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CMPUT 379 – Operating System Concepts
Assignment 2 – MapReduce Library

Objective
This programming assignment is intended to give you experience in using POSIX threads and synchronization
primitives.
MapReduce Paradigm
MapReduce is a programming model and a distributed computing paradigm for large-scale data processing. It
allows for applications to run various tasks in parallel, making them scalable and fault-tolerant. To use the MapReduce infrastructure, developers need to write just a little bit of code in addition to their program. They do not need
to worry about how to parallelize their program; the MapReduce runtime will make this happen!
To use the MapReduce infrastructure, developers must implement two callback functions, namely Map and Reduce.
The Map function takes a filename as input and generates intermediate key/value pairs from the data stored in that
file. The Reduce function processes a subset of intermediate key/value pairs, summarizing all values associated
with the same key. The summary operation typically reduces the list of values associated with a key to a single value. It could be as simple as summing up numerical values (e.g., in a distributed word count program) or
concatenating string values (e.g., in a distributed grep program) associated with the same key.
The MapReduce infrastructure utilizes three types of computing resources as shown in Figure 1:
1. workers executing the Map function (mappers);
2. workers executing the Reduce function (reducers);
3. a master (controller) assigning tasks to the two types of workers mentioned above.
These computing resources can be threads running on a multicore system or nodes in a distributed system. The
numbers of mappers and reducers must be specified by the developer. Depending on the workload, adding more
workers could improve the performance or not.
Your Task
In this programming assignment you are going to build a MapReduce library in C or C++ utilizing POSIX threads
and synchronization primitives. This library will support the execution of user-defined Map and Reduce functions
on a multicore system. The original MapReduce paper1
shows the programming paradigm to work in a distributed
computing environment where each worker in the map phase has its own set of intermediate key/value pairs stored
locally. These intermediate pairs are then distributed across the workers (in the shuffle phase) before the reduce
phase starts.
You will implement a different version of MapReduce in this assignment. We assume individual workers are
threads running on the same system. Hence, your MapReduce library should create a fixed number of mapper
threads (kept in reserve in a thread pool) and a fixed number of reducer threads to run the computation in parallel.
1Dean, J., & Ghemawat, S. (2008). MapReduce: Simplified Data Processing on Large Clusters. Communications of the ACM, 51(1),
107-113.
1
create
create
create create
Master
Mapper 0
Mapper 1
Mapper M-1 . . .
Reducer 0
Reducer 1
Reducer R-1 . . .
Split 0
Split 1
Split K – 1 . . .
Partition 0 . . .
Partition 1
Partition R-1
result-0.txt
result-1.txt
result-R-1.txt
thread
pool
Figure 1: MapReduce execution overview
Implementing the thread pool using synchronization primitives is a central challenge of this assignment. You are
not allowed to use an existing thread pool library.
Since the intermediate key/value pairs are stored in shared data structures, your MapReduce library must also use
synchronization primitives to access this data. Otherwise, the data will be overwritten and lost. Designing and
implementing this data structure is another challenge of the assignment.
MapReduce Execution
MapReduce execution can be divided into 7 steps that must be completed one after the other. These steps are
explained below:
1. Creating mappers: the master thread creates M mapper threads in the MR Run library function where M
is an argument of this function. The mapper threads are in a thread pool implemented using synchronization
primitives, such as mutex locks and condition variables. By maintaining a fixed number of threads, the
thread pool helps to minimize the thread creation and destruction overhead. Note that the master thread will
wait for the mapper threads to process all splits in the map phase before moving on to the reduce phase.
2. Assigning data splits to mappers: in the MR Run function, the master thread iterates over K input data
splits (represented by K files) and submits a job for each split to the thread pool. If there is an idle mapper
thread in the thread pool, it starts processing the job right away by invoking the user-defined Map function
with the passed argument (i.e., the filename). Otherwise, the job is added to a queue to be processed later
by an idle mapper thread. The master ensures that each split is processed exactly once. Note that there are
several different ways that jobs can be assigned to idle mapper threads; your implementation should use the
longest job first policy. This policy assigns the longest job (i.e., the largest input file) in the queue to the next
idle mapper thread. To check the size of each input file, you can use the stat system call.
