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arp.c [7837101:797b704] in mainline

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: 1 edited

uspace/srv/net/il/arp/arp.c (modified) (22 diffs)

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: Added
: Removed

uspace/srv/net/il/arp/arp.c

-              r7837101
+              r797b704
  * @see arp.h
  */
-#include "arp.h"
-#include "arp_header.h"
-#include "arp_oc.h"
-#include "arp_module.h"
 #include <async.h>
 …
 #include <ipc/arp.h>
 #include <ipc/il.h>
+#include <ipc/nil.h>
 #include <byteorder.h>
 #include <errno.h>
 #include <net/modules.h>
 #include <net/device.h>
 #include <net/packet.h>
+#include <nil_interface.h>
+#include <nil_remote.h>
 #include <protocol_map.h>
 #include <packet_client.h>
 #include <packet_remote.h>
 #include <il_interface.h>
 #include <il_local.h>
+#include <il_remote.h>
+#include <il_skel.h>
+#include "arp.h"
 /** ARP module name. */
 …
 /** Number of microseconds to wait for an ARP reply. */
+#define ARP_TRANS_WAIT  1000000
+#define ARP_TRANS_WAIT  1000000
+/** @name ARP operation codes definitions */
+/*@{*/
+/** REQUEST operation code. */
+#define ARPOP_REQUEST  1
+/** REPLY operation code. */
+#define ARPOP_REPLY  2
+/*@}*/
+/** Type definition of an ARP protocol header.
+ * @see arp_header
+ */
+typedef struct arp_header arp_header_t;
+/** ARP protocol header. */
+struct arp_header {
+        /**
+         * Hardware type identifier.
+         * @see hardware.h
+         */
+        uint16_t hardware;
+        /** Protocol identifier. */
+        uint16_t protocol;
+        /** Hardware address length in bytes. */
+        uint8_t hardware_length;
+        /** Protocol address length in bytes. */
+        uint8_t protocol_length;
+        /**
+         * ARP packet type.
+         * @see arp_oc.h
+         */
+        uint16_t operation;
+} __attribute__ ((packed));
 /** ARP global data. */
 …
                 trans->hw_addr = NULL;
+        }
         fibril_condvar_broadcast(&trans->cv);
+}
 …
+{
         int count;
+        arp_trans_t *trans;
         for (count = arp_addr_count(addresses) - 1; count >= 0; count--) {
+                trans = arp_addr_items_get_index(&addresses->values, count);
+                arp_trans_t *trans = arp_addr_items_get_index(&addresses->values,
+                    count);
                 if (trans)
                         arp_clear_trans(trans);
 …
+}
+/** Clears the device specific data.
+ *
+ * @param[in] device    The device specific data.
+/** Clear the device specific data.
+ *
+ * @param[in] device Device specific data.
  */
 static void arp_clear_device(arp_device_t *device)
+{
         int count;
+        arp_proto_t *proto;
         for (count = arp_protos_count(&device->protos) - 1; count >= 0;
             count--) {
+                proto = arp_protos_get_index(&device->protos, count);
+                arp_proto_t *proto = arp_protos_get_index(&device->protos,
+                    count);
                 if (proto) {
                         if (proto->addr)
                                 free(proto->addr);
                         if (proto->addr_data)
                                 free(proto->addr_data);
                         arp_clear_addr(&proto->addresses);
                         arp_addr_destroy(&proto->addresses);
+                }
+        }
         arp_protos_clear(&device->protos);
+}
 …
+{
         int count;
+        arp_device_t *device;
         fibril_mutex_lock(&arp_globals.lock);
         for (count = arp_cache_count(&arp_globals.cache) - 1; count >= 0;
             count--) {
+                device = arp_cache_get_index(&arp_globals.cache, count);
+                arp_device_t *device = arp_cache_get_index(&arp_globals.cache,
+                    count);
                 if (device) {
                         arp_clear_device(device);
                         if (device->addr_data)
                                 free(device->addr_data);
                         if (device->broadcast_data)
                                 free(device->broadcast_data);
+                }
+        }
         arp_cache_clear(&arp_globals.cache);
         fibril_mutex_unlock(&arp_globals.lock);
         printf("Cache cleaned\n");
         return EOK;
+}
 …
     services_t protocol, measured_string_t *address)
+{
-        arp_device_t *device;
-        arp_proto_t *proto;
-        arp_trans_t *trans;
         fibril_mutex_lock(&arp_globals.lock);
+        device = arp_cache_find(&arp_globals.cache, device_id);
+        arp_device_t *device = arp_cache_find(&arp_globals.cache, device_id);
         if (!device) {
                 fibril_mutex_unlock(&arp_globals.lock);
                 return ENOENT;
+        }
+        proto = arp_protos_find(&device->protos, protocol);
+        arp_proto_t *proto = arp_protos_find(&device->protos, protocol);
         if (!proto) {
                 fibril_mutex_unlock(&arp_globals.lock);
                 return ENOENT;
+        }
+        trans = arp_addr_find(&proto->addresses, address->value, address->length);
+        arp_trans_t *trans = arp_addr_find(&proto->addresses, address->value,
+            address->length);
         if (trans)
                 arp_clear_trans(trans);
         arp_addr_exclude(&proto->addresses, address->value, address->length);
         fibril_mutex_unlock(&arp_globals.lock);
         return EOK;
+}
 static int arp_clear_device_req(int arp_phone, device_id_t device_id)
+{
-        arp_device_t *device;
         fibril_mutex_lock(&arp_globals.lock);
+        device = arp_cache_find(&arp_globals.cache, device_id);
+        arp_device_t *device = arp_cache_find(&arp_globals.cache, device_id);
         if (!device) {
                 fibril_mutex_unlock(&arp_globals.lock);
                 return ENOENT;
+        }
         arp_clear_device(device);
         printf("Device %d cleared\n", device_id);
         fibril_mutex_unlock(&arp_globals.lock);
         return EOK;
+}
+/** Creates new protocol specific data.
