DE102006057686A1 - Procedure for exchanging information - Google Patents

Abstract

The invention relates to a method for exchanging information between a client (46) and a server (50), in which a request (48) comprising data is transmitted to the server (50) by the client (46), and in which, taking into account the data, layers of a protocol of a response (52) transmitted by the server (50) to the client (46) are generated.

Description

The Invention relates to a method for exchanging information, a first arithmetic unit for exchanging information, a second processor for exchanging information, a computer program and a computer program product.

State of the art

To the Exchanging data between different devices often becomes a so-called client-server model used. Here, a trained as a server device waits for a Request a device designed as a client. The server is editing the received request and sends a response back to the client. Become frequent these devices or corresponding devices in an arrangement which, for example, a Network is operated, so a server can query multiple, can serve different clients, in particular one after the other.

The Integrating a server into a network requires implementation many different protocols and protocol layers, for example. Ethernet, Internet Protocol (IP), User Datagram Protocol (UDP). Some of these protocols have to also be configured, which e.g. via an IP address can. Furthermore, such protocols are in different Networks in different versions or variants, eg as Internet Protocol Version 4 or Internet Protocol Version 6, operated.

moreover become devices involved in a network, which usually has a dedicated interface and communicate a point-to-point connection. With this kind that of communication becomes common on the implementation of protocol layers according to the standard DIN ISO 7498 for a so-called open system interconnection (Open System Interconnection, OSI) waived. Here, applications communicate on client and Server side directly with each other.

at the integration of these devices The network uses existing technologies, hardware interfaces and the infrastructure in the foreground. By implementing appropriate protocol layers can be a compatibility be provided with the existing network.

Some functionalities However, the different protocol layers are simple devices not required. Implementing the network protocols for these simple devices requires one considerable expense for Computing power and memory. Partially the devices are equipped with a Dedicated processor for coupling to a particular Ethernet equipped network. Furthermore If necessary, an already existing processor will be connected to a network interface extended. On this processor is a software that has all the necessary protocols can operate, implemented. The performance of such connections however, the network is often very limited.

Around the size of the required program memory can reduce the number of supported protocols become. It may depend on the separation of the individual protocol layers be omitted, resulting in a more compact code. Also the configurability of the devices can be kept to a minimum become, what to restrictions lead in ease of use can, but the needed Program and data memory reduced.

The Response times and the usable bandwidth to and from these devices strongly dependent on the processing power of the processor. Simple and inexpensive Microcontrollers offer only moderate performance, more powerful controllers can partly due to excessive power loss and too much space not used in compact arrangements or corresponding systems become.

The publication DE 10 2004 049 502 A1 describes a system for providing automated services to heterogeneous devices in a network environment. The described system includes a device agent anchored on each of the heterogeneous devices, a device communicator for registering and synchronizing the devices via each of the device agents, and a portal server for providing an interface to multiple content sources on behalf of the devices. It is envisaged that the devices communicate with the portal server through each of the device agents and the device communicator.

Disclosure of the invention

The The invention relates to a method for exchanging information between a client and a server where the client has a Request that includes data that is transmitted to the server, and in which considering of the data Layers of a protocol or protocol layers of a Response that is sent from the server to the client generates become.

The Answer can, for example, be generated or generated from these data. The invention is, for example, for Arrangements that are designed as networks suitable. in this connection the first device of the arrangement is a client and a second one Set up a server.

In In a variant, to generate the response, data is called Control information is transmitted from the client used. Alternative or supplementary are used to generate the response data as control information provided or maintained by the server. Thus, such a transmission the tax information is not mandatory. Independent of To enable origin Control information the use of partially unknown data.

In Another embodiment can be in a network, the response means the control information from request data received from the client, i.a. transmitted as data be generated from local data of the server.

It is thus possible that all elements of all layers of the protocol by the client be determined.

Besides that is provided in a further embodiment that the data in the Answer to be copied. This can i.a. mean that order specific Data, for example, about the control information will be copied into the response.

With Control information of the client and / or the server can be in one Embodiment communicated which data, in particular user data, in which addresses the answer will be copied.

alternative or in addition is the protocol by means of a state machine, in particular in the server, provided.

