FR3134638A1 - Method for developing a computer program on blockchain for motor vehicles and associated device - Google Patents

Abstract

Method for developing a first computer program (111) for a motor vehicle in a blockchain (1110), the blockchain (1110) comprising a decentralized execution module (114), the development method being characterized in that it comprises the following steps: Receiving an instruction to write the first computer program (111) in the blockchain (1110), the first computer program (111) being configured to produce an output data from an input data,Reception of an instruction to write a test data (112) in the blockchain (1110),Reception of an instruction to launch a execution of the first computer program (111), with the test data as input data of the first computer program (111), the launch being implemented by the centralized execution module (114), Storage of the output data (113) in the blockchain (1110). Figure for abstract: figure 1

Description

Method for developing a computer program on blockchain for motor vehicles and associated device

The invention relates to a method for developing a computer program for a motor vehicle.

There is a need to facilitate the collaborative development of applications for automotive vehicles, which are secure and include tracing of writes, tests and executions.

For this purpose, the invention relates to a method for developing a first computer program for a motor vehicle in a blockchain (called in English "blockchain", as defined for example in standard ISO 22739:202) , the blockchain comprising a decentralized execution module, the development process being characterized in that it comprises the following steps:

• Receiving an instruction to write the first computer program in the blockchain, the first computer program being configured to produce result data from input data (and therefore, the first program computer is stored or written in the block chain at this step),
• Receipt of an instruction to write test data into the blockchain (and therefore, the test data is stored or written into the blockchain at this step),
• Receipt of an instruction to launch an execution of the first computer program, with the test data as input data of the first computer program (thus, the computer program is executed during this step) , the launch being implemented by the centralized execution module (thus, the launch of the computer program is executed during this step by the centralized execution module),

• Storage of the output data in the blockchain.

The invention thus makes it possible to develop a computer program, in a collaborative and secure manner, with tracing of the operations carried out, in particular tests of the computer program.

A computer program for a motor vehicle is a computer program intended to be implemented in a processor included in a motor vehicle, possibly after optimization, translation, compilation or correction of the computer program (and the development process may include one or all of these steps). The first computer program can be source code, that is to say in the form of a text file.

A blockchain is capable of receiving an instruction also called a transaction. An instruction can be an instruction to write data in the blockchain or an instruction to launch a program stored in the blockchain. Writing or storing data in a blockchain consists of writing in a block of the blockchain (using an electronic processor).

A block of a blockchain includes, for example, the following elements: data written upon receipt of a write instruction, a checksum of the blockchain used as an identifier, a checksum of the previous block and a proof of work. The checksums are for example of the so-called “SHA-256” type and conform to the so-called “FIPS 180-4” standard. The blockchain is stored on a plurality of computers. The checksums are preferably signed using a private cryptographic key.

According to one embodiment, the execution module includes a script executable by a virtual machine. For example, the executable script is capable of compiling the first computer program (or controlling its compilation) before executing it.

The development process may further comprise the following steps:

• Receipt of an instruction to write expected result data into the blockchain (and therefore, the expected result data is written or stored in the blockchain at this step),
• Receipt of an instruction to launch a comparison between the output data and the expected result data, the comparison producing a comparison result (and therefore the comparison is carried out at this step),
• Memorization of the comparison result in the blockchain.

According to one embodiment, the first computer program is able to implement at least one of the following tasks:

• Geographic location of the motor vehicle,
• Scene recognition of the automobile vehicle environment,
• Automated determination of a trajectory of the motor vehicle,
• Tracking the trajectory of the motor vehicle.

The invention also relates to a second computer program comprising instructions, executable by a microprocessor or a microcontroller, for implementing the method according to the invention.

The method according to the invention is for example implemented by an electronic driving assistance device. The invention therefore also relates to an electronic device configured to implement the steps of the method according to the invention. Finally, the invention relates to a system comprising a plurality of electronic devices according to the invention.

The characteristics and advantages of the electronic device, the system and the second computer program are identical to those of the method, which is why they are not repeated here.

It is understood that an element such as the electronic device, or another element is "configured for" ("or capable of") carrying out a step or an operation, by the fact that the element comprises means for (in other words " is suitable for” or “is suitable for”) to carry out the step or operation. These are preferably electronic means, for example a computer program, processors, data in memory and/or specialized electronic circuits.

When a step or an operation is carried out (or implemented) by such an element, this generally implies that the element includes means for (in other words "is configured for" or "is adapted for" or "is configured for ") carry out the step or operation. It also concerns, for example, electronic means, for example a computer program, a processor, data in memory and/or specialized electronic circuits.

