Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free.

I wrote a virtual machine language to assembly translator for a computer systems course I'm taking (using the nand2tetris curriculum). I originally wrote it in Python, but since I'm learning D, I thought I'd translate it. D is fairly close to Python syntactically, so it wasn't too difficult. I assumed that D, being a performance language and compiled, would be at least as fast as Python and on a large file, would be much faster. But the opposite is true! Despite identical algorithms, D consistently performed slightly slower than python when I constructed a very large file to compile. On a file approximately 500000 lines long, python consistently took about 2.6 seconds to complete, while D consistently took about 3. This isn't an enormous gap, but it's notable that python would be at all faster.

I don't want to suggest that I'm naive enough to think that python is actually faster than D overall; however, in this instance it seems at the very least that D is not intuitively faster. I'd appreciate some input on possible sources of performance decreases in my D code. I think the bottleneck might be on IO operations, but I'm not sure.

The source code is below. The details aren't that important; some assembly language templates are allocated and then there's a linear pass through the virtual machine language, translating each instruction to an equivalent block of assembly code.

EDIT: after recompiling the D code using dmd -O -release -inline -m64, D comes out the victor with a time of 2.20s on the input. However, the question still remains of why with almost identical code, D seems to perform slower than python.

EDIT 2: using the advice from below, I switched from using a simple list of strings, to using an appender!string(), and improved the time by a noticeable amount. It's worth mentioning however, that if you have a bunch of strings in an appender, do not write them to a file with a command like:

auto outputfile = File("foo.txt","w");
foreach(str; my_appender.data)
   outputfile.write(str);

Rather instead, write something like:

auto outputfile = File("foo.txt","w");
outputfile.write(my_appender.data);

The second example will give you a small performance increase over using a simple string[]. But using the first one gave me a huge performance hit, doubling the execution time.

Changing to an appender!string(), the compilation of the aforementioned large file took about 2.75 seconds (to Python's 2.8), where the original had taken about 3. Doing this, and also using the optimization flags in dmd, gave a total compilation time of 1.98 seconds! :)

Python:

#!/usr/bin/python

import sys

operations_dict = {"add":"+", "sub":"-",
                   "and":"&", "or":"|",
                   "not":"!", "neg":"-",
                   "lt":"JLT", "gt":"JGT",
                   "eq":"JEQ", "leq":"JLE",
                   "geq":"JGE"}

vars_dict = {"this":("THIS","M"),
             "that":("THAT","M"),
             "argument":("ARG","M",),
             "local":("LCL","M",),
             "static":("f.%d","M",),
             "temp":("TEMP","A",)}

start = "@SP\nAM=M-1\n"
end = "@SP\nM=M+1\n"

binary_template = start + "D=M\n\
@SP\n\
AM=M-1\n\
M=M%sD\n" + end

unary_template = start + "M=%sM\n" + end

comp_template = start + "D=M\n\
@SP\n\
AM=M-1\n\
D=M-D\n\
@COMP.%d.TRUE\n\
D;%s\n\
@COMP.%d.FALSE\n\
0;JMP\n\
(COMP.%d.TRUE)\n\
@SP\n\
A=M\n\
M=-1\n\
@SP\n\
M=M+1\n\
@COMP.%d.END\n\
0;JMP\n\
(COMP.%d.FALSE)\n\
@SP\n\
A=M\n\
M=0\n" + end + "(COMP.%d.END)\n"

push_tail_template = "@SP\n\
A=M\n\
M=D\n\
@SP\n\
M=M+1\n"

push_const_template = "@%d\nD=A\n" + push_tail_template

push_var_template = "@%d\n\
D=A\n\
@%s\n\
A=%s+D\n\
D=M\n" + push_tail_template

push_staticpointer_template = "@%s\nD=M\n" + push_tail_template

pop_template = "@%d\n\
D=A\n\
@%s\n\
D=%s+D\n\
@R13\n\
M=D\n\
@SP\n\
AM=M-1\n\
D=M\n\
@R13\n\
A=M\n\
M=D\n"

pop_staticpointer_template = "@SP\n\
AM=M-1\n\
D=M\n\
@%s\n\
M=D"