+ *
+ * Allocates and returns the needed memory block as the proto parameter.
+ *
+ * @param[out] proto    The allocated protocol specific data.
+ * @param[in] service   The protocol module service.
+ * @param[in] address   The actual protocol device address.
+ * @return              EOK on success.
+ * @return              ENOMEM if there is not enough memory left.
+/** Create new protocol specific data.
+ *
+ * Allocate and return the needed memory block as the proto parameter.
+ *
+ * @param[out] proto   Allocated protocol specific data.
+ * @param[in]  service Protocol module service.
+ * @param[in]  address Actual protocol device address.
+ *
+ * @return EOK on success.
+ * @return ENOMEM if there is not enough memory left.
+ *
  */
 static int arp_proto_create(arp_proto_t **proto, services_t service,
     measured_string_t *address)
+{
-        int rc;
         *proto = (arp_proto_t *) malloc(sizeof(arp_proto_t));
         if (!*proto)
 …
         (*proto)->addr_data = address->value;
         rc = arp_addr_initialize(&(*proto)->addresses);
+        int rc = arp_addr_initialize(&(*proto)->addresses);
         if (rc != EOK) {
                 free(*proto);
 …
+}
+/** Registers the device.
+ *
+ * Creates new device entry in the cache or updates the protocol address if the
+ * device with the device identifier and the driver service exists.
+ *
+ * @param[in] device_id The device identifier.
+ * @param[in] service   The device driver service.
+ * @param[in] protocol  The protocol service.
+ * @param[in] address   The actual device protocol address.
+ * @return              EOK on success.
+ * @return              EEXIST if another device with the same device identifier
+ *                      and different driver service exists.
+ * @return              ENOMEM if there is not enough memory left.
+ * @return              Other error codes as defined for the
+ *                      measured_strings_return() function.
+ */
+static int arp_device_message(device_id_t device_id, services_t service,
+    services_t protocol, measured_string_t *address)
+{
+        arp_device_t *device;
+        arp_proto_t *proto;
+        hw_type_t hardware;
+        int index;
+/** Process the received ARP packet.
+ *
+ * Update the source hardware address if the source entry exists or the packet
+ * is targeted to my protocol address.
+ *
+ * Respond to the ARP request if the packet is the ARP request and is
+ * targeted to my address.
+ *
+ * @param[in]     device_id Source device identifier.
+ * @param[in,out] packet    Received packet.
+ *
+ * @return EOK on success and the packet is no longer needed.
+ * @return One on success and the packet has been reused.
+ * @return EINVAL if the packet is too small to carry an ARP
+ *         packet.
+ * @return EINVAL if the received address lengths differs from
+ *         the registered values.
+ * @return ENOENT if the device is not found in the cache.
+ * @return ENOENT if the protocol for the device is not found in
+ *         the cache.
+ * @return ENOMEM if there is not enough memory left.
