Project 2-1: MIPS Assembler


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CS61C Project 2-1: MIPS Assembler

Updates (Check here if there are updates in the future)
Commit and push your work to GitHub before updating, or you risk losing your work. Only one partner needs to apply any future
updates, so communicate with your partner beforehand. To apply the update, fetch/merge from the proj2_starter repository by typing:
git fetch proj2-starter
git merge proj2-starter/master -m “merge proj2-1 update”
Then, verify that your files are OK before pushing the changes to GitHub.
Changelog (a log for future changes):
Update #1 (7/09/15 8:30 PM) – Two sets of changes can be viewed here:
1. Bugfix to test_assembler.c regarding table name for test_table_1().
2. Updated reference files for testing
So What Is This About?
In this part of the project, we will be writing an assembler that translates a subset of the MIPS instruction set to machine code. Our
assembler is a two-pass assembler similar to the one described in lecture. However, we will only assemble the .text segment. At a high
level, the functionality of our assembler can be divided as follows:
Pass 1: Reads the input (.s) file. Comments are stripped, pseudoinstructions are expanded, and the address of each label is recorded
into the symbol table. Input validation of the labels and pseudoinstructions is performed here. The output is written to an intermediate
(.int) file .
Pass 2: Reads the intermediate file and translates each instruction to machine code. Instruction syntax and arguments are validated at
this step. The relocation table is generated, and the instructions, symbol table, and relocation table are written to an object (.out) file.
The Instruction Set
Please consult the MIPS Green Sheet for register numbers, instruction opcodes, and bitwise formats. Our asembler will support the
following registers: $zero, $at, $v0, $a0 – $a3, $t0 – $t3, $s0 – $s3, $sp, and $ra. The name $0 can be used in lieu of $zero. Other
register numbers (eg. $1, $2, etc.) are not supported.
We will have 18 instructions and 5 pseudoinstructions to assemble, one that is not a real pseudoinstruction. The instructions are:
Add Unsigned addu $rd, $rs, $rt
Or or $rd, $rs, $rt
Set Less Than slt $rd, $rs, $rt
Set Less Than Unsigned sltu $rd, $rs, $rt
Jump Register jr $rs
Shift Left Logical sll $rd, $rt, shamt
Add Immediate Unsigned addiu $rt, $rs, immediate
Or Immediate ori $rt, $rs, immediate
Load Upper Immediate lui $rt, immediate
Load Byte lb $rt, offset($rs)
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Load Byte Unsigned lbu $rt, offset($rs)
Load Word lw $rt, offset($rs)
Store Byte sb $rt, offset($rs)
Store Word sw $rt, offset($rs)
Branch on Equal beq $rs, $rt, label
Branch on Not Equal bne $rs, $rt, label
Jump j label
Jump and Link jal label
The pseudoinstructions are:
Load Immediate li $rt, immediate
Move move $rd, $rs
Branch on Less Than blt $rs, $rt, label
Branch on Greater Than bgt $rs, $rt, label
New Add Unsigned traddu $rd, $rs, $rt
IMPORTANT: The way traddu works is it stores the sum of three registers $rs, $rt, $rd in register $rd. R[rd] = R[rs] + R[rt] + R[rd].
Implementation Steps
Please note that your project will be graded on the HIVE machines. While you are free to develop on other machines, you need to
make sure that your code compiles and runs without errors on the hive machines before submitting. If you do not, you run the risk of
turning in non-compiling code and getting a ZERO on the entire project.
Step 0: Obtaining the Files
To make this process go as smoothly as possible, make sure you:
1. Use the shared proj2-XX-YY repositories for this project, NOT your individual repositories.
2. Create your shared git repository outside of any existing repositories (unless you really know what you’re doing).
If your shared repository is empty, you can use the GitHub importer by going to the repository’s page (, scrolling to the bottom, and clicking the import button:
Click on “Import Code”, and on the next screen enter the URL of the starter repository (
It will take GitHub a few moments to import the code. After it is done, your repository should have the same files as the starter
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Now you can clone the repository to your cs61c account/your computer, and then add the starter repository as a remote:
cd ~ # Make sure you are outside of any existing repositories (eg. ~/work)
git clone [email protected]:cs61c-summer2015/proj2-XX-YY.git
cd proj2-XX-YY # Go inside the directory that was created
git remote add proj2-starter [email protected]:cs61c-summer2015/proj2-starter
If you have already made commits to your shared repository, then simply add the
# Inside of your proj2-XX-YY repository
git remote add proj2-starter [email protected]:cs61c-summer2015/proj2-starter
git fetch proj2-starter
git merge proj2-starter/master -m “merge proj2-1 skeleton code”
You can compile you code by typing make. At first, you will get a bunch of -Wunused-variable and -Wunused-function warnings. The
warnings tell you that variables/functions were declared, but were not used in your code. Don’t worry, as you complete the assigment
the warnings will go away.