type_dict = {"add":"arithmetic", "sub":"arithmetic",
                   "and":"arithmetic", "or":"arithmetic",
                   "not":"arithmetic", "neg":"arithmetic",
                   "lt":"arithmetic", "gt":"arithmetic",
                   "eq":"arithmetic", "leq":"arithmetic",
                   "geq":"arithmetic", 
                   "push":"memory", "pop":"memory"}

binary_ops = ["add", "sub", "and", "or"]
unary_ops = ["not", "neg"]
comp_ops = ["lt", "gt", "eq", "leq", "geq"]


op_count = 0
line_count = 0
output = ["// Assembly file generated by my awesome VM compiler\n"]

def compile_operation(op):
    global line_count

    if (op[0:2] == "//") or (len(op.split()) == 0):
        return ""

    # print "input: " + op
    operation = op.split()[0]
    header = "// '" + op +  "' (line " + str(line_count) + ")\n"
    line_count += 1

    if type_dict[operation] == "arithmetic":
        return header + compile_arithmetic(op)
    elif type_dict[operation] == "memory":
        return header + compile_memory(op)

def compile_arithmetic(op):
    global op_count
    out_string = ""
    if op in comp_ops:
        out_string += comp_template % (op_count, operations_dict[op], op_count, \
            op_count, op_count, op_count, op_count)
        op_count += 1
    elif op in unary_ops:
        out_string += unary_template % operations_dict[op]
    else:
        out_string += binary_template % operations_dict[op]
    return out_string

def compile_memory(op):
    global output
    instructions = op.split()
    inst = instructions[0]
    argtype = instructions[1]
    val = int(instructions[2])
    if inst == "push":
        if argtype == "constant":
            return push_const_template % val
        elif argtype == "static":
            return push_staticpointer_template % ("f." + str(val))
        elif argtype == "pointer":
            if val == 0:
                return push_staticpointer_template % ("THIS")
            else:
                return push_staticpointer_template % ("THAT")
        else:
            return push_var_template % (val, vars_dict[argtype][0], vars_dict[argtype][1])
    elif inst == "pop":
        if argtype != "constant":
            if argtype == "static":
                return pop_staticpointer_template % ("f." + str(val))
            elif argtype == "pointer":
                if val == 0:
                    return pop_staticpointer_template % "THIS"
                else:
                    return pop_staticpointer_template % "THAT"
            else:
                return pop_template % (val, vars_dict[argtype][0], vars_dict[argtype][1])

def main():
    global output

    if len(sys.argv) == 1:
        inputfname = "test.txt"
    else:
        inputfname = sys.argv[1]
    outputfname = inputfname.split('.')[0] + ".asm"

    inputf = open(inputfname)
    output += ["// Input filename: %s\n" % inputfname]
    for line in inputf.readlines():
        output += [compile_operation(line.strip())]

    outputf = open(outputfname, 'w')
    for outl in output:
        outputf.write(outl)

    outputf.write("(END)\n@END\n0;JMP");
    inputf.close()
    outputf.close()
    print "Output written to " + outputfname


if __name__ == "__main__":
    main()

D:

import std.stdio, std.string, std.conv, std.format, std.c.stdlib;

string[string] operations_dict, type_dict;
string[][string] vars_dict;
string[] arithmetic, memory, comp_ops, unary_ops, binary_ops, lines, output;
string start, end, binary_template, unary_template,
        comp_template, push_tail_template, push_const_template,
        push_var_template, push_staticpointer_template,
        pop_template, pop_staticpointer_template;
int op_count, line_count;

void build_dictionaries() {
    vars_dict = ["this":["THIS","M"],
                 "that":["THAT","M"],
                 "argument":["ARG","M"],
                 "local":["LCL","M"],
                 "static":["f.%d","M"],
                 "temp":["TEMP","A"]];

    operations_dict = ["add":"+", "sub":"-",
                   "and":"&", "or":"|",
                   "not":"!", "neg":"-",
                   "lt":"JLT", "gt":"JGT",
                   "eq":"JEQ", "leq":"JLE",
                   "geq":"JGE"];

    type_dict = ["add":"arithmetic", "sub":"arithmetic",
                   "and":"arithmetic", "or":"arithmetic",
                   "not":"arithmetic", "neg":"arithmetic",
                   "lt":"arithmetic", "gt":"arithmetic",
                   "eq":"arithmetic", "leq":"arithmetic",
                   "geq":"arithmetic", 
                   "push":"memory", "pop":"memory"];

