Abstract:
The invention concerns a method for managing resources of a modular processor system comprising the following steps of transmitting an instruction of a programme contained in a first machine with higher level status to a second machine with lower level status to manage the running of the programme; attributing links between the different cells which contain the incoming data and the operators of the block of the machine with lower level status to perform the placement of said incoming data; attributing links between the operators of the block of the machine with lower status to perform processing of said incoming data; and reconfiguring the links between the different operators by the machine with lower level status, during the execution of the programme instructions, based on outgoing data obtained from processing of the incoming data.

Description:
FIELD OF THE INVENTION 
       [0001]    The present invention relates to a parallel processor system having a reconfigurable and hierarchical structure. 
       BACKGROUND OF THE INVENTION 
       [0002]    The sequential operation of most current processors advantageously economizes on resources (logic gates) at the cost of reduced performance linked directly to operations being effected in succession, so sequential processors must be at the cutting edge of integrated circuit speed and integration. Similarly, operation instructions (code) must be read sequentially over ever longer instruction words, making the introduction of parallel processes difficult unless including words of 128, 256 or more bits. 
         [0003]    In practice, current processors must support program structures that appear parallel by producing a multitasking execution structure. However, such a structure does not provide real simultaneity and represents a heavy load. In particular, multitasking requires additional management by the processor, made necessary if priorities are to be shared between the various tasks; such a heavy load has consequences: greater memory capacity is required (allocation of memory blocks per task), and a reduction of performance is caused by the fact that some resources are dedicated to task management. 
         [0004]    Some systems introduce multiple processors interconnected in a common environment in which they share resources and data. Although offering better performance than that having only one processor, this architecture has the drawback of being costly in interface components and its performance is limited by the capacity for exchange of data on a common bus. 
         [0005]    The introduction of parallelism is a priori costly; systems have introduced it and necessitate considerable resources. To a large degree these systems offer very high performance at the cost of a lack of flexibility and of wasting resources in that a large portion of the functions are not used to their full potential. In this instance, a parallel processor must exploit new structures enabling dynamic allocation of resources and efficient and economical exchange of data between resources. 
         [0006]    In French patent No. 2 783 630, application filed 23 Sep. 1998, and U.S. Pat. No. 6,137,044, application filed 23 Sep. 1999 and issued 24 Oct. 2000, the cell concept is introduced into a system for parallelization of sound signals in which the calculation elements are shared between cells and in which the inputs and outputs of the cells are interconnected by programmable links. Although they are shared (numerous parallel operations used sequentially), resources can be grouped together and an architecture can incorporate a plurality of these groups having their own resources in parallel at the same time as being capable of being linked in a programmable manner. The above patent introduces fully modular means for rendering these links programmable. The architecture described in the patent cited above is built around the concept of cells sharing calculation resources and offers solutions in the signal and time field (recursive mode) although it can equally well offer solutions in the more general field of calculating and data processing machines (non-recursive mode). 
         [0007]    Consequently, there remains a great deal of room for methods and systems that solve the principal limitations of existing processors and generalize parallel processing to any type of data and signals. 
       SUMMARY OF THE INVENTION 
       [0008]    The present invention introduces the functions of a parallel processor the elements whereof are configurable and reconfigurable in real time and dynamically. The processing and calculation resources are used by each cell independently, with or without sharing. The input data of the cells is linked to registers the values whereof come from variables or from calculation results from other resources. The cells are grouped into first level blocks. Those blocks can be grouped in turn, and so on. A state machine commands the operation of each group of level 1 or higher, in accordance with a program and if required reconfigurable in accordance with chosen results. The level 1 blocks include accumulators with multiple outputs that enable dynamic redirection of partial data from the outputs of cells, these accumulators enabling crossed calculations with programmable indexing. The higher level integrates all the levels and also contains a state macromachine that manages the operation of the subsystems. In this instance the processor is constituted of hierarchical elements on a plurality of levels, the elementary level constituting the cell; this hierarchical organization enables communication of data on simple calculations (low level) and on blocks of calculations (higher levels). 
         [0009]    This structure is fully parallel and entirely reconfigurable dynamically on external data or as a function of results obtained. 
         [0010]    The modular processor system is based on a hierarchical architecture enabling processing and calculation to be effected on data in memory in order to obtain data; said system comprises means for effecting arithmetic, logic, storage operations in parallel manner using resources in an adapted and reconfigurable structure including grouped operators disposed in whole or in part around a set of cells, available on a time sharing or predetermined basis in a flexible manner in all combinations, themselves grouped into blocks, in which cells and blocks data can be exchanged in programmable manner, so that processing can be effected independently and simultaneously using resources configured dynamically as required. 
         [0011]    The system is advantageously characterized in that the routing of the input and output data can be effected dynamically and independently at each input, output and calculation resource and on the basis of particular values in predefined memories corresponding to the links between the sources and the destinations. 
         [0012]    The system is advantageously characterized in that the various data links take account of the synchronization to compensate for the delays between the various inputs for each resource including a plurality of inputs such as the operators, the cells and the blocks of cells. 
         [0013]    The system is advantageously characterized in that the incoming data is directed dynamically to the groups of operators from an external processor or from input interfaces from external devices, the routing of the data to the groups being reconfigurable dynamically as required. 
         [0014]    The system is advantageously characterized in that the outgoing data is transmitted to memories or to external devices or output interfaces. 
         [0015]    The system is advantageously characterized in that said means for effecting arithmetic or logic or storage processing on operators incorporated in cells comprise:
       a circuit for configuration of the inputs of the various logic and arithmetic operators grouped into blocks, shared by cells and accessible by cells chosen dynamically;   a circuit for configuration of the inputs of the various logic and arithmetic operators in part assigned in fixed manner to cells according to the configuration requirements and alternatively to shared operator configurations;   an independent circuit for selection of the source of each input for each input of each operator;   a circuit for capture of output data in the form of accumulators including flip-flops the synchronization whereof can be parametered independently;   a synchronization circuit in the form of programmable counters for commanding sequences usable at the various processing levels, as required and configurable independently for each element;   a storage command circuit for the storage type operators;   an arithmetic and logic calculation circuit for the calculation, comparison or decision type operators;   a delay circuit using flip-flops for appropriate synchronization of the operator inputs for each input independently;   a circuit for grouping operators in cells including configuration registers giving the connection links for each operator input, the synchronization modes, the direction of the outputs, the connections between the operators of a cell, the connections between the cells, the connections external to the cells.       
 