In In another embodiment, the responses are event-based provided.

When additional Option is provided that repeating parts of answers stored in the server.

In addition, in a further embodiment of the invention for generating the Answer provided in the reply and in particular in the Protocol layers of the response are copied. This can u. a. thereby be realized that request-specific data indirectly via the control information be copied into the answer.

A Computing unit according to the invention is designed to exchange information with at least another arithmetic unit to this at least one further arithmetic unit providing a request that includes data provided is, taking into account These data layers of a log of an answer, of the other To transmit the arithmetic unit to the first processing unit according to the invention is to generate.

These Arithmetic unit is in an embodiment as a client within a network formed, the at least one further computing unit, with the the first computing unit according to the invention communicating for the exchange of information is, for example, as a server educated. Furthermore, it is provided that the computing unit according to the invention at least for implementation individual steps of the method according to the invention is suitable.

A also provided according to the invention Another arithmetic unit is designed to replace Information with at least one computing unit described above considering of data from the at least one further arithmetic unit in a request to the second processing unit to be transmitted, layers of a Protocol of a response from the arithmetic unit to the at least to transmit a computing unit described above, to generate.

These Arithmetic unit is in configuration as a server within a network educated. Furthermore, it is provided that the arithmetic unit at least for implementation individual steps of the inventive method is. In a further embodiment, this arithmetic unit is designed to to copy the data into layers of the protocol of the answer.

The Invention further relates to a computer program with program code means, to perform all the steps of a method according to the invention, if the computer program on a computer or equivalent Arithmetic unit, in particular in at least one of the above described arithmetic units, is executed.

The Invention also relates a computer program product with program code means operating on a computer readable medium are stored to all steps of a method according to the invention perform, if the computer program is on a computer or equivalent Arithmetic unit, in particular in at least one of the above described arithmetic units, is executed.

With of the invention through the server of control information and / or request data, which is usually sent to the server by the client in the request different protocols will be provided.

In one embodiment of the method transmit from the client all the data needed by the server to easily generate all protocol layers of the response. In the general case, these are control information and request data. The control information includes in design all information to generate from the data of the request and locally present in the server data the complete answer.

at Another embodiment of the invention are in the request Data and thus in particular control information and / or request data for Structure of all layers of the protocol of the response or a response message transmitted. this makes possible the renunciation of a complex generation of the protocol information by software in the device designed as a server.

In a case when all the data of the protocol layers known in the client can, for example, on the transfer the tax information is dispensed with. Here, the Control information provided in the server or kept statically become. The transferred Data is usually provided by the server exclusively for the Answer used.

With the control information is in another embodiment possible, Use data in the protocol layers that the client uses to Send time of the request not yet known but only at the time of transmission the answer from the server be put.

at Arrangements or systems in which the data comprise user data, read as values from server memory or as values can be written to memory, the control information both for generating the protocol layers and the payload be used. Such arrangements are e.g. Measuring systems, memory emulators, In-circuit emulators and the same. Thus, an efficient reading and writing is one Memory or memory area of the server possible.

In Further embodiment, in addition to the pure functionality of the server also the independent one Sending data packets due to certain events a configuration by the client.

Especially for logical point-to-point connections between devices of the network repetitive portions of responses cached in the server so that they are not to be sent again with each request.

With The presented method may be the complexity of log generation and configuring the protocol layers on the client side be relocated. The client, an appropriate device or a corresponding device is usually as a computer, eg. Desktop PC or notebook designed with high computing power and large memory expansion. Thus, for the realization of various variants in the rule No additional Requirements for common Clients or facilities provided and in particular no additional Hardware needed.

Of the Server, for example, a network device in the arrangement communicating with the client is at least adapted to be based on control information sequences of Perform copy actions can. This can e.g. with a state machine as a component of Servers are realized so that it is possible to use a processor entirely to renounce. The server can store a program memory to the log on the network, but such a program memory is not mandatory.

