Patent Document

BACKGROUND OF THE INVENTION 
     1. Technical Field 
     This disclosure concerns a system and method for parallelizing applications by using a software library of operators designed to implement detail parallelized computation plans. In particular, this disclosure relates to an efficient and cost effective way to implement parallelized applications. 
     2. Background Information 
     Currently a large disparity exists between the amount of data organizations need to process at any given time and the computing power available to the organization using single CPU (uniprocessors) systems. Today, organizations use applications that process terabytes and even petabytes of data in order to derive valuable information and business insight. Unfortunately, many of the applications typically run sequentially on uniprocessor machines, and require hours and even days of computation time to produce useable results. The gap between the amount of data that organizations must process and the computational performance of uniprocessors available to the organizations continues to widen. The amount of data collected and processed by organizations continues to grow exponentially. Organizations must address enterprise database growth rates of roughly 125% year over year or equivalent to doubling in size every 10 months. The volume of data for other data rich industries also continue to grow exponentially. For example, Astronomy has a data doubling rate of every 12 months, every 9 months for Bio-Sequences, and every 6 months for Functional Genomics. 
     Although storage capacity continues to grow at an exponential rate, the speed of uniprocessors no longer grows exponentially. Accordingly, even though organizations may have the ability to continue to increase data storage capacity, computational performance of uniprocessor configurations can no longer keep pace. Organizations must identify a technical solution to address the diverging trends of storage capacity and uniprocessors performance. 
     In order to process large amounts of data, applications need large amounts of computing power and high I/O throughput. Programmers face the technical challenges of identifying efficient ways to partition computational processing and coordinate computing across multiple CPUs to address the growing gap between the demand and supply of computing power. Given the reality of limited network bandwidth availability, programmers also face the technical challenge of addressing the large bandwidth requirements needed to deliver vast amounts of data to multiple CPUs performing parallel processing computations. Merely introducing an additional machine to a processing pool (configuration) does not increase the overall network bandwidth of the configuration. Although, the local disk I/O bandwidth may increase as a result. A network topology maybe represented as a tree that has many branches that represent network segments and leaves that represent processors. Accordingly, a single bottleneck along any one network segment may determine the overall network capacity and bandwidth of a configuration. In order to scale bandwidth, efficient use of local disk I/O bandwidth increases must be leveraged. 
     The extraordinary technical challenges associated with parallelizing computational operations include parallel programming complexity, adequate development and testing tools, network bandwidth scalability limits, the diverging trends of storage capacity and uniprocessors performance, and efficient partitioning of computational processing and coordination in multiprocessor configurations. 
     A need has long existed for a system and method that economically, efficiently implements parallel computing solutions and effectively relieves the burden of developing complex parallel programs by programmers. 
     SUMMARY 
     GridBatch provides an infrastructure framework that programmers can use to easily convert a high-level design into a parallelized computational implementation. The programmer analyzes the parallelization potential of computations in an application, decomposes the computations into discrete components and considers a data partitioning plan to achieve the highest performance. GridBatch implements the detailed parallelized computational plan developed by the programmer without requiring the programmer to create low level logic to carryout the execution of the computations. GridBatch provides a library of “operators” (a primitive for data set manipulation) as building blocks to implement the parallelization. GridBatch hides all the complexity associated with parallel programming in the GridBatch library so that the programmer only needs to understand how to apply the operators to correctly implement the parallelization. 
     Although GridBatch can support many types of applications, GridBatch provides a particular benefit to programmers focused on deploying analytics applications, because of the unique characteristics of analytics applications and the computational operators used by analytics applications. Programmers often write analytics applications to collect statistics from a large data set, such as how often a particular event occurs. The computational requirements of analytics applications often involve correlating data from two or more different data sets (e.g., the computational demands imposed by a table join expressed in a SQL statement). 
     GridBatch leverages data localization techniques to efficiently manage disk I/O and effectively scale system bandwidth requirements. In other words, GridBatch partitions computational processing and coordinates computing across multiple processors so that processors perform computations on local data. GridBatch minimizes the amounts of data transmitted to multiple processors to perform parallel processing computations. 
     GridBatch solves the technical problems associated with parallelizing computational operations by hiding parallel programming complexities, leveraging localized data to minimize network bandwidth requirements, and managing the partitioning of computational processing and coordination among multiprocessor configurations. 
     Other systems, methods, and features of the invention will be, or will become, apparent to one with skill in the art upon examination of the following figures and detailed description. It is intended that all such additional systems, methods, features and advantages be included within this description, be within the scope of the invention, and be protected by the following claims. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The disclosure can be better understood with reference to the following drawings and description. The components in the figures are not necessarily to scale, emphasis instead being placed upon illustrating the principles of the invention. Moreover, in the figures, like referenced numerals designate corresponding parts or elements throughout the different views. 
         FIG. 1  illustrates the GridBatch system configuration. 
         FIG. 2  shows an example Master Node. 
         FIG. 3  illustrates the GridBatch system configuration during the processing of a distribute function call. 
         FIG. 4  shows the GridBatch system configuration during the processing of a join function call. 
         FIG. 5  shows the GridBatch system configuration during the processing of a convolution function call. 
         FIG. 6  illustrates the GridBatch system configuration during the processing of a recurse function call. 
         FIG. 7  illustrates the logic flow the GridBatch system configuration may take to perform the distribute operator. 
         FIG. 8  shows the logic flow the GridBatch system configuration may take to perform the join operator. 
         FIG. 9  shows the logic flow the GridBatch system configuration may take to perform the Convolution operator. 
         FIG. 10  shows the logic flow the GridBatch system configuration may take to perform the recurse operator. 
         FIG. 11  illustrates GridBatch system configuration during the processing of a map function call. 
         FIG. 12  shows the logic flow GridBatch  100  may take to perform the map operator. 
     
    
    