+ *
+ */
+static int arp_receive_message(device_id_t device_id, packet_t *packet)
+{
         int rc;
+        fibril_mutex_lock(&arp_globals.lock);
+        /* An existing device? */
+        device = arp_cache_find(&arp_globals.cache, device_id);
+        if (device) {
+                if (device->service != service) {
+                        printf("Device %d already exists\n", device->device_id);
+                        fibril_mutex_unlock(&arp_globals.lock);
+                        return EEXIST;
+                }
+                proto = arp_protos_find(&device->protos, protocol);
+                if (proto) {
+                        free(proto->addr);
+                        free(proto->addr_data);
+                        proto->addr = address;
+                        proto->addr_data = address->value;
+                } else {
+                        rc = arp_proto_create(&proto, protocol, address);
+                        if (rc != EOK) {
+                                fibril_mutex_unlock(&arp_globals.lock);
+                                return rc;
+                        }
+                        index = arp_protos_add(&device->protos, proto->service,
+                            proto);
+                        if (index < 0) {
+                                fibril_mutex_unlock(&arp_globals.lock);
+                                free(proto);
+                                return index;
+                        }
+                        printf("New protocol added:\n\tdevice id\t= "
+                            "%d\n\tproto\t= %d", device_id, protocol);
+                }
+        } else {
+                hardware = hardware_map(service);
+                if (!hardware)
+                        return ENOENT;
+                /* Create a new device */
+                device = (arp_device_t *) malloc(sizeof(arp_device_t));
+                if (!device) {
+                        fibril_mutex_unlock(&arp_globals.lock);
+                        return ENOMEM;
+                }
+                device->hardware = hardware;
+                device->device_id = device_id;
+                rc = arp_protos_initialize(&device->protos);
+                if (rc != EOK) {
+                        fibril_mutex_unlock(&arp_globals.lock);
+                        free(device);
+                        return rc;
+                }
+                rc = arp_proto_create(&proto, protocol, address);
+                if (rc != EOK) {
+                        fibril_mutex_unlock(&arp_globals.lock);
+                        free(device);
+                        return rc;
+                }
+                index = arp_protos_add(&device->protos, proto->service, proto);
+                if (index < 0) {
+                        fibril_mutex_unlock(&arp_globals.lock);
+                        arp_protos_destroy(&device->protos);
+                        free(device);
+                        return index;
+                }
+                device->service = service;
+                /* Bind the new one */
+                device->phone = nil_bind_service(device->service,
+                    (sysarg_t) device->device_id, SERVICE_ARP,
+                    arp_globals.client_connection);
+                if (device->phone < 0) {
+                        fibril_mutex_unlock(&arp_globals.lock);
+                        arp_protos_destroy(&device->protos);
+                        free(device);
+                        return EREFUSED;
+                }
+                /* Get packet dimensions */
+                rc = nil_packet_size_req(device->phone, device_id,
+                    &device->packet_dimension);
+                if (rc != EOK) {
+                        fibril_mutex_unlock(&arp_globals.lock);
+                        arp_protos_destroy(&device->protos);
+                        free(device);
+                        return rc;
+                }
+                /* Get hardware address */
+                rc = nil_get_addr_req(device->phone, device_id, &device->addr,
+                    &device->addr_data);
+                if (rc != EOK) {
+                        fibril_mutex_unlock(&arp_globals.lock);
+                        arp_protos_destroy(&device->protos);
+                        free(device);
+                        return rc;
+                }
+                /* Get broadcast address */
+                rc = nil_get_broadcast_addr_req(device->phone, device_id,
+                    &device->broadcast_addr, &device->broadcast_data);
+                if (rc != EOK) {
+                        fibril_mutex_unlock(&arp_globals.lock);
+                        free(device->addr);
+                        free(device->addr_data);
+                        arp_protos_destroy(&device->protos);
+                        free(device);
+                        return rc;
+                }
+                rc = arp_cache_add(&arp_globals.cache, device->device_id,
+                    device);
+                if (rc != EOK) {
+                        fibril_mutex_unlock(&arp_globals.lock);
+                        free(device->addr);
+                        free(device->addr_data);
+                        free(device->broadcast_addr);
+                        free(device->broadcast_data);
+                        arp_protos_destroy(&device->protos);
+                        free(device);
+                        return rc;
+                }
+                printf("%s: Device registered (id: %d, type: 0x%x, service: %d,"
+                    " proto: %d)\n", NAME, device->device_id, device->hardware,
+                    device->service, protocol);
+        }
+        fibril_mutex_unlock(&arp_globals.lock);
+        return EOK;
+}
+/** Initializes the ARP module.
+ *
+ *  @param[in] client_connection The client connection processing function.
+ *                      The module skeleton propagates its own one.
+ *  @return             EOK on success.
+ *  @return             ENOMEM if there is not enough memory left.
+ */
+int arp_initialize(async_client_conn_t client_connection)
+{
+        int rc;
+        fibril_mutex_initialize(&arp_globals.lock);
+        fibril_mutex_lock(&arp_globals.lock);
+        arp_globals.client_connection = client_connection;
+        rc = arp_cache_initialize(&arp_globals.cache);
+        fibril_mutex_unlock(&arp_globals.lock);
+        return rc;
+}
+/** Updates the device content length according to the new MTU value.
+ *
+ * @param[in] device_id The device identifier.
+ * @param[in] mtu       The new mtu value.
+ * @return              ENOENT if device is not found.
+ * @return              EOK on success.
+ */
+static int arp_mtu_changed_message(device_id_t device_id, size_t mtu)
+{
+        arp_device_t *device;
+        fibril_mutex_lock(&arp_globals.lock);
+        device = arp_cache_find(&arp_globals.cache, device_id);
+        if (!device) {
+                fibril_mutex_unlock(&arp_globals.lock);
+                return ENOENT;
+        }
+        device->packet_dimension.content = mtu;
+        fibril_mutex_unlock(&arp_globals.lock);
+        printf("arp - device %d changed mtu to %zu\n\n", device_id, mtu);
+        return EOK;
+}
+/** Processes the received ARP packet.