    binary_ops = ["add", "sub", "and", "or"];
    unary_ops = ["not", "neg"];
    comp_ops = ["lt", "gt", "eq", "leq", "geq"];
}

bool is_in(string s, string[] list) {
    foreach (str; list)
        if (str==s) return true;
    return false;
}

void build_strings() {
    start = "@SP\nAM=M-1\n";
    end = "@SP\nM=M+1\n";

    binary_template = start ~ "D=M\n"
    "@SP\n"
    "AM=M-1\n"
    "M=M%sD\n" ~ end;

    unary_template = start ~ "M=%sM\n" ~ end;

    comp_template = start ~ "D=M\n"
    "@SP\n"
    "AM=M-1\n"
    "D=M-D\n"
    "@COMP.%s.TRUE\n"
    "D;%s\n"
    "@COMP.%s.FALSE\n"
    "0;JMP\n"
    "(COMP.%s.TRUE)\n"
    "@SP\n"
    "A=M\n"
    "M=-1\n"
    "@SP\n"
    "M=M+1\n"
    "@COMP.%s.END\n"
    "0;JMP\n"
    "(COMP.%s.FALSE)\n"
    "@SP\n"
    "A=M\n"
    "M=0\n" ~ end ~ "(COMP.%s.END)\n";

    push_tail_template = "@SP\n"
    "A=M\n"
    "M=D\n"
    "@SP\n"
    "M=M+1\n";

    push_const_template = "@%s\nD=A\n" ~ push_tail_template;

    push_var_template = "@%s\n"
    "D=A\n"
    "@%s\n"
    "A=%s+D\n"
    "D=M\n" ~ push_tail_template;

    push_staticpointer_template = "@%s\nD=M\n" ~ push_tail_template;

    pop_template = "@%s\n"
    "D=A\n"
    "@%s\n"
    "D=%s+D\n"
    "@R13\n"
    "M=D\n"
    "@SP\n"
    "AM=M-1\n"
    "D=M\n"
    "@R13\n"
    "A=M\n"
    "M=D\n";

    pop_staticpointer_template = "@SP\n"
    "AM=M-1\n"
    "D=M\n"
    "@%s\n"
    "M=D";
}

void init() {
    op_count = 0;
    line_count = 0;
    output = ["// Assembly file generated by my awesome VM compiler\n"];
    build_strings();
    build_dictionaries();
}

string compile_operation(string op) {
    if (op.length == 0 || op[0..2] == "//")
        return "";
    string operation = op.split()[0];
    string header = "// '" ~ op ~  "' (line " ~ to!string(line_count) ~ ")\n";
    ++line_count;

    if (type_dict[operation] == "arithmetic")
        return header ~ compile_arithmetic(op);
    else
        return header ~ compile_memory(op);
}

string compile_arithmetic(string op) {
    if (is_in(op, comp_ops)) {
        string out_string = format(comp_template, op_count, operations_dict[op], op_count, 
            op_count, op_count, op_count, op_count);
        op_count += 1;
        return out_string;
    } else if (is_in(op, unary_ops))
        return format(unary_template, operations_dict[op]);
    else
        return format(binary_template, operations_dict[op]);
}

string compile_memory(string op) {
    string[] instructions = op.split();
    string inst = instructions[0];
    string argtype = instructions[1];
    int val = to!int(instructions[2]);
    if (inst == "push") {
        if (argtype == "constant") {
            return format(push_const_template, val);
        } else if (argtype == "static")
            return format(push_staticpointer_template, ("f." ~ to!string(val)));
        else if (argtype == "pointer")
            if (val == 0)
                return format(push_staticpointer_template, "THIS");
            else
                return format(push_staticpointer_template, "THAT");
        else
            return format(push_var_template, val, vars_dict[argtype][0], vars_dict[argtype][1]);
    } else {
        if (argtype != "constant") {
            if (argtype == "static")
                return format(pop_staticpointer_template, ("f." ~ to!string(val)));
            else if (argtype == "pointer") {
                if (val == 0)
                    return format(pop_staticpointer_template, "THIS");
                else
                    return format(pop_staticpointer_template, "THAT");
            }
            else
                return format(pop_template, val, vars_dict[argtype][0], vars_dict[argtype][1]);
        } else {
            return "";
        }
    }
}

