itcs3146-project/NextFit.java

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/* David P. Turnbull
ITCS3146
group project
this class sets up a First Fit memory scheme
*/
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import java.lang.reflect.*;
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//this section sets up the Car class
class NextFit implements baseAlgorithm
{
//this section sets up the private elements of the class
private int jobId,
jobSize,
jobTime,
startLoc,
endLoc,
blkSize,
memSize = memoryManagement.MEMORYSIZE,
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active,
noJobs=0,
s1=0,
currentPosition=0,
positionToCompress=0,
loopCount,
compMemTest=0,
tableEntries=1;
private int[] tempVal = new int[6];
private int[][] memTable = new int[memSize+2][6];
private int[] memory = new int[memSize];
//this is a no argument constructor
public NextFit()
{
memTable[0][0]=0; //job number
memTable[0][1]=0; //job size
memTable[0][2]=0; //start location in memory
memTable[0][3]=memSize-1; //end location in memory
memTable[0][4]=memSize; //mem blk size size
memTable[0][5]=-1; //status, 0=not active, 1=active, -1=special
}
//this method sets the job up
public void allocate(int ID, int size, int jTime)
{
jobId = ID;
jobSize = size;
jobTime = jTime;
noJobs++;
s1=0;
loopCount=0;
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//Bradlee's code ***********************************************************************************
try
{
Method deallocateMethod = this.getClass().getMethod("deallocate", new Class[]{int.class, int.class});
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//checks to see if the job will fit in memory
if(jobSize>memSize)
{
System.out.println("\n\n*********************************************************"+
" THIS JOB IS TO LARGE TO FIT INTO MEMORY"+
"*********************************************************");
System.exit(0);
}
//this section looks for a place to put the new job
do
{
if(memTable[currentPosition][5]==-1 && memTable[currentPosition][4]>=jobSize &&
memTable[currentPosition][3]==memSize-1)
{
//runs only for the first job
if(noJobs==1)
{
memTable[currentPosition][0] = jobId;
memTable[currentPosition][1] = jobSize;
memTable[currentPosition][2] = 0;
memTable[currentPosition][3] = jobSize-1;
memTable[currentPosition][4] = memTable[0][3]-memTable[0][2]+1;
memTable[currentPosition][5] = 1;
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Job newJob = new Job(jobTime, jobId, jobSize, memTable[currentPosition][2], deallocateMethod, this);
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fillMemory(jobId, jobSize, memTable[currentPosition][2]);
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newJob.start();
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memTable[currentPosition+1][0] = 0;
memTable[currentPosition+1][1] = 0;
memTable[currentPosition+1][2] = memTable[currentPosition][3]+1;
memTable[currentPosition+1][3] = memSize-1;
memTable[currentPosition+1][4] = memSize-memTable[currentPosition+1][2];
memTable[currentPosition+1][5] = -1;
currentPosition++;
positionToCompress=currentPosition;
tableEntries++;
s1=memSize*2;
}
//runs after the first job and if the only available slot is at the end of memory
else
{
memTable[currentPosition][0] = jobId;
memTable[currentPosition][1] = jobSize;
memTable[currentPosition][2] = memTable[currentPosition-1][3]+1;
memTable[currentPosition][3] = jobSize+memTable[currentPosition][2]-1;
memTable[currentPosition][4] = memTable[currentPosition][3]-memTable[currentPosition][2]+1;
memTable[currentPosition][5] = 1;
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Job newJob = new Job(jobTime, jobId, jobSize, memTable[currentPosition][2], deallocateMethod, this);
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fillMemory(jobId, jobSize, memTable[currentPosition][2]);
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newJob.start();
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memTable[currentPosition+1][0] = 0;
memTable[currentPosition+1][1] = 0;
memTable[currentPosition+1][2] = memTable[currentPosition][3]+1;
memTable[currentPosition+1][3] = memSize-1;
memTable[currentPosition+1][4] = memSize-memTable[currentPosition+1][2];
memTable[currentPosition+1][5] = -1;
tableEntries++;
currentPosition++;
positionToCompress=currentPosition;