A State machine is usually for Provision of copy sequences is formed and can be a programmable Logic, eg. FPGA or ASIC, and thus have a lot in operation work efficiently and achieve a high data throughput. A Such a state machine can therefore be considered as a component of Servers be trained. Many meters already have a state machine for copying data. This may possibly be used directly so to generate the protocol layers of the response that also measuring devices to carry out at least one step of the method and within the arrangement serve as a server to provide answers to queries. Thus, you can Inexpensive measuring instruments in Networks are involved.

at Generating the answer are different complex scenarios conceivable.

at In a first scenario it is envisaged that answers with completely known Information of all protocol layers are provided in the client. If the client has all the items under this first scenario all protocol layers of the answer can already determine beforehand The server can use this information in the payload of the request just insert or copy that information into the response and along with it put his user data on the network. If only messages of this kind you do not have to Control information is transmitted in the request. In this In this case, the server can assume a static structure of the request and thus determine the data to be copied.

In a second scenario are in the client Answers with only partially known information ready. In some cases, some fields in the protocol layers are neither constant nor predictable by the client, so this data can not be transferred by the client. However, if the client knows where the server stores that data in its memory, the client can tell in the control information what data to copy from which address to generate the correct answer.

in the A third scenario is a representation of more complex ones Protocols possible. such More complex protocols, such as the Internet Protocol (IP), are required in their protocol layer variable fields. Here exists an identification field, that for the lifetime of a packet in the network is unique. Besides, exists a checksum over the data of this protocol layer.

Also These fields of more complex protocols may be part of the third Scenarios, especially without a processor, are easily generated, if for Each function uses a dedicated state machine. The State machine is particularly in application of the third scenario on registers, which are displayed in the memory area to control.

One Fourth scenario relates to event-based transmission of data. This fourth scenario is for Protocols, such as for a free-running data acquisition, suitable, the sending of Messages to a specific network participant due to a specific event. This is done first by the server through configuration messages announced which device within the arrangement as receiver the data is provided. An example of such a protocol is "XCP Ethernet "or" XCP " UDP ".

With the fourth scenario described here as a conceivable embodiment the method according to the invention Is it possible, Messages, ie inquiries and answers, due to events to produce and send. For this it is provided that the configuration messages Store event data in a free space on the server. These event data include both the control information as also for the client specific protocol information. If an event with is connected to a control information, this event may be the Dispatch the message.

One fifth Scenario relates to storage of data, in particular of static Data formed as control information in the server. Consequently Is it possible, Data needed for each answer can be, much like the data for an event-based sending, in the free space of the Drop off servers so that they do not retransmit every request Need to become. The tax information of the subsequent requests relates then always to the memory area where this data is stored become.

With The invention may in one embodiment a server-based device or a server-based network be built without a processor. The arrangement needed in In this case, no knowledge about the necessary protocol layers used to generate messages and in particular responses to inquiries. Consequently can for example, different protocols only by the use of any Software for the client will be generated. Furthermore, configuration data hardly needed. IP addresses can also given by the requests and thus by an application of the client to get managed.

The Procedure is especially for Arrangements or systems suitable that no processor for others Need tasks which require a high data throughput and which already for others Tasks copy machines are used. These include in particular In-circuit emulators, memory emulators, and DAQ devices.

Further Advantages and embodiments of the invention will become apparent from the Description and the accompanying drawings.

It it is understood that the above and the following yet to be explained features not only in the specified combination, but also in other combinations or alone, without to leave the scope of the present invention.

Brief description of the drawings

1 shows a schematic representation of a client-server model according to the prior art.

2 Fig. 12 is a schematic illustration of a point-to-point connection and an ISO layer model using a prior art network connection.

3 shows a diagram of a first embodiment of the method according to the invention.

4 shows a diagram of a second embodiment of the method according to the invention proceedings.

5 shows a diagram of a third embodiment of the method according to the invention.

6 shows a first diagram of a fourth embodiment of the method according to the invention.

7 shows a second diagram of a fourth embodiment of the method according to the invention.

Embodiments of the invention

The Invention is based on embodiments schematically shown in the drawings and will be in the following described in detail with reference to the drawings.

1 shows a schematic representation of a so-called. Client-server model 2 that a client 4 as well as a server 6 having. This is a communication between the client 4 and the server 6 in that the client 4 the server 6 a request 8th transmitted. Furthermore, the server transmits 6 to answer this request 8th the client an answer 10 ,

2 shows a schematic representation of a comparison of a left-side point-to-point connection 12 between a first client 14 and a first server 16 and a network connection shown on the right 18 with a second client 20 and a second server 22 , The point-to-point connection 12 as well as the network connection 18 are known from the prior art.