+ *
+ * Updates the source hardware address if the source entry exists or the packet
+ * is targeted to my protocol address.
+ * Responses to the ARP request if the packet is the ARP request and is
+ * targeted to my address.
+ *
+ * @param[in] device_id The source device identifier.
+ * @param[in,out] packet The received packet.
+ * @return              EOK on success and the packet is no longer needed.
+ * @return              One on success and the packet has been reused.
+ * @return              EINVAL if the packet is too small to carry an ARP
+ *                      packet.
+ * @return              EINVAL if the received address lengths differs from
+ *                      the registered values.
+ * @return              ENOENT if the device is not found in the cache.
+ * @return              ENOENT if the protocol for the device is not found in
+ *                      the cache.
+ * @return              ENOMEM if there is not enough memory left.
+ */
+static int arp_receive_message(device_id_t device_id, packet_t *packet)
+{
+        size_t length;
+        arp_header_t *header;
+        arp_device_t *device;
+        arp_proto_t *proto;
+        arp_trans_t *trans;
+        uint8_t *src_hw;
+        uint8_t *src_proto;
+        uint8_t *des_hw;
+        uint8_t *des_proto;
+        int rc;
+        length = packet_get_data_length(packet);
+        size_t length = packet_get_data_length(packet);
         if (length <= sizeof(arp_header_t))
                 return EINVAL;
         device = arp_cache_find(&arp_globals.cache, device_id);
+        arp_device_t *device = arp_cache_find(&arp_globals.cache, device_id);
         if (!device)
                 return ENOENT;
         header = (arp_header_t *) packet_get_data(packet);
+        arp_header_t *header = (arp_header_t *) packet_get_data(packet);
         if ((ntohs(header->hardware) != device->hardware) ||
             (length < sizeof(arp_header_t) + header->hardware_length * 2U +
 …
                 return EINVAL;
+        }
         proto = arp_protos_find(&device->protos,
+        arp_proto_t *proto = arp_protos_find(&device->protos,
             protocol_unmap(device->service, ntohs(header->protocol)));
         if (!proto)
                 return ENOENT;
+        src_hw = ((uint8_t *) header) + sizeof(arp_header_t);
+        src_proto = src_hw + header->hardware_length;
+        des_hw = src_proto + header->protocol_length;
+        des_proto = des_hw + header->hardware_length;
+        trans = arp_addr_find(&proto->addresses, (char *) src_proto,
+        uint8_t *src_hw = ((uint8_t *) header) + sizeof(arp_header_t);
+        uint8_t *src_proto = src_hw + header->hardware_length;
+        uint8_t *des_hw = src_proto + header->protocol_length;
+        uint8_t *des_proto = des_hw + header->hardware_length;
+        arp_trans_t *trans = arp_addr_find(&proto->addresses, src_proto,
             header->protocol_length);
+        /* Exists? */
+        if (trans && trans->hw_addr) {
+        if ((trans) && (trans->hw_addr)) {
+                /* Translation exists */
                 if (trans->hw_addr->length != header->hardware_length)
                         return EINVAL;
                 memcpy(trans->hw_addr->value, src_hw, trans->hw_addr->length);
+        }
         /* Is my protocol address? */
         if (proto->addr->length != header->protocol_length)
                 return EINVAL;
+        if (!str_lcmp(proto->addr->value, (char *) des_proto,
+            proto->addr->length)) {
+                /* Not already updated? */
+        if (!bcmp(proto->addr->value, des_proto, proto->addr->length)) {
                 if (!trans) {
+                        /* Update the translation */
                         trans = (arp_trans_t *) malloc(sizeof(arp_trans_t));
                         if (!trans)
                                 return ENOMEM;
                         trans->hw_addr = NULL;
                         fibril_condvar_initialize(&trans->cv);
                         rc = arp_addr_add(&proto->addresses, (char *) src_proto,
+                        rc = arp_addr_add(&proto->addresses, src_proto,
                             header->protocol_length, trans);
                         if (rc != EOK) {
 …
+                        }
+                }
                 if (!trans->hw_addr) {
                         trans->hw_addr = measured_string_create_bulk(
                             (char *) src_hw, header->hardware_length);
+                        trans->hw_addr = measured_string_create_bulk(src_hw,
+                            header->hardware_length);
                         if (!trans->hw_addr)
                                 return ENOMEM;
                         /* Notify the fibrils that wait for the translation. */
                         fibril_condvar_broadcast(&trans->cv);
+                }
                 if (ntohs(header->operation) == ARPOP_REQUEST) {
                         header->operation = htons(ARPOP_REPLY);
 …
+                }
+        }
         return EOK;
+}
+/** Returns the hardware address for the given protocol address.
+ *
+ * Sends the ARP request packet if the hardware address is not found in the
+ * cache.
+ *
+ * @param[in] device_id The device identifier.
+ * @param[in] protocol  The protocol service.
+ * @param[in] target    The target protocol address.
+ * @param[out] translation Where the hardware address of the target is stored.
