ladybird/Userland/Shell/Builtin.cpp

1596 lines
51 KiB
C++

/*
* Copyright (c) 2020-2021, the SerenityOS developers.
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include "AST.h"
#include "Shell.h"
#include "Shell/Formatter.h"
#include <AK/LexicalPath.h>
#include <AK/ScopeGuard.h>
#include <AK/Statistics.h>
#include <AK/String.h>
#include <LibCore/ArgsParser.h>
#include <LibCore/EventLoop.h>
#include <LibCore/File.h>
#include <errno.h>
#include <inttypes.h>
#include <limits.h>
#include <signal.h>
#include <sys/wait.h>
#include <unistd.h>
extern char** environ;
namespace Shell {
int Shell::builtin_noop(int, char const**)
{
return 0;
}
int Shell::builtin_dump(int argc, char const** argv)
{
if (argc != 2)
return 1;
Parser { StringView { argv[1], strlen(argv[1]) } }.parse()->dump(0);
return 0;
}
int Shell::builtin_alias(int argc, char const** argv)
{
Vector<String> arguments;
Core::ArgsParser parser;
parser.add_positional_argument(arguments, "List of name[=values]'s", "name[=value]", Core::ArgsParser::Required::No);
if (!parser.parse(argc, const_cast<char**>(argv), Core::ArgsParser::FailureBehavior::PrintUsage))
return 1;
if (arguments.is_empty()) {
for (auto& alias : m_aliases)
printf("%s=%s\n", escape_token(alias.key).characters(), escape_token(alias.value).characters());
return 0;
}
bool fail = false;
for (auto& argument : arguments) {
auto parts = argument.split_limit('=', 2, true);
if (parts.size() == 1) {
auto alias = m_aliases.get(parts[0]);
if (alias.has_value()) {
printf("%s=%s\n", escape_token(parts[0]).characters(), escape_token(alias.value()).characters());
} else {
fail = true;
}
} else {
m_aliases.set(parts[0], parts[1]);
add_entry_to_cache({ RunnablePath::Kind::Alias, parts[0] });
}
}
return fail ? 1 : 0;
}
int Shell::builtin_unalias(int argc, char const** argv)
{
bool remove_all { false };
Vector<String> arguments;
Core::ArgsParser parser;
parser.set_general_help("Remove alias from the list of aliases");
parser.add_option(remove_all, "Remove all aliases", nullptr, 'a');
parser.add_positional_argument(arguments, "List of aliases to remove", "alias", Core::ArgsParser::Required::No);
if (!parser.parse(argc, const_cast<char**>(argv), Core::ArgsParser::FailureBehavior::PrintUsage))
return 1;
if (remove_all) {
m_aliases.clear();
cache_path();
return 0;
}
if (arguments.is_empty()) {
warnln("unalias: not enough arguments");
parser.print_usage(stderr, argv[0]);
return 1;
}
bool failed { false };
for (auto& argument : arguments) {
if (!m_aliases.contains(argument)) {
warnln("unalias: {}: alias not found", argument);
failed = true;
continue;
}
m_aliases.remove(argument);
remove_entry_from_cache(argument);
}
return failed ? 1 : 0;
}
int Shell::builtin_bg(int argc, char const** argv)
{
int job_id = -1;
bool is_pid = false;
Core::ArgsParser parser;
parser.add_positional_argument(Core::ArgsParser::Arg {
.help_string = "Job ID or Jobspec to run in background",
.name = "job-id",
.min_values = 0,
.max_values = 1,
.accept_value = [&](auto value_ptr) -> bool {
StringView value { value_ptr, strlen(value_ptr) };
// Check if it's a pid (i.e. literal integer)
if (auto number = value.to_uint(); number.has_value()) {
job_id = number.value();
is_pid = true;
return true;
}
// Check if it's a jobspec
if (auto id = resolve_job_spec(value); id.has_value()) {
job_id = id.value();
is_pid = false;
return true;
}
return false;
} });
if (!parser.parse(argc, const_cast<char**>(argv), Core::ArgsParser::FailureBehavior::PrintUsage))
return 1;
if (job_id == -1 && !jobs.is_empty())
job_id = find_last_job_id();
auto* job = const_cast<Job*>(find_job(job_id, is_pid));
if (!job) {
if (job_id == -1) {
warnln("bg: No current job");
} else {
warnln("bg: Job with id/pid {} not found", job_id);
}
return 1;
}
job->set_running_in_background(true);
job->set_should_announce_exit(true);
job->set_shell_did_continue(true);
dbgln("Resuming {} ({})", job->pid(), job->cmd());
warnln("Resuming job {} - {}", job->job_id(), job->cmd());
// Try using the PGID, but if that fails, just use the PID.