Step 1: Building Blocks
Finish the implementation of translate_reg() and translate_num() in src/translation_utils.c. translate_reg() is incomplete, so you
need to fill in the rest of the register translations. You can find register numbers on the MIPS Green Sheet. Unfortunately, there are no
built-in switch statements for strings in C, so an if-else ladder is the way to compare multiple strings.
For translate_num(), you should use the library function strtol() (see documentation here). translate_num() should translate a
numerical string (either decimal or hexadecimal) into a signed number, and then check to make sure that the result is within the bounds
specified. If the string is invalid or outside of the bounds, return -1.
Step 2: SymbolTable
Use the given SymbolTable data structure to store symbol name-to-address mappings in src/tables.c. Multiple SymbolTables may be
created at the same time, and each must resize to fit an arbitrary number of entries (so you should use dynamic memory allocation). A
SymbolTable struct has been defined in src/tables.h, and you may use the existing implementation or create your own if that feels
more intuitive. Feel free to declare additional helper methods. See src/tables.c for details.
In add_to_table, you cannot simply store the character pointer that was given, as it could point to a temporary array. You must store a
copy of that string instead. You should use the helper functions defined in src/tables.c whenever appropriate. The provided
SymbolTable also comes with an INITIAL_SIZE and SCALING_FACTOR to appropriately create a table and also increase the size of the table
when trying to add to a table currently at full capacity. It may help to complete get_addr_forsymbol() prior to attempting to complete
You must make sure to free all memory that you allocate. See the Valgrind section under testing for more information.
Step 3: Instruction Translation
Implement translate_inst() in src/translate.c. The MIPS Green Sheet will again be helpful and perhaps even necessary, and so will
bitwise operations.
translate_inst() should translate instructions to hexadecimal. Note that the function is incomplete. You must first fix the funct fields,
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and then implement the rest of the function.You will find the translate_reg(), translate_num(), and write_inst_hex() functions, all
defined in translate_utils.h helpful in this step. Some instructions may also require the symbol and/or relocation table, which are given
to you by the symtbl and reltbl pointers. You are required to implement the write_*() functions declared in translate.h. This is a
requirement for your benefit. To lower the intensity of the project, most of the code for this step has been provided, however it is not
complete and some of the code provided may not have the correct values or assignments. The more important issue is input validation
— you must make sure that all arguments given are valid. If an input is invalid, you should NOT write anything to output but return -1
Use your knowledge about MIPS instruction formats and think carefully about how inputs could be invalid. You are encouraged to use
MARS as a resource. Do note that MARS has more pseudoinstruction expansions than our assembler, which means that instructions with
invalid arguments for our assembler could be treated as a pseduoinstruction by MARS. Therefore, you should check the text section
after assembling to make sure that the instruction has not been expanded by MARS .
If a branch ofset cannot fit inside the immediate field, you should treat it as an error.
Step 4: Pseudoinstruction Expansion
Implement write_pass_one() in src/translate.c, which should perform pseudoinstruction expansion on the load immediate (li), move
(move), branch on less than (blt), branch on greater than (bgt), and new add unsigned (traddu) instructions.
The li instruction normally get expanded into an lui-ori pair. However, an optimization can be made when the immediate is small. If
the immediate can fit inside the imm field of an addiu instruction, we will use an addiu instruction instead. Other assemblers may
implement additional optimizations, but ours will not.
The move instruction essentially copies over the contents of one register to another. Think about some operation consisting of a nonpseudo instruction that could accomplish this.
For the blt instruction, use the fewest number of instructions possible. After implementing blt , bgt should not be too difcult to
The traddu instruction is not a real pseudoinstruction (but assume it is for this project). This should be quite self-explanatory. How can
we take the contents of our three registers and store their sum into one? Hint: you should consider using addu.
Also, make sure that your pseudoinstruction expansions do not produce any unintended side efects. You will also be performing some
error checking on the pseudoinstructions (see src/translate.c for details). If there is an error, do NOT write anything to the
intermediate file, and return 0 to indicate that 0 lines have been written.
