Abstract: Provided is a technique for improving the transfer latency of vector register file data when an interrupt is generated. According to an aspect, when interrupt occurs, a core determines whether to store vector register file data currently being executed in a first memory or in a second memory based on whether or not the first memory can store the vector register file data therein. In response to not being able to store the vector register file data in the first memory, a data transfer unit, which is implemented as hardware, is provided to store vector register file data in the second memory.

Abstract: A technique for minimizing overhead caused by copying or moving a value from one cluster to another cluster is provided. A number of operations, for example, a mov operation for moving or copying a value from one cluster to another cluster and a normal operation may be executed concurrently. Accordingly, access to a register file outside of the cluster may be reduced and the performance of code may be improved.

Abstract: A virtual architecture generating apparatus and method, a runtime system, a multi-core system, and methods of operating the runtime system and the multi-core system may include analyzing a requirement of an application, a feature of the application, and a requirement of a system enabling an execution of the application, and include generating a virtual architecture corresponding to the application, based on a physical architecture of a reconfigurable processor, the analyzed requirements and the analyzed feature.

Abstract: Provided is a reconfigurable processor that may process a first type of operation in first mode using a first group of functional units, and process a second type of operation in second mode using a second group of functional units. The reconfigurable processor may selectively supply power to either the first group or the second group, in response to a mode-switch signal or a mode-switch instruction.

Abstract: An apparatus and method for dynamically determining the execution mode of a reconfigurable array are provided. Performance information of a loop may be obtained before and/or during the execution of the loop. The performance information may be used to determine whether to operate the apparatus in a very long instruction word (VLIW) mode or in a coarse grained array (CGA) mode.

Abstract: A reconfigurable processor which merges an inner loop and an outer loop which are included in a nested loop and allocates the merged loop to processing elements in parallel, thereby reducing processing time to process the nested loop. The reconfigurable processor may extract loop execution frequency information from the inner loop and the outer loop of the nested loop, and may merge the inner loop and the outer loop based on the extracted loop execution frequency information.

Abstract: Provided are a reconfigurable processor, which is capable of reducing the probability of an incorrect computation by analyzing the dependence between memory access instructions and allocating the memory access instructions between a plurality of processing elements (PEs) based on the results of the analysis, and a method of controlling the reconfigurable processor. The reconfigurable processor extracts an execution trace from simulation results, and analyzes the memory dependence between instructions included in different iterations based on parts of the execution trace of memory access instructions.

Abstract: A memory managing apparatus and method are provided. The memory managing apparatus may determine, based on a pointer indicator bit, the target memory area on which garbage collection is to be performed, and may perform the garbage collection on the target memory area. The memory managing apparatus may generate the pointer indicator bit and store the generated pointer indicator bit in a pointer field.

Abstract: An instruction compressing apparatus and method for a parallel processing computer such as a very long instruction word (VLIW) computer, are provided. The instruction compressing apparatus includes a bundle code generating unit, an instruction compressing unit, and an instruction converting unit. The bundle code generating unit may generate a bundle code in response to an input of instructions to be compressed. The bundle code may indicate whether a current instruction group is terminated, and also whether an instruction group following the current instruction group is a no-operation (NOP) instruction group. The instruction compressing unit may remove a NOP instruction and/or a NOP instruction group from the input instructions according to the generated bundle code. The instruction converting unit may include the generated bundle code in the remaining instructions which have not been removed by the instruction compressing unit.

Abstract: An apparatus and method for detecting software error are provided. Trace files are respectively generated by a target machine and a functional simulator that imitates the target machine and performs the same operation as the target machine. Each of the trace files may include at least one of a data-flow-type trace including execution information about one or more instructions and a control-flow-type trace representing information about a part in which a change in address indicating the position of an instruction is a predetermined threshold value or more when the instruction is executed. By comparing the generated trace files, software error may be detected.