s1=memSize*2;
}
}
//checks for first available free block that has been deallocated
else if(memTable[currentPosition][4]>=jobSize && memTable[currentPosition][5]==0)
{
memTable[currentPosition][0] = jobId;
memTable[currentPosition][1] = jobSize;
memTable[currentPosition][5] = 1;
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Job newJob = new Job(jobTime, jobId, jobSize, memTable[currentPosition][2], deallocateMethod, this);
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fillMemory(jobId, jobSize, memTable[currentPosition][2]);
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newJob.start();
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currentPosition++;
positionToCompress=currentPosition;
s1=memSize*2;
}
else if(currentPosition==tableEntries-1)
{
currentPosition=0;
s1++;
}
else
{
s1++;
currentPosition++;
}
}while(s1<tableEntries);
//if job will not fit this section will compress memory and try placing the job again
if(s1==tableEntries)
{
noJobs=noJobs-1;
compMem();
currentPosition=0;
positionToCompress=0;
allocate(ID, size, jobTime);
}
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} catch (Exception e)
{
System.out.println("Could not allocate job with ID " + jobId);
}
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}
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//this method is used if you want to deallocate a job by jobId
public void removeJob(int ID)
{
jobId = ID;
s1=0;
do
{
if(memTable[s1][0] == jobId)
{
jobSize = memTable[s1][1];
startLoc = memTable[s1][2];
s1=memSize*2;
}
else
{
s1++;
}
}while (s1<tableEntries);
deallocate(jobSize, startLoc);
}
//this method removes a job it does not check to see if the job exisits
public void deallocate(int jobSize, int beginningLocation)
//public void removeJob(int ID)
{
jobId = 0;
jobSize = jobSize;
startLoc = beginningLocation;
s1=0;
do
{
if(memTable[s1][2] == startLoc)
{
memTable[s1][0] = 0;
memTable[s1][1] = 0;
memTable[s1][5] = 0;
s1=memSize*2;
jobId=-1;
noJobs--;
}
else
{
s1++;
}
}while (s1<tableEntries);
}
//this method compacts the memory
public void compMem()
{
compMemTest=tableEntries;
for(int c=0; c<=compMemTest; c++)
{
//this section checks to see if two unused blks are next to each other and then
//comdines them
if(memTable[c][5]==0 && memTable[c+1][5]==0)
{
tempVal[0] = memTable[c+1][0];
tempVal[1] = memTable[c+1][1];
tempVal[2] = memTable[c+1][2];
tempVal[3] = memTable[c+1][3];
tempVal[4] = memTable[c+1][4];
tempVal[5] = memTable[c+1][5];
memTable[c+1][0]=-1;
memTable[c+1][1]=-1;
memTable[c+1][2]=-1;
memTable[c+1][3]=-1;
memTable[c+1][4]=-1;
memTable[c+1][5]=-1;
memTable[c][0]=0;
memTable[c][1]=0;
memTable[c][3]=tempVal[3];
memTable[c][4]=memTable[c][4]+tempVal[4];
memTable[c][5]=0;
//this loop shifts the remaining jobs up
for(int srt=c+1; srt<tableEntries; srt++)
{
memTable[srt][0]=memTable[srt+1][0];
memTable[srt][1]=memTable[srt+1][1];
memTable[srt][2]=memTable[srt+1][2];
memTable[srt][3]=memTable[srt+1][3];
memTable[srt][4]=memTable[srt+1][4];
memTable[srt][5]=memTable[srt+1][5];
}
memTable[tableEntries-1][0]=-1;
memTable[tableEntries-1][1]=-1;
memTable[tableEntries-1][2]=-1;
memTable[tableEntries-1][3]=-1;
memTable[tableEntries-1][4]=-1;
memTable[tableEntries-1][5]=-1;
c--;
}
}
s1=0;
for(int c1=0; c1<tableEntries; c1++)
{
if(memTable[c1][0]==-1)
{
s1++;
}
}
tableEntries=tableEntries-s1;
if(memTable[tableEntries-2][5]==0 && memTable[tableEntries-1][5]==-1)
{
memTable[tableEntries-2][3]=memTable[tableEntries-1][3];
memTable[tableEntries-2][4]=memTable[tableEntries-1][4]+memTable[tableEntries-2][4];
memTable[tableEntries-2][5]=-1;
tableEntries--;
}
currentPosition = 0;
positionToCompress = 0;
}
//this method fills the memory location with the data
private void fillMemory(int job, int size, int start)
{
jobId=job;
jobSize=size;
startLoc=start;
for(int fillCount=startLoc; fillCount<jobSize+startLoc; fillCount++)
{
memory[fillCount]=jobId;
}
}
//this method returns a String of all the elements stored in the object
public String toString()
{
String str;
str = ("\n\nJob ID\tJob Size\tStart Loc\tEnd Loc\tMem Blk Size\tStatus");
for(int cnt=0; cnt<tableEntries; cnt++)
{
str = (str+"\n"+memTable[cnt][0]+"\t"+memTable[cnt][1]+"\t\t"+memTable[cnt][2]+"\t\t"+
memTable[cnt][3]+"\t\t"+memTable[cnt][4]+"\t"+memTable[cnt][5]);
}
return str;
}
}