+ * @return              EOK on success.
+ * @return              EAGAIN if the caller should try again.
+ * @return              Other error codes in case of error.
+ */
+static int
+arp_translate_message(device_id_t device_id, services_t protocol,
+    measured_string_t *target, measured_string_t **translation)
+{
+        arp_device_t *device;
+        arp_proto_t *proto;
+        arp_trans_t *trans;
+        size_t length;
+/** Update the device content length according to the new MTU value.
+ *
+ * @param[in] device_id Device identifier.
+ * @param[in] mtu       New MTU value.
+ *
+ * @return ENOENT if device is not found.
+ * @return EOK on success.
+ *
+ */
+static int arp_mtu_changed_message(device_id_t device_id, size_t mtu)
+{
+        fibril_mutex_lock(&arp_globals.lock);
+        arp_device_t *device = arp_cache_find(&arp_globals.cache, device_id);
+        if (!device) {
+                fibril_mutex_unlock(&arp_globals.lock);
+                return ENOENT;
+        }
+        device->packet_dimension.content = mtu;
+        fibril_mutex_unlock(&arp_globals.lock);
+        printf("%s: Device %d changed MTU to %zu\n", NAME, device_id, mtu);
+        return EOK;
+}
+/** Process IPC messages from the registered device driver modules
+ *
+ * @param[in]     iid   Message identifier.
+ * @param[in,out] icall Message parameters.
+ *
+ */
+static void arp_receiver(ipc_callid_t iid, ipc_call_t *icall)
+{
         packet_t *packet;
-        arp_header_t *header;
-        bool retry = false;
         int rc;
+restart:
+        if (!target || !translation)
+                return EBADMEM;
+        device = arp_cache_find(&arp_globals.cache, device_id);
+        if (!device)
+                return ENOENT;
+        proto = arp_protos_find(&device->protos, protocol);
+        if (!proto || (proto->addr->length != target->length))
+                return ENOENT;
+        trans = arp_addr_find(&proto->addresses, target->value, target->length);
+        if (trans) {
+                if (trans->hw_addr) {
+                        *translation = trans->hw_addr;
+                        return EOK;
+                }
+                if (retry)
+                        return EAGAIN;
+                rc = fibril_condvar_wait_timeout(&trans->cv, &arp_globals.lock,
+                    ARP_TRANS_WAIT);
+                if (rc == ETIMEOUT)
+        while (true) {
+                switch (IPC_GET_IMETHOD(*icall)) {
+                case NET_IL_DEVICE_STATE:
+                        /* Do nothing - keep the cache */
+                        ipc_answer_0(iid, (sysarg_t) EOK);
+                        break;
+                case NET_IL_RECEIVED:
+                        rc = packet_translate_remote(arp_globals.net_phone, &packet,
+                            IPC_GET_PACKET(*icall));
+                        if (rc == EOK) {
+                                fibril_mutex_lock(&arp_globals.lock);
+                                do {
+                                        packet_t *next = pq_detach(packet);
+                                        rc = arp_receive_message(IPC_GET_DEVICE(*icall), packet);
+                                        if (rc != 1) {
+                                                pq_release_remote(arp_globals.net_phone,
+                                                    packet_get_id(packet));
+                                        }
+                                        packet = next;
+                                } while (packet);
+                                fibril_mutex_unlock(&arp_globals.lock);
+                        }
+                        ipc_answer_0(iid, (sysarg_t) rc);
+                        break;
+                case NET_IL_MTU_CHANGED:
+                        rc = arp_mtu_changed_message(IPC_GET_DEVICE(*icall),
+                            IPC_GET_MTU(*icall));
+                        ipc_answer_0(iid, (sysarg_t) rc);
+                        break;
+                default:
+                        ipc_answer_0(iid, (sysarg_t) ENOTSUP);
+                }
+                iid = async_get_call(icall);
+        }
+}
+/** Register the device.
+ *
+ * Create new device entry in the cache or update the protocol address if the
+ * device with the device identifier and the driver service exists.
+ *
+ * @param[in] device_id Device identifier.
+ * @param[in] service   Device driver service.
+ * @param[in] protocol  Protocol service.
+ * @param[in] address   Actual device protocol address.
+ *
+ * @return EOK on success.
+ * @return EEXIST if another device with the same device identifier
+ *         and different driver service exists.
+ * @return ENOMEM if there is not enough memory left.
+ * @return Other error codes as defined for the
+ *         measured_strings_return() function.
