Summary

This document is a chapter from a programming languages textbook. It discusses concurrency, outlining different levels of concurrent execution (instruction-level, statement-level, unit-level, and program-level). The chapter also covers several synchronization mechanisms and related concepts.

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Chapter 13 Concurrency ISBN 0-321-49362-1 Chapter 13 Topics Introduction Introduction to Subprogram-Level Concurrency Semaphores Monitors Message Passing Ada support for Concurrency Java Threads C# Threads Concurrency in Functional Languages S...

Chapter 13 Concurrency ISBN 0-321-49362-1 Chapter 13 Topics Introduction Introduction to Subprogram-Level Concurrency Semaphores Monitors Message Passing Ada support for Concurrency Java Threads C# Threads Concurrency in Functional Languages Statement-Level Concurrency Copyright © 2018 Pearson. All rights reserved. 1-2 Introduction Concurrency can occur at four levels: – Machine instruction level – High-level language statement level – Unit level – Program level Because there are no language issues in instruction- and program-level concurrency, they are not addressed here Copyright © 2018 Pearson. All rights reserved. 1-3 Multiprocessor Architectures Late 1950s - one general-purpose processor and one or more special-purpose processors for input and output operations Early 1960s - multiple complete processors, used for program-level concurrency Mid-1960s - multiple partial processors, used for instruction-level concurrency Single-Instruction Multiple-Data (SIMD) machines Multiple-Instruction Multiple-Data (MIMD) machines A primary focus of this chapter is shared memory MIMD machines (multiprocessors) Copyright © 2018 Pearson. All rights reserved. 1-4 Categories of Concurrency Categories of Concurrency: – Physical concurrency - Multiple independent processors ( multiple threads of control) – Logical concurrency - The appearance of physical concurrency is presented by time- sharing one processor (software can be designed as if there were multiple threads of control) Coroutines (quasi-concurrency) have a single thread of control A thread of control in a program is the sequence of program points reached as control flows through the program Copyright © 2018 Pearson. All rights reserved. 1-5 Motivations for the Use of Concurrency Multiprocessor computers capable of physical concurrency are now widely used Even if a machine has just one processor, a program written to use concurrent execution can be faster than the same program written for nonconcurrent execution Involves a different way of designing software that can be very useful—many real-world situations involve concurrency Many program applications are now spread over multiple machines, either locally or over a network Copyright © 2018 Pearson. All rights reserved. 1-6 Introduction to Subprogram-Level Concurrency A task or process or thread is a program unit that can be in concurrent execution with other program units Tasks differ from ordinary subprograms in that: – A task may be implicitly started – When a program unit starts the execution of a task, it is not necessarily suspended – When a task’s execution is completed, control may not return to the caller Tasks usually work together Copyright © 2018 Pearson. All rights reserved. 1-7 Two General Categories of Tasks Heavyweight tasks execute in their own address space Lightweight tasks all run in the same address space – more efficient A task is disjoint if it does not communicate with or affect the execution of any other task in the program in any way Copyright © 2018 Pearson. All rights reserved. 1-8 Task Synchronization A mechanism that controls the order in which tasks execute Two kinds of synchronization – Cooperation synchronization – Competition synchronization Task communication is necessary for synchronization, provided by: - Shared nonlocal variables - Parameters - Message passing Copyright © 2018 Pearson. All rights reserved. 1-9 Kinds of synchronization Cooperation: Task A must wait for task B to complete some specific activity before task A can continue its execution, e.g., the producer-consumer problem Competition: Two or more tasks must use some resource that cannot be simultaneously used, e.g., a shared counter – Competition is usually provided by mutually exclusive access (approaches are discussed later) Copyright © 2018 Pearson. All rights reserved. 1-10 Need for Competition Synchronization Task A: TOTAL = TOTAL + 1 Task B: TOTAL = 2 * TOTAL - Depending on order, there could be four different results Copyright © 2018 Pearson. All rights reserved. 1-11 Scheduler Providing synchronization requires a mechanism for delaying task execution Task execution control is maintained by a program called the scheduler, which maps task execution onto available processors Copyright © 2018 Pearson. All rights reserved. 