Step 5: Putting It All Together
Implement pass_one() and pass_two() in assembler.c. You may find the use of parse_args() very helpful in this task. You may find the
use of parse_args() very helpful in this task. Please keep in mind that if you use parse_args(), it MUST be called after the provided
line “char* token = strtok(buf, IGNORE_CHARS);” in pass_one() because parse_args() heavily depends on strtok(). This has to do
with the way strtok() works and how passing in NULL as an argument for strtok() is dependent on the last successful function
call of strtok() In the first pass, the assembler will strip comments, add labels to the symbol table, perform pseudoinstruction
expansion, and write assembly code into an intermediate file. The second pass will read the intermediate file, translate the instructions
into machine code using the symbol table, and write it to an output file. Afterwards, the symbol table and relocation table will be written
to the output file as well, but that has been handled for you.
Before you begin, make sure you understand the documentation of fgets() and strtok(). It will be easier to implement pass_two()
first. The comments in the function will give a more detailed outline of what to do, as well as what assumptions you may make. Your
program should not exit if a line contains an error. Instead, keep track of whether any errors have occured, and if so, return -1 at the
end. pass_one() should be structured similarly to pass_two(), except that you will also need to parse out comments and labels. You will
find the skip_comment() and add_if_label() functions useful.
As an aside, our parser is much more lenient than an actual MIPS parser. Building a good parser is outside the scope of this course, but
we encourage you to learn about finite state automata if you are interested.
Line Numbers and Byte Ofsets
When parsing, you will need to keep track of two numbers, the line number of the input file and the byte ofset of the current
instruction. Line numbers start at 1, and include whitespace. The byte ofset refers to how far away the current instruction is from the
first instruction, and does NOT include whitespace. You can think of the byte ofset as where each instruction will be if the instructions
were loaded into memory starting at address 0. See below for an example.
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The address of a label is the byte ofset of the next instruction. In the example below, L1 has an address of 4 (since the next instruction
is lw, whose address is 4) and L2 has an address of 8 (since the next instruction is ori, whose address is 8).
1 addiu $t0 $a0 0
2 L1: lw $t1 0($t0)
3 # This is a comment
4 L2:
5 ori $t1 $t1 0xABCD
6 addiu $t1 $t1 3
8 bne $t1 $a2 L2
addiu $t0 $a0 0 0
lw $t1 0($t0) 4
ori $t1 $t1 0xABCD 8
addiu $t1 $t1 3 12
bne $t1 $a2 label_2 16
Error Handling
If an input file contains an error, we only require that your program print the correct error messages. The contents of your .int and .out
files do not matter.
There are two kinds of errors you can get: errors with instructions and errors with labels. Error checking of labels is done for you by
add_if_label(). However, you will still need to record that an error has occurred so that pass_one() can return -1.
In pass_one(), errors with instructions can be raised by 1) write_pass_one() or 2) the instruction having too many arguments. In
pass_two(), errors with instructions will only be raised by translate_inst(). Both write_pass_one() and translate_inst() should return a
special value (0 and -1 respectively) in the event of an error. You will need to detect whether an instuction has too many arguments
yourself in pass_one().
Whenever an error is encountered in either pass_one() or pass_two(), record that there is an error and move on. Do not exit the function
prematurely. When the function exits, return -1.
For information about testing error message, please see the “Error Message Testing” section under “Running the Assembler”.
You are responsible for testing your code. While we have provided a few test cases, they are by no means comprehensive. In the
previous semester’s rendition of the project, it was heavily reflected in student grades who and who did not test their code. Fortunately,
you have a variety of testing tools at your service.
Note: CUnit tests must be compiled on either the hive or the Soda 2nd floor machines, or you will get compilation errors. We
have set up some unit tests in test_assembler.c. You can run them by typing:
make test-assembler
Check out Project 1 for a refresher on CUnit. You are encouraged to write more tests than the ones that we have given.
You should use Valgrind to check whether your code has any memory leaks. We have included a file, run-valgrind, which will run
Valgrind on any executable of your choosing. If you get a permission denied error, try changing adding the execute permission to the
chmod u+x run-valgrind
Then you can run by typing:
./run-valgrind <whatever program you want to run
For example, you wanted to see whether running ./assembler -p1 input/simple.s out/ would cause any memory leaks, you
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should run ./run-valgrind ./assembler -p1 input/simple.s out/
Since you’re writing an assembler, why not refer to an existing assembler? MARS is a powerful reference for you to use, and you are
encouraged to write your own MIPS files and assemble them using MARS.