+ *
+ */
+static int arp_device_message(device_id_t device_id, services_t service,
+    services_t protocol, measured_string_t *address)
+{
+        int index;
+        int rc;
+        fibril_mutex_lock(&arp_globals.lock);
+        /* An existing device? */
+        arp_device_t *device = arp_cache_find(&arp_globals.cache, device_id);
+        if (device) {
+                if (device->service != service) {
+                        printf("%s: Device %d already exists\n", NAME,
+                            device->device_id);
+                        fibril_mutex_unlock(&arp_globals.lock);
+                        return EEXIST;
+                }
+                arp_proto_t *proto = arp_protos_find(&device->protos, protocol);
+                if (proto) {
+                        free(proto->addr);
+                        free(proto->addr_data);
+                        proto->addr = address;
+                        proto->addr_data = address->value;
+                } else {
+                        rc = arp_proto_create(&proto, protocol, address);
+                        if (rc != EOK) {
+                                fibril_mutex_unlock(&arp_globals.lock);
+                                return rc;
+                        }
+                        index = arp_protos_add(&device->protos, proto->service,
+                            proto);
+                        if (index < 0) {
+                                fibril_mutex_unlock(&arp_globals.lock);
+                                free(proto);
+                                return index;
+                        }
+                        printf("%s: New protocol added (id: %d, proto: %d)\n", NAME,
+                            device_id, protocol);
+                }
+        } else {
+                hw_type_t hardware = hardware_map(service);
+                if (!hardware)
                         return ENOENT;
+                retry = true;
+                goto restart;
+        }
+        if (retry)
+                return EAGAIN;
+                /* Create new device */
+                device = (arp_device_t *) malloc(sizeof(arp_device_t));
+                if (!device) {
+                        fibril_mutex_unlock(&arp_globals.lock);
+                        return ENOMEM;
+                }
+                device->hardware = hardware;
+                device->device_id = device_id;
+                rc = arp_protos_initialize(&device->protos);
+                if (rc != EOK) {
+                        fibril_mutex_unlock(&arp_globals.lock);
+                        free(device);
+                        return rc;
+                }
+                arp_proto_t *proto;
+                rc = arp_proto_create(&proto, protocol, address);
+                if (rc != EOK) {
+                        fibril_mutex_unlock(&arp_globals.lock);
+                        free(device);
+                        return rc;
+                }
+                index = arp_protos_add(&device->protos, proto->service, proto);
+                if (index < 0) {
+                        fibril_mutex_unlock(&arp_globals.lock);
+                        arp_protos_destroy(&device->protos);
+                        free(device);
+                        return index;
+                }
+                device->service = service;
+                /* Bind */
+                device->phone = nil_bind_service(device->service,
+                    (sysarg_t) device->device_id, SERVICE_ARP,
+                    arp_receiver);
+                if (device->phone < 0) {
+                        fibril_mutex_unlock(&arp_globals.lock);
+                        arp_protos_destroy(&device->protos);
+                        free(device);
+                        return EREFUSED;
+                }
+                /* Get packet dimensions */
+                rc = nil_packet_size_req(device->phone, device_id,
+                    &device->packet_dimension);
+                if (rc != EOK) {
+                        fibril_mutex_unlock(&arp_globals.lock);
+                        arp_protos_destroy(&device->protos);
+                        free(device);
+                        return rc;
+                }
+                /* Get hardware address */
+                rc = nil_get_addr_req(device->phone, device_id, &device->addr,
+                    &device->addr_data);
+                if (rc != EOK) {
+                        fibril_mutex_unlock(&arp_globals.lock);
+                        arp_protos_destroy(&device->protos);
+                        free(device);
+                        return rc;
+                }
+                /* Get broadcast address */
+                rc = nil_get_broadcast_addr_req(device->phone, device_id,
+                    &device->broadcast_addr, &device->broadcast_data);
+                if (rc != EOK) {
+                        fibril_mutex_unlock(&arp_globals.lock);
+                        free(device->addr);
+                        free(device->addr_data);
+                        arp_protos_destroy(&device->protos);
+                        free(device);
+                        return rc;
+                }
+                rc = arp_cache_add(&arp_globals.cache, device->device_id,
+                    device);
+                if (rc != EOK) {
+                        fibril_mutex_unlock(&arp_globals.lock);
+                        free(device->addr);
+                        free(device->addr_data);
+                        free(device->broadcast_addr);
+                        free(device->broadcast_data);
+                        arp_protos_destroy(&device->protos);
+                        free(device);
+                        return rc;
+                }
+                printf("%s: Device registered (id: %d, type: 0x%x, service: %d,"