         [0025]    In the system for processing data at one or more levels, command is effected at each level by processes of processor-controller type or state machines and the higher levels instruct operations on the lower levels and the modes of calculation and of operation of each resource and the data links between the various resources are determined dynamically. 
         [0026]    Advantageously, the circuit for selection of the source of the inputs on each level, in this instance the links on a plurality of levels, comprises:
       a circuit for the selection of the sources of the inputs of operators in particular arithmetic, logic, storage functions, which circuit routes the outputs of other elements, whether that be other operators, cells, groups (in the description of the level 1 or other blocks), programmable counters or other circuit elements, direct data, to one or the other input of each operator, independently for each input of each operator;   a circuit for the selection of the sources of the inputs of cells, which circuit routes the outputs of other elements, whether that be cells, groups (in the description of the level 1 or other blocks), or selective group accumulators, programmable counters, operators or other circuit elements, direct data, to one or the other input of each cell, independently for each input of each cell;   a circuit for the selection of the sources of the inputs of groups of cells called level 1 blocks or higher level blocks incorporating lower level blocks, which circuit routes outputs of other elements, whether that be cells, groups (in the description of the level 1 or other blocks), or selective group accumulators, programmable counters, operators or other circuit elements, direct data, to one or the other input of each group, independently for each input of each group.       
 
         [0030]    The cell circuit advantageously groups calculation or processing elements comprising:
       memories, logic or arithmetic operators;   a circuit for selection of links between the elements of the cell at the inputs and outputs;   a circuit for selection of the links external to the cell enabling connection of different inputs or outputs of cells, operators, accumulators of cells, groups of cells or input data.       
 
         [0034]    The process command circuit of the cells advantageously comprises:
       programmable counters;   counter commands for the start, end and incrementation/decrementation values;   counter commands for activation of counting, setting to zero, loading of programming values and counting direction.       
 
         [0038]    The circuit for selective accumulation of the inputs of the cells advantageously comprises:
       outputs of elements to be selected including outputs of other cells, outputs of groups of cells, outputs of accumulators of groups of cells, outputs of operators, etc.;   a circuit for selection of inputs from programmed registers or programmed state machines, etc.       
 
         [0041]    The circuit for grouping cells advantageously groups cells comprising:
       memories, logic or arithmetic operators available to receive data from cells or from other sources, calculate and route results to other cells;   a circuit for selection of links between the cells at the inputs and outputs;   a circuit for selection of links external to the group enabling connection of different inputs or outputs of cells, operators, accumulators of cells, groups of cells or direct inputs.       
 
         [0045]    The cell group process command circuit advantageously comprises:
       programmable counters;   counter commands for the start, end and incrementation/decrementation values;   counter commands for activation of counting, setting to zero, loading programming values and counting direction.       
 
         [0049]    The circuit for selective accumulation of the outputs of the cells comprises:
       stored cell outputs;   a programmable selection circuit for choosing the values of cells to be added in a given clock cycle;   a circuit for commanding selection of values from counters or programmable state machines commanding the circuit for selection of cells to be added in a given cycle;   a programmable selection circuit for choosing the cell accumulators over a given clock cycle;   a circuit for commanding the selection of values from counters or programmable state machines commanding the circuit for selection of the accumulators over a given cycle;   a parallel adder of the values of the cells with selection of the inputs by the device for selection of outputs of cells to be added in a given cycle;   memories commanded selectively to assume the values added in a chosen cycle;   memories commanded cyclically for synchronizing the outputs of the memories selected in chosen cycles and transmitted in other cycles.       
 