if (killpg(job->pgid(), SIGCONT) < 0) {
if (kill(job->pid(), SIGCONT) < 0) {
perror("kill");
return 1;
}
}
return 0;
}
int Shell::builtin_type(int argc, char const** argv)
{
Vector<String> commands;
bool dont_show_function_source = false;
Core::ArgsParser parser;
parser.set_general_help("Display information about commands.");
parser.add_positional_argument(commands, "Command(s) to list info about", "command");
parser.add_option(dont_show_function_source, "Do not show functions source.", "no-fn-source", 'f');
if (!parser.parse(argc, const_cast<char**>(argv), Core::ArgsParser::FailureBehavior::PrintUsage))
return 1;
bool something_not_found = false;
for (auto& command : commands) {
// check if it is an alias
if (auto alias = m_aliases.get(command); alias.has_value()) {
printf("%s is aliased to `%s`\n", escape_token(command).characters(), escape_token(alias.value()).characters());
continue;
}
// check if it is a function
if (auto function = m_functions.get(command); function.has_value()) {
auto fn = function.value();
printf("%s is a function\n", command.characters());
if (!dont_show_function_source) {
StringBuilder builder;
builder.append(fn.name);
builder.append('(');
for (size_t i = 0; i < fn.arguments.size(); i++) {
builder.append(fn.arguments[i]);
if (!(i == fn.arguments.size() - 1))
builder.append(' ');
}
builder.append(") {\n"sv);
if (fn.body) {
auto formatter = Formatter(*fn.body);
builder.append(formatter.format());
printf("%s\n}\n", builder.build().characters());
} else {
printf("%s\n}\n", builder.build().characters());
}
}
continue;
}
// check if its a builtin
if (has_builtin(command)) {
printf("%s is a shell builtin\n", command.characters());
continue;
}
// check if its an executable in PATH
auto fullpath = Core::File::resolve_executable_from_environment(command);
if (fullpath.has_value()) {
printf("%s is %s\n", command.characters(), escape_token(fullpath.release_value()).characters());
continue;
}
something_not_found = true;
printf("type: %s not found\n", command.characters());
}
if (something_not_found)
return 1;
else
return 0;
}
int Shell::builtin_cd(int argc, char const** argv)
{
char const* arg_path = nullptr;
Core::ArgsParser parser;
parser.add_positional_argument(arg_path, "Path to change to", "path", Core::ArgsParser::Required::No);
if (!parser.parse(argc, const_cast<char**>(argv), Core::ArgsParser::FailureBehavior::PrintUsage))
return 1;
String new_path;
if (!arg_path) {
new_path = home;
} else {
if (strcmp(arg_path, "-") == 0) {
char* oldpwd = getenv("OLDPWD");
if (oldpwd == nullptr)
return 1;
new_path = oldpwd;
} else {
new_path = arg_path;
}
}
auto real_path = Core::File::real_path_for(new_path);
if (real_path.is_empty()) {
warnln("Invalid path '{}'", new_path);
return 1;
}
if (cd_history.is_empty() || cd_history.last() != real_path)
cd_history.enqueue(real_path);
auto path_relative_to_current_directory = LexicalPath::relative_path(real_path, cwd);
if (path_relative_to_current_directory.is_empty())
path_relative_to_current_directory = real_path;
char const* path = path_relative_to_current_directory.characters();
int rc = chdir(path);
if (rc < 0) {
if (errno == ENOTDIR) {
warnln("Not a directory: {}", path);
} else {
warnln("chdir({}) failed: {}", path, strerror(errno));
}
return 1;
}
setenv("OLDPWD", cwd.characters(), 1);
cwd = move(real_path);
setenv("PWD", cwd.characters(), 1);
return 0;
}
int Shell::builtin_cdh(int argc, char const** argv)
{
int index = -1;
Core::ArgsParser parser;
parser.add_positional_argument(index, "Index of the cd history entry (leave out for a list)", "index", Core::ArgsParser::Required::No);
if (!parser.parse(argc, const_cast<char**>(argv), Core::ArgsParser::FailureBehavior::PrintUsage))
