FR2764717A1 - Reading instructions for numerical data decoder microprocessor - Google Patents

Abstract

The microprocessor (1) has a random access memory (2) and a read only or flash read only memory. The read only memory (3) is divided into two zones (Z3,Z4). The first zone (Z3) contains microprocessor initialising instructions, zone reprogramming instructions and instructions permitting the transfer of the microprocessor instructions stored in the second zone (Z4) to the random access memory. The random access memory has two zones (Z1,Z2). The first zone (Z1) contains user data and the second zone (Z2) contains the microprocessor instructions transferred from the read only memory. The access time for the second zone (Z2) of the random access memory is less than that of the second zone (Z4) of the read only memory.

Description

METHOD FOR READING INSTRUCTIONS OF
DIGITAL DATA DECODER MICROPROCESSOR
AND DECODER USING SUCH A METHOD
The invention relates to a method for reading microprocessor instructions.

 More particularly, the invention relates to a method for reading instructions from a digital data decoder microprocessor.

 Preferably, the invention applies to a digital video data decoder such as, for example, a decoder allowing the processing of video data in MPEG II format.

 The digital data decoder microprocessor instructions are contained in ROM or FLASH-ROM circuits.

The acronym ROM comes from the English "Read Only Memory" and will be used later to designate a read only memory. As is known to those skilled in the art, ROM or FLASH-ROM memories are used because of their capacity to preserve their content in the absence of supply voltage.

Unlike ROM type memories, FLASH-ROM type memories have the characteristic of allowing an update of the data they contain.

 In order to increase the speed with which the various circuits constituting the decoder operate, it is desirable to use a microprocessor operating at a high frequency.

 To obtain a real advantage from a microprocessor working at high frequency, the access time to the instructions of the microprocessor must then be reduced. It is indeed necessary to perform a rapid transfer of the instructions contained in the ROM or FLASH-ROM memory to the microprocessor.

To quickly transfer instructions from ROM or
FLASH-ROM to the microprocessor, it is known to use ROM memories or
FLASH-ROM whose access times are very short, for example of the order of 60 ns. Such memories are very expensive.

 On the other hand, as has been mentioned above, in the case of the use of a FLASH-ROM type memory, it is possible to update the instructions of the microprocessor.

 To update the microprocessor instructions, it is necessary to reprogram the FLASH-ROM type memory using instructions specially dedicated to this task.

During the reprogramming cycle, the FLASH-ROM type memory is no longer accessible. The program which controls the update is then a complex program which operates the transfer of its own instructions from the FLASH-ROM type memory to a direct access memory commonly called RAM type memory. It is then necessary to reserve in the RAM type memory a memory area large enough to store the update program. The acronym RAM comes from the English wRandom Access
Memory "and will be used later to designate a direct access memory.

 According to the prior art, the RAM type memory used for checking the update is the memory which stores the various user data coming from program broadcasters. By user data is meant, for example, user rights management messages, or messages containing the different access conditions that a user has on the different services offered by a service provider.

The use, for the control of the update, of the type memory
RAM which stores user data has the consequence of limiting in a significant proportion the space available to store user data.

 This limitation is a real drawback. This disadvantage is all the more important as the update is carried out at the customer. Indeed, during an update carried out at the customer, it is desirable that the different functionalities of the decoder are not too limited so that the customer can continue to enjoy the use of the decoder under the best possible conditions .

 In addition, the update process control program generally occupies a larger memory space than the space available in the RAM memory mentioned above. The update must then be carried out by splitting the control program into several subroutines.

 These different subroutines are then either successively stored in the RAM type memory mentioned above in order to complete the update in its entirety by successive passes, or distributed in different RAM type memories associated with different circuits of the decoder.

 In the first case, the update is carried out slowly. As an example, the update time can be of the order of several minutes. However, during the update of the decoder, possible problems may arise, such as, for example, a power cut or an interruption in the transmission of data allowing the update. Due to the slowness with which the update is carried out, the probability that the decoder cannot be placed in correct operating conditions is then not negligible.

 In the second case, the various circuits whose memories are wholly or partly occupied by the subroutines mentioned above are unable to function.

 In both cases, the update according to the prior art therefore has many drawbacks.

 The invention does not have these drawbacks.

 The present invention relates to a method for reading, by a digital data decoder microprocessor, instructions allowing operation of the microprocessor, said instructions being contained in a memory area of ROM or FLASH-ROM type before the microprocessor is started up. The method includes a step allowing all or part of said instructions to be transferred to a specific RAM type memory area when the microprocessor is started up.

The present invention also relates to a digital data decoder comprising a microprocessor, a ROM type memory area or
FLASH-ROM containing microprocessor instructions. The digital decoder comprises a specific memory area of RAM type making it possible to store all or part of said instructions.

 By specific memory area is meant a memory area specially dedicated to storing the instructions of the microprocessor, that is to say a memory area distinct from the RAM type memory area which contains the data of the user as well as any memory area associated with any of the different circuits of the decoder.

 An advantage of the invention is to improve the speed with which a digital data decoder operates, whether the instructions of the microprocessor contained in the decoder are stored in a memory of the FLASH-ROM type or a memory of the ROM type.