     DETAILED DESCRIPTION 
     Earlier research on parallel computing focused on automatically detecting parallelism in a sequential application. For example, engineers developed techniques in computer architecture, such as out-of-order buffers, designed to detect dependencies among instructions and schedule independent instructions in parallel. Such techniques only examine code fragments coded in a sequential programming language and cannot exploit application-level parallelism. Accordingly, such techniques limit the amount of parallelism that can be exploited. 
     A large class of applications, in particular data-intensive batch applications, possess obvious parallelism at the data level. However, several technical challenges exist to implementing parallel applications. Programmers must address nontrivial issues relating to communications, coordination and synchronization between machines and processors when the programmers design a parallelized application. In stark contrast to sequential programs, programmers must anticipate all the possible interactions between all the machines in the configuration of a parallelized program, given the inherent asynchronous nature of parallel programs. Also, effective debugging tools for parallelized application and configuration development do not exist. For example, stepping through some code maybe difficult to perform in an environment where the configuration has many threads running on many machines. Also, because of the complex interactions that result in parallelized applications, programmers identify many of the bugs observed as transient in nature and difficult to reproduce. The technical challenges faced by programmers implementing parallelized applications translate directly into higher development costs and longer development cycles. In addition, often programmers cannot migrate or replicate a parallelized solution to other implementations. 
     Programmers recognize databases systems as well suited for the analytics applications. Unfortunately, database systems do not scale for large data sets for at least two reasons. First, databases systems present a high level SQL (Structured Query Language) with the goal of hiding the implementation details. Although SQL maybe relatively easy to use, the nature of such a high level language forces users to express computations in a way that results in processing that performs inefficiently from a parallelization perspective. In contrast to programming in a lower level language (e.g., C++) where the parallelized processing only reads a data set once, the same processing expressed in SQL may result in several reads being performed. Even though techniques have been developed to automatically optimize query processing, the performance realized by using a lower level language to implement a parallelized computation still far exceeds the performance of the higher level language such as SQL. Second, the I/O architecture of databases systems limits the scalability of distributed parallelized implementations because databases assume that data access to be via a common logical storage unit on the network, either through a distributed file system or SAN (storage area network) hardware. Databases do not leverage logical to physical mappings of data and therefore, do not take advantage of data locality or the physical location of data. Even though sophisticated caching mechanisms exist, databases often access data by traversing the network unnecessarily and consuming precious network bandwidth. 
     Analytics applications differ from web applications in several regards. Analytics applications typically process structured data, whereas, web applications frequently deal with unstructured data. Analytics applications often require cross referencing information from different sources (e.g., different database tables). Analytics applications typically focus on much fewer statistics than web applications. For example, a word counting application would require statistics for all words in a vocabulary, whereas, an analytics application may be only interested in the number of products sold. 
     GridBatch provides fundamental operators that may be employed for analytics or other applications. A detailed parallelized application implementation may be expressed as a combination of basic operators provided by GridBatch. GridBatch saves the programmer considerable time related to implementing and debugging because GridBatch addresses the parallel programming aspects for the programmer. Using GridBatch, the programmer determines the combination of operators desired, the sequence operators, and minimal programming to deploy each operator. 
     Although specific components of GridBatch will be described, methods, systems, and articles of manufacture consistent with GridBatch may include additional or different components. For example, a processor may be implemented as a microprocessor, microcontroller, application specific integrated circuit (ASIC), discrete logic, or a combination of other type of circuits or logic. Similarly, memories may be DRAM, SRAM, Flash or any other type of memory. Logic that implements the processing and programs described below may be stored (e.g., as computer executable instructions) on a computer readable medium such as an optical or magnetic disk or other memory. Alternatively or additionally, the logic may be realized in an electromagnetic or optical signal that may be transmitted between entities. Flags, data, databases, tables, and other data structures may be separately stored and managed, may be incorporated into a single memory or database, may be distributed, or may be logically and physically organized in many different ways. Programs may be parts of a single program, separate programs, or distributed across several memories and processors. Furthermore, the programs, or any portion of the programs, may instead be implemented in hardware. 
     One example is described below in which a web based retailer sells computer equipment such as PCs and printers. The retailer uses several tables requiring terabytes of storage to track volumes of data and information that can be used to derive analytics information using several tables including: transaction table; customer table; and distributor table. The transaction table stores the records for the product id of each item sold and the customer id of the purchaser. The customer table stores customer information for every customer, and the distributor table stores information regarding every distributor doing business with the retailer. The retailer may use GridBatch to analyze many analytics, some of the analytics include simple counting statistics (e.g., how many of a particular product have been sold and identify the top 10 revenue producing customers). The retailer may use GridBatch to analyze more complicated analytics that involve multiple tables and complex computations. For example, the retailer may use GridBatch to determine the number of customers located in geographical proximity to one of distribution facilities of the retailer in order to measure the efficiency of the distribution network. 
     The GridBatch infrastructure runs on a cluster of processing nodes (“nodes”). Two software components run in the GridBatch cluster environment named the file system manager and the job scheduler. The file system manager manages files and stores files across all computation nodes in the cluster. The file system manager may segment a large file into smaller chunks and store each chunk on separate nodes. Among all nodes in the cluster, GridBatch may designate, for example, one node to serve as the name node and all other nodes serve as data nodes. 
     A data node holds a chunk of a large file. In one implementation, depending on the number of nodes in the cluster and other configuration considerations, a data node may hold more than one chunk of a large file. A data node responds to client requests to read from and write to chunks assigned to the data node. The name node holds the name space for the file system. The name node maintains the mapping of a large file to the list of chunks, the data nodes assigned to each chunk, and the physical and logical location of each data node. The name node also responds to queries from clients request the location of a file and allocates chunks of large files to data nodes. In one implementation, GridBatch references nodes by the IP addresses of the nodes, so that GridBatch can access nodes directly. The master node also maintains a physical network topology which keeps track of which nodes are directly connected. The physical network topology may be populated manually by an administrator and/or discovered through an automated topology discovery algorithm. The network topology information may improve the performance of the recurse operator by indicating nearby neighbour slave nodes where intermediate results can be sent and/or retrieved in order to reduce network bandwidth consumption. A brief description of the topology and its use in facilitating execution of the recurse operator will be discussed below. 
     The GridBatch file system distributes large files across many nodes and informs the job scheduler of the location of each chunk so that the job scheduler can schedule tasks on the nodes that host the chunks to be processed. GridBatch targets large-scale data analysis problems, such as data warehousing, where a large amount of structured data needs to be processed. A file typically stores a large collection of data records that have identical schema (e.g., object owner, or structure, or family of objects). For structured data, GridBatch uses data partitioning to segment data into smaller pieces, similar to database partitioning. GridBatch file system stores files in a fixed number of chunks, each chunk having a chunk id (CID). A programmer may access any chunk, independent of other chunks in the file system. 
     In one implementation, the programmer may specify the number of chunks that GridBatch can assign. In another implementation, a GridBatch administrator specifies the number of chunks GridBatch can assign, and/or GridBatch determines the number of chunks GridBatch can assign based on the number of nodes available and/or other system configuration resource considerations. In one implementation, the GridBatch file system sets the highest assignable CID to be much larger than N, the number of nodes in the cluster. GridBatch employs a system level lookup table to prescribe the mapping from CID to N translation. The translation provides support for dynamic change of the cluster size such that when the configuration decommissions nodes and additional nodes join the cluster, the GridBatch file system can automatically re-balance the storage and workload. In other words, the file system maintains a mapping of CID to data node, and moves data automatically to different nodes when the CID to data node mapping changes (e.g., when a data nodes joins and/or leaves the GridBatch cluster  102 ). 
     In one implementation, GridBatch processes two kinds of data sets: vector and indexed vector. Similar to records of a database table, a vector includes a set of records that GridBatch considers to be independent of each other. The records in a vector may follow the same schema, and each record may include several fields (similar to database columns). In contrast to a vector, but similar to an indexed database table, each record in an indexed vector also has an associated index. For example, one of the fields of the record in the indexed vector could be the associated index of the indexed vector and the index can be of any data type (e.g., string or integer). 