2
3. Running the user-defined Map function: each mapper runs the user-defined Map function on a given split
to generate key/value pairs. Every time a key/value pair is generated, the Map function invokes the MR Emit
library function, to write the intermediate key/value pair to a particular shared data structure. Since multiple
mapper threads may attempt to concurrently update a shared data structure, this library function must use
proper synchronization primitives, such as mutex locks.
4. Partitioning the map output: when the MR Emit function is called by a mapper thread, it first determines
where to write the given key/value pair by calling the MR Partition function. The MR Partition
function takes a key and maps it to an integer between 0 and R − 1, which indicates the data structure the
key/value pair must be written to. This way MR Partition allows the MapReduce library to create R
separate data structures (i.e., partitions), each containing a subset of keys and the value list associated with
each of them. Once the partition that a key/value pair must be written to is identified, MR Emit inserts the
pair in a certain position in that partition, keeping the partition sorted in ascending key order at all times.
This is necessary for the MR GetNext library function to easily distinguish when a new reduce task should
start, which is exactly when the next key in the sorted partition is different from the previous key.
5. Creating reducers: the master thread terminates the mapper threads when all K splits are processed in the
map phase. It then creates R reducer threads in the MR Run library function where R is an argument of
this function. Each reducer thread is responsible for processing data in a particular partition; hence, the ith
partition (0 ≤ i < R) is assigned to the ith reducer. Each reducer thread runs the MR ProcessPartition
library function which takes as input the index of the partition assigned to it.
6. Running the user-defined Reduce function: the MR ProcessPartition library function invokes the
user-defined Reduce function on the next unprocessed key in the given partition in a loop. Thus, Reduce
is invoked only once for each key. To perform the summary operation, the Reduce function calls the
MR GetNext library function to iterate over all values that have the same key in its partition. The MR GetNext
function returns the next value associated with the given key in the sorted partition or NULL when the key’s
values have been processed completely.
7. Producing the final output: each reducer thread writes the result of the summary operation performed
on the value list associated with the passed key to a file named result- These output files are created initially by the reducer threads. The master thread terminates a reducer thread
as soon as all keys in its corresponding partition are processed. The master thread frees up its resources and
returns from the MR Emit function once all keys in all R partitions are processed.
The MapReduce Library
We now describe the functions in the mapreduce.h header file (included in the starter code) to help you understand how to write your MapReduce library:
// function pointer types used by library functions
typedef void (*Mapper)(char *file_name);
typedef void (*Reducer)(char *key, int partition_number);
// library functions you must define
void MR_Run(int num_files, char *filenames[],
Mapper map, int num_mappers,
Reducer concate, int num_reducers);
void MR_Emit(char *key, char *value);
unsigned long MR_Partition(char *key, int num_partitions);
3
void MR_ProcessPartition(int partition_number);
char *MR_GetNext(char *key, int partition_number);
The MapReduce execution is started off by a call to MR Run in the user program. This function is passed an array
of filenames containing K data splits, that is filenames[0], · · · , filenames[K − 1] (K = num files). Additionally,
the MR Run function is passed the number of mappers M, the number of reducers R, and two function pointers
for Map and Reduce functions. The main thread that runs the MR Run function is the master thread. It creates M
mappers and R reducers as depicted in Figure 1.
The MR Emit library function takes a key and a value associated with it, and writes this pair to a specific partition
which is determined by passing the key to the MR Partition library function. This function can be any “good”
hash function such as CRC32, MurmurHash, or the following algorithm known as DJB2:
unsigned long MR_Partition(char *key, int num_partitions) {
unsigned long hash = 5381;
int c;
while ((c = *key++) != ‘\0’)
hash = hash * 33 + c;
return hash % num_partitions;
}
You can use the above hash function or the open-source implementation of a well-known hash function. Make sure
to cite your sources in the readme file.
The MR ProcessPartition library function takes the index of the partition assigned to the thread that runs
it. It invokes the user-defined Reduce function in a loop, each time passing it the next unprocessed key. This
continues until all keys in the partition are processed.
The MR GetNext library function takes a key and a partition number, and returns a value associated with the key
that exists in that partition. In particular, the ith call to this function should return the ith value associated with the
key in the sorted partition or NULL if i is greater than the number of values associated with the key.