For the point-to-point connection 12 occurs a communication of applications 24 through direct exchange of inquiries 26 and answers 28 ,

At the network connection 18 a communication takes place and thus an exchange of applications 30 about ISO layer models 32 , It is in the client 20 as well as in the server 22 one ISO shift model each 32 provided, each with an ISO layer model 32 a transport layer 34 , a network layer 36 , a link layer 38 , and a bit transmission layer 40 having. Thus, the application becomes 30 starting from the client 20 via the ISO layer model as a request 42 over the network connection 18 to the server 22 and again via the ISO layer model 32 as an application 30 receive. In the opposite direction becomes the application 30 starting from the server 22 about the ISO layer model 32 as answer 44 over the network connection 18 to the client 20 transferred and again in response 30 about the ISO layer model 32 receive.

3 shows a schematic representation of a diagram of a first embodiment of the method according to the invention, wherein within this diagram one of a client 46 provided request 48 and one from a server 50 provided answer 52 are shown. This includes the request 48 of the client 46 payload 54 who have an order 56 as well as tax information 58 include. These tax formations 58 are to generate the answer 52 intended. This tax information 58 comprise a control information-specific transport layer 60 , a control information-specific network layer 62 and a control information specific link layer 64 , In addition, the request includes 48 next to the user data 54 a request-specific transport layer 66 , a request-specific network layer 68 and a request-specific link layer 70 ,

To provide the answer 52 is provided that the order 56 from the server 50 in a first step 72 is interpreted, so that on this interpreted order 56 based user data 74 for the answer 52 to be provided. In a second step 76 is provided that the tax information 58 the user data 54 the request 48 in the answer 52 be copied, so that from the tax information-specific transport layer 60 an answer-specific transport layer 78 , from the control information-specific network layer 80 an address-specific network layer and from the control information-specific data link layer 64 an answer-specific link layer 82 provided.

So if all the information for all protocol layers of the answer 52 at the client 46 already known at the time of the request, these data are used as user data 54 in the request 48 transported and from the server 52 in the appropriate place of the answer 52 copied.

4 shows a diagram of a second embodiment of the method according to the invention. The diagram 4 shows a server memory 84 a server, a request 86 as well as an answer 88 , Here includes the request 86 payload 90 with tax information 92 for a better overview in the middle of 4 again detailed, as well as user-specific protocol layers 94 that is a payload-specific UDP layer 96 , a payload-specific IP layer 98 and a payload-specific Ethernet layer 100 include. It also rejects the request 86 a request-specific UDP layer 102 . a request-specific IP layer 104 and a request-specific Ethernet layer 106 on. In the server store 84 are identification data 108 as well as MAC addresses 110 saved. In this embodiment of the method it is provided that the identification data 108 as control information-specific identification data 112 in the control information 92 be copied.

Furthermore, the user-data-specific UDP layer 96 and IP layer 98 in a second control information specific layer 114 to provide an Ethernet type as well as an IP and UDP headers. The MAC address 110 from the server memory 84 becomes a third control information specific layer 116 copied, providing Ethernet and MAC data for a source address. In addition, starting from the payload-specific Ethernet layer 100 Data in a fourth tax information-specific layer 118 to copy Ethernet and MAC data for a destination address.

For user data 120 The answer 88 are starting from the first tax information specific layer 112 identification data 122 provided. Starting from the second tax information-specific layer 114 become data for an address-specific UDP layer 124 and an address-specific IP layer 126 provided.

From the data of the third tax information-specific layer 116 and the fourth tax information-specific layer 118 become data for an address-specific Ethernet layer 128 provided.

This second embodiment is useful, if not all elements of the protocol layers of the response 120 at the time of sending the request 86 known to the client. Thus, this data can be obtained through the control information 92 from the server in the right place in the answer 120 be inserted. The Ethernet MAC address of the server is the source address of the response 120 entered.

