Difference between revisions of "Computer Science/162/proj1"
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− | ==KThread.join()== | + | =={{c|KThread.join()}}== |
===Implementation=== | ===Implementation=== | ||
− | {{c|KThread}} has a new state variable {{c|joinedOnMe}}, a {{c|ThreadQueue}} | + | ;New state variables |
+ | {{c|KThread}} has a new state variable {{c|joinedOnMe}}, a {{c|ThreadQueue}}, and {{c|isJoined}}, a {{c|boolean}} | ||
+ | |||
+ | ;Implementation details | ||
* When {{c|threadA}} calls {{c|threadB.join()}}, {{c|threadB}} adds it to its internal {{c|joinedOnMe}} queue and then puts it to sleep. In {{c|threadB}}'s {{c|finish()}} method, {{c|threadB}} calls {{c|nextThread()}} on its {{c|joinedOnMe}} queue before returning. | * When {{c|threadA}} calls {{c|threadB.join()}}, {{c|threadB}} adds it to its internal {{c|joinedOnMe}} queue and then puts it to sleep. In {{c|threadB}}'s {{c|finish()}} method, {{c|threadB}} calls {{c|nextThread()}} on its {{c|joinedOnMe}} queue before returning. | ||
* {{c|join()}} also checks that this thread is not equal to the current thread and that {{c|joinedOnMe}} is not already occupied by another thread with a boolean flag, which determines whether {{c|join()}} has already been called on this thread. | * {{c|join()}} also checks that this thread is not equal to the current thread and that {{c|joinedOnMe}} is not already occupied by another thread with a boolean flag, which determines whether {{c|join()}} has already been called on this thread. | ||
===Testing=== | ===Testing=== | ||
− | * | + | * {{c|threadA}} prints out a few statements, calls {{c|threadB.join()}}, then prints out a few more statements. {{c|threadB}} also prints out a series of statements. We then verify that {{c|threadB}} executes contiguously to completion before {{c|threadA}} resumes its execution, as evidenced by the sequence of printed statements. |
− | * Have a thread attempt to join itself, | + | * Have a thread attempt to {{c|join()}} to itself, call {{c|join()}} on a second thread multiple times, and attempt to call {{c|join()}} on a third finished thread (all separately). These should all return immediately as this is the expected behavior. |
− | * | + | * Test a chain of threads. Thread C will attempt to join Thread B. Thread B will attempt to join Thread A. Thread A forks last. Verify that A executes before B, and B executes before C. |
===Pseudocode=== | ===Pseudocode=== | ||
− | join() { | + | {{c|<pre>join() { |
Disable interrupts; | Disable interrupts; | ||
If (CurrentThread == self or isJoined) or (status is Finished) { | If (CurrentThread == self or isJoined) or (status is Finished) { | ||
− | + | Re-enable interrupts; | |
Return; // conditions for join not satisfied | Return; // conditions for join not satisfied | ||
} else { | } else { | ||
Line 22: | Line 25: | ||
} | } | ||
Re-enable interrupts; | Re-enable interrupts; | ||
− | } | + | }</pre>}} |
− | finish(){ | + | |
+ | {{c|<pre>finish() { | ||
// Interrupts have been disabled. | // Interrupts have been disabled. | ||
...(existing code)... | ...(existing code)... | ||
− | Ready the thread | + | Ready the thread on the joinedOnMe queue; |
Sleep (existing); | Sleep (existing); | ||
− | } | + | }</pre>}} |
− | == | + | ==Condition2.java== |
===Implementation=== | ===Implementation=== | ||
− | Condition2 has a new state variable waitQueue, a ThreadQueue with transferPriority flag set to false. | + | ;New state variables |
− | * In the sleep() method, we disable interrupts, the | + | Condition2 has a new state variable {{c|waitQueue}}, a {{c|ThreadQueue}} with {{c|transferPriority}} flag set to false. |
− | * The wake() method disables interrupts and | + | |
− | * wakeAll() will | + | ;Implementation details |
+ | * In the {{c|sleep()}} method, we disable interrupts, the current thread is added to the {{c|waitQueue}} of threads, the corresponding lock is released, and the current thread is put to sleep. When it wakes up, the thread attempts to reacquire the corresponding lock and interrupts are re-enabled. | ||
+ | * The {{c|wake()}} method disables interrupts and retrieves the next thread from {{c|waitQueue}}. If the thread returned is not null, that thread is readied. Finally, the interrupts are re-enabled. | ||
+ | * The {{c|wakeAll()}} method also disables the interrupts and stores the next thread from {{c|waitQueue}} as a {{c|KThread}} variable, {{c|nextThread}}. While {{c|nextThread}} is not null, the method will ready that thread and set {{c|nextThread}} to the next thread from {{c|waitQueue}}. This procedure continues until there are no more threads in {{c|waitQueue}}. | ||
===Testing=== | ===Testing=== | ||
− | * Sleep several threads on the condition variable. Upon waking, these threads should print a unique statement and perform a wake() on the condition variable. Have one thread perform an initial wake() on the condition variable and verify that all threads are executed. | + | * {{c|Condition2.java}} was tested using a class called {{c|CondThread}}, which implements {{c|Runnable}}. The class is instantiated with an integer {{c|iterations}}, a lock, a {{c|Condition2}} variable to call {{c|sleep()}} on, and a {{c|Condition2}} variable to call {{c|wake()}} on. When a {{c|CondThread}} runs, it acquires the lock, then enters a for-loop of 6 iterations. On each iteration, the thread will print out a debug statement noting that the current thread is on the ith iteration. When the loop iteration number is equal to {{c|iterations}}, threads can take one of three actions: |
− | + | *#If the thread's ID is '0', then that thread is the waking thread and calls {{c|wake()}} on its second condition variable. | |
+ | *#If the thread's ID is '0-all', it calls {{c|wakeAll()}} on its second condition variable | ||
+ | *#Otherwise, it goes to sleep on its first condition variable. Using the output, we verify that the threads all run in the correct order and all execute to completion. | ||
+ | * Sleep several threads on the condition variable. Upon waking, these threads should print a unique statement and perform a {{c|wake()}} on the condition variable. Have one thread perform an initial {{c|wake()}} on the condition variable and verify that all threads are executed. | ||
+ | * Sleep several threads on several various condition variables. Verify via console print statements that the proper threads wake up at the correct times according to which condition variable they were sleeping on. | ||
+ | * Sleep several threads on the condition variable, then have one final thread wake them all with {{c|wakeAll()}}. Verify that all threads have woken up via console print statements. | ||
+ | * Sleep several threads on several various condition variables, then have one thread call {{c|wakeAll()}} on one of the condition variables. Verify via console print statements that all the threads put to sleep on that condition variable wake up and that only those threads wake up. | ||