In the following section, we provide an example user program which is useful for testing your MapReduce library.
Your task is to implement the library assuming that there exists a parallelizable user program that includes your
library and calls the MR Run function.
Example Map and Reduce Functions
To illustrate how the library functions are invoked from the user program, we describe a simple distributed word
count program, distwc.c, which uses the MapReduce library. A word count program counts the number of
times each word appears in a given set of files. We will assume that the filenames are valid and the files exist in
the file system. This main function takes a list of text files and passes it to MR Run along with the numbers of
mappers and reducers, and two function pointers. All the developer has to do is to include the MapReduce library
and implement Map and Reduce functions. The distributed word count program is described below.
#include <assert.h
#include <stdio.h
#include <stdlib.h
#include <string.h
#include “mapreduce.h”
4
Generated
Key/Value
Pairs
Mapper 1
Mapper 2
Mapper
Car: 1
River: 1
Car: 1
Tea: 1
River: 1
Bear: 1
Bee: 1
Cat: 1
Bird: 1
River: 1
River Bear Bee …
File
File
Car River Car Tea
Cat Bird River …
File
Hash function
Car: 1
Car: 1
Cat: 1
Bear: 1
Bee: 1
Tea: 1
River: 1
River: 1
River: 1
Cat: 1
Cat: 1
Tea: 1
River: 1
Partition 1
Partition R
Partition 2
Bee: 1
Bear: 1
River: 1
Partition 2
Partition R
Bird: 1
Cat: 1
River: 1
Partition 2
Partition 1
Partition R
Sorted Intermediate
Data Structure
Partition 1
Partition 2
Partition R
Reducer 1
Reducer 2
Reducer
Output Files
Car: 2
Cat: 1
Bear: 1
Bee: 1
Tea: 1
River: 3
Splits
Figure 2: Example MapReduce data flow
void Map(char *file_name) {
FILE *fp = fopen(file_name, “r”);
assert(fp != NULL);
char *line = NULL;
size_t size = 0;
while (getline(&line, &size, fp) != -1) {
char *token, *dummy = line;
while ((token = strsep(&dummy, ” \t\n\r”)) != NULL) {
MR_Emit(token, “1”);
}
}
free(line);
fclose(fp);
}
void Reduce(char *key, int partition_number) {
int count = 0;
char *value, name[100];
while ((value = MR_GetNext(key, partition_number)) != NULL)
count++;
sprintf(name, “result-%d.txt”, partition_number);
FILE *fp = fopen(name, “a”);
fprintf(fp, “%s: %d\n”, key, count);
fclose(fp);
}
int main(int argc, char *argv[]) {
MR_Run(argc – 1, &(argv[1]), Map, 10, Reduce, 10);
}
Using Pthreads
To implement the MapReduce library, you must use the POSIX threads library (pthreads) for thread management.
See the man page of pthreads for more information. We are going to assume that the intermediate key/value pairs
5
are fixed during the reduce phase. Thus, you must wait until all mapper threads finish execution, before starting
the reduce phase.
Intermediate Data Structures
The data structures being used for the intermediate key/value pairs are shared among multiple threads. Hence, they
must be global variables in the MapReduce library and support concurrency for correctness. Each thread must
obtain the lock on a shared data structure before updating it. For locking and unlocking the data structure you will
use pthread mutex.
The implementation of the shared data structures is up to you. You might use data structures from C++ STL
or implement the data structures you need (if you write code in C, for example). While there are many ways
to implement this data structure, it must be thread-safe, and support efficient implementation of MR Emit and
MR GetNext functions.
Thread Pool
The MapReduce library adopts a thread pool library to create a fixed number of mapper threads and assign the task
of running the Map callback function on input files to them.
In this assignment, you will write your own thread pool library using POSIX mutex locks and condition variables.
