C++17 Command Line Parsing!
Parsing command line options is part of many applications. While there are many good libraries out there, writing your own can be a very good C++ exercise.
Yet another command line parser?
For a bigger project which requires complex conditional command line parsing I would definitely suggest using an existing library. Most likely, the best choice would be boost::program_options. However, this introduces a huge dependency for a task which should be easy to solve. Therefore, especially for small-scale prototype applications, a simple class which you can copy to your source tree might be a better solution.
The command line class
I have been using this class in various projects now and it always did a great job. It supports arguments as int32_t
, uint32_t
, double
, float
, bool
and std::string
. For arguments with type bool
, no value has to be given - that way simple flags like --help
can be implemented.
It’s quite easy to extend it to support custom data types. It uses std::variant to store pointers to local variables which are then set to the values given by the user. The actual parsing is done using std::stringstream.
CommandLine.hpp
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#ifndef COMMAND_LINE_HPP
#define COMMAND_LINE_HPP
#include <iostream>
#include <string>
#include <variant>
#include <vector>
// This class is a simple and effective class to parse command line arguments.
// For each possible argument it stores a pointer to a variable. When the
// corresponding argument is set on the command line (given to the parse()
// method) the variable is set to the given value. If the option is not set,
// the variable is not touched. Hence it should be initialized to a default
// state.
// For each argument, several names (aliases) can be defined. Thus, the same
// boolean could be set via '--help' or '-h'. While not required, it is a good
// practice to precede the argument names with either '--' or '-'. Except for
// booleans, a value is expected to be given. Booleans are set to 'true' if no
// value is provided (that means they can be used as simple flags as in the
// '--help' case). Values can be given in two ways: Either the option name and
// the value should be separated by a space or by a '='. Here are some valid
// examples:
// --string="Foo Bar"
// --string "Foo Bar"
// --help
// --help=false
// --help true
class CommandLine {
public:
// These are the possible variables the options may point to. Bool and
// std::string are handled in a special way, all other values are parsed
// with a std::stringstream. This std::variant can be easily extended if
// the stream operator>> is overloaded. If not, you have to add a special
// case to the parse() method.
typedef std::variant<int32_t*,
uint32_t*,
double*,
float*,
bool*,
std::string*> Value;
// The description is printed as part of the help message.
explicit CommandLine(std::string description);
// Adds a possible option. A typical call would be like this:
// bool printHelp = false;
// cmd.addArgument({"--help", "-h"}, &printHelp, "Print this help message");
// Then, after parse() has been called, printHelp will be true if the user
// provided the flag.
void addArgument(std::vector<std::string> const& flags,
Value const& value, std::string const& help);
// Prints the description given to the constructor and the help
// for each option.
void printHelp(std::ostream& os = std::cout) const;
// The command line arguments are traversed from start to end. That means,
// if an option is set multiple times, the last will be the one which is
// finally used. This call will throw a std::runtime_error if a value is
// missing for a given option. Unknown flags will cause a warning on
// std::cerr.
void parse(int argc, char* argv[]) const;
private:
struct Argument {
std::vector<std::string> mFlags;
Value mValue;
std::string mHelp;
};
std::string mDescription;
std::vector<Argument> mArguments;
};
#endif // COMMAND_LINE_HPP
CommandLine.cpp
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#include "CommandLine.hpp"
#include <algorithm>
#include <iomanip>
CommandLine::CommandLine(std::string description)
: mDescription(std::move(description)) {
}
void CommandLine::addArgument(std::vector<std::string> const& flags,
Value const& value, std::string const& help) {
mArguments.emplace_back(Argument{flags, value, help});
}
void CommandLine::printHelp(std::ostream& os) const {
// Print the general description.
os << mDescription << std::endl;
// Find the argument with the longest combined flag length (in order
// to align the help messages).
uint32_t maxFlagLength = 0;
for (auto const& argument : mArguments) {
uint32_t flagLength = 0;
for (auto const& flag : argument.mFlags) {
// Plus comma and space.
flagLength += static_cast<uint32_t>(flag.size()) + 2;
}
maxFlagLength = std::max(maxFlagLength, flagLength);
}
// Now print each argument.
for (auto const& argument : mArguments) {
std::string flags;
for (auto const& flag : argument.mFlags) {
flags += flag + ", ";
}
// Remove last comma and space and add padding according to the
// longest flags in order to align the help messages.
std::stringstream sstr;
sstr << std::left << std::setw(maxFlagLength)
<< flags.substr(0, flags.size() - 2);
// Print the help for each argument. This is a bit more involved
// since we do line wrapping for long descriptions.
size_t spacePos = 0;
size_t lineWidth = 0;
while (spacePos != std::string::npos) {
size_t nextspacePos = argument.mHelp.find_first_of(' ', spacePos + 1);
sstr << argument.mHelp.substr(spacePos, nextspacePos - spacePos);
lineWidth += nextspacePos - spacePos;
spacePos = nextspacePos;
if (lineWidth > 60) {
os << sstr.str() << std::endl;
sstr = std::stringstream();
sstr << std::left << std::setw(maxFlagLength - 1) << " ";
lineWidth = 0;
}
}
}
}
void CommandLine::parse(int argc, char* argv[]) const {
// Skip the first argument (name of the program).