     When using indexed vectors, the programmer defines how data should be partitioned across chunks through a partition function. When a new data record needs to be written, the file system calls the partition function to determine the chunk id and appends the new data record to the end of the chunk corresponding to the chunk id. In one implementation, the user-defined partition function takes the form: int[ ] partitionFunc (index X) where X represents the index for the record to be written and int[ ] indicates an array of integers. The partition function applies a hash function to convert the index into one or more integers in the range of 1 to CID that indicate the assigned chunk id(s) where the data record should be stored. In another implementation, the partition function may take the form: int[ ] partitionFunc (distributionkey X) where X represents the distribution key indicator for the record to be written to indicate a preferred processor and/or set of processors to use. When using vectors, the GridBatch file system may write each new record to a randomly chosen chunk. 
     In one implementation, when a user requests a new file for a new indexed vector to be created, the user provides the file system manager a user-defined hash function, which has the form of int[ ] hashFunc(distributionkey X). The hash function accepts a distribution key as input, and produces one or more integers in the range of 1 to CID. When a new record is written, the file system manager invokes the hash function to determine which partition to write the new record. As a result, GridBatch partitions the index vector as new records are processed by the file system manager. 
     The job scheduling system includes a master node and multiple slave nodes. The master node may use master node logic to implement the master node functionality. A slave node manages the execution of a task assigned to the slave node by the master node. The master node may use the master node logic to break down a job (e.g., a computation) into many smaller tasks as expressed in a program by a programmer. In one implementation, the master node logic distributes the tasks across the slave nodes in the cluster, and monitors the tasks to make sure all of the tasks complete successfully. In one implementation, GridBatch designates data nodes as slave nodes. Accordingly, when the master node schedules a task, the master node can schedule the task on the node that also holds the chunk of data to be processed. GridBatch increases computational performance by reducing network bandwidth dependencies because GridBatch minimizes data transfers and performs data processing on data local to the nodes. 
     GridBatch provides a set of commonly used primitives called operators that the programmer can use to implement computational parallelization. The operators handle the details of distributing the work to multiple nodes, thus the programmer avoids the burden of addressing the complex issues associated with implementing a parallel programming solution. The programmer introduces a set of operators into a program, in the same fashion as writing a traditional sequential program. 
     GridBatch provides five operators: distribute, join, convolution, recurse, map. The distribute operator converts a source vector or a source indexed vector to destination indexed vector with a destination index. The conversion involves transferring data from a source data node to a destination data node. The distribute operator takes the following form: Vector Distribute (vector V, Func newPartitionFunc) where V represents the vector where the data to be converted resides and newPartitionFunc represents the partition function that indicates the destination data node where GridBatch will generate a new vector. In one implementation, the user-defined partition function takes the form int[ ] newPartitionFunc(index X), where X represents the index of the record, and int[ ] denotes an array of integers. The user-defined partition function returns a list of numbers corresponding to the list of destination data nodes. In one implementation, the distribute operator may duplicate a vector on all nodes, so that each node has an exact copy for convenient local processing. Duplication of the vector on all nodes may result when the newPartitionFunc returns a list of all the data nodes as destination nodes. 
     The Join operator takes two indexed vectors and merges the corresponding records where the indexed field matches. GridBatch identifies the corresponding records that have a matching index and invokes a user-defined join function. The user-defined join function may simply merge the two records (e.g., similar to a database join), but generally may implement any desired function. The join operator takes the following form: Vector Join (Vector X, Vector Y, Func joinFunc) where X and Y represent the indexed vectors to be joined and joinFunc represents the user-defined join function to apply to the corresponding records in the indexed vectors. The join operator produces a new vector that includes the results of applying the user-defined function. The user-defined join function takes the following form: Record joinFunc (Record Z, Record K) where Z and K represent a record of vector X and Y, respectively. When GridBatch invokes the user-defined function, GridBatch may guarantee that the indexes for record Z and K match. 
     GridBatch may perform a distribute operation before performing the join operation so that GridBatch partitions vector X and Y using the partition function on the same index field that the Join will subsequently use. The join operator performs the join on each node locally without determining whether GridBatch has distributed or fetched data to each node. In one implementation, the join operator automatically performs the distribute operator before performing the join. 
     The join operator may be used when an exact match exists on the index field. However, when a programmer desires to identify the inverse result of the Join operator (e.g., identifying non-matching records), every record Z is checked against every record K. The convolution operator identifies matching Z and K records and applies a user-defined function to each match. The convolution operator provides additional capability and provides more computational options to the programmer. In one implementation, all the computational operations that involve two vectors can be accomplished through the convolution operator. The convolution operator can perform the join function on non-indexed vectors and indexed vectors using any vector field, even when the join uses a non-indexed field for the join. The convolution operator takes the following form: vector Convolution (vector X, vector Y, func convFunc) where X and Y represent the two input vectors, and convFunc represents the user-defined convolution function provided by the programmer. The convolution operator produces a new vector as a result. The user-defined function takes the following form: Record convFunc (record Z, record K) where Z and K represent a record of vector X and Y, respectively. The convFunc function determines whether any action should be taken (e.g., determines whether record Z matches record K) and then performs the corresponding action. 
     GridBatch may perform a Distribute operator before performing the convolution operator so that GridBatch partitions vector X and Y on the same index field that the convolution may subsequently use. The convolution operator performs the computation on each node locally without determining whether GridBatch has distributed or fetched data to each node. In other implementations, the convolution operator automatically performs the distribute operator before performing the convolution. 
     As one example, a programmer may desire to determine the number of customers located in close proximity to the distributors of a retailer. The GridBatch file system would generate a customer vector that includes a physical location field that indicates the physical location of each customer, and a distributor vector that includes a physical location field that indicates the physical location of each distributor. The programmer may use GridBatch to merge the customer vector and distributor vector based on the physical location field of both vectors. The programmer may use the convFunc to evaluate the physical distance between each customer and each distributor based on the proximity specified by the programmer, and store each record meeting the specified proximity in a results vector. 
     In one implementation, the GridBatch recurse operator performs a reduce operation, which takes all records of a vector and merges them into a single result. The actual logical operation performed on the records of the vector is defined by a user-specified function. Addition is an example of the reduce operation where all records of a vector are added together. Sorting another example of the reduce operation where all the records of a vector are checked against each other to produce a desired sequence. The recurse operator spreads the reduce operation across many nodes. Web applications often perform frequent reduce operations (e.g., word count, where each word requires a reduce operation to add up the number of appearances), in contrast to most analytics applications which perform few reduce operations. The reduce operator of most analytics applications becomes a bottleneck and limit the scalability of an application when a programmer merely needs sorted output for reporting or a few statistics. Many reduce operations exhibit commutative and associative properties, and may be performed order independently. 
     For example, counting the number of occurrences of an event involves the commutative and associative operator known as addition. The order in which the addition occurs does not affect the end result. Similarly, sorting may be order independent. GridBatch recurse operator performs order independent reduce operations and takes the following form: Record Recurse (Vector X, Func recurseFunc) where X represents the input vector to reduce and recurseFunc represents the user-defined recurse function to apply. The recurse operator merges the vector into a single record. The user-defined function recurseFunc takes the following form: Record recurseFunc (Record Z 1 , Record Z 2 ) where Z 1  and Z 2  represent partial results from merges of two subparts of vector X. The recurseFunc function specifies how to further merge the two partial results. 
     For example, where vector X represents a vector of integers and the programmer desires to compute the sum of the integers then the programmer will use the addition function as the user-defined recurseFunc function expressed: Record addition(Record Z 1 , Record Z 2 ) {return new Record(Z 1 .value( )+Z 2 .value( ));}. GridBatch will apply the addition function recursively over the records of vector X to eventually compute the sum total of the integers in the vector. 
     In another example, vector X includes records that represent sorted lists of strings and the programmer desires to sort the strings for final reporting. Table 1 illustrates how GridBatch may implement the user-defined function for sorting the strings. The user-defined function merges two sorted list of strings into one sorted string and when the programmer implements the user-defined function to be called recursively, the user-defined function implements the merge sort algorithm. 
     