Below we describe the functions and struct declarations in the threadpool.h header file to help you understand
what this library is supposed to do.
typedef void (*thread_func_t)(void *arg);
typedef struct ThreadPool_work_t {
thread_func_t func; // The function pointer
void *arg; // The arguments for the function
// TODO: add other members here if needed
} ThreadPool_work_t;
typedef struct {
// TODO: add members here
} ThreadPool_work_queue_t;
typedef struct {
// TODO: add members here
} ThreadPool_t;
/**
* A C style constructor for creating a new ThreadPool object
* Parameters:
* num – The number of threads to create
* Return:
* ThreadPool_t* – The pointer to the newly created ThreadPool object
*/
ThreadPool_t *ThreadPool_create(int num);
/**
* A C style destructor to destroy a ThreadPool object
6
* Parameters:
* tp – The pointer to the ThreadPool object to be destroyed
*/
void ThreadPool_destroy(ThreadPool_t *tp);
/**
* Add a task to the ThreadPool’s task queue
* Parameters:
* tp – The ThreadPool object to add the task to
* func – The function pointer that will be called in the thread
* arg – The arguments for the function
* Return:
* true – If successful
* false – Otherwise
*/
bool ThreadPool_add_work(ThreadPool_t *tp, thread_func_t func, void *arg);
/**
* Get a task from the given ThreadPool object
* Parameters:
* tp – The ThreadPool object being passed
* Return:
* ThreadPool_work_t* – The next task to run
*/
ThreadPool_work_t *ThreadPool_get_work(ThreadPool_t *tp);
/**
* Run the next task from the task queue
* Parameters:
* tp – The ThreadPool Object this thread belongs to
*/
void *Thread_run(ThreadPool_t *tp);
The ThreadPool create and ThreadPool destroy functions create and destroy the ThreadPool object,
respectively. Each thread created by ThreadPool create runs the Thread run function which gets a task
from the task queue and executes it (this is done in a loop). The ThreadPool destroy function should wait
until all tasks are executed before destroying the ThreadPool.
The ThreadPool add work function is used to submit a task (i.e., the execution of a function) to the thread
pool. You must create your own task queue and have a mechanism to support concurrency. The ThreadPool get work
function is used to get a task from the queue and have it processed by an idle thread.
You will have to define ThreadPool work t, ThreadPool work queue t, and ThreadPool t structs in
threadpool.h.
Deliverables
The starter code includes two header files, mapreduce.h and threadpool.h, and one example program,
distwc.c, that utilizes the MapReduce library. Your task is to implement the MapReduce and ThreadPool
libraries. You might modify mapreduce.h and threadpool.h.
7
Submit your assignment as a single compressed archive file (mapreduce.zip or mapreduce.tar.gz) containing:
1. A custom Makefile with at least these targets: (a) the main target wc which simply links all object files and
produces an executable file called wordcount, (b) the target compile which compiles your code and
the provided distributed word count program, and produces the object file(s), (c) the target clean which
removes the objects and executable files, and (d) the target compress which creates the compressed archive
for submission.
2. A plain text document, called readme.md, which explains how to store the intermediate key/value pairs,
the time complexity of MR Emit and MR GetNext functions, the data structure used to implement the task
queue in the thread pool library, and your implementation of the thread pool library. Furthermore, you need
to explain what synchronization primitives you used and how you tested the correctness of your code. Make
sure you cite all sources that contributed to your assignment in this file. You may use a markup language,
such as Markdown, to format this plain text file.
3. All files required to build your project including mapreduce.h and threadpool.h.
Misc. Notes
• This assignment must be completed individually without consultation with anyone besides the instructor
and TAs.
• You can write code in C or C++, and compile it with gcc or g++ passing -Wall -Werror -pthread
flags. No warnings should be returned when your code is compiled these flags. Make sure that your code
does not print anything extra for debugging.
• We encourage you to write more parallelizable programs that utilize the MapReduce library. Test your
MapReduce library using these programs with different numbers of mapper threads and reducer threads
besides the distributed word count program that we provided.
• You are not allowed to usCMPUT 379 – Operating System Concepts
Assignment 2 – MapReduce Library

Objective
This programming assignment is intended to give you experience in using POSIX threads and synchronization
primitives.
MapReduce Paradigm
MapReduce is a programming model and a distributed computing paradigm for large-scale data processing. It
allows for applications to run various tasks in parallel, making them scalable and fault-tolerant. To use the MapReduce infrastructure, developers need to write just a little bit of code in addition to their program. They do not need
to worry about how to parallelize their program; the MapReduce runtime will make this happen!
To use the MapReduce infrastructure, developers must implement two callback functions, namely Map and Reduce.