In the Ethernet and TCP / IP environment it is customary to identify a system via a broadcast. At this time, neither MAC address on the Ethernet layer nor IP address on the IP layer of the server are known. For the answer 120 however, the server must use a unique MAC address. A configured device must also use a unique IP address. An unconfigured device may also respond to the IP address with the value 0.0.0.0 (0 * means: a device in the local network).

• – kopiere 6 Byte aus dem Datenbereich der Anfrage 86 über die Steuerinformationen 92 in die Antwort 88 (setze die Ethernet MAC Ziel-Adresse auf die MAC Adresse des Clients),
• – kopiere 6 Byte aus dem Datenspeicher des Geräts von der Adresse der lokalen MAC Adresse über die Steuerinformationen 92 in die Antwort 88, setze die Ethernet MAC Quell-Adresse auf die individuelle MAC Adresse des Servers,
• – kopiere 22 Byte aus dem Datenbereich der Anfrage 86 über die Steuerinformationen 92 in die Antwort 88 (Ethernet Protokoll-Typ = Ox0800 (IP), vollständiger IP-Header mit konstanten Daten unter der Annahme eines nicht konfigurierten Systems mit der IP-Addresse 0.0.0.0, vollständiger UDP-Header),
• – kopiere n Byte aus dem Datenspeicher des Geräts d.h. aus dem Serverspeicher 84 des Servers von der Adresse der Identifikationsdaten (Geräte-Typ, Seriennummer, usw.) in die Antwort 88.

In this case, the following control statement is required:

• - copy 6 bytes from the data area of the request 86 about the tax information 92 in the answer 88 (set the Ethernet MAC destination address to the MAC address of the client),
• Copy 6 bytes from the data memory of the device from the address of the local MAC address via the control information 92 in the answer 88 , set the Ethernet MAC source address to the individual MAC address of the server,
• - copy 22 bytes from the data area of the request 86 about the tax information 92 in the answer 88 (Ethernet protocol type = Ox0800 (IP), complete IP header with constant data assuming an unconfigured system with the IP address 0.0.0.0, full UDP header),
• - Copy n bytes from the data memory of the device, ie from the server memory 84 the server from the address of the identification data (device type, serial number, etc.) in the response 88 ,

5 shows a schematic representation of a third embodiment of the method according to the invention. Similar to in 4 are also here schematically a server memory 130 a server, a request 132 and an answer 134 shown. tax information 136 the request 132 are also shown in more detail here. As data includes the request 132 a reference sum 138 (RefSum), data for a destination MAC address 140 , Data for one type 142 , Data for one version 144 , Data for a TOS 146 , Data for a length 148 (TOTLEN), data for a fragment 150 , Data for a TTL 152 , Data for a log 154 (Prot), data for a source internet protocol 156 , Data for a destination internet protocol 158 , Data for a source connection 160 , Data for a destination connection 162 , Data for a UDP length 164 as well as data for a code 166 (0x000).

The tax information 136 have a first tax information specific layer 168 for data copies, a second control information-specific layer for data copies, a third control information-specific layer 172 for data copies, a fourth control information specific layer 174 for data copies, a fifth control information specific layer 176 for data copies, a sixth control information specific layer 178 for data copies, a seventh control information specific layer 180 for data copies and an eighth tax information-specific layer 182 for data copies.

To carry out this embodiment of the method is provided that from the request 132 the reference sum in the first shift 168 the tax information 136 is copied. The data for the destination MAC address 140 the request 132 be in the second layer 170 the tax information 136 copied. From the server store 130 become data for a device MAC address 184 from the server memory 130 in the third layer 172 the tax information 136 copied. The data for the type 142 , the version 144 , the TOS 146 as well as the total length 148 the request 132 be in the fourth shift 174 the tax information 136 copied.

Furthermore, on the server storage 130 a first state machine designed as an identification generator 186 with a counter as a first input register 188 saved. A read access 190 leads to an increase of the counter. The data provided is in the fifth layer 176 the control information 136 copied. In the sixth layer 178 the tax information 136 will be out of the request 132 Data for the fragment 150 , the TTL 152 and the protocol 154 copied.