1-12 Task Execution States New - created but not yet started Ready - ready to run but not currently running (no available processor) Running Blocked - has been running, but cannot now continue (usually waiting for some event to occur) Dead - no longer active in any sense Copyright © 2018 Pearson. All rights reserved. 1-13 Task Execution States (continued) Copyright © 2018 Pearson. All rights reserved. 1-14 Liveness and Deadlock Liveness is a characteristic that a program unit may or may not have - In sequential code, it means the unit will eventually complete its execution In a concurrent environment, a task can easily lose its liveness If all tasks in a concurrent environment lose their liveness, it is called deadlock Copyright © 2018 Pearson. All rights reserved. 1-15 Design Issues for Concurrency Competition and cooperation synchronization* Controlling task scheduling How can an application influence task scheduling How and when tasks start and end execution How and when are tasks created * The most important issue Copyright © 2018 Pearson. All rights reserved. 1-16 Methods of Providing Synchronization Semaphores Monitors Message Passing Copyright © 2018 Pearson. All rights reserved. 1-17 Semaphores Dijkstra - 1965 A semaphore is a data structure consisting of a counter and a queue for storing task descriptors – A task descriptor is a data structure that stores all of the relevant information about the execution state of the task Semaphores can be used to implement guards on the code that accesses shared data structures Semaphores have only two operations, wait and release (originally called P and V by Dijkstra) Semaphores can be used to provide both competition and cooperation synchronization Copyright © 2018 Pearson. All rights reserved. 1-18 Cooperation Synchronization with Semaphores Example: A shared buffer The buffer is implemented as an ADT with the operations DEPOSIT and FETCH as the only ways to access the buffer Use two semaphores for cooperation: emptyspots and fullspots The semaphore counters are used to store the numbers of empty spots and full spots in the buffer Copyright © 2018 Pearson. All rights reserved. 1-19 Cooperation Synchronization with Semaphores (continued) DEPOSIT must first check emptyspots to see if there is room in the buffer If there is room, the counter of emptyspots is decremented and the value is inserted If there is no room, the caller is stored in the queue of emptyspots When DEPOSIT is finished, it must increment the counter of fullspots Copyright © 2018 Pearson. All rights reserved. 1-20 Cooperation Synchronization with Semaphores (continued) FETCH must first check fullspots to see if there is a value – If there is a full spot, the counter of fullspots is decremented and the value is removed – If there are no values in the buffer, the caller must be placed in the queue of fullspots – When FETCH is finished, it increments the counter of emptyspots The operations of FETCH and DEPOSIT on the semaphores are accomplished through two semaphore operations named wait and release Copyright © 2018 Pearson. All rights reserved. 1-21 Semaphores: Wait and Release Operations wait(aSemaphore) if aSemaphore’s counter > 0 then decrement aSemaphore’s counter else put the caller in aSemaphore’s queue attempt to transfer control to a ready task -- if the task ready queue is empty, -- deadlock occurs end release(aSemaphore) if aSemaphore’s queue is empty then increment aSemaphore’s counter else put the calling task in the task ready queue transfer control to a task from aSemaphore’s queue end Copyright © 2018 Pearson. All rights reserved. 1-22 Producer and Consumer Tasks semaphore fullspots, emptyspots; fullstops.count = 0; emptyspots.count = BUFLEN; task producer; loop -- produce VALUE –- wait (emptyspots); {wait for space} DEPOSIT(VALUE); release(fullspots); {increase filled} end loop; end producer; task consumer; loop wait (fullspots);{wait till not empty}} FETCH(VALUE); release(emptyspots); {increase empty} -- consume VALUE –- end loop; end consumer; Copyright © 2018 Pearson. All rights reserved. 1-23 Competition Synchronization with Semaphores A third semaphore, named access, is used to control access (competition synchronization) – The counter of access will only have the values 0 and 1 – Such a semaphore is called a binary semaphore Note that wait and release must be atomic! Copyright © 2018 Pearson. All rights reserved. 1-24 Producer Code for Semaphores semaphore access, fullspots, emptyspots; access.count = 0; fullstops.count = 0; emptyspots.count = BUFLEN; task producer; loop -- produce VALUE –- wait(emptyspots); {wait for space} wait(access); {wait for access) DEPOSIT(VALUE); release(access); {relinquish access} release(fullspots); {increase filled} end loop; end producer; Copyright © 2018 Pearson. All rights reserved. 