The Map function takes a filename as input and generates intermediate key/value pairs from the data stored in that
file. The Reduce function processes a subset of intermediate key/value pairs, summarizing all values associated
with the same key. The summary operation typically reduces the list of values associated with a key to a single value. It could be as simple as summing up numerical values (e.g., in a distributed word count program) or
concatenating string values (e.g., in a distributed grep program) associated with the same key.
The MapReduce infrastructure utilizes three types of computing resources as shown in Figure 1:
1. workers executing the Map function (mappers);
2. workers executing the Reduce function (reducers);
3. a master (controller) assigning tasks to the two types of workers mentioned above.
These computing resources can be threads running on a multicore system or nodes in a distributed system. The
numbers of mappers and reducers must be specified by the developer. Depending on the workload, adding more
workers could improve the performance or not.
Your Task
In this programming assignment you are going to build a MapReduce library in C or C++ utilizing POSIX threads
and synchronization primitives. This library will support the execution of user-defined Map and Reduce functions
on a multicore system. The original MapReduce paper1
shows the programming paradigm to work in a distributed
computing environment where each worker in the map phase has its own set of intermediate key/value pairs stored
locally. These intermediate pairs are then distributed across the workers (in the shuffle phase) before the reduce
phase starts.
You will implement a different version of MapReduce in this assignment. We assume individual workers are
threads running on the same system. Hence, your MapReduce library should create a fixed number of mapper
threads (kept in reserve in a thread pool) and a fixed number of reducer threads to run the computation in parallel.
1Dean, J., & Ghemawat, S. (2008). MapReduce: Simplified Data Processing on Large Clusters. Communications of the ACM, 51(1),
107-113.
1
create
create
create create
Master
Mapper 0
Mapper 1
Mapper M-1 . . .
Reducer 0
Reducer 1
Reducer R-1 . . .
Split 0
Split 1
Split K – 1 . . .
Partition 0 . . .
Partition 1
Partition R-1
result-0.txt
result-1.txt
result-R-1.txt
thread
pool
Figure 1: MapReduce execution overview
Implementing the thread pool using synchronization primitives is a central challenge of this assignment. You are
not allowed to use an existing thread pool library.
Since the intermediate key/value pairs are stored in shared data structures, your MapReduce library must also use
synchronization primitives to access this data. Otherwise, the data will be overwritten and lost. Designing and
implementing this data structure is another challenge of the assignment.
MapReduce Execution
MapReduce execution can be divided into 7 steps that must be completed one after the other. These steps are
explained below:
1. Creating mappers: the master thread creates M mapper threads in the MR Run library function where M
is an argument of this function. The mapper threads are in a thread pool implemented using synchronization
primitives, such as mutex locks and condition variables. By maintaining a fixed number of threads, the
thread pool helps to minimize the thread creation and destruction overhead. Note that the master thread will
wait for the mapper threads to process all splits in the map phase before moving on to the reduce phase.
2. Assigning data splits to mappers: in the MR Run function, the master thread iterates over K input data
splits (represented by K files) and submits a job for each split to the thread pool. If there is an idle mapper
thread in the thread pool, it starts processing the job right away by invoking the user-defined Map function
with the passed argument (i.e., the filename). Otherwise, the job is added to a queue to be processed later
by an idle mapper thread. The master ensures that each split is processed exactly once. Note that there are
several different ways that jobs can be assigned to idle mapper threads; your implementation should use the
longest job first policy. This policy assigns the longest job (i.e., the largest input file) in the queue to the next
idle mapper thread. To check the size of each input file, you can use the stat system call.
2
3. Running the user-defined Map function: each mapper runs the user-defined Map function on a given split
to generate key/value pairs. Every time a key/value pair is generated, the Map function invokes the MR Emit
library function, to write the intermediate key/value pair to a particular shared data structure. Since multiple
mapper threads may attempt to concurrently update a shared data structure, this library function must use
proper synchronization primitives, such as mutex locks.
