_account_tmpbuf, tmpbuf_pos); tmpbuf_pos = 0; } memcpy(ipt_account_tmpbuf+tmpbuf_pos, &handle_ip, handle_ip_size); tmpbuf_pos += handle_ip_size; } } } } } } /* Flush remaining data to userspace */ if (tmpbuf_pos) copy_to_user(buffer, ipt_account_tmpbuf, tmpbuf_pos); return 0; } return -1; } static int ipt_account_set_ctl(struct sock *sk, int cmd, void *user, unsigned int len) { struct ipt_account_handle_sockopt handle; int ret = -EINVAL; if (!capable(CAP_NET_ADMIN)) return -EPERM; switch (cmd) { case IPT_SO_SET_ACCOUNT_HANDLE_FREE: if (len != sizeof(struct ipt_account_handle_sockopt)) { printk("ACCOUNT: ipt_account_set_ctl: wrong data size (%u != %u) for IPT_SO_SET_HANDLE_FREE\n", len, sizeof(struct ipt_account_handle_sockopt)); break; } if (copy_from_user (&handle, user, len)) { printk("ACCOUNT: ipt_account_set_ctl: copy_from_user failed for IPT_SO_SET_HANDLE_FREE\n"); break; } spin_lock_bh(&ipt_account_userspace_lock); ret = ipt_account_handle_free(handle.handle_nr); spin_unlock_bh(&ipt_account_userspace_lock); break; case IPT_SO_SET_ACCOUNT_HANDLE_FREE_ALL: { unsigned int i; spin_lock_bh(&ipt_account_userspace_lock); for (i = 0; i < ACCOUNT_MAX_HANDLES; i++) ipt_account_handle_free(i); spin_unlock_bh(&ipt_account_userspace_lock); ret = 0; break; } default: printk("ACCOUNT: ipt_account_set_ctl: unknown request %i\n", cmd); } return ret; } static int ipt_account_get_ctl(struct sock *sk, int cmd, void *user, int *len) { struct ipt_account_handle_sockopt handle; int ret = -EINVAL; if (!capable(CAP_NET_ADMIN)) return -EPERM; switch (cmd) { case IPT_SO_GET_ACCOUNT_PREPARE_READ_FLUSH: case IPT_SO_GET_ACCOUNT_PREPARE_READ: if (*len < sizeof(struct ipt_account_handle_sockopt)) { printk("ACCOUNT: ipt_account_get_ctl: wrong data size (%u != %u) for IPT_SO_GET_ACCOUNT_PREPARE_READ/READ_FLUSH\n", *len, sizeof(struct ipt_account_handle_sockopt)); break; } if (copy_from_user (&handle, user, sizeof(struct ipt_account_handle_sockopt))) { printk("ACCOUNT: ipt_account_get_ctl: copy_from_user failed for IPT_SO_GET_ACCOUNT_PREPARE_READ/READ_FLUSH\n"); break; } spin_lock_bh(&ipt_account_lock); spin_lock_bh(&ipt_account_userspace_lock); if (cmd == IPT_SO_GET_ACCOUNT_PREPARE_READ_FLUSH) handle.handle_nr = ipt_account_handle_prepare_read_flush(handle.name, &handle.itemcount); else handle.handle_nr = ipt_account_handle_prepare_read(handle.name, &handle.itemcount); spin_unlock_bh(&ipt_account_userspace_lock); spin_unlock_bh(&ipt_account_lock); if (handle.handle_nr == -1) { printk("ACCOUNT: ipt_account_get_ctl: ipt_account_handle_prepare_read failed\n"); break; } if (copy_to_user(user, &handle, sizeof(struct ipt_account_handle_sockopt))) { printk("ACCOUNT: ipt_account_set_ctl: copy_to_user failed for IPT_SO_GET_ACCOUNT_PREPARE_READ/READ_FLUSH\n"); break; } ret = 0; break; case IPT_SO_GET_ACCOUNT_GET_DATA: if (*len < sizeof(struct ipt_account_handle_sockopt)) { printk("ACCOUNT: ipt_account_get_ctl: wrong data size (%u != %u) for IPT_SO_GET_ACCOUNT_PREPARE_READ/READ_FLUSH\n", *len, sizeof(struct ipt_account_handle_sockopt)); break; } if (copy_from_user (&handle, user, sizeof(struct ipt_account_handle_sockopt))) { printk("ACCOUNT: ipt_account_get_ctl: copy_from_user failed for IPT_SO_GET_ACCOUNT_PREPARE_READ/READ_FLUSH\n"); break; } if (handle.handle_nr >= ACCOUNT_MAX_HANDLES) { printk("ACCOUNT: Invalid handle for IPT_SO_GET_ACCOUNT_GET_DATA: %u\n", handle.handle_nr); break; } if (*len < ipt_account_handles[handle.handle_nr].itemcount*sizeof(struct ipt_account_handle_ip)) { printk("ACCOUNT: ipt_account_get_ctl: not enough space (%u < %u) to store data from IPT_SO_GET_ACCOUNT_GET_DATA\n", *len, ipt_account_handles[handle.handle_nr].itemcount*sizeof(struct ipt_account_handle_ip)); ret = -ENOMEM; break; } spin_lock_bh(&ipt_account_userspace_lock); ret = ipt_account_handle_get_data(handle.handle_nr, user); spin_unlock_bh(&ipt_account_userspace_lock); if (ret) { printk("ACCOUNT: ipt_account_get_ctl: ipt_account_handle_get_data