     
    
     
       DESCRIPTION OF THE FIGURES 
         [0058]    The figures represent a structure with three levels: higher level, level 1, cells. The architecture is not limited to this number of levels, however, and could equally well feature a number of levels larger or smaller than three. 
           [0059]      FIG. 1  ( 1   a ,  1   b ) represents the higher level of the architecture which contains in particular the first state machine that commands all of the architecture and the Level 1 blocks. 
           [0060]      FIG. 2  ( 2   a ,  2   b ,  2   c ) represents the elements of a Level 1 block shown in  FIG. 1 , which includes its own state machine—supervised by the first state machine, its configuration registers, the process commands, the block cells, the operators and the multiple-output accumulator. It constitutes a set of one or more calculations effected on the cells. 
           [0061]      FIG. 3  ( 3   a ,  3   b ,  3   c ) represents the elements of a cell shown in  FIG. 2 , including the configuration registers, the process commands, the input accumulator, data from which is routed selectively to the operators, the operator selectors and the output accumulator of the cell. 
           [0062]      FIG. 4  represents in detail process commands in a level 1 block as shown in  FIG. 2 . 
           [0063]      FIG. 5  represents in detail the multiple-output accumulator of the cells, shown in  FIG. 2 , including the synchronization of outputs coming from each cell which are combined (adder  501 ) and directed selectively to one or more outputs. 
           [0064]      FIG. 6  represents in detail process commands in a cell as shown in  FIG. 3 , including programmable counters the values from which can be used in commands specific to each cell. 
           [0065]      FIG. 7  represents in detail the input accumulator of a cell, shown in  FIG. 3 , including multiplexers directing level 1 outputs to one or more operators of the cell as required. 
           [0066]      FIG. 8  represents in detail a generic operator, shown in  FIG. 2 , including selectors for choosing the source of each operator input, synchronizers for the ‘pipeline’ and the operation function as such, which can be an arithmetic or logic function: adder-subtractor, multiplier, divider, linear/non-linear function table, comparator, memory or register, bit shifter unit, etc. 
           [0067]      FIG. 9  represents in detail the output accumulator of the cell, shown in  FIG. 3 , which chooses one or the other output of the operator as the specific output of a given cell. 
       