       
         
               
             
               
               
             
           
               
                 TABLE 1 
               
               
                   
               
               
                 User-Defined Function for Sorting. 
               
               
                   
               
             
             
               
                   
               
             
          
           
               
                   
                 Record mergeSort (Record Z1, Record Z2) 
               
               
                   
                  { new Record Z; 
               
               
                   
                   // next string from record Z1 
               
               
                   
                   String a = Z1.next( ); 
               
               
                   
                   // next string from record Z2 
               
               
                   
                   String b = Z2.next( ); 
               
               
                   
                   do { 
               
               
                   
                    if ( a &lt; b ) { 
               
               
                   
                      Z.append(a); 
               
               
                   
                      a = Z1.next( ); 
               
               
                   
                    } 
               
               
                   
                    else { 
               
               
                   
                      Z.append(b); 
               
               
                   
                      b = Z2.next( ); 
               
               
                   
                    } 
               
               
                   
                  } while ( !Z1.empty ( ) &amp;&amp; 
               
               
                   
                       !Z2.empty( ) ) ; 
               
               
                   
                  return x; 
               
               
                   
                 } 
               
               
                   
                   
               
             
          
         
       
     
     Recurse parallelizes the reduce operation over many nodes. In addition, Recurse minimizes network traffic for operations that need partial results. For example, where a programmer needs to identify the top 10 revenue producing customers, each node computes the local top 10 customers and forwards the results (e.g., partial results) to neighbouring nodes that in turn merge the partial results with the local result of the receiving node to produce the top 10. Each node only passes the top 10 records to particular neighbouring nodes, rather than passing every record of each node to a single node performing the reduce operation. Accordingly, the recurse operator avoids large bandwidth requirements and undesired network traffic, and provides higher computational performance. 
     The map operator applies a user-defined map function to all records of a vector. The map operator takes the following form: Vector Map(vector V, Func mapFunc) where V represents the vector, more specifically the records of the vector, to which the mapFunc will be applied. The user-defined map function may take the following form: Record mapFunc(Record X). The user-defined function, mapFunc, accepts one record of the input vector as an argument and produces a new record for the result vector. 
     In one implementation, GridBatch tolerates slave node failures and errors by re-executing tasks when slave nodes fail to complete tasks. Each vector chunk of a vector is duplicated X times on X different slave nodes designated backup nodes, where X is a constant that may be specified by the user and/or determined by GridBatch based on the configuration, available resources and/or historical observations. During the computation of any operator, if a slave node fails before the slave node completes the assigned task, the master node is informed and the master node starts another process on a slave node that holds a backup copy of the vector chunk. The master node identifies a slave node as a failed slave node when the master node does not receive a periodic heartbeat from the slave node. 
       FIG. 1  illustrates the GridBatch system configuration  100  (GridBatch) that includes a GridBatch cluster  102 , an application  104  and user interface  106 . GridBatch  100  components communicate through a network  108  (e.g., the internet, a local area network, wide area network, or any other network). GridBatch cluster  102  includes multiple nodes (e.g., master node  116  and slave node  120 ). Each slave node  120  may include a communications interface  113  and memory  118 . GridBatch  100  designates a master node  116 , and the remaining nodes slave nodes (e.g., slave node  120 ). GridBatch  100  may designate slave nodes as data nodes (e.g., data node  134 ), described further below. The slave node  120  uses slave node logic  160  to manage the execution of slave tasks  158  assigned to the slave node  120  by the master node  116 . 
       FIG. 2  shows an example Master Node  116 . The master node  116  may include a communications interface  211  and memory  215 . GridBatch  100  uses file system manager logic  222  to manage and store files across all the nodes in GridBatch cluster  102 . In one implementation, the file system manager logic  222  segments a large file into smaller chunks and stores the chunks among slave nodes. The file system manager logic  222  maintains a mapping of CID to data node, and moves data automatically to different nodes when the CID to data node mapping changes (e.g., when a data nodes joins and/or leaves the GridBatch cluster  102 ). GridBatch  100  uses job scheduler logic  230  to coordinate operations between all the nodes in GridBatch cluster  102 . 
     Among all the nodes in GridBatch cluster  102 , GridBatch  100  may designate the master node  116  as the name node  232 , and designate all other nodes to serve as data nodes (e.g., data node  134 ). The name node  232  holds the name space  238  of the file system  240 . The name node  232  maintains the vector mappings  242  of files to the list of corresponding vector chunks, the data nodes assigned to each chunk, and the physical and logical location of each data node. The name node  232  also responds to task requests  244  for the location of a file. In one implementation, the name node  232  allocates chunks of large files to data nodes. 
     The master node  116  breaks down a task  252  (e.g., a computation) as expressed in a program by a programmer into slave tasks (e.g., slave task  158 ) that the job scheduler logic  230  distributes among the slave nodes. In one implementation, the master node  116  distributes the slave tasks across the slave nodes in GridBatch cluster  102 , and monitors the slave tasks to make sure all of the tasks complete successfully. Accordingly, when the master node  116  schedules a task  252 , the master node  116  can schedule the slave tasks (e.g., slave task  158 ) on the slave node that also holds the chunk of data to be processed. For example, the master node  116  may decompose the task  252  into slave tasks corresponding to slave nodes where the data to be processed resides locally in vector chunks, so that GridBatch  100  increases computational performance by reducing network bandwidth dependencies by minimizing data transfers and performing data processing on data local to the nodes. 
     In one implementation, GridBatch  100  implements master node logic  260  on the master node  116  that coordinates communication and interaction between GridBatch cluster  102 , the application  104  and user interface  106 . The master node logic  260  may coordinate and control the file system manager logic  222  and job schedule logic  230 . The master node logic  260  may maintain GridBatch software library  262  that includes the distribute operator logic  264 , join operator logic  266 , convolution operator logic  268 , recurse operator logic  270  and map operator logic  278 . The master node  116  may receive task requests  244  and coordinate the execution of the task requests  244  through the slave nodes and the slave node logic  160 . 