===Pseudocode=== | ===Pseudocode=== | ||
− | + | {{c|<pre>sleep() { | |
− | Disable Interrupts; | + | Disable Interrupts; |
− | Add current thread to wait queue; | + | Add current thread to wait queue; |
− | Release the lock; | + | Release the lock; |
− | Put the current thread to sleep; | + | Put the current thread to sleep; |
− | Acquire the lock; | + | Acquire the lock; |
− | Re-enable Interrupts; | + | Re-enable Interrupts; |
− | } | + | }</pre>}} |
+ | {{c|<pre>wake() { | ||
+ | AssertTrue (lock held by current thread); | ||
+ | Disable interrupts; | ||
+ | If there is a thread on the wait queue: | ||
+ | Remove the first thread and wake it; | ||
+ | Re-enable interrupts; | ||
+ | }</pre>}} | ||
− | + | {{c|<pre>wakeAll() { | |
− | + | Disable interrupts; | |
− | + | While there are threads on the wait queue: | |
− | + | Remove the first thread and wake it; | |
− | + | Re-enable interrupts; | |
− | + | }</pre>}} | |
− | |||
− | |||
− | Disable interrupts; | ||
− | While there are threads on the wait queue | ||
− | Re-enable interrupts; | ||
− | } | ||
+ | =={{c|waitUntil()}}== | ||
+ | ===Implementation=== | ||
+ | ;New state variables | ||
+ | Alarm has a new instance variable, {{c|waitingThreads}}, which is a Java {{c|PriorityQueue}} of waiting threads with the target wake time as their priority. It also contains a new inner class named {{c|WaitingThread}}, which contains a reference to a {{c|KThread}} and its associated {{c|wakeTime}}. The {{c|PriorityQueue waitingThreads}} will be populated with instances of this inner class. | ||
− | + | ;Implementation details | |
− | + | * {{c|waitUntil()}} creates a new instance of {{c|waitingThread}}, which will associate the current thread with the given time argument. It will then add this {{c|waitingThread}} instance to the {{c|PriorityQueue}} and put the current thread to sleep. This method is atomic. | |
− | + | * {{c|timerInterrupt()}} peeks at the first {{c|WaitingThread}} in the {{c|waitQueue}} and checks if its associated wake time is less than or equal to the current time. If it is, this method will pop the {{c|WaitingThread}} off the {{c|waitQueue}} and wake the associated thread. This process is repeated until the wake time of the first {{c|WaitingThread}} is greater than the current time. | |
− | * waitUntil() creates a new instance of waitingThread, which will associate the | ||
− | * timerInterrupt() | ||
===Testing=== | ===Testing=== | ||
− | * Have the timer interrupt print a debug statement, and have timed threads print the times they go to sleep and when they have woken up. Verify that they wake up relatively close to their expected | + | * Have the timer interrupt print a debug statement, and have timed threads print the times they go to sleep and when they have woken up. Verify that they wake up relatively close to their expected wake time. |
− | * Make sure threads called with illegal times return immediately. Test threads that go to sleep chronologically in order (1, 500, 1050) as well as threads that go to sleep with the same times ( 50, 50) and threads that go to sleep in reverse order (500, 250). Verify they all wake up when they are supposed to. | + | * Make sure threads called with illegal times return immediately. Test threads that go to sleep chronologically in order (1, 500, 1050) as well as threads that go to sleep with the same times (50, 50) and threads that go to sleep in reverse order (500, 250). Verify they all wake up when they are supposed to. |
===Pseudocode=== | ===Pseudocode=== | ||
− | waitUntil(time){ | + | {{c|<pre>waitUntil(time){ |
Disable interrupts; | Disable interrupts; | ||
Create a new waitingThread; | Create a new waitingThread; | ||
Line 83: | Line 99: | ||
Sleep the current thread; | Sleep the current thread; | ||
Re-enable interrupts; | Re-enable interrupts; | ||
− | } | + | }</pre>}} |
− | + | {{c|<pre>timerInterrupt(){ | |
− | timerInterrupt(){ | ||
AssertTrue (interrupts have already been disabled); | AssertTrue (interrupts have already been disabled); | ||
For all waitingThreads that have exceeded their associated wait time; | For all waitingThreads that have exceeded their associated wait time; | ||
Wake their associated threads and remove from queue; | Wake their associated threads and remove from queue; | ||
− | } | + | }</pre>}} |
− | |||
==Communicator== | ==Communicator== | ||
===Implementation=== | ===Implementation=== | ||
− | + | ;New state variables | |
− | Lock lock | + | {{c|<pre>Lock lock = new Lock() |
− | int activeSpeakers | + | int activeSpeakers = 0 |
− | int waitingSpeakers | + | int waitingSpeakers = 0 |
− | int activeListeners | + | int activeListeners = 0 |
− | int waitingListeners | + | int waitingListeners = 0 |
− | Condition speakers | + | Condition speakers |
Condition listeners | Condition listeners | ||
− | Condition return | + | Condition return</pre>}} |
− | * The first lone speaker or listener will be counted as active, or in the process of exchanging a message and returning, and will sleep on the return condition variable until its counterpart wakes it up so that they can both return. | + | |
− | * A second thread performing the same action as a currently active thread will be counted as waiting, and be put to sleep on its respective condition variable. Otherwise, it will check if there is an active thread of its counterpart action waiting on the return condition variable. If there | + | ;Implementation details |
− | * Any interjecting threads that execute in between an exchange of message will be stopped by the active counters, which do not decrement until | + | * The first lone speaker or listener will be counted as ''active'', or in the process of exchanging a message and returning, and will sleep on the {{c|return}} condition variable until its counterpart wakes it up so that they can both return. |
+ | * A second thread performing the same action as a currently active thread will be counted as ''waiting'', and be put to sleep on its respective condition variable. Otherwise, it will check if there is an ''active'' thread of its counterpart action waiting on the {{c|return}} condition variable. If there isn't, it will attempt to wake waiting threads of its counterpart action prior to going to sleep on the return condition variable. If there is a counterpart ''active'' thread, it will wake it up and they both will return. Prior to returning, the counterpart action will also attempt to wake ''waiting'' threads of its type. | ||
+ | * Any interjecting threads that execute in between an exchange of message will be stopped by the ''active'' counters, which do not decrement until '''both''' counterparts in the exchange have returned. | ||
===Testing=== | ===Testing=== | ||