4. Partitioning the map output: when the MR Emit function is called by a mapper thread, it first determines
where to write the given key/value pair by calling the MR Partition function. The MR Partition
function takes a key and maps it to an integer between 0 and R − 1, which indicates the data structure the
key/value pair must be written to. This way MR Partition allows the MapReduce library to create R
separate data structures (i.e., partitions), each containing a subset of keys and the value list associated with
each of them. Once the partition that a key/value pair must be written to is identified, MR Emit inserts the
pair in a certain position in that partition, keeping the partition sorted in ascending key order at all times.
This is necessary for the MR GetNext library function to easily distinguish when a new reduce task should
start, which is exactly when the next key in the sorted partition is different from the previous key.
5. Creating reducers: the master thread terminates the mapper threads when all K splits are processed in the
map phase. It then creates R reducer threads in the MR Run library function where R is an argument of
this function. Each reducer thread is responsible for processing data in a particular partition; hence, the ith
partition (0 ≤ i < R) is assigned to the ith reducer. Each reducer thread runs the MR ProcessPartition
library function which takes as input the index of the partition assigned to it.
6. Running the user-defined Reduce function: the MR ProcessPartition library function invokes the
user-defined Reduce function on the next unprocessed key in the given partition in a loop. Thus, Reduce
is invoked only once for each key. To perform the summary operation, the Reduce function calls the
MR GetNext library function to iterate over all values that have the same key in its partition. The MR GetNext
function returns the next value associated with the given key in the sorted partition or NULL when the key’s
values have been processed completely.
7. Producing the final output: each reducer thread writes the result of the summary operation performed
on the value list associated with the passed key to a file named result- These output files are created initially by the reducer threads. The master thread terminates a reducer thread
as soon as all keys in its corresponding partition are processed. The master thread frees up its resources and
returns from the MR Emit function once all keys in all R partitions are processed.
The MapReduce Library
We now describe the functions in the mapreduce.h header file (included in the starter code) to help you understand how to write your MapReduce library:
// function pointer types used by library functions
typedef void (*Mapper)(char *file_name);
typedef void (*Reducer)(char *key, int partition_number);
// library functions you must define
void MR_Run(int num_files, char *filenames[],
Mapper map, int num_mappers,
Reducer concate, int num_reducers);
void MR_Emit(char *key, char *value);
unsigned long MR_Partition(char *key, int num_partitions);
3
void MR_ProcessPartition(int partition_number);
char *MR_GetNext(char *key, int partition_number);
The MapReduce execution is started off by a call to MR Run in the user program. This function is passed an array
of filenames containing K data splits, that is filenames[0], · · · , filenames[K − 1] (K = num files). Additionally,
the MR Run function is passed the number of mappers M, the number of reducers R, and two function pointers
for Map and Reduce functions. The main thread that runs the MR Run function is the master thread. It creates M
mappers and R reducers as depicted in Figure 1.
The MR Emit library function takes a key and a value associated with it, and writes this pair to a specific partition
which is determined by passing the key to the MR Partition library function. This function can be any “good”
hash function such as CRC32, MurmurHash, or the following algorithm known as DJB2:
unsigned long MR_Partition(char *key, int num_partitions) {
unsigned long hash = 5381;
int c;
while ((c = *key++) != ‘\0’)
hash = hash * 33 + c;
return hash % num_partitions;
}
You can use the above hash function or the open-source implementation of a well-known hash function. Make sure
to cite your sources in the readme file.
The MR ProcessPartition library function takes the index of the partition assigned to the thread that runs
it. It invokes the user-defined Reduce function in a loop, each time passing it the next unprocessed key. This
continues until all keys in the partition are processed.
The MR GetNext library function takes a key and a partition number, and returns a value associated with the key
that exists in that partition. In particular, the ith call to this function should return the ith value associated with the
key in the sorted partition or NULL if i is greater than the number of values associated with the key.
In the following section, we provide an example user program which is useful for testing your MapReduce library.
Your task is to implement the library assuming that there exists a parallelizable user program that includes your
library and calls the MR Run function.
Example Map and Reduce Functions
To illustrate how the library functions are invoked from the user program, we describe a simple distributed word
count program, distwc.c, which uses the MapReduce library. A word count program counts the number of
times each word appears in a given set of files. We will assume that the filenames are valid and the files exist in
the file system. This main function takes a list of text files and passes it to MR Run along with the numbers of
mappers and reducers, and two function pointers. All the developer has to do is to include the MapReduce library
and implement Map and Reduce functions. The distributed word count program is described below.