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
       [0068]    Generally speaking, the present invention proposes a modular, reconfigurable and hierarchical processor using parallel calculation and processing. The data supplied for calculation and processing may come firstly from memories, external processors or input/output interfaces. The hierarchical configuration of the elements, in particular the links between them, may be commanded by an external processor that processes and decides on the evolution of the configuration in accordance with the calculations executed, or by the introduction of state machines ( 101 ) as shown in  FIG. 1   a , in which case the processor may act autonomously as much as in an evolving manner by virtue of the fact that the data resulting from the calculations may be evaluated by the state machine  101 , which acts as a system operation control processor. 
         [0069]    The higher level manages all of the processor and includes the level 1 blocks if the system does not include an intermediate level. The higher level may equally include the level ‘n’ blocks if ‘n’ hierarchical levels are introduced. In a simplified structure it could include only the cells as described hereinafter and no intermediary. The structure of the blocks of a given level could be symmetrical (the blocks being identical) or non-symmetrical (the blocks being different). In the present description, which seeks to be typical and of intermediate complexity, a structure will be considered with one level constituting a set of identical level 1 blocks each having a given number ‘JA’ of cells. 
         [0070]    At the higher level the state machine ( 101 ,  FIG. 1   a ) effects configuration directly on the level 1 blocks, in particular the setting of the parameters of the state machines of each level 1 block ( 201 ,  FIG. 2   a ). The underlying performance is managed by the latter machines, and therefore indirectly and in a decentralized manner by the higher state machine ( 101 ). 
         [0071]    The higher level state machine ( 101 ) manage the operation of the system conjointly with the state machines of the level 1 blocks ( 201 ,  FIG. 2   a ). 
         [0072]    At the level of its logical operation, the higher level state machine ( 101 ) is comparable to a microcontroller; in the module ( 101 ) the encoding memory block ( 102 ) includes the various level 1 configuration codes, i.e. the various registers governing the operation of the elements of the level 1 blocks. To be more precise, the memory blocks ( 102  to  104 ) are organized so that the functions to be accomplished are grouped into memory sections as program functions in the manner of a processor; the diverse functions can call others like function calls in software conditionally (on the basis of the results) or unconditionally. The encoding of the operations in the state machines is effected in words of the VLIW (very long instruction word) type comprising the blocks of codes to be transferred to the state machines of the level 1 blocks ( 201 ); these blocks to be transferred constitute commands for the hardware of the system; the transfer of memory blocks  101  to the state machine  201  normally occurs on start-up but may be effected at any time. Once the procedure blocks have been transferred, they can be executed by the state machines of the level 1 blocks ( 201 ) on the instructions of the higher state machine ( 101 ). This hierarchical mode of operation means that decisions from the higher level can be routed to the level 1 blocks ( FIG. 2 ) and ultimately to the elements of the cells ( FIG. 3 ). Thus the transfers between the various state machines constitute all of the code and the execution instructions transmitted from the higher state machine to the others. The VLIW encoding therefore includes the types of operations to be effected, the implied low level configuration, in particular on the operators ( FIG. 8 ), the connections between the various elements including the operators, the configuration of the accumulators, the types of decisions (comparators in particular); all of the above is similar to a microprocessor but decentralized, rendered hierarchical and shared between the state machines of the different levels. Each element can be configured directly or conditionally through the intermediary of the comparators ( 107 ) according to the results received at the level 1 result memory blocks ( 103 ) (outputs of the Level 1 blocks N 1 _ 1 _ 1  to N 1 _ 1 _JM for the Level 1 block # 1  up to N 1 _JN_ 1  to N 1 _JN_JM for the Level 1 block #JN) or the cells result memory blocks ( 104 ) (cell outputs CELL_ 1 _ 1 _V to CELL_ 1 _JA_V for the first Level 1 block up to CELL_JN_ 1 _V to CELL_JN_JA_V for the Level 1 block #‘JN’) or even on predefined loops as in programming. The Encoding Memory ( 102 ) moves from one address to the next in a sequential order that may be interrupted by the results from the comparators ( 107 ) which can selectively instruct a change of addressing of the state machine ( 101 ) on the encoding memory ( 102 ) according to the results obtained from the memory blocks  103  and  104  the results of which are compared in a configurable manner to one or more values. The routing of the configuration of the level 1 blocks ( 105  to  106 ) is identified on the signals N 1 _ 1 _PROG to N 1 _JN_PROG for the ‘JN’ level 1 blocks. Either according to the results of comparisons or unconditionally, the execution instructions (addresses) are given immediately to the level 1 state machines ( 202 ,  FIG. 2   a ) concerned. 
         [0073]    The higher state machine ( 101 ) behaves in a similar way to a microprocessor, and could in fact be a microprocessor program if the latter is fast enough to process the information received rapidly. However, an adapted state machine will always offer better performance and be better integrated in that it enables parallel and simultaneous processing of the incoming data and gives instructions in parallel to the state machines of the level 1 blocks ( 201   2 ). 
         [0074]    In  FIG. 1   b  the ‘JN’ level 1 blocks ( 109  to  110 ) whose details are given in  FIG. 2  are grouped together ( 108 ). Each level 1 block includes the inputs coming from the other level 1 blocks that can be used selectively (by configuration from the state machine  101 ) for the calculations, and thus each level 1 block has ‘JM’ outputs (N 1 _ 1 _ 1  to N 1 _ 1 _JM for the block  109  up to N 1 _JN_ 1  to N 1 _JN_JM for the JN th  block  110 ) coming from its ‘JA’ cells (actively selected by the accumulator  204  in  FIG. 2   b ). Each level 1 block ( 109  to  110 ) also routes the outputs of the respective cells that form part of it (CELL_ 1 _ 1 _V to CELL_ 1 _JA_V for the block  109  up to CELL_JN_ 1 _V to CELL_JN_JA_V for the JN th  block  110 ), or, for example, for blocks each including ‘JA’ cells, although the blocks could all equally well include a different number of cells. 
         [0075]      FIGS. 2   a  to  2   c  illustrate in detail a level 1 block. A state machine ( 201 ) is incorporated in each level 1 block. That machine includes blocks of operations in memory ( 211 ). The various operations are transferred beforehand by the first state machine ( 101 ,  FIG. 1   a ) at initialization time or as and when required; thereafter the first state machine ( 101 ) gives the instructions to execute the various operations in unconditional manner of the instruction call type or conditionally on various results, in particular on the cells and the level 1 blocks. The operations effected as encoded in instructions of VLIW (very long instruction word) type. The VLIW encoding therefore includes the types of operations to be effected, the low level configuration (operators — FIG. 8 ) involved, the connections between the various elements, the configuration of the accumulators, the types of decisions (comparators in particular). The codes are intended for configuring the cells or the elements of the level 1 block including the process command block ( 203 ). As described hereinabove, the codes are either fixed or depend on instructions given by the higher state machine ( 101 ,  FIG. 1   a ) or other results incoming to the level 1 state machine ( 201 ) entering the comparators ( 212 ), in particular the cell output values (CELL_ 1 _V to CELL_JA_V), programmable counters coming from process commands  203  (by NPC_ 1 _CNT to NPC_IB_CNT and NPC_T_CNT) which are also programmed directly under the signal N 1 _RG determining the process command parameters by the block of configuration registers ( 202 ). Each instruction received from the higher state machine ( 101 ) or the comparators ( 212 ) commands an address or a sequence of addresses in the memories ( 211 ) containing a set of values transmitted by the selectors ( 213 ) including the data-addresses of registers on level 1 blocks including N 1 _RG and NST as well as on the cells of the block in particular CELL_ 1 _RG to CELL_JA_RD. Thus the level 1 state machine ( 201 ) configures and commands all operations of the level 1 block and the cells that form part of it, and does so dynamically as a function of preprogrammed commands or on the basis of the results obtained. 