Warning: in some cases the output of MARS will difer from the specifications of this project. You should always follow the
specs. This is because MARS 1) supports more pseudoinstructions, 2) has slightly diferent pseudoinstruction expansion rules, and 3)
acts as an assembler and linker. For example, MARS may expand an addiu with a 32-bit immediate into li followed by an addiu
instruction. Not only will the machine code be diferent, but the addresses of any labels will also be diferent. Therefore, you should
always examine the assembled instructions carefully when testing with MARS.
MARS also supports an assemble-only mode via the command-line (see documentation here). To save assembled output to a text file,
mars a dump .text HexText <output location <input MIPS file
Dif (this should be your best friend for this project)
diff is a utility for comparing the contents of files. Running the following command will print out the diferences between file1 and
diff <file1 <file2
To see how to interpret dif results, click here. We have provided some sample input-output pairs (again, these are not comprehensive
tests) located in the input and out/ref directories respectively. For example, to check the output of running simple.s on your assembler
against the expected output, run:
./assembler input/simple.s out/ out/simple.out
diff out/simple.out out/ref/simple_ref.out
Running the Assembler
First, make sure your assembler executable is up to date by running make.
By default, the assembler runs two passes. The first pass reads an input file and translates it into an intermediate file. The second pass
reads the intermediate file and translates it into an output file. To run both passes, type:
./assembler <input file <intermediate file <output file
Alternatively, you can run only a single pass, which may be helpful while debugging. To run only the first pass, use the -p1 flag:
./assembler <-p1 <input file <intermediate file
To run only the second pass, use the -p2 flag. Note that when running pass two only, your symbol and relocation table will be empty
since labels were stripped in pass_one(), so it may afect your branch instructions.
./assembler <-p2 <intermediate file <output file
When testing cases that should produce error messages, you may want to use the -log flag to log error messages to a text file. The -log
flag should be followed with the location of the output file (WARNING: old contents will be overwritten!), and it can be used with any of
the three modes above.
Error Message Testing
We have provided two tests for error messages, one for errors that should be raised during pass_one(), and one for errors that should
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be raised during pass_two(). To test for pass_one() errors, assemble input/p1_errors.s with the -p1 flag and verify that your output
matches the expected output:
./assembler -p1 input/p1_errors.s out/ -log log/p1_errors.txt
diff log/p1_errors.txt log/ref/p1_errors_ref.txt
To test for pass_two() errors, assemble input/p2_errors.s running both passes:
./assembler input/p2_errors.s out/ out/p2_errors.out -log log/p2_errors.txt
diff log/p2_errors.txt log/ref/p2_errors_ref.txt
Your intermediate and output files (.int and .out files) do NOT need to match the reference output if the input file contains an error.
Did you test thoroughly on the hive machines? If you do not, you risk getting a ZERO on the entire project.
There are two steps required to submit proj2-1. Failure to perform both steps will result in loss of credit:
1. First, you must submit using the standard unix submit program on the instructional servers. This assumes that you followed the
earlier instructions and did all of your work inside of your git repository. To submit, follow these instructions after logging into
your cs61c-XX class account:
cd ~/proj2-XX-YY # Or where your shared git repo is
submit proj2-1
Once you type submit proj2-1, follow the prompts generated by the submission system. It will tell you when your submission has
been successful and you can confirm this by looking at the output of glookup -t.
2. Additionally, you must submit proj2-1 to your shared GitHub repository:
cd ~/proj2-XX-YY # Or where your shared git repo is
git add -u
git commit -m “project 2-1 submission”
git tag “proj2-1-sub” # The tag MUST be “proj2-1-sub”. Failure to do so will result in loss of credit.
git push origin proj2-1-sub # This tells git to push the commit tagged proj2-1-sub
If you need to re-submit, you can follow the same set of steps that you would if you were submitting for the first time, but you will need
to use the -f flag to tag and push to GitHub:
# Do everything as above until you get to tagging
git tag -f “proj2-1-sub”
git push -f origin proj2-1-sub
Note that in general, force pushes should be used with caution. They will overwrite your remote repository with information from your
local copy. As long as you have not damaged your local copy in any way, this will be fine.

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