Another advantage of the invention is to improve the conditions for updating the instructions of a digital decoder microprocessor in the case where the instructions of the microprocessor are stored in a memory of the type
FLASH-ROM.

 Other characteristics and advantages of the invention will appear on reading a preferred embodiment made with reference to the attached figure.

 The attached figure includes a microprocessor 1, a RAM memory 2 and a ROM or FLASH-ROM memory 3.

 The memory 3 is divided into two zones, Z3 and Z4.

Zone Z4 contains instructions from microprocessor 1 and zone Z3 contains
-instructions for initializing the operation of microprocessor 1,
the instructions allowing the transfer, to the memory 2, of the instructions contained in the zone Z4,
-instructions for reprogramming the zone
Z4.

 According to the invention, the instructions contained in the zone Z4 are transferred in whole or in part, preferably each time the decoder is started, in a zone of the memory 2.

 The memory 2 is divided into two zones Z1 and Z2.

 zone Z1 contains user data and zone Z2 contains data from zone Z4.

 The memory area Z2 has an access time less than the access time of the memory area Z4. Advantageously, it follows that the time taken by the microprocessor 1 to access its instructions is shorter according to the invention than according to the known art.

 According to the invention, the RAM memory 2 is sized to be able to simultaneously contain the user data in the zone Z1 and the instructions of the microprocessor which it stores in the zone Z2 when the decoder is started up.

 According to an improvement of the invention, the instructions of the microprocessor consist, in whole or in part, of compressed data. The memory zone Z3 then includes instructions allowing the compression of the data representing the instructions of the microprocessor to be carried out in the zone Z4. As an example, the compression program can be a 'Huffman' type algorithm suitable for binary code compression.

According to the invention, the memory capacity of memory 3 can then advantageously be reduced compared to the memory capacity of memories
ROM or FLASH-ROM used according to the prior art.

 All other things being equal, the memory capacity of the memory 3 according to the invention can thus, for example, be reduced by half compared to the memory capacity of a memory of the same type used according to the prior art.

 A ROM or FLASH-ROM memory being of a higher cost than a RAM type memory, it advantageously follows that the memory circuit used for managing the instructions of the microprocessor according to the invention is of a cost lower than the circuit used according to the prior art.

 According to the improvement of the invention mentioned above, the data representing the instructions of the microprocessor are compressed data. The zone Z2 of the RAM type memory 2 then contains a program for decompressing the compressed data. By way of example, the decompression program can be a “Huffman” type algorithm suitable for compressing binary code.

 In the case of the use of a FLASH-ROM memory as a memory containing the instructions of the microprocessor 1, an advantage of the invention is to allow updating of the instructions without disturbing the various functionalities of the decoder.

 According to the invention, it is no longer necessary to split the program which controls the updating of the instructions into subroutines and to distribute these different subroutines in the different RAM memories of different circuits of the decoder. The decoder can thus advantageously continue to work in all of its functionalities.

 Another advantage of the invention is that it no longer makes access to memory 3 necessary after the instructions contained in the memory area Z4 have been copied to the memory area Z2. It is then possible to modify, as necessary, the various functionalities of the decoder in a simple manner. An evolution of the functionalities of the decoder can result in new programs which improve on previous programs or which make it possible to use completely new modes of operation. For example, specific protocols for communication with a new server can be easily installed at the customer's site.

 It is then possible, according to the invention, to design decoders whose software only integrates basic and updating functions.

By way of nonlimiting example, the invention makes it possible to produce a decoder whose microprocessor 1 works at a frequency of 25 MHz, whose memory
RAM 2 is a memory of two Megabytes and whose ROM or FLASH memory
ROM 3 is a memory of one Megabyte. The exchange of data between the RAM memory 2 and the microprocessor 1 is then carried out with data coded on 16 bits at a rate of the order of 17 Mega-bytes per second and the exchange of data between the ROM memory or FLASH-ROM 3 with data coded on 8 bits at a rate of 4 Megabytes per second.

Claims (6)

 1. Method for reading, by a microprocessor (1) of a digital data decoder, instructions allowing operation of the microprocessor (1), said instructions being contained in a memory area (Z4) of ROM or FLASH-ROM type before the startup of the microprocessor (1), characterized in that it comprises a step allowing the transfer of all or part of said instructions in a specific memory area (Z2) of RAM type during startup of the microprocessor (1).  2. Method according to claim 1, characterized in that it comprises a step of compressing the data which represent said instructions when said data are contained in the memory area (Z4) of ROM type or FLASH-ROM and a decompression step, in the memory area (Z2) of type RAM, compressed data from the compression step.  3. Method according to any one of claims 1 or 2, characterized in that the memory area (Z4) being of the FLASH-ROM type, it comprises a step allowing the updating of the instructions contained in said memory area (Z4) .  4. Method according to any one of claims 1 to 3, characterized in that the digital data are video data.  5. Decoder for digital data comprising a microprocessor (1), a memory area (Z4) of ROM or FLASH-ROM type containing instructions of the microprocessor (1), characterized in that it comprises a specific memory area (Z2) of RAM type for storing all or part of said instructions.  6. Decoder according to claim 5, characterized in that the memory (3) of ROM or FLASH-ROM type comprises means for compressing the data representing the instructions of the microprocessor (1) and the specific memory area (Z2) means for decompress the compressed data it contains.