       FIG. 3  shows GridBatch  100  during the processing of a distribute function call  300  (e.g., task request  244 ) and exercise of the distribute operator logic  264 . In one implementation, the master node  116  receives the distribute function call  300  to perform the distribute operator with parameters that include a first vector identifier  272  that identifies a first vector to redistribute to obtain redistributed vector chunks redistributed among a set of nodes. For example, the first vector may represent a previously distributed vector with distributed vector chunks V 1 C 1   308 , V 1 C 2   310 , and V 1 C 3   312  among a set of nodes (e.g., slave node  1   328 , slave node  3   330 , and slave node  6   332 , respectively). The vector chunks V 1 C 1   308 , V 1 C 2   310 , and V 1 C 3   312  include corresponding vector chunk records V 1 C 1 R 1 -V 1 C 1 RX  322 , V 1 C 2 R 1 -V 1 C 2 RY  324  and V 1 C 3 R 1 -V 1 C 3 RZ  326 , respectively. 
     The master node logic  260  initiates execution of a partition function by spawning partitioning tasks  334  on each set of nodes (e.g., slave node  1   328 , slave node  3   330 , and slave node  6   332 , respectively) With first vector chunks. The arrow  336  represents a transition to a node state where each node with first vector chunks runs partitioning tasks  334 . The records of each vector chunk V 1 C 1   308 , V 1 C 2   310  and V 1 C 3   312  of the first vector chunk may be evaluated by corresponding partitioning tasks  334  to determine destination vector chunk assignments. For example, each partitioning task  334  may evaluate the first vector chunk records residing on the corresponding slave node to determine a destination vector chunk location to redistribute each first vector chunk record. Each partitioning task  334  may create destination vector chunk assignment files (e.g., V 1 C 1 F 1   338 , V 1 C 2 F 1 -V 1 C 2 F 4 -V 1 C 2 F 3 -V 1 C 2 F 6   340  and V 1 C 3 F 1 -V 1 C 3 F 2 -V 1 C 3 F 5 -V 1 C 3 F 6   342 ) on the corresponding slave node for each destination vector chunk location (e.g., destination vector chunk assignment) where the first vector chunk records will be redistribute. 
     The master node  116  may receive task completion notifications from each partitioning task  334  as each partitioning task  334  completes. The master node  116  initiates execution of a redistribution task by spawning redistribution tasks  344  on each slave node (e.g., slave node  1   328 , slave node  3   330 , slave node  4   346 , slave node  5   348 , slave node  6   332  and slave node  8   350 ). The arrow  346  represents a transition to a node state in which each node corresponding to destination vector chunks run redistribution tasks  344 . The destination vector chunks (e.g., V 1 C 1   352 , V 1 C 2   354 , V 1 C 3   356 , V 1 C 4   358 , V 1 C 5   360  and V 1 C 6   362 ) indicated by the vector chunk locations identified by the vector chunk assignment files (e.g., V 1 C 1 F 1   338 , V 1 C 2 F 1 -V 1 C 2 F 4 -V 1 C 2 F 3 -V 1 C 2 F 6   340  and V 1 C 3 F 1 -V 1 C 3 F 2 -V 1 C 3 F 5 -V 1 C 3 F 6   342 ). The redistribution tasks  344  initiate the remote copying of the vector chunk assignment files to the corresponding destination slave nodes to collocate the vector chunk assignment files on the slave node corresponding to the vector chunk assigned to the slave node (e.g., V 1 C 1 F 1 -V 1 C 3 F 1 -V 1 C 2 F 1   364 , V 1 C 3 F 2   368 , V 1 C 2 F 3   370 , V 1 C 2 F 4   372 , V 1 C 3 F 5   374 , and V 1 C 3 F 6 -V 1 C 3 F 6   376 ). 
     The redistribution tasks  344  initiates a merge  378  of the records (e.g., V 1 C 1 R 1 -V 1 C 1 RX  382 , V 1 C 2 R 1 -V 1 C 2 RY  384 , V 1 C 3 R 1 -V 1 C 3 RZ  386 , V 1 C 4 R 1 -V 1 C 4 RQ  388 , V 1 C 5 R 1 -V 1 C 5 RS  390  and V 1 C 6 R 1 -V 1 C 6 RT  392 ) located in each vector chunk assignment file corresponding to a particular destination vector chunk. The arrow  380  represents a transition to a node state in which each node corresponding to destination vector chunks perform the merge  378 . The merge  378  results in the redistributed vector chunks of the first vector redistributed among the set of nodes. The slave node logic  160  of each slave node sends the master node  116  a completion notice that indicates the completion status of the merge  378 . 
       FIG. 4  shows GridBatch  100  during the processing of a join function call  400  (e.g., task request  244 ) and exercise of the join operator logic  266 . In one implementation, the master node  116  receives the join function call  400  with parameters that include the first vector identifier  272  and a second vector identifier  274 , and a user-defined join function (e.g., a user-defined function  276 ). The first vector identifier  272  and a second vector identifier  274  identify the first vector and a second vector partitioned into first vector chunks (e.g., V 1 C 1   404 , V 1 C 2   406  and V 1 C 3   408 ) and second vector chunks (e.g., V 2 C 1   410 , V 2 C 2   412  and V 2 C 3   414 ). The first vector chunks and second vector chunks include first vector chunk records (e.g., V 1 C 1 R 1 -V 1 C 1 RZ  416 , V 1 C 2 R 8 -V 1 C 2 RJ  418  and V 1 C 3 R 4 -V 1 C 3 RL  420 ) and second vector chunk records (e.g., V 2 C 1 R 3 -V 2 C 1 RY  422 , V 2 C 2 R 7 -V 2 C 2 RK  424  and V 2 C 3 R 4 -V 2 C 3 RM  426 ), respectively. 
     The master node  116  initiates spawning of sorting tasks (e.g., slave tasks  158 ) locally on the set of nodes (e.g., slave node  1   428 , slave node  4   430  and slave node  6   432 ) corresponding to the location of the first vector chunks and second vector chunks to sort each of the first vector chunks and second vector chunks for the second vector located on each of the set of nodes. In one implementation, the sorting task  434  sorts the first vector records and the second vector records according to an index value of the join index field present in each first vector record of the first vector (e.g., V 1 C 1 R 1 IF-V 1 C 1 RZIF  438 , V 1 C 2 R 81 F-V 1 C 2 RJIF  440  and V 1 C 3 R 41 F-V 1 C 3 RLIF  442 ) and each second vector record of the second vector (e.g., V 2 C 1 R 3 IF-V 2 C 1 RYIF  444 , V 2 C 2 R 7 -V 2 C 2 RKIF  446  and V 2 C 3 R 4 -V 2 C 3 RMIF  448 ), respectively. The arrow  436  represents a transition to a node state in which each node with vector chunks runs sorting tasks  434 . 
     In one implementation, the sorting task  434  compares the index value of the index field present in the first vector records and the second vector records to determine first vector records and second vector records that include matching index values and apply the user-defined function  276  (e.g., a user-defined join function) to first vector records and second vector records with matching index field values. The sorting task  434  performs a matching task  450  which compares the index field values of the index fields of the first vector records and second vector records. The arrow  452  represents a transition to a node state in which each node with vector chunks run matching tasks  450 . The matching task  450  applies the user-defined function  276  (e.g., a user-defined join function) to first vector records and second vector records with matching index field values for corresponding vector chunks (e.g., V 1 C 2 RBIF  454  and V 2 C 2 RPIF  456 , and V 1 C 2 RBIF  458  and V 2 C 2 RPIF  460 ) to obtain a join function chunk result (e.g., “NO JFC 1 R”  462 , JFC 2 R  464  and JFC 3 R  466 ). The matching task  450  does not apply the user-defined join function to first vector records and second vector records when the index field values for corresponding vector chunks do not match (e.g., V 1 C 1 RXIF  468  and V 2 C 1 RYIF  470 ). 
     The join function chunk results form a join function vector result that identify join function vector chunks (e.g., JFVC 1   476  and JFVC 2   478 ) that include join function vector chunk records (JFVC 1 RT  480  and JFVC 2 R 3 -JFVC 2 RN  482 ) obtained from the join function chunk results (e.g., JFC 2 R  464  and JFC 3 R  466 ). In one implementation, the slave node logic  160  of each slave node sends the master node  116  a completion notice that indicates that the completion status of the sorting task  434 . 