The server storage 130 also has a second state machine 192 for checksum computation on what by the first input register 188 to manipulate and with an initial register 194 to provide a sum. This sum will be in the seventh shift 180 the control information 136 copied. Based on the request 132 will be data for the source ip 156 , the destination IP 158 , the source entrance 160 , the destination entrance 162 , the ODP length 164 and for the code 166 in the eighth layer 182 the tax information 136 copied.

In the further progress of this third embodiment of the method are from the first layer 168 the tax information 136 in a first input register 196 Data for a server memory reference total 130 provided that it is provided that in a write access calculation 198 is started.

In addition, data from the second layer becomes 170 the tax information 136 Response-specific data for a destination MAC 200 provided. From the third layer 172 the control information 136 be for the answer 134 Data for a source MAC 202 provided. From the data of the fourth shift 174 the control information 136 be for the answer 134 Data for one version 204 or an HDR length, data for a TOS 206 , Data for one type 208 and data for a total length 210 provided. From data of the fifth layer 176 The control information becomes data for an identity 212 The answer 134 provided. From data of the sixth shift 178 the tax information 136 be on the side of the answer 134 Data for a TTL 214 , Data for a log 216 and data for a fragment 218 provided. From the data of the seventh shift 180 the control information 136 be for the answer 134 Data for a sum of mercury 220 provided. Starting from the eighth layer 182 the control information 136 will be response-specific data for a source IP 222 , a destination IP 224 , a source connection 226 , a destination connection 228 , a UDP length 230 and a checksum 232 provided.

Thus, the third embodiment shows 5 an example for the generation of an Ethernet and IP header with variable identification field (ID) and adapted checksum. For these calculations, the two state machines 186 . 192 needed. The request continues to consist solely of control information 136 and dates around the answer 136 to generate.

The identification field as the first tax information-specific layer 168 This is done by a simple counter and thus the first input register 188 generated. Any read access to the current value increments the counter 188 , The tax information 136 to generate the answer 133 are then modified so that the identification field is not transferred from the client, but from a dedicated address in the server, here a register formed as an identification generator state machine 186 , in the answer 134 is copied.

The checksum of the IP layer can be used with the adder serving as a second state machine 192 with two input registers 188 . 196 and the output register 194 easy to deploy. In most cases, all information of the IP layer is known except for the value of the identification field. Then a checksum can be predicted assuming a value of zero for the identification field. In the server may be an input of the second state machine 192 fixed to the current counter value of the identification field. Describing the other input for the reference sum 138 with the precalculated checksum starts the adder and thus the second state machine 192 , The result is in the output register 194 provided as a sum. A value of this sum is given by the control information 136 in the IP header of the answer 134 inserted.

Corresponding The above examples can be further operations realize with a high data throughput in a programmable logic. Usually is a processing of this data by a processor possible if this in a system available stands.

6 shows a schematic diagram of a diagram of a fourth embodiment of the method according to the invention. This diagram is a server store 234 , a request 236 and an answer 238 shown. The server memory includes this 234 memory-specific event data 240 and a memory-specific MAC address 242 , The request 236 includes user data 244 with control information 246 , which are also shown enlarged here. In addition, the user data includes 244 the request 236 request-specific event data 248 , request-specific ODP data 250 , request-specific IP data 252 and user-specific Ethernet data 254 , In addition, each request-specific ODP data 256 , IP data 258 and Ethernet data 260 intended.

In this embodiment of the method, payload-specific event data becomes 248 the request 236 in a first tax information specific layer 262 copied to provide event data. The user-specific UDP data 250 and IP data 252 become a second tax information specific layer 264 that is intended to provide an Ethernet type, an IP header, and a UDP header. The MAC address 242 from the server memory 234 becomes a source address in a third control information specific layer 266 copied for Ethernet data and MAC data. The user-specific Ethernet data 254 the request 236 become a fourth tax information specific layer 268 copied as Ethernet data and MAC data for a destination address. The event data from the first shift 262 the tax information 246 become the event data 240 the server memory 234 transmitted. The answer 238 points next to the payload 270 Response-specific UDP data 272 and address-specific IP data 274 on. These are from the second control information-specific layer 264 provided. Response-specific Ethernet data 276 become from the third tax information specific layer 266 provided for source addresses and the fourth control information specific layer 268 provided for destination addresses.