+                    " proto: %d)\n", NAME, device->device_id, device->hardware,
+                    device->service, protocol);
+        }
+        fibril_mutex_unlock(&arp_globals.lock);
+        return EOK;
+}
+int il_initialize(int net_phone)
+{
+        fibril_mutex_initialize(&arp_globals.lock);
+        fibril_mutex_lock(&arp_globals.lock);
+        arp_globals.net_phone = net_phone;
+        int rc = arp_cache_initialize(&arp_globals.cache);
+        fibril_mutex_unlock(&arp_globals.lock);
+        return rc;
+}
+static int arp_send_request(device_id_t device_id, services_t protocol,
+    measured_string_t *target, arp_device_t *device, arp_proto_t *proto)
+{
         /* ARP packet content size = header + (address + translation) * 2 */
         length = 8 + 2 * (proto->addr->length + device->addr->length);
+        size_t length = 8 + 2 * (proto->addr->length + device->addr->length);
         if (length > device->packet_dimension.content)
                 return ELIMIT;
         packet = packet_get_4_remote(arp_globals.net_phone,
+        packet_t *packet = packet_get_4_remote(arp_globals.net_phone,
             device->packet_dimension.addr_len, device->packet_dimension.prefix,
             length, device->packet_dimension.suffix);
         if (!packet)
                 return ENOMEM;
         header = (arp_header_t *) packet_suffix(packet, length);
+        arp_header_t *header = (arp_header_t *) packet_suffix(packet, length);
         if (!header) {
                 pq_release_remote(arp_globals.net_phone, packet_get_id(packet));
                 return ENOMEM;
+        }
         header->hardware = htons(device->hardware);
         header->hardware_length = (uint8_t) device->addr->length;
 …
         header->protocol_length = (uint8_t) proto->addr->length;
         header->operation = htons(ARPOP_REQUEST);
         length = sizeof(arp_header_t);
         memcpy(((uint8_t *) header) + length, device->addr->value,
             device->addr->length);
 …
         length += device->addr->length;
         memcpy(((uint8_t *) header) + length, target->value, target->length);
         rc = packet_set_addr(packet, (uint8_t *) device->addr->value,
+        int rc = packet_set_addr(packet, (uint8_t *) device->addr->value,
             (uint8_t *) device->broadcast_addr->value, device->addr->length);
         if (rc != EOK) {
 …
                 return rc;
+        }
         nil_send_msg(device->phone, device_id, packet, SERVICE_ARP);
+        return EOK;
+}
+/** Return the hardware address for the given protocol address.
+ *
+ * Send the ARP request packet if the hardware address is not found in the
+ * cache.
+ *
+ * @param[in]  device_id   Device identifier.
+ * @param[in]  protocol    Protocol service.
+ * @param[in]  target      Target protocol address.
+ * @param[out] translation Where the hardware address of the target is stored.
+ *
+ * @return EOK on success.
+ * @return EAGAIN if the caller should try again.
+ * @return Other error codes in case of error.
+ *
+ */
+static int arp_translate_message(device_id_t device_id, services_t protocol,
+    measured_string_t *target, measured_string_t **translation)
+{
+        bool retry = false;
+        int rc;
+restart:
+        if ((!target) || (!translation))
+                return EBADMEM;
+        arp_device_t *device = arp_cache_find(&arp_globals.cache, device_id);
+        if (!device)
+                return ENOENT;
+        arp_proto_t *proto = arp_protos_find(&device->protos, protocol);
+        if ((!proto) || (proto->addr->length != target->length))
+                return ENOENT;
+        arp_trans_t *trans = arp_addr_find(&proto->addresses, target->value,
+            target->length);
+        if (trans) {
+                if (trans->hw_addr) {
+                        *translation = trans->hw_addr;
+                        return EOK;
+                }
+                if (retry) {
+                        /* Remove the translation from the map */
+                        arp_clear_trans(trans);
+                        arp_addr_exclude(&proto->addresses, target->value,
+                            target->length);
+                        return EAGAIN;
+                }
+                rc = fibril_condvar_wait_timeout(&trans->cv, &arp_globals.lock,
+                    ARP_TRANS_WAIT);
+                if (rc == ETIMEOUT)
+                        return ENOENT;
+                retry = true;
+                goto restart;
+        }
+        if (retry)
+                return EAGAIN;
         trans = (arp_trans_t *) malloc(sizeof(arp_trans_t));
         if (!trans)
                 return ENOMEM;
         trans->hw_addr = NULL;
         fibril_condvar_initialize(&trans->cv);
         rc = arp_addr_add(&proto->addresses, target->value, target->length,
             trans);
 …
+        }
+        rc = arp_send_request(device_id, protocol, target, device, proto);
+        if (rc != EOK)
+                return rc;
         rc = fibril_condvar_wait_timeout(&trans->cv, &arp_globals.lock,
             ARP_TRANS_WAIT);
         if (rc == ETIMEOUT)
                 return ENOENT;
         retry = true;
         goto restart;
+}
+/** Processes the ARP message.
+ *
+ * @param[in] callid    The message identifier.
+ * @param[in] call      The message parameters.
+ * @param[out] answer   The message answer parameters.
+ * @param[out] answer_count The last parameter for the actual answer in the
+ *                      answer parameter.
+ * @return              EOK on success.
+ * @return              ENOTSUP if the message is not known.
+/** Process the ARP message.
+ *
+ * @param[in]  callid Message identifier.
+ * @param[in]  call   Message parameters.
+ * @param[out] answer Answer.
+ * @param[out] count  Number of arguments of the answer.
+ *
+ * @return EOK on success.
+ * @return ENOTSUP if the message is not known.