1-25 Consumer Code for Semaphores task consumer; loop wait(fullspots);{wait till not empty} wait(access); {wait for access} FETCH(VALUE); release(access); {relinquish access} release(emptyspots); {increase empty} -- consume VALUE –- end loop; end consumer; Copyright © 2018 Pearson. All rights reserved. 1-26 Evaluation of Semaphores Misuse of semaphores can cause failures in cooperation synchronization, e.g., the buffer will overflow if the wait of fullspots is left out Misuse of semaphores can cause failures in competition synchronization, e.g., the program will deadlock if the release of access is left out Copyright © 2018 Pearson. All rights reserved. 1-27 Monitors Ada, Java, C# The idea: encapsulate the shared data and its operations to restrict access A monitor is an abstract data type for shared data Copyright © 2018 Pearson. All rights reserved. 1-28 Competition Synchronization Shared data is resident in the monitor (rather than in the client units) All access resident in the monitor – Monitor implementation guarantee synchronized access by allowing only one access at a time – Calls to monitor procedures are implicitly queued if the monitor is busy at the time of the call Copyright © 2018 Pearson. All rights reserved. 1-29 Cooperation Synchronization Cooperation between processes is still a programming task – Programmer must guarantee that a shared buffer does not experience underflow or overflow Copyright © 2018 Pearson. All rights reserved. 1-30 Evaluation of Monitors A better way to provide competition synchronization than are semaphores Semaphores can be used to implement monitors Monitors can be used to implement semaphores Support for cooperation synchronization is very similar as with semaphores, so it has the same problems Copyright © 2018 Pearson. All rights reserved. 1-31 Message Passing Message passing is a general model for concurrency – It can model both semaphores and monitors – It is not just for competition synchronization Central idea: task communication is like seeing a doctor--most of the time she waits for you or you wait for her, but when you are both ready, you get together, or rendezvous Copyright © 2018 Pearson. All rights reserved. 1-32 Message Passing Rendezvous To support concurrent tasks with message passing, a language needs: - A mechanism to allow a task to indicate when it is willing to accept messages - A way to remember who is waiting to have its message accepted and some “fair” way of choosing the next message When a sender task’s message is accepted by a receiver task, the actual message transmission is called a rendezvous Copyright © 2018 Pearson. All rights reserved. 1-33 Ada Support for Concurrency The Ada 83 Message-Passing Model – Ada tasks have specification and body parts, like packages; the spec has the interface, which is the collection of entry points: task Task_Example is entry ENTRY_1 (Item : in Integer); end Task_Example; Copyright © 2018 Pearson. All rights reserved. 1-34 Task Body The body task describes the action that takes place when a rendezvous occurs A task that sends a message is suspended while waiting for the message to be accepted and during the rendezvous Entry points in the spec are described with accept clauses in the body accept entry_name (formal parameters) do... end entry_name; Copyright © 2018 Pearson. All rights reserved. 1-35 Example of a Task Body task body Task_Example is begin loop accept Entry_1 (Item: in Float) do... end Entry_1; end loop; end Task_Example; Copyright © 2018 Pearson. All rights reserved. 1-36 Ada Message Passing Semantics The task executes to the top of the accept clause and waits for a message During execution of the accept clause, the sender is suspended accept parameters can transmit information in either or both directions Every accept clause has an associated queue to store waiting messages Copyright © 2018 Pearson. All rights reserved. 1-37 Rendezvous Time Lines Copyright © 2018 Pearson. All rights reserved. 1-38 Message Passing: Server/Actor Tasks A task that has accept clauses, but no other code is called a server task (the example above is a server task) A task without accept clauses is called an actor task – An actor task can send messages to other tasks – Note: A sender must know the entry name of the receiver, but not vice versa (asymmetric) Copyright © 2018 Pearson. All rights reserved. 1-39 Graphical Representation of a Rendezvous Copyright © 2018 Pearson. All rights reserved. 1-40 Multiple Entry Points Tasks can have more than one entry point – The specification task has an entry clause for each – The task body has an accept clause for each entry clause, placed in a select clause, which is in a loop Copyright © 2018 Pearson. All rights reserved. 