Our original solution exhibited non-deterministic behavior, so after rewriting it, we decided to stress it exceptionally to make sure that it was working correctly. We tested our communicator in three main ways. | Our original solution exhibited non-deterministic behavior, so after rewriting it, we decided to stress it exceptionally to make sure that it was working correctly. We tested our communicator in three main ways. | ||
− | First, we set up a manual sequence of speak() and listen() actions on different threads and executed them in a particular order, verifying that the resulting sequence of messages was correct, monitored via print statements to the console | + | First, we set up a manual sequence of {{c|speak()}} and {{c|listen()}} actions on different threads and executed them in a particular order, verifying that the resulting sequence of messages was correct, monitored via print statements to the console |
Second, we set off a random number of speakers, followed by a random number of listeners, and verified that the limiting resource was completely used up, i.e. that a matching number of speakers and listeners returned and that this was equal to the smaller of numbers of created speakers/listeners. | Second, we set off a random number of speakers, followed by a random number of listeners, and verified that the limiting resource was completely used up, i.e. that a matching number of speakers and listeners returned and that this was equal to the smaller of numbers of created speakers/listeners. | ||
− | |||
− | + | Finally, we repeated the same procedure, but intermingled the creation of speakers and listeners via {{c|.fork()}}, such that listeners would start listening before all the speakers were queued up. | |
− | + | ||
+ | The latter two tests were run with up to 500 threads of speakers and listeners each (with a temporary override on the number of max threads in Nachos) and the number of listen and speak operations was analyzed via script. The speakers and listeners would print statements while executing code, which allowed us to perform this analysis. | ||
+ | To be able to perform these tests, we created a number of helper classes which implement Runnable. {{c|MassSpeaker}} and {{c|MassListener}} are designed to be run by a single thread each. These will iterate until a given limit, and on each iteration, there is a 50% chance that a speak (or listen) is called. After each iteration, the thread yields to the opposite thread to do the same. Debug statements will display what threads are doing at each iteration and how messages are being exchanged. With this we can generate large amounts of calls with randomized orders between two threads, and will be able to verify all speaks are correctly received by a listen. | ||
− | + | A second set of runnables, {{c|MassTSpeaker}} and {{c|MassTListener}}, are designed to fork off several threads themselves, with each of these forked threads performing a single speak or listen. These forked threads are also executed with 50% chance on each iteration to provide random ordering. We can also verify if all threads are correctly paired off via print statements to console. | |
+ | ===Pseudocode=== | ||
+ | {| | ||
+ | | style="vertical-align: top;"| | ||
speak(int word) { | speak(int word) { | ||
Acquire the lock; | Acquire the lock; | ||
Line 139: | Line 159: | ||
Wake a waiting listener; | Wake a waiting listener; | ||
} | } | ||
− | Sleep as | + | Sleep as waiting to return; |
AS--; | AS--; | ||
AL--; | AL--; | ||
Line 149: | Line 169: | ||
} | } | ||
} | } | ||
− | + | || | |
listen() { | listen() { | ||
Acquire the lock; | Acquire the lock; | ||
Line 168: | Line 188: | ||
Wake a waiting speaker; | Wake a waiting speaker; | ||
} | } | ||
− | Sleep as | + | Sleep as waiting to return; |
AL--; | AL--; | ||
AS--; | AS--; | ||
Line 179: | Line 199: | ||
} | } | ||
} | } | ||
+ | |} | ||
==Priority Scheduler== | ==Priority Scheduler== | ||
===Implementation=== | ===Implementation=== | ||
− | New state variables | + | ;New state variables |
− | PriorityQueue | + | * {{c|PriorityQueue.holder}} - this ThreadState corresponds to the holder of the resource signified by the |
− | ThreadState | + | * {{c|PriorityQueue.waitQueue}} - an ArrayList of ThreadStates waiting on this resource. Unsorted. |
− | + | * {{c|PriorityQueue.dirty}} - set to true when a new thread is added to the queue, or any of the queues in the waitQueue flag themselves as dirty. | |
− | + | * {{c|PriorityQueue.effective}} - the cached highest of the effective priorities in the waitQueue. This value is invalidated while dirty is true. | |
− | |||
− | * | ||
− | |||
− | |||
− | |||
− | |||
− | |||
− | * | ||
− | |||
− | |||
− | |||
+ | * {{c|ThreadState.myResources}} - collection of PriorityQueues that signify the Locks or other resources that this thread currently holds. | ||
+ | * {{c|ThreadState.waitingOn}} - collection of PriorityQueues corresponding to resources that this thread has attempted to acquire but could not. | ||
+ | * {{c|ThreadState.effective}} - the cached effective priority of this thread. this value is invalidated when dirty is true | ||
+ | * {{c|ThreadState.dirty}} - set to true when this thread's priority is changed, or when one of the queues in myResources flags itself as dirty. | ||
+ | ;Implementation overview | ||
+ | The idea here is that {{c|Thread}}s keep track of the {{c|PriorityQueue}}s corresponding to both the resources that they are currently holding and those that they want to hold. We can do this via hooks in {{c|PriorityQueue}}'s {{c|waitForAccess()}}, {{c|acquire}}, and {{c|nextThread}} methods. | ||
+ | |||
+ | Once we have this, every time a thread tries to wait on a queue, or takes control of a queue, we can tell the queue that its overall effective priority may have changed, and it can, in turn, tell the thread that currently holds the resource that one of the {{c|PriorityQueue}}s it holds may have had its priority changed. That holder can in turn tell the same to the {{c|PriorityQueue}}s that it is waiting on, and so forth. Eventually a thread, which is holding a resource that everyone needs, but has a low priority, will be marked for priority recalculation and thus priority escalation. | ||
+ | |||
+ | At this point, recalculation is simple. The effective priority of a thread is the maximum of its own actual priority and the priorities of all the {{c|PriorityQueue}}s that it currently holds. The effective priority of a {{c|PriorityQueue}} is the maximum effective priority of all the threads waiting on it (if the queue is supposed to donate priority), and so on and so forth in a mutually recursive manner. | ||
+ | |||
+ | ;Implementation details | ||
+ | * {{c|PriorityQueue.nextThread()}} | ||