+ *
  * @see arp_interface.h
  * @see IS_NET_ARP_MESSAGE()
  */
+int
 arp_message_standalone(ipc_callid_t callid, ipc_call_t *call,
     ipc_call_t *answer, int *answer_count)
+ *
+ */
+int il_module_message(ipc_callid_t callid, ipc_call_t *call, ipc_call_t *answer,
+    size_t *count)
+{
         measured_string_t *address;
         measured_string_t *translation;
+        char *data;
+        packet_t *packet;
+        packet_t *next;
+        uint8_t *data;
         int rc;
         *answer_count = 0;
+        *count = 0;
         switch (IPC_GET_IMETHOD(*call)) {
         case IPC_M_PHONE_HUNGUP:
 …
                         return rc;
                 rc = arp_device_message(IPC_GET_DEVICE(call),
                     IPC_GET_SERVICE(call), ARP_GET_NETIF(call), address);
+                rc = arp_device_message(IPC_GET_DEVICE(*call),
+                    IPC_GET_SERVICE(*call), ARP_GET_NETIF(*call), address);
                 if (rc != EOK) {
                         free(address);
                         free(data);
+                }
                 return rc;
 …
                 fibril_mutex_lock(&arp_globals.lock);
                 rc = arp_translate_message(IPC_GET_DEVICE(call),
                     IPC_GET_SERVICE(call), address, &translation);
+                rc = arp_translate_message(IPC_GET_DEVICE(*call),
+                    IPC_GET_SERVICE(*call), address, &translation);
                 free(address);
                 free(data);
                 if (rc != EOK) {
                         fibril_mutex_unlock(&arp_globals.lock);
                         return rc;
+                }
                 if (!translation) {
                         fibril_mutex_unlock(&arp_globals.lock);
                         return ENOENT;
+                }
                 rc = measured_strings_reply(translation, 1);
                 fibril_mutex_unlock(&arp_globals.lock);
                 return rc;
         case NET_ARP_CLEAR_DEVICE:
                 return arp_clear_device_req(0, IPC_GET_DEVICE(call));
+                return arp_clear_device_req(0, IPC_GET_DEVICE(*call));
         case NET_ARP_CLEAR_ADDRESS:
                 rc = measured_strings_receive(&address, &data, 1);
 …
                         return rc;
                 arp_clear_address_req(0, IPC_GET_DEVICE(call),
                     IPC_GET_SERVICE(call), address);
+                arp_clear_address_req(0, IPC_GET_DEVICE(*call),
+                    IPC_GET_SERVICE(*call), address);
                 free(address);
                 free(data);
 …
         case NET_ARP_CLEAN_CACHE:
                 return arp_clean_cache_req(0);
-        case NET_IL_DEVICE_STATE:
-                /* Do nothing - keep the cache */
-                return EOK;
-        case NET_IL_RECEIVED:
-                rc = packet_translate_remote(arp_globals.net_phone, &packet,
-                    IPC_GET_PACKET(call));
-                if (rc != EOK)
-                        return rc;
-                fibril_mutex_lock(&arp_globals.lock);
-                do {
-                        next = pq_detach(packet);
-                        rc = arp_receive_message(IPC_GET_DEVICE(call), packet);
-                        if (rc != 1) {
-                                pq_release_remote(arp_globals.net_phone,
-                                    packet_get_id(packet));
+                        }
-                        packet = next;
-                } while (packet);
-                fibril_mutex_unlock(&arp_globals.lock);
-                return EOK;
-        case NET_IL_MTU_CHANGED:
-                return arp_mtu_changed_message(IPC_GET_DEVICE(call),
-                    IPC_GET_MTU(call));
+        }
 …
+}
-/** Default thread for new connections.
+ *
- * @param[in] iid       The initial message identifier.
- * @param[in] icall     The initial message call structure.
- */
-static void il_client_connection(ipc_callid_t iid, ipc_call_t *icall)
+{
-        /*
-         * Accept the connection
-         *  - Answer the first IPC_M_CONNECT_ME_TO call.
-         */
-        ipc_answer_0(iid, EOK);
-        while (true) {
-                ipc_call_t answer;
-                int answer_count;
-                /* Clear the answer structure */
-                refresh_answer(&answer, &answer_count);
-                /* Fetch the next message */
-                ipc_call_t call;
-                ipc_callid_t callid = async_get_call(&call);
-                /* Process the message */
-                int res = il_module_message_standalone(callid, &call, &answer,
-                    &answer_count);
-                /*
-                 * End if told to either by the message or the processing
-                 * result.
-                 */
-                if ((IPC_GET_IMETHOD(call) == IPC_M_PHONE_HUNGUP) ||
-                    (res == EHANGUP))
-                        return;
-                /* Answer the message */
-                answer_call(callid, res, &answer, answer_count);
+        }
+}
-/** Starts the module.
+ *
- * @return              EOK on success.
- * @return              Other error codes as defined for each specific module
- *                      start function.
- */
 int main(int argc, char *argv[])
+{
-        int rc;
         /* Start the module */
+        rc = il_module_start_standalone(il_client_connection);
+        return rc;
+        return il_module_start(SERVICE_ARP);
+}
 /** @}
  */

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