1-41 A Task with Multiple Entries task body Teller is loop select accept Drive_Up(formal params) do... end Drive_Up;... or accept Walk_Up(formal params) do... end Walk_Up;... end select; end loop; end Teller; Copyright © 2018 Pearson. All rights reserved. 1-42 Semantics of Tasks with Multiple accept Clauses If exactly one entry queue is nonempty, choose a message from it If more than one entry queue is nonempty, choose one, nondeterministically, from which to accept a message If all are empty, wait The construct is often called a selective wait Extended accept clause - code following the clause, but before the next clause – Executed concurrently with the caller Copyright © 2018 Pearson. All rights reserved. 1-43 Cooperation Synchronization with Message Passing Provided by Guarded accept clauses when not Full(Buffer) => accept Deposit (New_Value) do... end An accept clause with a with a when clause is either open or closed – A clause whose guard is true is called open – A clause whose guard is false is called closed – A clause without a guard is always open Copyright © 2018 Pearson. All rights reserved. 1-44 Semantics of select with Guarded accept Clauses: select first checks the guards on all clauses If exactly one is open, its queue is checked for messages If more than one are open, non-deterministically choose a queue among them to check for messages If all are closed, it is a runtime error A select clause can include an else clause to avoid the error – When the else clause completes, the loop repeats Copyright © 2018 Pearson. All rights reserved. 1-45 Competition Synchronization with Message Passing Modeling mutually exclusive access to shared data Example--a shared buffer Encapsulate the buffer and its operations in a task Competition synchronization is implicit in the semantics of accept clauses – Only one accept clause in a task can be active at any given time Copyright © 2018 Pearson. All rights reserved. 1-46 Partial Shared Buffer Code task body Buf_Task is Bufsize : constant Integer := 100; Buf : array (1..Bufsize) of Integer; Filled : Integer range 0..Bufsize := 0; Next_In, Next_Out : Integer range 1..Bufsize := 1; begin loop select when Filled < Bufsize => accept Deposit(Item : in Integer) do Buf(Next_In) := Item; end Deposit; Next_In := (Next_In mod Bufsize) + 1; Filled := Filled + 1; or... end loop; end Buf_Task; Copyright © 2018 Pearson. All rights reserved. 1-47 A Consumer Task task Consumer; task body Consumer is Stored_Value : Integer; begin loop Buf_Task.Fetch(Stored_Value); -- consume Stored_Value – end loop; end Consumer; Copyright © 2018 Pearson. All rights reserved. 1-48 Concurrency in Ada 95 Ada 95 includes Ada 83 features for concurrency, plus two new features – Protected objects: A more efficient way of implementing shared data to allow access to a shared data structure to be done without rendezvous – Asynchronous communication Copyright © 2018 Pearson. All rights reserved. 1-49 Ada 95: Protected Objects A protected object is similar to an abstract data type Access to a protected object is either through messages passed to entries, as with a task, or through protected subprograms A protected procedure provides mutually exclusive read-write access to protected objects A protected function provides concurrent read-only access to protected objects Copyright © 2018 Pearson. All rights reserved. 1-50 Evaluation of the Ada Message passing model of concurrency is powerful and general Protected objects are a better way to provide synchronized shared data In the absence of distributed processors, the choice between monitors and tasks with message passing is somewhat a matter of taste For distributed systems, message passing is a better model for concurrency Copyright © 2018 Pearson. All rights reserved. 1-51 Java Threads The concurrent units in Java are methods named run – A run method code can be in concurrent execution with other such methods – The process in which the run methods execute is called a thread class myThread extends Thread public void run () {…} } … Thread myTh = new MyThread (); myTh.start(); Copyright © 2018 Pearson. All rights reserved. 1-52 Controlling Thread Execution The Thread class has several methods to control the execution of threads – The yield is a request from the running thread to voluntarily surrender the processor – The sleep method can be used by the caller of the method to block the thread – The join method is used to force a method to delay its execution until the run method of another thread has completed its execution Copyright © 2018 Pearson. All rights reserved. 1-53 Thread Priorities A thread’s default priority is the same as the thread that create it – If main creates a thread, its default priority is NORM_PRIORITY Threads defined two other priority constants, MAX_PRIORITY and MIN_PRIORITY The priority of a thread can be changed with the methods setPriority Copyright © 2018 Pearson. All rights reserved. 