     For example, in one implementation, a programmer may use GridBatch  100  to index two vectors, a product vector (e.g., first vector identified by the first vector identifier  272 ) indexed by a product id field (e.g., index fields V 1 C 1 R 1 IF-V 1 C 1 RZIF  438 , V 1 C 2 R 81 F-V 1 C 2 RJIF  440  and V 1 C 3 R 41 F-V 1 C 3 RLIF  442 ) and the customer vector (e.g., second vector identified by the second vector identifier  274 ) indexed by customer id field (e.g., index fields V 2 C 1 R 3 IF-V 2 C 1 RYIF  444 , V 2 C 2 R 7 -V 2 C 2 RKIF  446  and V 2 C 3 R 4 -V 2 C 3 RMIF  448 ). The product vector includes the product id and the customer id corresponding to the products purchased (e.g., index field values). The customer vector holds the customer id and the demographic information of the customers (e.g., index field values such as age, address, gender). In the event the programmer desires to know how many people in each age group purchased a particular product, the programmer invokes a join function call with the product vector and the customer vector as parameters to obtain a join result that links the product ID information with the customer demographic information. In one implementation, in order to ensure the highest performance by GridBatch  100  in processing the join function call  400  of the product vector and the customer vector based on the customer id field (e.g., index field), the programmer invokes the distribute function call  300  to index the product vector by the customer id instead of the product id. The distribute function call ensures that GridBatch  100  distributes the records of the product vector to the nodes in GridBatch cluster  102  according to the customer id field. GridBatch  100  then may apply the user-defined function  276  (e.g., a user-defined join function) to each record of the product vector and the customer vector where the customer id field values of both product vector and the customer vector equal to obtain the join function vector result. 
       FIG. 5  shows GridBatch  100  during the processing of a convolution function call  500  (e.g., task request  244 ) and exercise of the convolution operator logic  268 . In one implementation, the master node  116  receives the convolution function call  500  with parameters that include the first vector identifier  272  and the second vector identifier  274 , and a user-defined convolution function (e.g., a user-defined function  276 ). The first vector identifier  272  and a second vector identifier  274  identify the first vector and a second vector partitioned into first vector chunks (e.g., V 1 C 1   504  and V 1 C 2   506 ) and second vector chunks (e.g., V 2 C 1   508  and V 2 C 2   510 ) correspond to partitioned vector chunks distributed across the nodes of GridBatch cluster  102 . The first vector chunks and second vector chunks include first vector chunk records (e.g., V 1 C 1 R 1 -V 1 C 1 RZ  512  and V 1 C 3 R 4 -V 1 C 3 RL  514 ) and second vector chunk records (e.g., V 2 C 1 R 3 -V 2 C 1 RY  516  and V 2 C 3 R 4 -V 2 C 3 RM  518 ), respectively. 
     The master node  116  initiates spawning of convolution tasks (e.g., slave tasks  158 ) locally on the set of nodes (e.g., slave node  1   520  and slave node  8   522 ) corresponding to the location of the first vector chunks and second vector chunks. The arrow  526  represents a transition to a node state for each node where the master node  116  spawns the convolution tasks  524 . The convolution tasks  524  apply the user-defined function  276  (e.g., a user-defined convolution function) locally to the permutations of first vector chunk records and second vector chunk records (e.g.,  528  and  530 ). The user-defined convolution function evaluates each permutation of corresponding first vector chunk records and second vector chunk records (e.g.,  528  and  530 ) to obtain convolution function evaluation results (e.g.,  536 ,  538 ,  540  and  542 ). The arrow  534  represents a transition to a node state for each node where the user-defined convolution function evaluates each permutation of corresponding first vector chunk records and second vector chunk records. The convolution function evaluation results may indicate when a permutation of the corresponding first vector chunk records and second vector chunk records results in a convolution function chunk result records (e.g., CFC 1 R 1 -CFC 1 R 3 -CFC 1 R 4 -CFC 1 RZ  536  and CFC 2 R 3 -CFC 2 RK  540 ). The convolution function evaluation results may indicate when a permutation of the corresponding first vector chunk records and second vector chunk records results in no convolution function chunk result records (e.g., “NO CFC 1 RX”  538  and “NO CFC 2 RY”  542 ). The user-defined convolution function may transform the convolution function results into convolution function chunk result records (e.g., CFVC 1 R 1 -CFVC 1 R 3 -CFVC 1 R 4 -CFVC 1 RZ  548  and CFVC 2 R 3 -CFVC 2 RK  550 ) to obtain convolution function results for each node (e.g., slave node  1   520  and slave node  8   522 ). 
     For example, in one implementation, a programmer may invoke the convolution function call  500  to determine the number of customers located in close proximity to the distributors of a retailer. The file system manager logic  222  may include a customer vector (e.g., first vector identified by the first vector identifier  272 ) that includes a physical location field that indicates the physical location of each customer and a distributor vector (e.g., second vector identified by the second vector identifier  274 ) that includes a physical location field that indicates the physical location of each distributor. The programmer may invoke the convolution function call  500  to apply a user-defined convolution function (e.g., user-defined function  276 ) to the customer vector and distributor vector based on the physical location field to evaluate the physical distance between each customer and each distributor and obtain a convolution function results vector. In one implementation, the user-defined convolution function may be expressed as convFunc. Before the convolution call, the customer vector may be partitioned into customer vector chunks (e.g., first vector chunks—V 1 C 1   504  and V 1 C 2   506 ) partitioned across the nodes of GridBatch cluster  102  according to the physical location field (e.g., index field) present in each of the customer vector records. The distributor vector chunks (e.g., second vector chunks—V 2 C 1   508  and V 2 C 2   510 ) may be copied to all nodes of the cluster. This can be achieved by supplying a partition function which always returns a list of all nodes to the distribute operator. The user-defined convolution function evaluates the permutations of customer vector records and the distributor vector records residing on corresponding slave nodes, to obtain convolution function chunk results records. In other words, where the customer vector chunk has Z number of records and the distributor vector chunk has K number of records, the user-defined convolution function may evaluate Z×K number of permutations where for each record  1  through Z of the customer vector chunk GridBatch  100  applies the user-defined convolution function to every record  1  though K of the distributor vector chunk. The result of the convolution function call performed by each slave node of GridBatch cluster  102  results in corresponding convolution function vector chunks to obtain convolution function results for each node (e.g., slave node  1   520  and slave node  8   522 ). 
       FIG. 6  illustrates GridBatch  100  during the processing of a recurse function call  600  (e.g., task request  244 ) and exercise of the recurse operator logic  270 . In one implementation, the master node  116  receives the recurse function call  600  with parameters that include the first vector identifier  272  and a user-defined recurse function (e.g., a user-defined function  276 ). The first vector identifier  272  identifies the first vector partitioned into first vector chunks (e.g., V 1 C 1   604 , V 1 C 2   606  and V 1 C 3   610 ) corresponding to partitioned vector chunks distributed across the nodes of GridBatch cluster  102 . The first vector chunks include first vector chunk records (e.g., V 1 C 1 R 1 -V 1 C 1 RX  616 , V 1 C 1 R 3 -V 1 C 1 RJ  618 , V 1 C 2 R 1 -V 1 C 2 RY  620 , V 1 C 2 RK-V 1 C 2 RN  622 , V 1 C 3 R 4 -V 1 C 3 RZ  624  and V 1 C 3 RG-V 1 C 3 RM  626 ). 
     The master node  116  initiates spawning of recurse tasks  634  (e.g., slave tasks  158 ) locally on the set of nodes (e.g., slave node  1   628 , slave node  4   630  and slave node  6   632 ) corresponding to the location of the first vector chunks. The arrow  636  represents a transition to a node state in which each node with first vector chunks run the recurse tasks  634 . The recurse tasks  634  initially apply the user-defined recurse function to the first vector chunk records to produce intermediate recurse vector chunk results for each first vector chunks (e.g., IRV 1 C 1 R 1   638 , IRV 1 C 1 R 2   640 , IRV 1 C 2 R 1   642 , IRV 1 C 2 R 2   644 , IRV 1 C 3 R 1   646  and IRV 1 C 3 R 2   648 ). The recurse tasks invoke the user-defined recurse function on the intermediate recurse vector chunk results to produce intermediate recurse slave node results (e.g., IRSN 1 R  650 , IRSN 4 R  652  and IRSN 6 R  654 ). 