         [0076]    The group configuration registers block ( 202 ) from  FIG. 2   a  supplies the operating parameters of the process command block  203 , i.e. the number ‘IB’ of programmable counters of the outputs NPC_ 1 _CNT to NPC_IB_CNT and NPC_T_CNT. The programming of these counters is effected by establishing the initial value (NPC_ 1 _VINI to NPC_IB_VINI and NPC_T_VINI), the final value (NPC_ 1 _VFIN to NPC_IB_VFIN and NPC_T_VFIN), and the increment (NPC_ 1 _VINC to NPC_IB_VINC and NPC_T_VINC). Synchronization is effected by four distinct signals namely reset to 0 (NPC_ 1 _R to NPC_IB_R and NPC_T_R), load values (NPC_ 1 _M to NPC_IB_M and NPC_T_M), counting direction (NPC_ 1 _DIR to NPC_IB_DIR and NPC_T_DIR) and activate count (NPC_ 1 _A to NPC_IB_A and NPC_T_A). Moreover the group configuration registers  202  determine the source values of the inputs A and B of the operators  208  ( 209 ,  210 , of which there are a number ‘IC’) by the signals COPR_SEL_ 1 _A and COPR_SEL_ 1 _B to COPR_SEL_IC_A and COPR_SEL_IC_B; the same applies to the ‘Pipeline’ commands of the operators at the same inputs via the signals COPR_SEL_ 1 _PL_A and COPR_SEL_ 1 _PL_B to COPR_SEL_IC_PL_A and COPR_SEL_IC_PL_B. The group configuration registers ( 202 ) provide direct values DVAL_ 1  to DVAL_IC available as and when required via one or the other operator input. The group configuration registers ( 202 ) determine over a given time period which cell will command the inputs of each operator (NCEL_OPR_ 1  to NCEL_OPR_IC), the outputs of the operators being independent of the inputs and in fact able to be associated dynamically with different cells at the input and at the output. Finally, the command of the accumulators of the group is determined on the registers ( 202 ) by the signal NACC_SEL which selects redirection and combination of the output values of the cells in additive manner or otherwise as required. 
         [0077]    The process command block  203  of  FIG. 2   b  constitutes the command of the processes by programmable counters on initial values, step, modulo, direction which can as required and selectively command the addresses, calculation factors or the indexing of the calculations of the cells, storage or direction of the results. The process command block  203  is shown in detail in  FIG. 4  and supplies ‘IB’ distinct count values on the signals NPC_ 1 _CNT to NPC_IB_CNT and NPC_T_CNT. 
         [0078]    The ‘JA’ cells  205  as such are summarily grouped in  FIG. 2   c  ( 206  to  207 ). The external data incoming to the cells is a choice between the data from registers of the state machine ( 201 ); the signals CELL_ 1 _RG to CELL_JA_RG); outputs of the level 1 block accumulators of the ‘JN’ level 1 blocks  108  (of the accumulator  204  of each level 1 block i.e.  109  to  110  on N 1 _ 1 _ 1  to N 1 _ 1 _JM for the level 1 block # 1  up to N 1 _JN_ 1  to N 1 _JN_JM for the level 1 block #JN); the selections of the operator inputs by the cells NCEL_OPR_ 1  to NCEL_OPR_IC The outputs of the cells are identified by the signals CELL_ 1 _V to CELL_JA_V. The cell block is shown in detail in  FIG. 3 . 
         [0079]    The elements  209  to  210  from  FIG. 2   c  constitute the operators  208 . These operators  208  constitute the core of the structure of the system. They are shown in detail in  FIG. 8 . The operator inputs are from diverse sources: either process command inputs from the source cell selected for each operator at a given time by the signals NCEL_OPR_ 1  to NCEL_OPR_IC selecting the selected cell process command signals for each operator at a given time in this instance (CPC_ 1 _CO_ 1 _CNT to CPC_IA_CO_ 1 _CNT) to (CPC_ 1 _CO_IC_CNT to CPC_IA_CO_IC_CNT) for ‘A’ command signals on IC operators activated on one cell at a time at a given time for each operator, level 1 block process command inputs (NPC_ 1 _CNT to NPC_IB_CNT), other operator outputs (OPR_ 1 _V to OPR_IC_V), cell input accumulators, also for each operator at a given time by the signals NCEL_OPR_ 1  to NCEL_OPR_IC selecting the selected cell accumulator input signals for each operator at a given time i.e. (CIN_ 1 _CO_V to CIN_ID_CO_ 1 _V) up to (CIN_ 1 _CO_IC_V to CIN_ID_CO_IC_V) or direct register values (DVAL_ 1  to DVAL_IC) supplied by the level 1 configuration registers ( 202 ). The selection of the ‘A’ operator inputs is determined by the signals COPR_SEL_ 1 _A to COPR_SEL_IC_A and the pipelines of the ‘A’ operator inputs is determined by the signals COPR_SEL_ 1 _PL_A to COPR_SEL_IC_PL_A, the selection of the ‘B’ operator inputs is determined by the signals COPR_SEL_ 1 _B to COPR_SEL_IC_B and the pipelines of the operator inputs ‘B’ are determined by the signals COPR_SEL_ 1 _PL_B to COPR_SEL_IC_PL_B; all of these command signals come from the Configuration Register Groups block  202 . 
         [0080]    The level 1 block accumulator ( 204 ) captures the outputs of each cell (CELL_ 1 _V to CELL_JA_V). 
         [0081]    The accumulator output redirection commands are determined by different signals selected by the state of the signal NACC_SEL coming from the configuration register block  202 . The accumulator output commands come from the choice (by NACC_SEL) of the synchronization counter NPC_T_CNT, the programmable state register NST coming from the level 1 state machine ( 201 ), or other sources. 
         [0082]    The level 1 accumulator is shown in detail in  FIG. 5 . There are ‘JM’ resulting outputs from the accumulator and they stem from programmed combination of the outputs of the cells of the level 1 block. 
         [0083]      FIGS. 3  ( 3   a ,  3   b ,  3   c ) illustrate in detail a typical cell. That is to say at the input of the cell  302 —input accumulator, routing the inputs of the cell to the operators. The input accumulator of cell  302  captures the outputs of the ‘JN’ level 1 blocks each on ‘JM’ outputs (N 1 _ 1 _ 1  to N 1 _ 1 _JM for the level 1 block # 1  up to N 1 _JN_ 1  to N 1 _JN_JM for the level 1 block #JN). The signal CACCIN_SEL_A comes from the configuration registers of the cell ( 301 ) and chooses ‘ID’ available signals from the incoming signals and makes them available to the operators (CIN_ 1 _V to CIN_ID_V). The input accumulators are shown in detail in  FIG. 7 . 
         [0084]    Like the level 1 blocks ( FIG. 2 ) the cells include process command cells ( 303 ) specific to each cell. The configuration registers of each cell ( 301 ) supply in particular the parameters of the process command block  303 , i.e. the number ‘IA’ of programmable counters of the outputs (CPC_ 1 _CNT to CPC_IA_CNT). The programming of these counters is effected by the configuration registers ( 301 ) by establishing the initial value (CPC_ 1 _VINI to CPC_IA_VINI), the final value (CPC_ 1 _VFIN to CPC_IA_VFIN), and the increment (CPC_ 1 _VINC to CPC_IA_VINC). The synchronization is effected by four separate signals i.e. reset to zero (CPC_ 1 _R to CPC_IA_R), load values (CPC_ 1 _M to CPC_IA_M), counting direction (CPC_ 1 _DIR to CPC_IA_DIR) and activate counting (CPC_ 1 _A to CPC_IA_A). 
         [0085]    The selectors of the operator inputs  305  to  306  of  FIG. 3   c  route the ‘IC’ operator inputs ( 307 ) that come from the cells, that is to say for the chosen cell in a given time for each operator: in this instance the signals coming from the process command cell  303  (described in detail with reference to  FIG. 6 ) of the cell CPC_ 1 _CNT to CPC_IA_CNT and the signals CIN_ 1 _V to CIN_ID_V coming from the input accumulators of the cell  302 . Note that the other operator inputs come from other resources including the groups and therefore do not pass through the selectors  305  to  306 . This selection operation is effected for each of the ‘IC’ operators, the passage to the operators is chosen by the signals NCEL_OPR_ 1  to NCEL_OPR_IC supplied by the configuration registers of the group ( 202  in  FIG. 2   a ), that is to say for each operator the value determining at a given time from which cell the cell level inputs come. First of all the outputs of the operator input selectors  305  to  306  i.e. CPC_ 1 _CO_ 1 _CNT to CPC_ 1 A_CO_ 1 _CNT up to CPC_ 1 _CO_IC_CNT to CPC_ 1 A_CO_IC_CNT for ‘IC’ operators. Then the outputs of the operator input selectors  305  to  306  i.e. CIN_ 1 _CO_ 1 _V to CIN_IA_CO_ 1 _V up to CIN_ 1 _CO_IC_V to CIN_ 1 A_CO_IC_V of a given cell correspond to the incoming signals CIN_ 1 _V to CIN_ 1 A_V from the cell routed to one or more operators always in accordance with the command inputs NCEL_OPR_ 1  to NCEL_OPR_IC. All these outputs of the operator input selectors  305  to  306  are active at a given time only for a given operator link selector i.e. on the cell chosen (respectively by NCEL_OPR_ 1  to NCEL_OPR_IC) at a given time for commanding that operator by the data that it routes there. The output of each cell from  FIG. 3  is determined by the output accumulator block  304 . The accumulator block  304  selects the output of the operator (OPR 11 —V to OPR_IC_V) that constitutes the effective output of the cell, the selection being effected by the signal CACCOUT_SEL that comes from the configuration register block  301 . In this instance an operator having an output assigned to a given cell output may equally well have its inputs coming from another cell. 
         [0086]      FIG. 4  illustrates in detail the process command module of the level 1 block ( 203 ) from  FIG. 2   b . Each level 1 block includes such a module which supplies global synchronization signals for the cells that it contains, in this instance ‘IB’ programmable counters ( 401  to  402 ) for managing progressive factorization data, addressing or operation loops. The synchronization signals are NPC_ 1 _CNT to NPC_IB_CNT and may be directed selectively and in any combination to the inputs of the various operators. Moreover a supplementary programmable counter ( 403 ) is used for timing the accumulators of the current level 1 block ( 204 ) in  FIG. 2   b , in particular enabling progressive selection of the cell outputs to various outputs of the level 1 block, which enables crossed calculations, for example, or matrix calculations. 
         [0087]    The various counters  401  to  403  of  FIG. 4  are programmed by the configuration registers ( 202 — FIG. 2   a ). Various values are established in these counters beforehand, as follows:
       The initial value (NPC_ 1 _VINI to NPC_IB_VINI and NPC_T_VINI), this data constitutes the starting value of the counter or the return value after a complete counting cycle.   The final value (NPC_ 1 _VFIN to NPC_IB_VFIN and NPC_T_VFIN), this data constitutes the end of counting cycle value from which a new cycle begins on the initial value.   The increment (NPC_ 1 _VINC to NPC_IB_VINC and NPC_T_VINC). This data constitutes the progression value of the counter either for incrementation or for decrementation according to the direction determined.       
 