1-54 Semaphores in Java Copyright © 2018 Pearson. All rights reserved. 1-55 Competition Synchronization with Java Threads A method that includes the synchronized modifier disallows any other method from running on the object while it is in execution … public synchronized void deposit( int i) {…} public synchronized int fetch() {…} … The above two methods are synchronized which prevents them from interfering with each other If only a part of a method must be run without interference, it can be synchronized thru synchronized statement synchronized (expression) statement Copyright © 2018 Pearson. All rights reserved. 1-56 Cooperation Synchronization with Java Threads Cooperation synchronization in Java is achieved via wait, notify, and notifyAll methods – All methods are defined in Object, which is the root class in Java, so all objects inherit them The wait method must be called in a loop The notify method is called to tell one waiting thread that the event it was waiting has happened The notifyAll method awakens all of the threads on the object’s wait list Copyright © 2018 Pearson. All rights reserved. 1-57 Java’s Thread Evaluation Java’s support for concurrency is relatively simple but effective Not as powerful as Ada’s tasks Copyright © 2018 Pearson. All rights reserved. 1-58 C# Threads Loosely based on Java but there are significant differences Basic thread operations – Any method can run in its own thread – A thread is created by creating a Thread object – Creating a thread does not start its concurrent execution; it must be requested through the Start method – A thread can be made to wait for another thread to finish with Join – A thread can be suspended with Sleep – A thread can be terminated with Abort Copyright © 2018 Pearson. All rights reserved. 1-59 Synchronizing Threads Three ways to synchronize C# threads – The Interlocked class Used when the only operations that need to be synchronized are incrementing or decrementing of an integer – The lock statement Used to mark a critical section of code in a thread lock (expression) {… } – The Monitor class Provides four methods that can be used to provide more sophisticated synchronization Copyright © 2018 Pearson. All rights reserved. 1-60 C#’s Concurrency Evaluation An advance over Java threads, e.g., any method can run its own thread Thread termination is cleaner than in Java Synchronization is more sophisticated Copyright © 2018 Pearson. All rights reserved. 1-61 Statement-Level Concurrency Objective: Provide a mechanism that the programmer can use to inform compiler of ways it can map the program onto multiprocessor architecture Minimize communication among processors and the memories of the other processors Copyright © 2018 Pearson. All rights reserved. 1-62 High-Performance Fortran A collection of extensions that allow the programmer to provide information to the compiler to help it optimize code for multiprocessor computers Specify the number of processors, the distribution of data over the memories of those processors, and the alignment of data Copyright © 2018 Pearson. All rights reserved. 1-63 Primary HPF Specifications Number of processors !HPF$ PROCESSORS procs (n) Distribution of data !HPF$ DISTRIBUTE (kind) ONTO procs :: identifier_list – kind can be BLOCK (distribute data to processors in blocks) or CYCLIC (distribute data to processors one element at a time) Relate the distribution of one array with that of another ALIGN array1_element WITH array2_element Copyright © 2018 Pearson. All rights reserved. 1-64 Statement-Level Concurrency Example REAL list_1(1000), list_2(1000) INTEGER list_3(500), list_4(501) !HPF$ PROCESSORS proc (10) !HPF$ DISTRIBUTE (BLOCK) ONTO procs :: list_1, list_2 !HPF$ ALIGN list_1(index) WITH list_4 (index+1) … list_1 (index) = list_2(index) list_3(index) = list_4(index+1) Copyright © 2018 Pearson. All rights reserved. 1-65 Statement-Level Concurrency (continued) FORALL statement is used to specify a list of statements that may be executed concurrently FORALL (index = 1:1000) list_1(index) = list_2(index) Specifies that all 1,000 RHSs of the assignments can be evaluated before any assignment takes place Copyright © 2018 Pearson. All rights reserved. 1-66 Summary Concurrent execution can be at the instruction, statement, or subprogram level Physical concurrency: when multiple processors are used to execute concurrent units Logical concurrency: concurrent united are executed on a single processor Two primary facilities to support subprogram concurrency: competition synchronization and cooperation synchronization Mechanisms: semaphores, monitors, rendezvous, threads High-Performance Fortran provides statements for specifying how data is to be distributed over the memory units connected to multiple processors Copyright © 2018 Pearson. All rights reserved. 1-67

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