return 1;
if (index == -1) {
if (cd_history.is_empty()) {
warnln("cdh: no history available");
return 0;
}
for (ssize_t i = cd_history.size() - 1; i >= 0; --i)
printf("%zu: %s\n", cd_history.size() - i, cd_history.at(i).characters());
return 0;
}
if (index < 1 || (size_t)index > cd_history.size()) {
warnln("cdh: history index out of bounds: {} not in (0, {})", index, cd_history.size());
return 1;
}
char const* path = cd_history.at(cd_history.size() - index).characters();
char const* cd_args[] = { "cd", path, nullptr };
return Shell::builtin_cd(2, cd_args);
}
int Shell::builtin_dirs(int argc, char const** argv)
{
// The first directory in the stack is ALWAYS the current directory
directory_stack.at(0) = cwd.characters();
bool clear = false;
bool print = false;
bool number_when_printing = false;
char separator = ' ';
Vector<String> paths;
Core::ArgsParser parser;
parser.add_option(clear, "Clear the directory stack", "clear", 'c');
parser.add_option(print, "Print directory entries one per line", "print", 'p');
parser.add_option(number_when_printing, "Number the directories in the stack when printing", "number", 'v');
parser.add_positional_argument(paths, "Extra paths to put on the stack", "path", Core::ArgsParser::Required::No);
if (!parser.parse(argc, const_cast<char**>(argv), Core::ArgsParser::FailureBehavior::PrintUsage))
return 1;
// -v implies -p
print = print || number_when_printing;
if (print) {
if (!paths.is_empty()) {
warnln("dirs: 'print' and 'number' are not allowed when any path is specified");
return 1;
}
separator = '\n';
}
if (clear) {
for (size_t i = 1; i < directory_stack.size(); i++)
directory_stack.remove(i);
}
for (auto& path : paths)
directory_stack.append(path);
if (print || (!clear && paths.is_empty())) {
int index = 0;
for (auto& directory : directory_stack) {
if (number_when_printing)
printf("%d ", index++);
print_path(directory);
fputc(separator, stdout);
}
}
return 0;
}
int Shell::builtin_exec(int argc, char const** argv)
{
if (argc < 2) {
warnln("Shell: No command given to exec");
return 1;
}
Vector<char const*> argv_vector;
argv_vector.append(argv + 1, argc - 1);
argv_vector.append(nullptr);
execute_process(move(argv_vector));
}
int Shell::builtin_exit(int argc, char const** argv)
{
int exit_code = 0;
Core::ArgsParser parser;
parser.add_positional_argument(exit_code, "Exit code", "code", Core::ArgsParser::Required::No);
if (!parser.parse(argc, const_cast<char**>(argv), Core::ArgsParser::FailureBehavior::PrintUsage))
return 1;
if (m_is_interactive) {
if (!jobs.is_empty()) {
if (!m_should_ignore_jobs_on_next_exit) {
warnln("Shell: You have {} active job{}, run 'exit' again to really exit.", jobs.size(), jobs.size() > 1 ? "s" : "");
m_should_ignore_jobs_on_next_exit = true;
return 1;
}
}
}
stop_all_jobs();
if (m_is_interactive) {
m_editor->save_history(get_history_path());
printf("Good-bye!\n");
}
exit(exit_code);
}
int Shell::builtin_export(int argc, char const** argv)
{
Vector<String> vars;
Core::ArgsParser parser;
parser.add_positional_argument(vars, "List of variable[=value]'s", "values", Core::ArgsParser::Required::No);
if (!parser.parse(argc, const_cast<char**>(argv), Core::ArgsParser::FailureBehavior::PrintUsage))
return 1;
if (vars.is_empty()) {
for (size_t i = 0; environ[i]; ++i)
puts(environ[i]);
return 0;
}
for (auto& value : vars) {
auto parts = value.split_limit('=', 2);
if (parts.size() == 1) {
auto value = lookup_local_variable(parts[0]);
if (value) {
auto values = value->resolve_as_list(*this);
StringBuilder builder;
builder.join(' ', values);
parts.append(builder.to_string());
} else {
// Ignore the export.