The storage of event data 240 in the free memory area 234 The server is used to prepare for an event-oriented sending of messages. In contrast to the previously considered embodiments are here in the request 236 also transfer data that is not for the answer 238 needed, but in server memory 234 the server are stored.

7 shows a schematic diagram of a fifth embodiment of the method, in this diagram, a server memory 278 , the event data 280 , User data 282 an event and a MAC address 284 includes, is shown. The event data 280 are in the middle of the diagram 7 shown enlarged and include control information 286 as well as log data 288 , In a first tax information-specific layer 290 become the payload 282 of the event copied. The log data 288 include a field 292 in which a MAC address as well as IP header information and UDP header information are stored. Out of this box 292 the log data 288 The IP header information and the UDP header information are converted into a second control information specific layer 294 to provide an Ethernet type as well as an IP header and a UDP header. In a third tax information-specific layer 296 becomes the MAC address 284 to provide an Ethernet MACS as the source address. The MAC address from the field 292 the log data 288 gets into a fourth shift 298 the tax information 286 copied, providing an Ethernet MAC as the destination address. In a further step of this embodiment of the method becomes a message 300 provided. This includes message-specific user data 302 , the payload 304 an event, this payload 304 the event from the first shift 290 the tax information 286 be transmitted. Also, within the embassy 300 message-specific UDP data 306 and IP data 308 provided jointly from the second layer 294 the tax information 286 to be provided. Message-specific Ethernet data 310 become from the third tax information specific layer 296 and the fourth control information specific layer 298 provided.

After the event data 280 associated with an event, the event becomes the processing of the control information 286 the event data 280 trigger. In this example, for the sake of clarity, a constant IP header is assumed. The generation of a header with a unique identification field and adapted IP checksum is also possible.

Claims (12)

Procedure for exchanging information between a client ( 46 ) and a server ( 50 ), by which the client ( 46 ) a request ( 48 . 86 . 132 . 236 ), which includes data, to the server ( 50 ) and taking into account the data layers of a protocol of a response ( 52 . 88 . 134 . 238 ) from the server ( 50 ) to the client ( 46 ) is generated. Method according to Claim 1, in which the generation of the response ( 52 . 88 . 134 . 238 ) Data that is used as control information ( 92 . 136 . 246 . 286 ) are used. Method according to Claim 1 or 2, in which, to generate the response, data which is used as control information ( 92 . 136 . 246 . 286 ) from the server ( 50 ) can be used. Method according to Claim 2 or 3, in which the control information determines which data in which addresses of the response ( 52 . 88 . 134 . 238 ) are copied. Method according to one of the preceding claims, in which for generating the answer ( 52 . 88 . 134 . 238 ) Data transmitted as request data. Method according to one of the preceding claims, in which answers ( 52 . 88 . 134 . 238 ) are provided event-based. Method according to one of the preceding claims, in which repetitive parts of replies ( 52 . 88 . 134 . 238 ) in the server ( 50 ) get saved. Method according to one of the preceding claims, in which the data in the response ( 52 . 88 . 134 . 238 ) are copied. Arithmetic unit which is designed to exchange information with at least one further arithmetic unit to this at least one further arithmetic unit a request ( 48 . 86 . 132 . 236 ), which comprises data, whereby it is provided, taking into account these data, layers of a protocol of a reply ( 52 . 88 . 134 . 238 ), which is to be transmitted from the further arithmetic unit to the arithmetic unit. Arithmetic unit, which is designed to exchange information with at least one further arithmetic unit, taking into account data transmitted by the at least one further arithmetic unit in a request to the arithmetic unit, layers of a protocol of an answer ( 52 . 88 . 134 . 238 ), which is to be transmitted from the arithmetic unit to the at least one further arithmetic unit. Computer program with program code means to all To perform steps of a method according to any one of claims 1 to 8, when the computer program on a computer or equivalent Arithmetic unit, in particular a computing unit according to claim 9 or 10, is executed. Computer program product with program code means, which are stored on a computer-readable medium to all To perform steps of a method according to any one of claims 1 to 8, when the computer program on a computer or equivalent Arithmetic unit, in particular a computing unit according to claim 9 or 10, executed becomes.