+ | :This method retrieves and removes the highest priority thread off the Priority-Time {{c|ArrayList}}. It then flags the previous holder of this resource as {{c|dirty}}, and removes the queue from that holder's resource list. It then sets the retrieved thread to this queue's new {{c|holder}}, and flags that thread as {{c|dirty}} as well. | ||
+ | * {{c|PriorityQueue.acquire(KThread thread)}} | ||
+ | :Sets the {{c|holder}} of this queue to the specified thread, bypassing the queue. Resets previous {{c|holder}} and sets {{c|dirty}} flags as in {{c|nextThread()}}. | ||
+ | * {{c|PriorityQueue.pickNextThread()}} | ||
+ | :Simply retrieves the highest priority thread off this queue. | ||
+ | * {{c|PriorityQueue.setDirty()}} | ||
+ | :Set this queue's {{c|dirty}} flag, and calls {{c|setDirty}} on the current holder of this thread. | ||
+ | * {{c|PriorityQueue.getEffectivePriority()}} | ||
+ | :If this queue is {{c|dirty}}, returns the maximum of each of the {{c|ThreadState}}s{{c|.getEffectivePriority()}} in this queue. Those calls in turn become mutually recursive when they call {{c|getEffectivePriority()}} on the {{c|PriorityQueues}} in their {{c|myResources}}. | ||
+ | * {{c|ThreadState.setPriority()}} | ||
+ | :This method will change the actual priority of the thread associated with the {{c|ThreadState}}. It then calls {{c|setDirty()}} on this thread. | ||
+ | * {{c|ThreadState.setDirty()}} | ||
+ | :Sets the {{c|dirty}} flag on this thread, then calls {{c|setDirty()}} on each of the {{c|PriorityQueue}}s that the thread is waiting for. Mutually recursive. | ||
+ | * {{c|ThreadState.getEffectivePriority}} | ||
+ | :Like the analogue of this function in {{c|PriorityQueue}}, returns the (cached) priority if this thread is not {{c|dirty}}; otherwise, recalculates by returning the max of the effective priorities of the {{c|PriorityQueue}}s in {{c|myResources}}. | ||
===Testing=== | ===Testing=== | ||
* Instantiate new threads and set their priorities in decreasing order. Have the threads state their priorities as they execute and verify that they were run in decreasing order according to their priorities. | * Instantiate new threads and set their priorities in decreasing order. Have the threads state their priorities as they execute and verify that they were run in decreasing order according to their priorities. | ||
* Verify donation works by creating a high priority thread and joining it to a low priority thread with a high priority thread already queued. | * Verify donation works by creating a high priority thread and joining it to a low priority thread with a high priority thread already queued. | ||
+ | * Create complex set of interdependent threads and multiple locks, verify that execution order is correct. | ||
===Pseudocode=== | ===Pseudocode=== | ||
+ | ;PriorityQueue | ||
+ | {{c|<pre> | ||
+ | public void waitForAccess(KThread thread) | ||
+ | add this thread to my waitQueue | ||
+ | thread.waitForAccess(this) | ||
+ | |||
+ | public void acquire(KThread thread) | ||
+ | if I have a holder and I transfer priority, remove myself from the holder's resource list | ||
+ | thread.acquire(this) | ||
+ | |||
+ | public KThread nextThread() | ||
+ | if I have a holder and I transfer priority, remove myself from the holder's resource list | ||
+ | if waitQueue is empty, return null | ||
+ | ThreadState firstThread = pickNextThread(); | ||
+ | remove firstThread from waitQueue | ||
+ | firstThread.acquire(this); | ||
+ | return firstThread | ||
+ | |||
+ | public int getEffectivePriority() | ||
+ | if I do not transfer priority, return minimum priority | ||
+ | if (dirty) | ||
+ | effective = minimum priority; | ||
+ | for each ThreadState t in waitQueue | ||
+ | effective = MAX(effective, t.getEffectivePriority()) | ||
+ | dirty = false; | ||
+ | return effective; | ||
+ | |||
+ | public void setDirty() | ||
+ | if I do not transfer priority, there is no need to recurse, return | ||
+ | dirty = true; | ||
+ | if I have a holder, holder.setDirty() | ||
+ | |||
+ | protected ThreadState pickNextThread() | ||
+ | ThreadState ret = null | ||
+ | for each ThreadState ts in waitQueue | ||
+ | if ret is null OR ts has higher priority/time ranking than ret | ||
+ | set ret to ts | ||
+ | return ret;</pre>}} | ||
+ | |||
+ | ;ThreadState | ||
+ | {{c|<pre> | ||
+ | public int getPriority() | ||
+ | return non-donated priority. | ||
+ | |||
+ | public int getEffectivePriority() | ||
+ | if (dirty) { | ||
+ | effective = non-donated priority | ||
+ | for each PriorityQueue pq that I am currently holding | ||
+ | effective = MAX(effective, pq.getEffectivePriority) | ||
+ | } | ||
+ | return effective; | ||
+ | |||
+ | public void setPriority(int priority) | ||
+ | set non-donated priority to the argument | ||
+ | setDirty(); | ||
+ | |||
+ | public void setDirty() | ||
+ | if already dirty return | ||
+ | dirty = true; | ||
+ | for each of the PriorityQueues pq I am waiting on, | ||
+ | pq.setDirty | ||
+ | |||
+ | public void waitForAccess(PriorityQueue waitQueue) | ||
+ | add the waitQueue to my waitingOn list | ||
+ | if the waitQueue was previously in myResources, remove it and set its holder to null. | ||
+ | if waitQueue has a holder, set the queue to dirty to signify possible change in the queue's effective priority | ||
+ | public void acquire(PriorityQueue waitQueue) | ||
+ | add waitQueue to myResources list | ||
+ | if waitQueue was in my waitingOn list, remove it | ||
+ | setWaitQueue's holder to me | ||
+ | setDirty();</pre>}} | ||
==Boat.java== | ==Boat.java== | ||
===Implementation=== | ===Implementation=== | ||
− | + | ;New state variables (all shared) | |
− | + | {{c|<pre>lock = new Lock() | |
− | + | boatIsland = Island.A | |
− | |||
− | lock | ||
− | boatIsland = A | ||
boatPilot = null | boatPilot = null | ||
boatDeparting = false | boatDeparting = false | ||
boatLookingForChild = false | boatLookingForChild = false | ||
− | + | childCounter = 0 | |
− | + | adultCounterA = 0 | |
− | + | adultCounterB = 0 | |
− | + | sleepingChildren = 0 | |
− | + | waiters = 0 | |
− | |||
− | |||
− | |||
− | |||
− | |||
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− | |||
− | |||
− | |||
− | |||
− | + | pipe = new Communicator()</pre>}} | |
− | |||
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− | |||
− | } | ||
− | |||
− | |||
− | } | ||
− | + | Condition variables, all on lock: {{c|childrenWaitingOnA}}, {{c|adultsWaitingOnA}}, {{c|childrenWaitingOnB}}, {{c|adultsWaitingOnB}}, {{c|waitingToRide}}, {{c|waitingToPilot}} | |
− | + | In addition, each thread has a local variable to keep track of which island the person is currently on. | |
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− | If the child | + | ;Implementation overview |