failed for handle %u\n", handle.handle_nr); break; } ret = 0; break; case IPT_SO_GET_ACCOUNT_GET_HANDLE_USAGE: { if (*len < sizeof(struct ipt_account_handle_sockopt)) { printk("ACCOUNT: ipt_account_get_ctl: wrong data size (%u != %u) for IPT_SO_GET_ACCOUNT_GET_HANDLE_USAGE\n", *len, sizeof(struct ipt_account_handle_sockopt)); break; } /* Find out how many handles are in use */ unsigned int i; handle.itemcount = 0; spin_lock_bh(&ipt_account_userspace_lock); for (i = 0; i < ACCOUNT_MAX_HANDLES; i++) if (ipt_account_handles[i].data) handle.itemcount++; spin_unlock_bh(&ipt_account_userspace_lock); if (copy_to_user(user, &handle, sizeof(struct ipt_account_handle_sockopt))) { printk("ACCOUNT: ipt_account_set_ctl: copy_to_user failed for IPT_SO_GET_ACCOUNT_GET_HANDLE_USAGE\n"); break; } ret = 0; break; } case IPT_SO_GET_ACCOUNT_GET_TABLE_NAMES: { spin_lock_bh(&ipt_account_lock); /* Determine size of table names */ unsigned int size = 0, i; for (i = 0; i < ACCOUNT_MAX_TABLES; i++) { if (ipt_account_tables[i].name[0] != 0) size += strlen (ipt_account_tables[i].name) + 1; } size += 1; /* Terminating NULL character */ if (*len < size) { spin_unlock_bh(&ipt_account_lock); printk("ACCOUNT: ipt_account_get_ctl: not enough space (%u < %u) to store table names\n", *len, size); ret = -ENOMEM; break; } /* Copy table names to userspace */ char *tnames = user; for (i = 0; i < ACCOUNT_MAX_TABLES; i++) { if (ipt_account_tables[i].name[0] != 0) { int len = strlen (ipt_account_tables[i].name) + 1; copy_to_user(tnames, ipt_account_tables[i].name, len); /* copy string + terminating zero */ tnames += len; } } /* Append terminating zero */ i = 0; copy_to_user(tnames, &i, 1); spin_unlock_bh(&ipt_account_lock); ret = 0; break; } default: printk("ACCOUNT: ipt_account_get_ctl: unknown request %i\n", cmd); } return ret; } static struct ipt_target ipt_account_reg = { { NULL, NULL } , "ACCOUNT", ipt_account_target, ipt_account_checkentry, ipt_account_deleteentry, THIS_MODULE }; static struct nf_sockopt_ops ipt_account_sockopts = { { NULL, NULL } , PF_INET, IPT_SO_SET_ACCOUNT_HANDLE_FREE, IPT_SO_SET_ACCOUNT_MAX+1, ipt_account_set_ctl, IPT_SO_GET_ACCOUNT_PREPARE_READ, IPT_SO_GET_ACCOUNT_MAX+1, ipt_account_get_ctl, 0, NULL }; static int __init init(void) { if ((ipt_account_tables = kmalloc(ACCOUNT_MAX_TABLES*sizeof(struct ipt_account_table), GFP_KERNEL)) == NULL) { printk("ACCOUNT: Out of memory allocating account_tables structure"); return -EINVAL; } memset(ipt_account_tables, 0, ACCOUNT_MAX_TABLES*sizeof(struct ipt_account_table)); if ((ipt_account_handles = kmalloc(ACCOUNT_MAX_HANDLES*sizeof(struct ipt_account_handle), GFP_KERNEL)) == NULL) { printk("ACCOUNT: Out of memory allocating account_handles structure"); kfree (ipt_account_tables); ipt_account_tables = NULL; return -EINVAL; } memset(ipt_account_handles, 0, ACCOUNT_MAX_HANDLES*sizeof(struct ipt_account_handle)); /* Allocate one page as temporary storage */ if ((ipt_account_tmpbuf = (void*)__get_free_page(GFP_KERNEL)) == NULL) { printk("ACCOUNT: Out of memory for temporary buffer page\n"); kfree(ipt_account_tables); kfree(ipt_account_handles); ipt_account_tables = NULL; ipt_account_handles = NULL; return -EINVAL; } /* Register setsockopt */ if (nf_register_sockopt(&ipt_account_sockopts) < 0) { printk("ACCOUNT: Can't register sockopts. Aborting\n"); kfree(ipt_account_tables); kfree(ipt_account_handles); free_page((unsigned long)ipt_account_tmpbuf); ipt_account_tables = NULL; ipt_account_handles = NULL; ipt_account_tmpbuf = NULL; return -EINVAL; } if (ipt_register_target(&ipt_account_reg)) return -EINVAL; return 0; } static void __exit fini(void) { ipt_unregister_target(&ipt_account_reg); nf_unregister_sockopt(&ipt_account_sockopts); kfree(ipt_account_tables); kfree(ipt_account_handles); free_page((unsigned long)ipt_account_tmpbuf); ipt_account_tables = NULL; ipt_account_handles = NULL; ipt_account_tmpbuf = NULL; } module_init(init); module_exit(fini); MODULE_LICENSE("GPL");