continue;
}
}
int setenv_return = setenv(parts[0].characters(), parts[1].characters(), 1);
if (setenv_return != 0) {
perror("setenv");
return 1;
}
if (parts[0] == "PATH")
cache_path();
}
return 0;
}
int Shell::builtin_glob(int argc, char const** argv)
{
Vector<String> globs;
Core::ArgsParser parser;
parser.add_positional_argument(globs, "Globs to resolve", "glob");
if (!parser.parse(argc, const_cast<char**>(argv), Core::ArgsParser::FailureBehavior::PrintUsage))
return 1;
for (auto& glob : globs) {
for (auto& expanded : expand_globs(glob, cwd))
outln("{}", expanded);
}
return 0;
}
int Shell::builtin_fg(int argc, char const** argv)
{
int job_id = -1;
bool is_pid = false;
Core::ArgsParser parser;
parser.add_positional_argument(Core::ArgsParser::Arg {
.help_string = "Job ID or Jobspec to bring to foreground",
.name = "job-id",
.min_values = 0,
.max_values = 1,
.accept_value = [&](auto const* value_ptr) -> bool {
StringView value { value_ptr, strlen(value_ptr) };
// Check if it's a pid (i.e. literal integer)
if (auto number = value.to_uint(); number.has_value()) {
job_id = number.value();
is_pid = true;
return true;
}
// Check if it's a jobspec
if (auto id = resolve_job_spec(value); id.has_value()) {
job_id = id.value();
is_pid = false;
return true;
}
return false;
} });
if (!parser.parse(argc, const_cast<char**>(argv), Core::ArgsParser::FailureBehavior::PrintUsage))
return 1;
if (job_id == -1 && !jobs.is_empty())
job_id = find_last_job_id();
RefPtr<Job> job = find_job(job_id, is_pid);
if (!job) {
if (job_id == -1) {
warnln("fg: No current job");
} else {
warnln("fg: Job with id/pid {} not found", job_id);
}
return 1;
}
job->set_running_in_background(false);
job->set_shell_did_continue(true);
dbgln("Resuming {} ({})", job->pid(), job->cmd());
warnln("Resuming job {} - {}", job->job_id(), job->cmd());
tcsetpgrp(STDOUT_FILENO, job->pgid());
tcsetpgrp(STDIN_FILENO, job->pgid());
// Try using the PGID, but if that fails, just use the PID.
if (killpg(job->pgid(), SIGCONT) < 0) {
if (kill(job->pid(), SIGCONT) < 0) {
perror("kill");
return 1;
}
}
block_on_job(job);
if (job->exited())
return job->exit_code();
else
return 0;
}
int Shell::builtin_disown(int argc, char const** argv)
{
Vector<int> job_ids;
Vector<bool> id_is_pid;
Core::ArgsParser parser;
parser.add_positional_argument(Core::ArgsParser::Arg {
.help_string = "Job IDs or Jobspecs to disown",
.name = "job-id",
.min_values = 0,
.max_values = INT_MAX,
.accept_value = [&](auto const* value_ptr) -> bool {
StringView value { value_ptr, strlen(value_ptr) };
// Check if it's a pid (i.e. literal integer)
if (auto number = value.to_uint(); number.has_value()) {
job_ids.append(number.value());
id_is_pid.append(true);
return true;
}
// Check if it's a jobspec
if (auto id = resolve_job_spec(value); id.has_value()) {
job_ids.append(id.value());
id_is_pid.append(false);
return true;
}
return false;
} });
if (!parser.parse(argc, const_cast<char**>(argv), Core::ArgsParser::FailureBehavior::PrintUsage))
return 1;
if (job_ids.is_empty()) {
job_ids.append(find_last_job_id());
id_is_pid.append(false);
}
Vector<Job const*> jobs_to_disown;
for (size_t i = 0; i < job_ids.size(); ++i) {
auto id = job_ids[i];
auto is_pid = id_is_pid[i];
auto job = find_job(id, is_pid);
if (!job)
warnln("disown: Job with id/pid {} not found", id);
else
jobs_to_disown.append(job);
}
if (jobs_to_disown.is_empty()) {
if (job_ids.is_empty())
warnln("disown: No current job");
// An error message has already been printed about the nonexistence of each listed job.