     The recurse tasks communicate a subset of the intermediate recurse slave node results (e.g., IRSN 1 R  650 ) to a subset of the set of nodes (e.g., slave node  4   630 ) and the recurse tasks iterate invocation of the user-defined recurse function on the intermediate results (e.g., IRSN 1 R  650  and IRSN 4 R  652 ) to produce increasingly fewer intermediate slave node results (e.g., IFIRSN 4 R  660 ). The recurse tasks communicate a subset of the increasingly fewer intermediate results (e.g., IFIRSN 4 R  660 ) to an increasingly smaller subset of the set of nodes (e.g., slave node  6   632 ) until GridBatch  100  obtains a final recurse result (e.g., FRR  668 ) on a final node in the set of nodes. 
     In one implementation, a subset of the intermediate results communicated by the recurse tasks to a subset of the set of nodes includes one-half of the intermediate results that produce a subset of increasingly fewer intermediate results. Similarly, each subset of increasingly fewer intermediate results subsequently communicated by the recurse tasks to a subset of the set of nodes includes one-half of the increasingly fewer intermediate results. In one implementation, the recurse operator logic  270  uses network topology information to improve computation performance of the recurse operator by identifying nearby neighbour slave nodes where intermediate results can be sent and/or retrieved in order to reduce network bandwidth consumption. The programmer, user and/or GridBatch  100  may define the factors that determine whether a slave node constitutes a nearby neighbour slave node to another slave node. The factors that may be used to determine whether a slave node is designated a nearby neighbour slave node may include data transmission times between slave nodes, the number of network hops (e.g., number of network routers) between slave nodes, or a combination of data transmission times and network hops. 
       FIG. 6  illustrates how the GridBatch recurse operator logic  270  distributes intermediate results among slave nodes of GridBatch cluster  102 . The slave nodes may compute a local intermediate recurse result (e.g., IRSN 1 R  650 , IRSN 4 R  652  and IRSN 6 R  654 ). A subset of the slave nodes (e.g., slave node  1   628 ) may transmit the local intermediate recurse result (e.g., IRSN 1 R  650 ) to a subset of the slave nodes (e.g., slave node  4   630 ). The slave nodes receiving intermediate recurse results from other slave nodes may iteratively apply the transmitted intermediate results (e.g., IRSN 1 R  650 ) with the local intermediate results (e.g., IRSN 4 R  652 ). Iteratively, until a single slave node (e.g., slave node  6   632 ) produces the final recurse result (e.g., FRR  668 ), a subset (e.g., one-half) of the slave nodes transmit intermediate results to the other one-half of nodes with local intermediate results (e.g., folding transmitted intermediate results into local intermediate results). In one implementation, the master node determines the scheme for passing intermediate results to slave nodes in the set of nodes and the number of folding iterations required to produce a final recurse result (e.g., FRR  668 ). 
       FIG. 7  illustrates the logic flow GridBatch  100  may take to perform the distribute operator. In one implementation, the master node  116  receives the distribute function call  300  to perform the distribute operator. In one implementation, the distribute function call  300  may be expressed as Distribute (vector V, func newPartitionfunc). Vector V represents the source vector and the newPartitionfunc represents a function that determines the location of new nodes for data in vector V.  FIG. 7  and the discussion here uses vector U as a notational aid to explain the redistribution of the data in vector V. Vector V contains the same data as vector U. The distribute function call  300  results in one vector remaining, possibly partitioned into new chunks that may be redistributed to a different set of nodes. The master node logic  260  spawns a slave task (e.g., slave task  158 ) corresponding to each vector chunk of vector V ( 702 ). In one implementation, the number of slave tasks equal the number of vector chunks of vector V. The slave tasks reside on the slave nodes where corresponding vector chunks reside ( 704 ). Localizing the slave tasks to slave nodes where corresponding vector chunks reside minimizes data transfer and avoids network bandwidth scaling issues. Slave nodes invoke slave node logic  212  to generate output files corresponding to vector chunks of vector U where GridBatch  100  will redistribute records of vector V ( 706 ). The slave node logic  160  evaluates each record of the corresponding vector chunk of V to determine the chunk identifier of vector U where GridBatch  100  will redistribute the record. The slave node logic  160  writes the record to the output file corresponding to the vector chunk of vector U where GridBatch  100  will redistribute the record of vector V. 
     As each slave task completes evaluation of the records of the corresponding vector chunks of V, each slave task notifies the master node logic  260  of the completion status of the slave task and the location of the output files corresponding to the vector chunks of vector U ( 708 ). The master node logic  260  spawns new slave tasks on slave nodes where GridBatch  100  will redistribute vector chunks of vector V to vector chunks of vector U ( 710 ). Each slave task receives a list of the locations of output files that include vector chunks of U that correspond to the slave node corresponding to the slave task and retrieves the output files to the slave node (e.g., using a remote copy operation, or other file transfer). Each slave task merges the output files into corresponding vector chunks of U and notifies the master node logic  260  of the completion status of the slave task ( 712 ). In one implementation, the distribute function call  300  distributes all records of the first vector to all the available slave nodes. For example, the newPartitionfunc of the distribute function call  300  expressed as Distribute (vector V, func newPartitionfunc) may direct GridBatch  100  to distribute each record of vector V to all of the available slave nodes to duplicate vector V on all the available slave nodes. 
       FIG. 8  shows the logic flow GridBatch  100  may take to perform the join operator. In one implementation, the master node logic  260  receives the join function call  400  to join vector X and vector Y. In one implementation, the join function call  400  may be expressed as Vector Join (vector X, vector Y, Func joinFunc) ( 802 ). The master node logic  260  spawns a slave task corresponding to a vector chunk number (e.g., vector chunk id), where the file system manager logic  222  partitions vector X and vector Y into an equal number of vector chunks and the file system manager logic  222  assigns vector chunks of X and vector chunks of Y with corresponding chunk numbers or vector chunk ids ( 804 ). For example, the file system manager logic  222  may assign a particular chunk id to both a vector chunk of X and a vector chunk of Y residing on a corresponding slave node. In one implementation, the slave task sorts, according to an indexed field value, the records of the vector chunk of X and records of vector chunk of Y residing on the corresponding slave node ( 806 ). The slave task invokes slave node logic  160  and evaluates the indexed field value of the records of the vector chunk of X and records of vector chunk of Y. Where the indexed field values of the records of the vector chunk of X and records of vector chunk of Y equal ( 808 ), GridBatch  100  invokes a user-defined join function (e.g., user-defined function  276 ). In one implementation, the user-defined join function may be expressed as Record joinFunc (Record Z, Record K) that joins the records of the vector chunk of X and records of vector chunk of Y ( 814 ). Where the slave node logic  160  evaluates the indexed field value of record Z of vector chunk X to be less than the indexed field value of record K of vector chunk of Y then the slave node logic  160  evaluates the next record Z of vector chunk of X with the indexed field value of record K of vector chunk of Y ( 810 ). Where the slave node logic  160  evaluates the indexed field value of record Z of vector chunk X to be greater than the indexed field value of record K of vector chunk of Y then the slave node logic  160  evaluates the next record K of vector chunk of Y with the indexed field value of record Z of vector chunk of X ( 812 ). The slave node logic  160  evaluates every record Z of vector chunk of X and record K of vector chunk of Y ( 816 ). 
