CS 361 HW4: A Garbage Collector

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Background
Dynamic memory (i.e. memory accessed via the malloc and free family of commands) is
essential to many programs in the freedom, control, and interpretability it allows. Section
9.9 discusses 2 different types of management for dynamic memory: implicit allocators and
explicit allocators.
This assignment focuses on the implicit allocator, perhaps better known as the garbage
collector, where we don’t need to explicitly free the unused memory. Intuitively, we want this
tool to find the blocks (or chunks as we refer to them) that are not being used and return
them to the process as free chunks.
For further reference, please see section 9.9-9.10 (and specifically 9.10.2) of the textbook.
Memory layout review
As a quick review, we can visualize dynamic memory (aka the heap) as a list of chunks. From
class, we know that each allocated or free block is started with header (shown as ‘h’ in the
figure below), contains a payload (‘x’), and ends with a footer (‘f’). (Figure 9.39: Format of
heap block that uses a boundary tag.)
———————————————————————-
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6/15/2020 CS 361 Summer 2020 – HW4
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|h|x|x|f|h| | | | |f|h|x|x|x|x|f|h| | | | |…
———————————————————————-
^ ^ ^ ^
| | | |
a b c the rest of the heap…
(inuse) (free) (inuse)
In the figure, ‘a’ represents an allocated section of the heap with a payload + padding taking
up 2 words worth of space. Similarly, ‘b’ is a free node of size 4 words.
Finding unreachable blocks
To perform garbage collection, the garbage collector needs to know what blocks are still
being used (live) and what are unreachable (dead). To be specific, the dead blocks are
considered in-use by the memory allocator but they have been abandoned by the
application.
Suppose we are managing a naive hash table (and nothing else) where each bucket contains
a chain of items, each created by a malloc(). The dead blocks can be identified by obtaining
the list of all in-use blocks and removing the objects on the hash table.
In the example, the buckets of the hash tables contains chains of live blocks. To perform the
mark-and-sweep garbage collection, we need to:
(1) MARK: traverse the hash table and mark all the blocks.
(2) SWEEP: scan the list of blocks managed by the heap memory allocator. Every memory
block that is not marked shall be freed.
In a more general case, the application maintains a set of root pointers to the directed
graphs of live node.
Your garbage collector
In this homework, we will build a simple garbage collector for C programs. Starting from the
set of root pointers, we traverse the object graphs (actually singly-linked lists) to find all
chunks reachable from the roots. These are marked using the second lowest order bit in the
header of each chunk. We have implemented several helpful functions for you ranging from
checking for marked chunks to navigation of the heap. Please read the skeleton code to get
a feel for what is available and what you should be doing.
As of the release of this assignment, we have not covered the concepts related to garbage
CS 361 Summer 2020 Home Schedule Homeworks
6/15/2020 CS 361 Summer 2020 – HW4
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g p g g
collection in class; to start on this homework, take a look at section 9.10, and 9.10.2
specifically. The labs on 3/2 and 3/9 will help you get started on the assignment as well.
The skeleton code
The memory allocator
The textbook provides us a small but fully functional memory allocator implementation:
memlib.c explicitly manages the heap space. Its job is just to request more pages from
the OS and extend the size of the heap memory.
mm.c contains the actual allocator code that manages the blocks within the available
heap space. When it needs more space, it asks memlib for it.
The application
The main function in main.c performs a lot of memory allocations but rarely free them. It
tries to remember some of the allocated blocks in the root table, but can still get things lost
for various reasons. Imagine there is a long-running process that consistently makes these
mistakes, the process will quickly build up garbage and eventually get itself terminated by
the OOM (out-of-memory) killer.
The garbage collector
To save it from creating long-lasting leaks, you will need to implement the garbage collector
in hw4.c, which will interact with the memory allocator and the root table to find and free
the dead blocks. In the skeleton code, the function gc() does nothing.
To compile the template, type make, and run it with ./hw4
To get started, read main.c and see what’s wrong in the output.
Expect to spend a lot of time to read and understand the code. To successfully implement
the garbage collector, you will have to understand everything in main.c, hw4.c, and
memlib.c, and at least 50% of mm.c.
Requirements
Your code goes to the end of hw4.c, starting from Line 75. The autograder will build hw4
using your hw4.c and all of the other original skeleton code. Any changes to the other files
will be ignored.
CS 361 Summer 2020 Home Schedule Homeworks
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Runtime performance is not a major goal for this homework. However if your program is
taking more than 2 seconds, you almost certainly did something wrong.
Finally, make sure you do not output anything extra in your implementations. This will break
the autograder.
Grading
You can start the assignment via the invite link at the top of the page. It should be turned in
via Gradescope as with other homework assignments.
Due Date
This assignment is due Friday, 3/13, 11:59PM Central Time. See the course home page for
the late turnin policy.
CS 361 Summer 2020 Home Schedule Homeworks