#include <assert.h
#include <stdio.h
#include <stdlib.h
#include <string.h
#include “mapreduce.h”
4
Generated
Key/Value
Pairs
Mapper 1
Mapper 2
Mapper
Car: 1
River: 1
Car: 1
Tea: 1
River: 1
Bear: 1
Bee: 1
Cat: 1
Bird: 1
River: 1
River Bear Bee …
File
File
Car River Car Tea
Cat Bird River …
File
Hash function
Car: 1
Car: 1
Cat: 1
Bear: 1
Bee: 1
Tea: 1
River: 1
River: 1
River: 1
Cat: 1
Cat: 1
Tea: 1
River: 1
Partition 1
Partition R
Partition 2
Bee: 1
Bear: 1
River: 1
Partition 2
Partition R
Bird: 1
Cat: 1
River: 1
Partition 2
Partition 1
Partition R
Sorted Intermediate
Data Structure
Partition 1
Partition 2
Partition R
Reducer 1
Reducer 2
Reducer
Output Files
Car: 2
Cat: 1
Bear: 1
Bee: 1
Tea: 1
River: 3
Splits
Figure 2: Example MapReduce data flow
void Map(char *file_name) {
FILE *fp = fopen(file_name, “r”);
assert(fp != NULL);
char *line = NULL;
size_t size = 0;
while (getline(&line, &size, fp) != -1) {
char *token, *dummy = line;
while ((token = strsep(&dummy, ” \t\n\r”)) != NULL) {
MR_Emit(token, “1”);
}
}
free(line);
fclose(fp);
}
void Reduce(char *key, int partition_number) {
int count = 0;
char *value, name[100];
while ((value = MR_GetNext(key, partition_number)) != NULL)
count++;
sprintf(name, “result-%d.txt”, partition_number);
FILE *fp = fopen(name, “a”);
fprintf(fp, “%s: %d\n”, key, count);
fclose(fp);
}
int main(int argc, char *argv[]) {
MR_Run(argc – 1, &(argv[1]), Map, 10, Reduce, 10);
}
Using Pthreads
To implement the MapReduce library, you must use the POSIX threads library (pthreads) for thread management.
See the man page of pthreads for more information. We are going to assume that the intermediate key/value pairs
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are fixed during the reduce phase. Thus, you must wait until all mapper threads finish execution, before starting
the reduce phase.
Intermediate Data Structures
The data structures being used for the intermediate key/value pairs are shared among multiple threads. Hence, they
must be global variables in the MapReduce library and support concurrency for correctness. Each thread must
obtain the lock on a shared data structure before updating it. For locking and unlocking the data structure you will
use pthread mutex.
The implementation of the shared data structures is up to you. You might use data structures from C++ STL
or implement the data structures you need (if you write code in C, for example). While there are many ways
to implement this data structure, it must be thread-safe, and support efficient implementation of MR Emit and
MR GetNext functions.
Thread Pool
The MapReduce library adopts a thread pool library to create a fixed number of mapper threads and assign the task
of running the Map callback function on input files to them.
In this assignment, you will write your own thread pool library using POSIX mutex locks and condition variables.
Below we describe the functions and struct declarations in the threadpool.h header file to help you understand
what this library is supposed to do.