+ | If there are no children on Molokai or if there are no adults left on Oahu, two children from Oahu will pilot over and one will return to Molokai. If there is a child on Molokai, an adult will pilot over to Molokai and the child will bring the boat back to Oahu. This process, carried to completion eventually results in all of the adults and children on Molokai. Each thread will attempt to acquire the lock (which essentially represents control over the boat). If the thread can perform one of the tasks fitting for the current state of the world, it executes it. Otherwise, it will go to sleep on the condition variable corresponding to its current role and location. | ||
− | + | ;Implementation details | |
− | + | Each child will begin running on Oahu and try to acquire the lock. | |
− | |||
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− | |||
− | |||
− | If | + | If the child is on Oahu and the boat is available for use (i.e. {{c|<nowiki>boatLookingForChild == false</nowiki>}} and {{c|<nowiki>boatPilot == null</nowiki>}} and {{c|<nowiki>boatDeparting == false</nowiki>}}), it will assume the role of pilot and set the {{c|boatLookingForChild}} variable to true, then going to sleep on {{c|waitingToPilot}}. Once a passenger child is found, the pilot will be awoken by the passenger child and pilot them both to Molokai, while the passenger goes to sleep on {{c|waitingToRide}}. He then increments the {{c|childCounter}}, wakes up the passenger child so that he can ride to Molokai, and goes back to sleep. |
− | + | The passenger, upon arrival at Molokai, increments the {{c|childCounter}} and speaks to {{c|begin()}} the number of children on Molokai. The child passenger then wakes up the pilot and goes to sleep on {{c|childrenWaitingOnB}}. Once the pilot child reawakens, he returns to Oahu, decrementing {{c|childCounter}} before departure. | |
− | |||
− | |||
− | |||
− | sleep on | ||
− | } | ||
− | + | Upon return to Oahu, if the number of adults on Oahu (according to {{c|adultsWaitingOnA}}) is not 0 and there is still a child left on Molokai to row the boat back after the adult goes across (according to {{c|childCounter}}), the pilot wakes up the adults waiting on A, puts himself to sleep on {{c|childrenWaitingOnA}}, releases the lock after wake, and restarts the looop. Otherwise, he simply releases the lock and restarts the loop. | |
− | |||
− | + | The adults all begin on Oahu, try to acquire the lock, and each initially increment {{c|adultCounterA}}. | |
− | |||
− | |||
− | |||
− | |||
− | If the adult is on | + | If the adult is on Oahu, the boat is available for use, and there is at least one child on Molokai according to {{c|childCounter}}, the adult pilots to Molokai. Otherwise, he wakes a child on {{c|childrenWaitingOnA}} and goes to sleep on {{c|adultsWaitingOnA}}. |
− | + | If the adult does pilot across, he increments {{c|adultCounterB}} upon arrival to Molokai, speaks to {{c|begin()}} the value of {{c|childCounter}}, wakes up a child from {{c|childrenWaitingOnB}} so that he can pilot the boat back to Oahu, and then puts himself to sleep on {{c|adultsWaitingOnB}}. The adult is now done and will never be woken again. | |
− | |||
− | |||
− | |||
− | |||
− | |||
− | |||
− | |||
− | + | If a child is sleeping on Molokai on {{c|childrenWaitingOnB}} and gets woken by an adult, he will decrement {{c|childCounter}} and pilot himself back to Oahu. Upon arrival, he releases the lock and restarts the loop. | |
− | + | For both adults and children, if the boat is busy or inaccessible as determined by the state of the {{c|boatPilot}}, {{c|boatDeparting}}, {{c|boatLookingForChild}}, and {{c|boatIsland}} variables given the person's current location, each will go back to sleep on the appropriate condition variable (i.e. {{c|childrenWaitingOnA}} for child threads on Oahu). | |
− | |||
− | sleep on | ||
− | |||
− | |||
− | |||
− | + | ;{{c|begin()}} behavior | |
+ | {{c|begin()}} creates the required number of child and adult threads and then forks them. Then, it begins to {{c|listen()}} on the one shared Communicator ({{c|pipe}}). When {{c|begin()}} receives a message, it checks the "spoken" number as well as {{c|adultCounterB}} against the number of spawned threads to see if everyone is across yet. | ||
+ | The reason that it does not check the value of {{c|childCounter}} directly is because by the time it receives the message, it is possible that a child has already piloted back to Oahu, thus decrementing the counter and preventing {{c|begin()}} from knowing the true number of children on Molokai. | ||
===Testing=== | ===Testing=== | ||
Line 334: | Line 373: | ||
Finally, we tested larger numbers of both adults and children and verified that the rowing patterns were correct. We tested both combinations with more adults than children and vice versa. The rowing pattern, as well as number of people on Molokai, was monitored to make sure no rules were being violated. | Finally, we tested larger numbers of both adults and children and verified that the rowing patterns were correct. We tested both combinations with more adults than children and vice versa. The rowing pattern, as well as number of people on Molokai, was monitored to make sure no rules were being violated. | ||
+ | |||
+ | ==Design questions== | ||
+ | ;Why is it fortunate that we did not ask you to implement priority donation for semaphores? | ||
+ | :Currently, each time a thread acquires a lock or calls {{c|join()}}, we know who is currently holding the resource. This allows us to donate priority to this single resource if a higher-priority thread begins waiting on it. With semaphores, this is not possible for initial values greater than 1, because the last thread to successfully "acquire" the semaphore will not necessarily be the one with the lowest priority. The implementation would need to change to keep track of all threads that are actually using the semaphore currently and thus be able to determine which of those has the lowest priority and needs to "receive" a donation. | ||
+ | ;A student proposes to solve the boats problem by use of a counter, AdultsOnOahu. Since this number isn't known initially, it will be started at zero, and incremented by each adult thread before they do anything else. Is this solution likely to work? Why or why not? | ||
+ | :No, because there is no way of enforcing the fact that everyone will increment it before they do anything else. |
Latest revision as of 03:51, 20 February 2023
Contents
KThread.join()
Implementation
- New state variables
KThread
has a new state variable joinedOnMe
, a ThreadQueue
, and isJoined
, a boolean
- Implementation details
- When
threadA
callsthreadB.join()
,threadB
adds it to its internaljoinedOnMe
queue and then puts it to sleep. InthreadB
'sfinish()
method,threadB
callsnextThread()
on itsjoinedOnMe
queue before returning. join()
also checks that this thread is not equal to the current thread and thatjoinedOnMe
is not already occupied by another thread with a boolean flag, which determines whetherjoin()
has already been called on this thread.