int i = 1;
while (i < argc) {
// First we have to identify wether the value is separated by a space
// or a '='.
std::string flag(argv[i]);
std::string value;
bool valueIsSeparate = false;
// If there is an '=' in the flag, the part after the '=' is actually
// the value.
size_t equalPos = flag.find('=');
if (equalPos != std::string::npos) {
value = flag.substr(equalPos + 1);
flag = flag.substr(0, equalPos);
}
// Else the following argument is the value.
else if (i + 1 < argc) {
value = argv[i + 1];
valueIsSeparate = true;
}
// Search for an argument with the provided flag.
bool foundArgument = false;
for (auto const& argument : mArguments) {
if (std::find(argument.mFlags.begin(), argument.mFlags.end(), flag)
!= std::end(argument.mFlags)) {
foundArgument = true;
// In the case of booleans, there must not be a value present.
// So if the value is neither 'true' nor 'false' it is considered
// to be the next argument.
if (std::holds_alternative<bool*>(argument.mValue)) {
if (!value.empty() && value != "true" && value != "false") {
valueIsSeparate = false;
}
*std::get<bool*>(argument.mValue) = (value != "false");
}
// In all other cases there must be a value.
else if (value.empty()) {
throw std::runtime_error(
"Failed to parse command line arguments: "
"Missing value for argument \"" + flag + "\"!");
}
// For a std::string, we take the entire value.
else if (std::holds_alternative<std::string*>(argument.mValue)) {
*std::get<std::string*>(argument.mValue) = value;
}
// In all other cases we use a std::stringstream to
// convert the value.
else {
std::visit(
[&value](auto&& arg) {
std::stringstream sstr(value);
sstr >> *arg;
},
argument.mValue);
}
break;
}
}
// Print a warning if there was an unknown argument.
if (!foundArgument) {
std::cerr << "Ignoring unknown command line argument \"" << flag
<< "\"." << std::endl;
}
// Advance to the next flag.
++i;
// If the value was separated, we have to advance our index once more.
if (foundArgument && valueIsSeparate) {
++i;
}
}
}
Usage
You can copy the source code from above to two files called CommandLine.hpp
and CommandLine.cpp
. Then store the code below in main.cpp
.
main.cpp
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#include "CommandLine.hpp"
#include <iostream>
int main(int argc, char* argv[]) {
// This variables can be set via the command line.
std::string oString = "Default Value";
int32_t oInteger = -1;
uint32_t oUnsigned = 0;
double oDouble = 0.0;
float oFloat = 0.f;
bool oBool = false;
bool oPrintHelp = false;
// First configure all possible command line options.
CommandLine args("A demonstration of the simple command line parser.");
args.addArgument({"-s", "--string"}, &oString, "A string value");
args.addArgument({"-i", "--integer"}, &oInteger, "A integer value");
args.addArgument({"-u", "--unsigned"}, &oUnsigned, "A unsigned value");
args.addArgument({"-d", "--double"}, &oDouble, "A float value");
args.addArgument({"-f", "--float"}, &oFloat, "A double value");
args.addArgument({"-b", "--bool"}, &oBool, "A bool value");
args.addArgument({"-h", "--help"}, &oPrintHelp,
"Print this help. This help message is actually so long "
"that it requires a line break!");
// Then do the actual parsing.
try {
args.parse(argc, argv);
} catch (std::runtime_error const& e) {
std::cout << e.what() << std::endl;
return -1;
}
// When oPrintHelp was set to true, we print a help message and exit.
if (oPrintHelp) {
args.printHelp();
return 0;
}
// Print the resulting values.
std::cout << "mString: " << oString << std::endl;
std::cout << "mInteger: " << oInteger << std::endl;
std::cout << "mUnsigned: " << oUnsigned << std::endl;
std::cout.precision(std::numeric_limits<double>::max_digits10);
std::cout << "mDouble: " << oDouble << std::endl;
std::cout.precision(std::numeric_limits<float>::max_digits10);
std::cout << "mFloat: " << oFloat << std::endl;
std::cout << "mBool: " << oBool << std::endl;
return 0;
}
Then you can compile the example application with the following command. You can also compile the application on a recent MSVC shipped with Visual Studio 2017.
Running the executable without any arguments will show the default values of all available command line arguments. ./a.out --help
(or ./a.out -h
) will show a list of supported options.
Further Ideas
While the class is quite useful in the current state, it could be improved in several ways. Most obvious is the lack of required arguments. A basic implementation would be simple: Just add a bool
to the CommandLine::Argument
struct indicating wether it’s a required argument and throw an error if such an argument is not given.
However, you may want to have dependent arguments - if one argument is given, another one becomes possible or even required. This would not be straight-forward to implement in a proper way.
Anyway, I hope this class may help you to improve you productivity! If you spot any bugs or have ideas for improving it, let me know in the comments below!