typedef void (*thread_func_t)(void *arg);
typedef struct ThreadPool_work_t {
thread_func_t func; // The function pointer
void *arg; // The arguments for the function
// TODO: add other members here if needed
} ThreadPool_work_t;
typedef struct {
// TODO: add members here
} ThreadPool_work_queue_t;
typedef struct {
// TODO: add members here
} ThreadPool_t;
/**
* A C style constructor for creating a new ThreadPool object
* Parameters:
* num – The number of threads to create
* Return:
* ThreadPool_t* – The pointer to the newly created ThreadPool object
*/
ThreadPool_t *ThreadPool_create(int num);
/**
* A C style destructor to destroy a ThreadPool object
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* Parameters:
* tp – The pointer to the ThreadPool object to be destroyed
*/
void ThreadPool_destroy(ThreadPool_t *tp);
/**
* Add a task to the ThreadPool’s task queue
* Parameters:
* tp – The ThreadPool object to add the task to
* func – The function pointer that will be called in the thread
* arg – The arguments for the function
* Return:
* true – If successful
* false – Otherwise
*/
bool ThreadPool_add_work(ThreadPool_t *tp, thread_func_t func, void *arg);
/**
* Get a task from the given ThreadPool object
* Parameters:
* tp – The ThreadPool object being passed
* Return:
* ThreadPool_work_t* – The next task to run
*/
ThreadPool_work_t *ThreadPool_get_work(ThreadPool_t *tp);
/**
* Run the next task from the task queue
* Parameters:
* tp – The ThreadPool Object this thread belongs to
*/
void *Thread_run(ThreadPool_t *tp);
The ThreadPool create and ThreadPool destroy functions create and destroy the ThreadPool object,
respectively. Each thread created by ThreadPool create runs the Thread run function which gets a task
from the task queue and executes it (this is done in a loop). The ThreadPool destroy function should wait
until all tasks are executed before destroying the ThreadPool.
The ThreadPool add work function is used to submit a task (i.e., the execution of a function) to the thread
pool. You must create your own task queue and have a mechanism to support concurrency. The ThreadPool get work
function is used to get a task from the queue and have it processed by an idle thread.
You will have to define ThreadPool work t, ThreadPool work queue t, and ThreadPool t structs in
threadpool.h.
Deliverables
The starter code includes two header files, mapreduce.h and threadpool.h, and one example program,
distwc.c, that utilizes the MapReduce library. Your task is to implement the MapReduce and ThreadPool
libraries. You might modify mapreduce.h and threadpool.h.
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Submit your assignment as a single compressed archive file (mapreduce.zip or mapreduce.tar.gz) containing:
1. A custom Makefile with at least these targets: (a) the main target wc which simply links all object files and
produces an executable file called wordcount, (b) the target compile which compiles your code and
the provided distributed word count program, and produces the object file(s), (c) the target clean which
removes the objects and executable files, and (d) the target compress which creates the compressed archive
for submission.
2. A plain text document, called readme.md, which explains how to store the intermediate key/value pairs,
the time complexity of MR Emit and MR GetNext functions, the data structure used to implement the task
queue in the thread pool library, and your implementation of the thread pool library. Furthermore, you need
to explain what synchronization primitives you used and how you tested the correctness of your code. Make
sure you cite all sources that contributed to your assignment in this file. You may use a markup language,
such as Markdown, to format this plain text file.
3. All files required to build your project including mapreduce.h and threadpool.h.
Misc. Notes
• This assignment must be completed individually without consultation with anyone besides the instructor
and TAs.
• You can write code in C or C++, and compile it with gcc or g++ passing -Wall -Werror -pthread
flags. No warnings should be returned when your code is compiled these flags. Make sure that your code
does not print anything extra for debugging.
• We encourage you to write more parallelizable programs that utilize the MapReduce library. Test your
MapReduce library using these programs with different numbers of mapper threads and reducer threads
besides the distributed word count program that we provided.
• You are not allowed to use a standard thread pool library in this assignment. You must implement a thread
pool yourself using synchronization primitives.
• The use of implicit threading (e.g., OpenMP, Intel TBB, etc.) is not permitted in this assignment.
• Check your code for memory leaks. You may use the Valgrind tool suite:
valgrind –tool=memcheck –leak-check=yes ./wordcount
• You can use your own machine to write the code, but you must make sure that it compiles and runs on the
Linux lab machines (e.g., ugXX.cs.ualberta.ca where XX is a number between 00 and 34).
• When developing and testing your program, make sure that you clean up all processes before you logout of
a workstation.
8e a standard thread pool library in this assignment. You must implement a thread
pool yourself using synchronization primitives.
• The use of implicit threading (e.g., OpenMP, Intel TBB, etc.) is not permitted in this assignment.
• Check your code for memory leaks. You may use the Valgrind tool suite:
valgrind –tool=memcheck –leak-check=yes ./wordcount
• You can use your own machine to write the code, but you must make sure that it compiles and runs on the
Linux lab machines (e.g., ugXX.cs.ualberta.ca where XX is a number between 00 and 34).
• When developing and testing your program, make sure that you clean up all processes before you logout of
a workstation.
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