Testing
threadA
prints out a few statements, callsthreadB.join()
, then prints out a few more statements.threadB
also prints out a series of statements. We then verify thatthreadB
executes contiguously to completion beforethreadA
resumes its execution, as evidenced by the sequence of printed statements.- Have a thread attempt to
join()
to itself, calljoin()
on a second thread multiple times, and attempt to calljoin()
on a third finished thread (all separately). These should all return immediately as this is the expected behavior. - Test a chain of threads. Thread C will attempt to join Thread B. Thread B will attempt to join Thread A. Thread A forks last. Verify that A executes before B, and B executes before C.
Pseudocode
join() {
Disable interrupts;
If (CurrentThread == self or isJoined) or (status is Finished) {
Re-enable interrupts;
Return; // conditions for join not satisfied
} else {
add CurrentThread to joinedOnMe queue;
isJoined = true;
Sleep the currentThread;
}
Re-enable interrupts;
}
finish() {
// Interrupts have been disabled.
...(existing code)...
Ready the thread on the joinedOnMe queue;
Sleep (existing);
}
Condition2.java
Implementation
- New state variables
Condition2 has a new state variable waitQueue
, a ThreadQueue
with transferPriority
flag set to false.
- Implementation details
- In the
sleep()
method, we disable interrupts, the current thread is added to thewaitQueue
of threads, the corresponding lock is released, and the current thread is put to sleep. When it wakes up, the thread attempts to reacquire the corresponding lock and interrupts are re-enabled. - The
wake()
method disables interrupts and retrieves the next thread fromwaitQueue
. If the thread returned is not null, that thread is readied. Finally, the interrupts are re-enabled. - The
wakeAll()
method also disables the interrupts and stores the next thread fromwaitQueue
as aKThread
variable,nextThread
. WhilenextThread
is not null, the method will ready that thread and setnextThread
to the next thread fromwaitQueue
. This procedure continues until there are no more threads inwaitQueue
.
Testing
Condition2.java
was tested using a class calledCondThread
, which implementsRunnable
. The class is instantiated with an integeriterations
, a lock, aCondition2
variable to callsleep()
on, and aCondition2
variable to callwake()
on. When aCondThread
runs, it acquires the lock, then enters a for-loop of 6 iterations. On each iteration, the thread will print out a debug statement noting that the current thread is on the ith iteration. When the loop iteration number is equal toiterations
, threads can take one of three actions:- If the thread's ID is '0', then that thread is the waking thread and calls
wake()
on its second condition variable. - If the thread's ID is '0-all', it calls
wakeAll()
on its second condition variable - Otherwise, it goes to sleep on its first condition variable. Using the output, we verify that the threads all run in the correct order and all execute to completion.
- If the thread's ID is '0', then that thread is the waking thread and calls
- Sleep several threads on the condition variable. Upon waking, these threads should print a unique statement and perform a
wake()
on the condition variable. Have one thread perform an initialwake()
on the condition variable and verify that all threads are executed. - Sleep several threads on several various condition variables. Verify via console print statements that the proper threads wake up at the correct times according to which condition variable they were sleeping on.
- Sleep several threads on the condition variable, then have one final thread wake them all with
wakeAll()
. Verify that all threads have woken up via console print statements. - Sleep several threads on several various condition variables, then have one thread call
wakeAll()
on one of the condition variables. Verify via console print statements that all the threads put to sleep on that condition variable wake up and that only those threads wake up.
Pseudocode
sleep() {
Disable Interrupts;
Add current thread to wait queue;
Release the lock;
Put the current thread to sleep;
Acquire the lock;
Re-enable Interrupts;
}
wake() {
AssertTrue (lock held by current thread);
Disable interrupts;
If there is a thread on the wait queue:
Remove the first thread and wake it;
Re-enable interrupts;
}
wakeAll() {
Disable interrupts;
While there are threads on the wait queue:
Remove the first thread and wake it;
Re-enable interrupts;
}
waitUntil()
Implementation
- New state variables
Alarm has a new instance variable, waitingThreads
, which is a Java PriorityQueue
of waiting threads with the target wake time as their priority. It also contains a new inner class named WaitingThread
, which contains a reference to a KThread
and its associated wakeTime
. The PriorityQueue waitingThreads
will be populated with instances of this inner class.
- Implementation details
waitUntil()
creates a new instance ofwaitingThread
, which will associate the current thread with the given time argument. It will then add thiswaitingThread
instance to thePriorityQueue
and put the current thread to sleep. This method is atomic.timerInterrupt()
peeks at the firstWaitingThread
in thewaitQueue
and checks if its associated wake time is less than or equal to the current time. If it is, this method will pop theWaitingThread
off thewaitQueue
and wake the associated thread. This process is repeated until the wake time of the firstWaitingThread
is greater than the current time.
Testing
- Have the timer interrupt print a debug statement, and have timed threads print the times they go to sleep and when they have woken up. Verify that they wake up relatively close to their expected wake time.
- Make sure threads called with illegal times return immediately. Test threads that go to sleep chronologically in order (1, 500, 1050) as well as threads that go to sleep with the same times (50, 50) and threads that go to sleep in reverse order (500, 250). Verify they all wake up when they are supposed to.
Pseudocode
waitUntil(time){
Disable interrupts;
Create a new waitingThread;
Add the waiting thread to the priority queue;
Sleep the current thread;
Re-enable interrupts;
}
timerInterrupt(){
AssertTrue (interrupts have already been disabled);
For all waitingThreads that have exceeded their associated wait time;
Wake their associated threads and remove from queue;
}
Communicator
Implementation
- New state variables
Lock lock = new Lock()
int activeSpeakers = 0
int waitingSpeakers = 0
int activeListeners = 0
int waitingListeners = 0
Condition speakers
Condition listeners
Condition return
- Implementation details
- The first lone speaker or listener will be counted as active, or in the process of exchanging a message and returning, and will sleep on the
return
condition variable until its counterpart wakes it up so that they can both return. - A second thread performing the same action as a currently active thread will be counted as waiting, and be put to sleep on its respective condition variable. Otherwise, it will check if there is an active thread of its counterpart action waiting on the
return
condition variable. If there isn't, it will attempt to wake waiting threads of its counterpart action prior to going to sleep on the return condition variable. If there is a counterpart active thread, it will wake it up and they both will return. Prior to returning, the counterpart action will also attempt to wake waiting threads of its type. - Any interjecting threads that execute in between an exchange of message will be stopped by the active counters, which do not decrement until both counterparts in the exchange have returned.
Testing
Our original solution exhibited non-deterministic behavior, so after rewriting it, we decided to stress it exceptionally to make sure that it was working correctly. We tested our communicator in three main ways.
First, we set up a manual sequence of speak()
and listen()
actions on different threads and executed them in a particular order, verifying that the resulting sequence of messages was correct, monitored via print statements to the console
Second, we set off a random number of speakers, followed by a random number of listeners, and verified that the limiting resource was completely used up, i.e. that a matching number of speakers and listeners returned and that this was equal to the smaller of numbers of created speakers/listeners.