         [0091]    Command and synchronization are effected by four separate signals i.e.:
       Reset to zero (NPC_ 1 _R to NPC_IB_R and NPC_T_R), on this signal the counter is set to zero and stops counting.   Load values (NPC_ 1 _M to NPC_IB_M and NPC_T_M), on this signal the counter loads the three values (initial, final, incrementation).   Counting direction (NPC_ 1 _DIR to NPC_IB_DIR and NPC_T_DIR). The counter progresses upward or downward by the given increment value.   Activate counting (NPC_ 1 _A to NPC_IB_A and NPC_T_A). Command to start the counter.       
 
         [0096]    These counter commands can be sent specifically to each counter or to a plurality of counters simultaneously, the configuration register  202  decoding a series of addresses corresponding to specific counters or to a set of counters. Thus, as may be required, all of the structure or a portion of the structure of a level 1 block may be synchronized precisely (the same applies to a plurality of level 1 blocks, by means of supplementary addressing). 
         [0097]      FIG. 5  shows the output accumulator of the level 1 block ( 204 ) from  FIG. 2   b . Overall, this circuit processes the data leaving the cells of each level 1 block. In fact each cell output is represented therein CELL_ 1 _V to CELL_JA_V for ‘JA’ cells in a given level 1 block. The cell values are added thereto in the adder block ( 501 ). The latter values are represented so as to be added globally but it is possible to introduce a selector controlled by a state machine that chooses the cells to be added, in which case a selector is introduced between the adder ( 501 ) and the cell outputs. The addition results are directed to flip-flops ( 505 ,  506 ) to be stored therein, the choice of the flip-flop that will store the addition value is effected on each clock cycle and may in particular be determined by the global counter NPC_T_CNT (block  403  from  FIG. 4 ) or by a state NST coming from the state machine of the level 1 block ( 201  in  FIG. 2   a ), the choice of the source signal determining the recording of one or the other flip-flop ( 505 ,  506 ) is effected by the signal NACC_SEL coming from the configuration register ( 202 — FIG. 2   a ). A multiplexer ( 502 )/decoder ( 504 ) pair is represented for choosing one and only one flip-flop for storing an addition to a cycle, but the multiplexer  502  and the decoder  504  could be replaced by a bit field each bit whereof would select which flip-flops (one or more) would store at a given time the values produced by the adder  501 . Finally, a second group of flip-flops ( 507 ,  508 ) loads the values of the first row of flip-flops, in the example this is effected at the end of a count of NPC_T_CNT on the NOR gate  503 , but could equally be a programmable and variable condition such as a combination of values of NPC_T_CNT, a state machine replacing the NOR gate  503 , a fixed value in particular. Thus ‘JM’ values are available cyclically at the outputs of the flip-flops  507 ,  508  for subsequent processing. 
         [0098]      FIG. 6  shows in detail a process command cell ( 303  in  FIG. 3   b ). Each cell contains a group of ‘IA’ counters the values whereof are available for synchronization, addressing memories, factorization on the various operators: in this instance ‘IA’ programmable counters ( 601  to  602 ) for managing progressive factorization data, addressing or operation loops. The synchronization signals are CPC_ 1 _CNT to CPC_IA_CNT and may be directed selectively and in any combination to the inputs of various operators. The various counters  601  to  602  from  FIG. 6  are programmed by the configuration registers ( 301 - FIG. 3   a ). Various values are established in these counters beforehand:
       The initial value (CPC_ 1 _VINI to CPC_IA_VINI), this data constitutes the counter starting value or return value after a complete counting cycle.   The final value (CPC  1 _VFIN to CPC_IA_VFIN), this data constitutes the end of counting cycle value from which a new cycle begins on the initial value.         
         [0101]    The increment (CPC_ 1 _VINC to CPC_IA_VINC). This data constitutes the progression value of the counter either for incrementation or for decrementation according to the direction determined. 
         [0102]    Command and synchronization are effected by four separate signals i.e.:
       Reset to zero (CPC_ 1 _R to CPC_IA_R), on this signal the counter is set to zero and stops counting.   Load values (CPC_ 1 _M to CPC_IA_M), on this signal the counter loads the three values (initial, final, incrementation).   Counting direction (CPC_ 1 _DIR to CPC_IA_DIR). The counter progresses upward or downward by the given increment value.   Activate counting (CPC_ 1 _A to CPC_IA A). Command for starting the counter.       
 