       FIG. 9  shows the logic flow GridBatch  100  may take to perform the convolution operator. In one implementation, the master node logic  260  receives the convolution function call  500  to process vector X and vector Y ( 902 ). In one implementation, the convolution function call  500  may be expressed as Vector Convolution (vector X, vector Y, Func convFunc), where convFunc is the user-specified convolution function. For each record  1  to Z of the vector chunks of vector X the master node logic  260  applies a user-defined convolution function (e.g., user-defined function  276 ), expressed as Record convFunc (Record Z, Record K) to records  1  to K of vector chunks of vector Y ( 904 ). In other words, where a vector chunk of vector X has Z number of records and a vector chunk of vector Y has K number of records, the user-defined convolution function evaluates Z×K number of permutations of record pairs. The slave node logic  160  applies the user-defined convolution function to each record  1  though K of the vector Y ( 906 ) with every record  1  through Z of the vector chunk X ( 908 ). 
       FIG. 10  shows the logic flow GridBatch  100  may take to perform the recurse operator. In one implementation, the master node logic  260  receives the recurse function call  600  to recurse vector X. In one implementation, the recurse function call  600  may be expressed as Record Recurse (vector X, Func recurseFunc). The master node logic  260  spawns recurse operation slave tasks corresponding to each vector chunk residing on corresponding slave nodes ( 1002 ). Slave tasks invoke slave node logic  160  to reduce (e.g., merge) the first record and the second records of vector chunk of vector X residing on corresponding slave nodes. The slave node logic  160  stores the intermediate recurse (e.g., merger) result ( 1004 ). The slave node logic  160  evaluates whether more records of vector chunk of vector X exist ( 1006 ) and merges the next record of vector chunk of vector X to the intermediate merge result ( 1008 ). Once the slave node logic  160  obtains the intermediate merge result of the vector chunks of vector X, each slave task notifies the master node logic  260  of the completion status of the slave task ( 1010 ). A subset of slave tasks (e.g., one-half) send intermediate merge results to the remaining slave tasks (e.g., the other one-half) with local intermediate results. The subset of slave tasks receiving the intermediate merge results merge the intermediate merge tasks with local intermediate merge results ( 1012 ). The slave nodes with intermediate merge results iteratively fold the intermediate merge results into fewer slave nodes, until the slave nodes merge the increasingly smaller number of intermediate merge results into a final merge result residing on one slave node ( 1014 ). 
       FIG. 11  illustrates GridBatch  100  during the processing of a map function call  1100  (e.g., task request  244 ) and exercise of the map operator logic  278 . The map operator may be expressed as Vector Map(vector V, Func mapFunc) where V represents the vector, more specifically the records of the vector, to which the mapFunc will be applied to obtain a new vector of mapped records of vector V. The map operator allows the user to apply a user-defined function to all the records of a vector. In one implementation, the master node logic  260  receives the map function call  1100  with parameters that include a first vector identifier  272  and a user-defined map function (e.g., a user-defined function  276 ). The first vector identifier  272  identifies the first vector partitioned into first vector chunks (e.g., V 1 C 1   1104 , V 1 C 2   1108  and V 1 C 3   1110 ) corresponding to partitioned vector chunks distributed across the nodes of GridBatch cluster  102 . The first vector chunks include first vector chunk records (e.g., V 1 C 1 R 1   1116 , V 1 C 1 RX  1118 , V 1 C 2 R 1   1120 , V 1 C 2 RY  1122 , V 1 C 3 R 4   1124 , and V 1 C 3 RZ  1126 ). 
     The master node  116  initiates spawning of map tasks  1134  (e.g., slave tasks  158 ) locally on the set of nodes (e.g., slave node  1   1128 , slave node  4   1130  and slave node  6   1132 ) corresponding to the location of the first vector chunks. The arrow  1136  represents a transition to a node state in which each node with first vector chunks run the map tasks  1134  (e.g., map tasks running in parallel  1150 ,  1152  and  1154 ). The map tasks  1134  apply the user-defined map function to each of first vector chunk records to produce the mapped vector chunk records that form mapped vector chunks of vector M. The arrow  1158  represents a transition to a node state in which each node with first vector chunks includes corresponding mapped vector chunks (e.g., VMC 1   1160 , VMC 2   1162 , and VMC 3   1164 ) with corresponding mapped vector chunk records (e.g., VMC 1 R 1   1166 , VMC 1 RX  1168 , VMC 2 R 1   1170 , VMC 2 RY  1172 , VMC 3 R 4   1174 , and VMC 3 RZ  1176 ). 
     For example, a sales record vector  1180  may include a customer ID, product ID, and date of purchase field, along with several other fields. However, for a particular analysis, only two fields of the sales record vector may be of interest, such as the customer ID and the product ID. For efficient processing performance, a programmer may invoke the map function call  1100  to perform the map operator to extract just the customer ID and the product ID fields from the sales record vector; the map function call  1100  may be expressed in the following form: Vector newVector=Map(saleRecordVector, chop). The user-defined chop function parses each record of the sale record vector  1180  to produce new records that only include the customer ID and product ID fields in the newVector  1182  records. 
       FIG. 12  shows the logic flow GridBatch  100  may take to perform the map operator. The master node logic  260  receives the map function call  1100  to map vector V ( 1202 ). The master node logic  260  spawns slave tasks corresponding to each vector chunk of vector V ( 1204 ). Slave tasks invoke slave node logic  160  to locate each vector chunk of vector V assigned to corresponding slave nodes ( 1206 ). For each vector chunk of vector V, the slave node logic  160  applies the user-defined mapFunc to each vector chunk record to obtain mapped vector chunk records that form a mapped vector chunk of vector M ( 1208 ). Once the slave node logic  160  has applied the mapFunc to each vector chunk record of vector V, each slave task notifies the master node logic  260  of the completion status of the slave task and the location of the corresponding mapped vector chunk of M. The map operator successfully finishes when the slave nodes notify the master node that all slave tasks have finished ( 1210 ). The mapped vector chunks of vector M combine to form a new vector M. 
     The additional operators that GridBatch provides yield unexpectedly good results for parallel programming techniques. In particular, each operator provides significant advantages over prior attempts at application parallelization. The unexpectedly good results include significant additional programming flexibility, efficiency, and applicability to extraordinarily difficult problems faced by modern businesses, particularly with enormous amounts of data that must be processed in a realistic timeframe to achieve meaningful results. 
     The MapReduce programming model implements a unitary programming construct. In particular, a Map function is always paired with a Reduce function. On the other hand, GridBatch provides multiple independent operators: Recurse, Convolution, Join, Distribute, and Map that a programmer may use in virtually any order or sequence to build a complex application that executes in parallel across many nodes. Furthermore, the Gridbatch framework implements user defined functions specified for the independent operators through which the programmer may impart an immense degree of custom functionality. Such user defined functions include a partition function to determine how to break a vector into chunks, a hash function for distributing vector chunks among nodes, a join function for specifying how to combine records, a convolution function to support the join operator, a recurse function that specifies how to merge partial results of the recurse operator, and a map function for application to records of a vector. 
     A number of implementations have been described. Nevertheless, it will be understood that various modifications may be made without departing from the spirit and scope of the invention. Accordingly, other implementations are within the scope of the following claims.

Technology Category: 3