Finally, we repeated the same procedure, but intermingled the creation of speakers and listeners via .fork()
, such that listeners would start listening before all the speakers were queued up.
The latter two tests were run with up to 500 threads of speakers and listeners each (with a temporary override on the number of max threads in Nachos) and the number of listen and speak operations was analyzed via script. The speakers and listeners would print statements while executing code, which allowed us to perform this analysis.
To be able to perform these tests, we created a number of helper classes which implement Runnable. MassSpeaker
and MassListener
are designed to be run by a single thread each. These will iterate until a given limit, and on each iteration, there is a 50% chance that a speak (or listen) is called. After each iteration, the thread yields to the opposite thread to do the same. Debug statements will display what threads are doing at each iteration and how messages are being exchanged. With this we can generate large amounts of calls with randomized orders between two threads, and will be able to verify all speaks are correctly received by a listen.
A second set of runnables, MassTSpeaker
and MassTListener
, are designed to fork off several threads themselves, with each of these forked threads performing a single speak or listen. These forked threads are also executed with 50% chance on each iteration to provide random ordering. We can also verify if all threads are correctly paired off via print statements to console.
Pseudocode
speak(int word) { Acquire the lock; while (There is an active speaker) { WS++; Sleep as a waiting speaker; WS--; } AS++; Set the word; if (There is an active listener) { Wake the active listener; Release the lock; Return; } else { if (There are waiting listeners) { Wake a waiting listener; } Sleep as waiting to return; AS--; AL--; if (There are waiting speakers) { Wake a waiting speaker; } Release the lock; Return; } } |
listen() { Acquire the lock; while (There is an active listener) { WL++; Sleep as a waiting listener; WL--; } AL++; if (There is an active speaker) { Wake an active speaker; Store the word; Release the lock; Return the word; } else { if (There are waiting speakers) { Wake a waiting speaker; } Sleep as waiting to return; AL--; AS--; if (There are waiting listeners) { Wake a waiting listener; } Store the word; Release the lock; Return the word; } } |
Priority Scheduler
Implementation
- New state variables
PriorityQueue.holder
- this ThreadState corresponds to the holder of the resource signified by thePriorityQueue.waitQueue
- an ArrayList of ThreadStates waiting on this resource. Unsorted.PriorityQueue.dirty
- set to true when a new thread is added to the queue, or any of the queues in the waitQueue flag themselves as dirty.PriorityQueue.effective
- the cached highest of the effective priorities in the waitQueue. This value is invalidated while dirty is true.
ThreadState.myResources
- collection of PriorityQueues that signify the Locks or other resources that this thread currently holds.ThreadState.waitingOn
- collection of PriorityQueues corresponding to resources that this thread has attempted to acquire but could not.ThreadState.effective
- the cached effective priority of this thread. this value is invalidated when dirty is trueThreadState.dirty
- set to true when this thread's priority is changed, or when one of the queues in myResources flags itself as dirty.
- Implementation overview
The idea here is that Thread
s keep track of the PriorityQueue
s corresponding to both the resources that they are currently holding and those that they want to hold. We can do this via hooks in PriorityQueue
's waitForAccess()
, acquire
, and nextThread
methods.
Once we have this, every time a thread tries to wait on a queue, or takes control of a queue, we can tell the queue that its overall effective priority may have changed, and it can, in turn, tell the thread that currently holds the resource that one of the PriorityQueue
s it holds may have had its priority changed. That holder can in turn tell the same to the PriorityQueue
s that it is waiting on, and so forth. Eventually a thread, which is holding a resource that everyone needs, but has a low priority, will be marked for priority recalculation and thus priority escalation.
At this point, recalculation is simple. The effective priority of a thread is the maximum of its own actual priority and the priorities of all the PriorityQueue
s that it currently holds. The effective priority of a PriorityQueue
is the maximum effective priority of all the threads waiting on it (if the queue is supposed to donate priority), and so on and so forth in a mutually recursive manner.
- Implementation details
PriorityQueue.nextThread()
- This method retrieves and removes the highest priority thread off the Priority-Time
ArrayList
. It then flags the previous holder of this resource asdirty
, and removes the queue from that holder's resource list. It then sets the retrieved thread to this queue's newholder
, and flags that thread asdirty
as well.
PriorityQueue.acquire(KThread thread)
- Sets the
holder
of this queue to the specified thread, bypassing the queue. Resets previousholder
and setsdirty
flags as innextThread()
.
PriorityQueue.pickNextThread()
- Simply retrieves the highest priority thread off this queue.
PriorityQueue.setDirty()
- Set this queue's
dirty
flag, and callssetDirty
on the current holder of this thread.
PriorityQueue.getEffectivePriority()
- If this queue is
dirty
, returns the maximum of each of theThreadState
s.getEffectivePriority()
in this queue. Those calls in turn become mutually recursive when they callgetEffectivePriority()
on thePriorityQueues
in theirmyResources
.
ThreadState.setPriority()
- This method will change the actual priority of the thread associated with the
ThreadState
. It then callssetDirty()
on this thread.
ThreadState.setDirty()
- Sets the
dirty
flag on this thread, then callssetDirty()
on each of thePriorityQueue
s that the thread is waiting for. Mutually recursive.
ThreadState.getEffectivePriority
- Like the analogue of this function in
PriorityQueue
, returns the (cached) priority if this thread is notdirty
; otherwise, recalculates by returning the max of the effective priorities of thePriorityQueue
s inmyResources
.
Testing
- Instantiate new threads and set their priorities in decreasing order. Have the threads state their priorities as they execute and verify that they were run in decreasing order according to their priorities.
- Verify donation works by creating a high priority thread and joining it to a low priority thread with a high priority thread already queued.
- Create complex set of interdependent threads and multiple locks, verify that execution order is correct.