         [0107]    These counter commands can be sent specifically to each counter or to a plurality of counter simultaneously, the configuration register  301  decoding a series of addresses corresponding to specific counters or to a set of counters. Thus as may be required the structure or a portion of the structure of a cell may be synchronized precisely (the same applies to a plurality of cells, by means of supplementary addressing). 
         [0108]      FIG. 7  shows in detail the input accumulators of a cell ( 302  in  FIG. 3   a ). The input signals of the cell are in particular outputs of accumulators of level 1 blocks i.e. N 1 _ 1 _ 1  to N 1 _ 1 _JM for ‘JM’ outputs of the level 1 block # 1  up to N 1 _JN_ 1  to N 1 _JN_JM for ‘JM’ outputs of the level 1 block #JN. Another possible choice that may be added and is not represented in  FIG. 7  may also consist of the outputs from the other cells of a given level 1 block, for example the outputs of the ‘JA’ cells of the same level 1 block as the current cell i.e. the outputs CELL_ 1 _V to CELL_JA_V of the cells  1  to ‘JA’ of a given level 1 block. The selection of the inputs is effected by multiplexers  701 ,  702  in  FIG. 7  on the command CACCIN_SEL_A coming from the configuration registers ( 301 — FIG. 3   a ), thus there are ‘ID’ multiplexers the data supplied selectively to the cell is CIN_ 1 _V to CIN_ID_V and may be chosen on the various operators. 
         [0109]      FIG. 8  represents in detail the operator ( 209  to  210  in  FIG. 2   c ) dynamically assigned to a selected cell at a given time at its inputs. The operator is the resource at which the system data converges and is processed, and thus constitutes the operational core of the system. The operator has inputs and an output. An operator typically has two inputs like an adder arithmetic operator, multiplier on inputs A and B; like a logic operator on inputs A and B; like a non-linear operator, a comparator; like a storage operator on address/data inputs. The architecture of the system can nevertheless support a greater number of inputs if required, in particular data such as A and B, or commands (subtract/add, store—‘write memory’). 
         [0110]    The multiplexing modules  801  and  802  in  FIG. 8  effect the selection of the incoming data from the operator, two in the present example. Into these multiplexer modules  801  and  802  are introduced the values available for the operator, i.e. in particular:
       The counters CPC_ 1 _CNT to CPC_IA_CNT coming from the process command block of the cell ( 303  in  FIG. 3   b ) of a dynamically selected cell.   The counters NPC_ 1 _CNT to NPC_IB_CNT coming from the process command block of the level 1 block ( 203  in  FIG. 2   b ).   Outputs from other operators OPR_ 1 _V to OPR_IC_V coming from the operator blocks ( 209  to  210  in  FIG. 2   c ).   The input accumulator  302  in  FIG. 3   a  in detail in  FIG. 7  on the signals CIN_ 1 _V to CIN_ID_V. This accumulator processes data external to the selected cell i.e. in particular outputs of accumulators of level 1 blocks (N 1 _ 1 _ 1  to N 1 _ 1 _JM of the level 1 block # 1  to N 1 _JN_ 1  to N 1 _JN_JM of the level 1 block #JN) as indicated in  FIG. 7 , or otherwise outputs of other cells CELL_ 1 _V to CELL_JA_V of the same level 1 block, this latter case is not represented but is equally possible.   Direct data DVAL coming from configuration registers ( 202   FIG. 2   a ) available for each operator of cell selected as input.   Other inputs not represented: cyclic values in memory, external interface inputs (ports), etc.       
 