void main(string args[]) {
    init();
    if (args.length < 2) {
        writefln("usage: %s <filename>", args[0]);
        exit(0);
    }
    string inputfname = args[1];
    string outputfname = args[1].split(".")[0] ~ ".asm";

    auto inputf = File(inputfname, "r");
    output ~= format("// Input filename: %s\n", inputfname);
    foreach (line; inputf.byLine) {
        output ~= compile_operation(to!string(line).strip);
    }
    inputf.close();

    auto outputf = File(outputfname, "w");
    foreach (outl; output)
        outputf.write(outl);

    outputf.write("(END)\n@END\n0;JMP");
    outputf.close();
    writeln("Compilation successful. Output written to " ~ outputfname);
}
share|improve this question
3  
Have you tried profiling to see what is happening? Don't assume. Use the -profile compiler flag. –  dcousens Feb 11 '13 at 10:18
    
You might also want to add -noboundscheck when compiling the D code. I'm not sure it would cause any difference in this case, but generally, you might want that in a release version. It would also be interesting to see gdc's or ldc's performance. –  yaz Feb 11 '13 at 15:58
    
@Daniel can you explain what -profile does? I ran dmd -profile vmt.d (vmt.d is the name of my file) and when I ran the program on a large input file, it just hung (or I didn't wait long enough, but either way). –  limp_chimp Feb 11 '13 at 18:05
1  
Try compiling with GDC for optimal performance. –  Robik Feb 11 '13 at 18:07
    
@yaz -noboundscheck seems to shave a few tenths of a second off the running time. –  limp_chimp Feb 11 '13 at 18:07

2 Answers 2

up vote 6 down vote accepted

For output variable use Appender (docs):

import std.array : appender;

void main() {
   auto output = appender!string("// Assembly file generated by my awesome VM compiler\n");
   //...
   output.put(format("// Input filename: %s\n", inputfname));
   foreach (line; inputf.byLine) {
       output.put(compile_operation(line.to!string().strip()));
   }
   //...
   outputf.write(output.data());
   //...
}

Also, I suggest that you should change your type_dict to something like int[string] and use it with integer constants.

int[string] type_dict;

const TYPE_ARITHMETIC = 0,
    TYPE_MEMORY = 1;

//...
type_dict = ["add": TYPE_ARITHMETIC, "push": TYPE_MEMORY]; // etc
//...

//...
if (type_dict[operation] == TYPE_ARITHMETIC) {
    //...
}
//...

Use canFind method (docs) instead of custom is_in. Or even try SortedRange (docs).

share|improve this answer

You might want to try using std.array.appender for output instead of array concatenation in your main function as appender minimizes the number of allocations and is generally optimized for appending. You can also experiment with reserve.

//Note: untested code
import std.array;
auto output = appender!string();

void init() {
   ...
   output.put("// Assembly file generated by my awesome VM compiler\n");
   ...
}

void main() {
   ...
   output.put(format("// Input filename: %s\n", inputfname));
   foreach (line; inputf.byLine) {
       output.put(compile_operation(to!string(line).strip));
   }
   ...
   foreach (outl; output.data)
       outputf.write(outl);
   ...
}
share|improve this answer
    
I put it in, but oddly enough, that doubled (!) the running time of the program. Wow, what is going on there. By the way, apparently it's illegal to declare auto output = appender!string(); in a global scope. I tried to declare it just as auto output; and initialize it in my init() function, but it didn't like the ambiguous type. Since I'm not sure what type it is (one of my few gripes with D are these seemingly anonymous types), and declaring it as an Appender didn't work either, I changed init to return auto and declared output in init. Any smoother way to do this? –  limp_chimp Feb 11 '13 at 18:01
    
string is an alias for (immutable char)[] and appender needs to change the elements of the array, changing it to appender!char will solve that. and there is a template somewhere in the lib to properly change the result to string with assumeUnique (assuming the array is only referenced locally) –  ratchet freak Feb 11 '13 at 19:23
1  
"and appender needs to change the elements of the array" - What? –  CyberShadow Feb 16 '13 at 15:05

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.