Other characteristics and advantages of the present invention will appear more clearly on reading the detailed description which follows including embodiments of the invention given by way of non-limiting examples and illustrated by the appended drawings, in which.

represents an electronic device according to one embodiment of the invention.

represents the method of the invention, according to an exemplary embodiment, implemented in particular by the electronic device of the .

Detailed description of an example of embodiment of the invention

There represents an electronic device 1000 according to the invention. The device 1000 has, for example, the architecture of a computer. It includes in particular an electronic microprocessor 1200 (in other words: a processor 1200) and a memory 1100 comprising a chain of blocks 1110. Copies of the chain of blocks 1110 are stored on a plurality of computers (not shown).

The block chain 1110 notably includes blocks 110, 120 and 130.

In the block 110 (respectively 120 and 130), the memory area 117 (respectively 127 and 137) stores a checksum of the chain of blocks 110 (respectively 120 and 130) used as an identifier of the block chain 110 (respectively 120). and 130), a checksum of the previous block 120 (respectively 130 and a block not shown) and a proof of work. The checksums are for example of the so-called “SHA-256” type and conform to the so-called “FIPS 180-4” standard. The checksums are preferably signed using a private cryptographic key.

Blocks 130, 120 and 110 include a decentralized execution module 114. The decentralized execution module 114 includes a script executable by a virtual machine included in the block chain 1110. For example, the executable script is capable of compiling a computer program 111 (or to order its compilation) before executing it.

In reference to the and 2, in step S10, the device 1000 receives an instruction to write a new version of a computer program 111 developed by a user. The computer program 111 is then stored in the block 130 by the processor 1200.

The computer program 111 is intended to be implemented in a processor included in a motor vehicle, possibly after optimization, translation, compilation or correction of the computer program 111. The computer program 111 can be a source code ( that is to say in the form of at least one text file) for example in a computer language known as “C” or “C++”.

the computer program 111 is capable of (or configured to) implement at least one of the following tasks:

• Geographic location of the motor vehicle,
• Scene recognition of the automobile vehicle environment,
• Automated determination of a trajectory of the motor vehicle,
• Tracking the trajectory of the motor vehicle.

In step S20, the device 1000 receives an instruction to write test data 112 in the block chain 1110. The test data 112 is then stored in the block 120 by the processor 1200.

In step S30, the device 1000 receives an instruction to write expected result data 115 in the block chain 1110. The expected result data 115 is then stored in block 120 by the processor 1200.

In step S40, the device 1000 receives (in other words: receives) an instruction to launch an execution of the computer program 111 by the decentralized execution module 114, with the test data as input data 112. On receipt of the launch instruction, the processor 1200 executes the script of the decentralized execution module 114 using a virtual machine included in the blockchain 1110. For example, the script is capable of compiling the computer program 111 (or to order its compilation) before executing it. The execution of the computer program 111 by the processor 1200 produces an output result 113 stored in the block 110.

In step S50, the device 1000 receives an instruction to launch a comparison between the output data 113 and the expected result data 115. The processor 1200 then carries out the comparison and stores the result 116 of the comparison in the block 110.

The aforementioned write and launch instructions can be received (via a human machine interface) from a user of the device 1000 or from another device through a telecommunications network (not shown) connected to the device 1000 and can be implemented by the processor 1200.

The device 1000 can store a computer program comprising instructions, executable by processor 1200, for implementing steps S10 to S50.

Claims (6)

Method for developing a first computer program (111) for a motor vehicle in a blockchain (1110), the blockchain (1110) comprising a decentralized execution module (114), the development method being characterized in that it comprises the following steps:

• Receiving a write instruction (S10) from the first computer program (111) into the blockchain (1110), the first computer program (111) being configured to produce output data from an input data,
• Receiving a write instruction (S20) for test data (112) in the block chain (1110),
• Receiving a launch instruction (S40) for an execution of the first computer program (111), with the test data as input data of the first computer program (111), the launch being activated implemented by the centralized execution module (114),
• Storage of the output data (113) in the block chain (1110).

Development method according to the preceding claim further comprising the following steps:

• Receiving a write instruction (S30) of expected result data (115) in the blockchain,
• Receiving an instruction to launch (S50) a comparison between the output data (113) and the expected result data (115), the comparison producing a comparison result (116),
• Storage of the comparison result in the blockchain (116).

Development method according to any one of the preceding claims in which the first computer program (111) is capable of implementing at least one of the following tasks:

• Geographic location of the motor vehicle,
• Scene recognition of the automobile vehicle environment,
• Automated determination of a trajectory of the motor vehicle,
• Following a trajectory of the motor vehicle.

Second computer program comprising instructions, executable by a microprocessor or a microcontroller, for implementing the method according to any one of claims 1 to 3. Electronic device (1000) configured to implement the steps of the method according to any one of claims 1 to 3. System comprising a plurality of electronic devices according to the preceding claim.