         [0117]    The selection on the multiplexing modules  801  and  802  in  FIG. 8  is effected by the signals COPR_SEL_A to COPR_SEL_B respectively for the inputs A and B, these selection signals coming from the group configuration module ( 202  in  FIG. 2   a ) on the signals COPR_SEL_ 1 _A to COPR_SEL_IC_A and COPR_SEL_ 1 _B to COPR_SEL_IC_B. Once the inputs of a given operator are chosen they must be synchronized appropriately. The ‘IC’ operators are interlinked, which implies that the calculations are effected over separate clock cycles, and it may therefore happen that on a given operator an input has passed through two operators for example (delay of two clock cycles) and that the other input has passed through four operators for example (delay of four clock cycles), in which case the first input is in advance by two clock cycles, now on the processing in the operation block ( 809  in  FIG. 8 ) that receives these two inputs, the latter must be coherent (on the same clock cycle), in the case of this example the first signal must be delayed by two clock cycles. The series of flip-flops ( 803 ,  805 ,  804 ,  806 ) adjust these clock cycles. Thus the delay of clock cycles or the adjustment of latency of the inputs of the operator is effected selectively on the choice of the output of the flip-flop by the multiplexers  807  and  808  from  FIG. 8 . In the example the first signal passes through three successive flip-flops and the second input passes through a single flip-flop. The command for selection of the delays on the multiplexers ( 807  which chooses on the series of flip-flops  803 - 805 ;  808  which chooses on the series of flip-flops  804 - 806 ) is respectively COPR_SEL_PL_A and COPR_SEL_PL_B, these commands coming from the cell configuration register block ( 301  in  FIG. 3   a ) on the signals COPR_SEL_ 1 _PL_A to COPR_SEL_IC_PL_A and COPR_SEL_ 1 _PL_B to COPR_SEL_IC_PL_B. 
         [0118]    In  FIG. 8  the function of the operator is finally effected by the module  809 . Depending on the implantation of the system, this operator is an arithmetic (fixed or floating point), logic or memory function; in particular and non-exhaustively:
       Arithmetic: adder/subtractor, multiplexer, divider, linear/non-linear function, incrementation/decrementation, etc.   Logic: comparator (equal to, greater than, less than, etc.), left-right shifter (barrel shifter), etc.   Memory: write/read, function table, etc.       
 
         [0122]    Thus on a given group of cells including a group of ‘IC’ operators, it could for example have two addition/subtraction operators, one multiplier, three addressable memories, one logic bit shifter, one non-linear function table, two comparators, etc. And as indicated hereinabove the operators may equally have more than two inputs as shown in the diagrams. The output of the operator is the signal OPR_V, on a cell we have OPR_ 1 _V to OPR_IC_V for a number ‘IC’ of operators. As indicated hereinabove these outputs are treated at the level of the level 1 blocks or can be redirected to other cells. Where appropriate operators could be intended in fixed manner for cells. 
         [0123]      FIG. 9  represents the cell output accumulator ( 304  in  FIG. 3   b ). 
         [0124]    In this module the output of an operator of a given cell is essentially chosen the operator the result whereof constitutes also the output of the cell. Thus on the multiplexer  901 , the ‘IC’ outputs of the ‘IC’ operators OPR_ 1 _V to OPR_IC_V; the selection command CACCOUT_SEL comes from the cell configuration register module ( 301  in  FIG. 3   a ).