Pseudocode
- PriorityQueue
public void waitForAccess(KThread thread)
add this thread to my waitQueue
thread.waitForAccess(this)
public void acquire(KThread thread)
if I have a holder and I transfer priority, remove myself from the holder's resource list
thread.acquire(this)
public KThread nextThread()
if I have a holder and I transfer priority, remove myself from the holder's resource list
if waitQueue is empty, return null
ThreadState firstThread = pickNextThread();
remove firstThread from waitQueue
firstThread.acquire(this);
return firstThread
public int getEffectivePriority()
if I do not transfer priority, return minimum priority
if (dirty)
effective = minimum priority;
for each ThreadState t in waitQueue
effective = MAX(effective, t.getEffectivePriority())
dirty = false;
return effective;
public void setDirty()
if I do not transfer priority, there is no need to recurse, return
dirty = true;
if I have a holder, holder.setDirty()
protected ThreadState pickNextThread()
ThreadState ret = null
for each ThreadState ts in waitQueue
if ret is null OR ts has higher priority/time ranking than ret
set ret to ts
return ret;
- ThreadState
public int getPriority()
return non-donated priority.
public int getEffectivePriority()
if (dirty) {
effective = non-donated priority
for each PriorityQueue pq that I am currently holding
effective = MAX(effective, pq.getEffectivePriority)
}
return effective;
public void setPriority(int priority)
set non-donated priority to the argument
setDirty();
public void setDirty()
if already dirty return
dirty = true;
for each of the PriorityQueues pq I am waiting on,
pq.setDirty
public void waitForAccess(PriorityQueue waitQueue)
add the waitQueue to my waitingOn list
if the waitQueue was previously in myResources, remove it and set its holder to null.
if waitQueue has a holder, set the queue to dirty to signify possible change in the queue's effective priority
public void acquire(PriorityQueue waitQueue)
add waitQueue to myResources list
if waitQueue was in my waitingOn list, remove it
setWaitQueue's holder to me
setDirty();
Boat.java
Implementation
- New state variables (all shared)
lock = new Lock()
boatIsland = Island.A
boatPilot = null
boatDeparting = false
boatLookingForChild = false
childCounter = 0
adultCounterA = 0
adultCounterB = 0
sleepingChildren = 0
waiters = 0
pipe = new Communicator()
Condition variables, all on lock: childrenWaitingOnA
, adultsWaitingOnA
, childrenWaitingOnB
, adultsWaitingOnB
, waitingToRide
, waitingToPilot
In addition, each thread has a local variable to keep track of which island the person is currently on.
- Implementation overview
If there are no children on Molokai or if there are no adults left on Oahu, two children from Oahu will pilot over and one will return to Molokai. If there is a child on Molokai, an adult will pilot over to Molokai and the child will bring the boat back to Oahu. This process, carried to completion eventually results in all of the adults and children on Molokai. Each thread will attempt to acquire the lock (which essentially represents control over the boat). If the thread can perform one of the tasks fitting for the current state of the world, it executes it. Otherwise, it will go to sleep on the condition variable corresponding to its current role and location.
- Implementation details
Each child will begin running on Oahu and try to acquire the lock.
If the child is on Oahu and the boat is available for use (i.e. boatLookingForChild == false
and boatPilot == null
and boatDeparting == false
), it will assume the role of pilot and set the boatLookingForChild
variable to true, then going to sleep on waitingToPilot
. Once a passenger child is found, the pilot will be awoken by the passenger child and pilot them both to Molokai, while the passenger goes to sleep on waitingToRide
. He then increments the childCounter
, wakes up the passenger child so that he can ride to Molokai, and goes back to sleep.
The passenger, upon arrival at Molokai, increments the childCounter
and speaks to begin()
the number of children on Molokai. The child passenger then wakes up the pilot and goes to sleep on childrenWaitingOnB
. Once the pilot child reawakens, he returns to Oahu, decrementing childCounter
before departure.
Upon return to Oahu, if the number of adults on Oahu (according to adultsWaitingOnA
) is not 0 and there is still a child left on Molokai to row the boat back after the adult goes across (according to childCounter
), the pilot wakes up the adults waiting on A, puts himself to sleep on childrenWaitingOnA
, releases the lock after wake, and restarts the looop. Otherwise, he simply releases the lock and restarts the loop.
The adults all begin on Oahu, try to acquire the lock, and each initially increment adultCounterA
.
If the adult is on Oahu, the boat is available for use, and there is at least one child on Molokai according to childCounter
, the adult pilots to Molokai. Otherwise, he wakes a child on childrenWaitingOnA
and goes to sleep on adultsWaitingOnA
.
If the adult does pilot across, he increments adultCounterB
upon arrival to Molokai, speaks to begin()
the value of childCounter
, wakes up a child from childrenWaitingOnB
so that he can pilot the boat back to Oahu, and then puts himself to sleep on adultsWaitingOnB
. The adult is now done and will never be woken again.
If a child is sleeping on Molokai on childrenWaitingOnB
and gets woken by an adult, he will decrement childCounter
and pilot himself back to Oahu. Upon arrival, he releases the lock and restarts the loop.
For both adults and children, if the boat is busy or inaccessible as determined by the state of the boatPilot
, boatDeparting
, boatLookingForChild
, and boatIsland
variables given the person's current location, each will go back to sleep on the appropriate condition variable (i.e. childrenWaitingOnA
for child threads on Oahu).
begin()
behavior
begin()
creates the required number of child and adult threads and then forks them. Then, it begins to listen()
on the one shared Communicator (pipe
). When begin()
receives a message, it checks the "spoken" number as well as adultCounterB
against the number of spawned threads to see if everyone is across yet.
The reason that it does not check the value of childCounter
directly is because by the time it receives the message, it is possible that a child has already piloted back to Oahu, thus decrementing the counter and preventing begin()
from knowing the true number of children on Molokai.
Testing
We tested different numbers of both children and adults and verified by hand that the sequence of events, in terms of rowing from one island to the other, was correct.
First, we tried various numbers of children with no adults at all: the base case of two children, then a small but odd number of children, and then large numbers of both odd and even amounts of children.
Then, we tested having small numbers of children and adults together, with a greater number of children than adults, both odd and even-number combinations. Again, we monitored that the rowing pattern was correct by hand. We also watched the number of people who have arrived at Molokai and made sure that these numbers made sense.
Finally, we tested larger numbers of both adults and children and verified that the rowing patterns were correct. We tested both combinations with more adults than children and vice versa. The rowing pattern, as well as number of people on Molokai, was monitored to make sure no rules were being violated.
Design questions
- Why is it fortunate that we did not ask you to implement priority donation for semaphores?
- Currently, each time a thread acquires a lock or calls
join()
, we know who is currently holding the resource. This allows us to donate priority to this single resource if a higher-priority thread begins waiting on it. With semaphores, this is not possible for initial values greater than 1, because the last thread to successfully "acquire" the semaphore will not necessarily be the one with the lowest priority. The implementation would need to change to keep track of all threads that are actually using the semaphore currently and thus be able to determine which of those has the lowest priority and needs to "receive" a donation. - A student proposes to solve the boats problem by use of a counter, AdultsOnOahu. Since this number isn't known initially, it will be started at zero, and incremented by each adult thread before they do anything else. Is this solution likely to work? Why or why not?
- No, because there is no way of enforcing the fact that everyone will increment it before they do anything else.