return 1;
}
for (auto job : jobs_to_disown) {
job->deactivate();
if (!job->is_running_in_background())
warnln("disown warning: Job {} is currently not running, 'kill -{} {}' to make it continue", job->job_id(), SIGCONT, job->pid());
jobs.remove(job->pid());
}
return 0;
}
int Shell::builtin_history(int, char const**)
{
for (size_t i = 0; i < m_editor->history().size(); ++i) {
printf("%6zu %s\n", i + 1, m_editor->history()[i].entry.characters());
}
return 0;
}
int Shell::builtin_jobs(int argc, char const** argv)
{
bool list = false, show_pid = false;
Core::ArgsParser parser;
parser.add_option(list, "List all information about jobs", "list", 'l');
parser.add_option(show_pid, "Display the PID of the jobs", "pid", 'p');
if (!parser.parse(argc, const_cast<char**>(argv), Core::ArgsParser::FailureBehavior::PrintUsage))
return 1;
Job::PrintStatusMode mode = Job::PrintStatusMode::Basic;
if (show_pid)
mode = Job::PrintStatusMode::OnlyPID;
if (list)
mode = Job::PrintStatusMode::ListAll;
for (auto& it : jobs) {
if (!it.value->print_status(mode))
return 1;
}
return 0;
}
int Shell::builtin_popd(int argc, char const** argv)
{
if (directory_stack.size() <= 1) {
warnln("Shell: popd: directory stack empty");
return 1;
}
bool should_not_switch = false;
Core::ArgsParser parser;
parser.add_option(should_not_switch, "Do not switch dirs", "no-switch", 'n');
if (!parser.parse(argc, const_cast<char**>(argv), Core::ArgsParser::FailureBehavior::PrintUsage))
return 1;
auto popped_path = directory_stack.take_last();
if (should_not_switch)
return 0;
auto new_path = LexicalPath::canonicalized_path(popped_path);
if (chdir(new_path.characters()) < 0) {
warnln("chdir({}) failed: {}", new_path, strerror(errno));
return 1;
}
cwd = new_path;
return 0;
}
int Shell::builtin_pushd(int argc, char const** argv)
{
StringBuilder path_builder;
bool should_switch = true;
// From the BASH reference manual: https://www.gnu.org/software/bash/manual/html_node/Directory-Stack-Builtins.html
// With no arguments, pushd exchanges the top two directories and makes the new top the current directory.
if (argc == 1) {
if (directory_stack.size() < 2) {
warnln("pushd: no other directory");
return 1;
}
String dir1 = directory_stack.take_first();
String dir2 = directory_stack.take_first();
directory_stack.insert(0, dir2);
directory_stack.insert(1, dir1);
int rc = chdir(dir2.characters());
if (rc < 0) {
warnln("chdir({}) failed: {}", dir2, strerror(errno));
return 1;
}
cwd = dir2;
return 0;
}
// Let's assume the user's typed in 'pushd <dir>'
if (argc == 2) {
directory_stack.append(cwd.characters());
if (argv[1][0] == '/') {
path_builder.append({ argv[1], strlen(argv[1]) });
} else {
path_builder.appendff("{}/{}", cwd, argv[1]);
}
} else if (argc == 3) {
directory_stack.append(cwd.characters());
for (int i = 1; i < argc; i++) {
char const* arg = argv[i];
if (arg[0] != '-') {
if (arg[0] == '/') {
path_builder.append({ arg, strlen(arg) });
} else
path_builder.appendff("{}/{}", cwd, arg);
}
if (!strcmp(arg, "-n"))
should_switch = false;
}
}
auto real_path = LexicalPath::canonicalized_path(path_builder.to_string());
struct stat st;
int rc = stat(real_path.characters(), &st);
if (rc < 0) {
warnln("stat({}) failed: {}", real_path, strerror(errno));
return 1;
}
if (!S_ISDIR(st.st_mode)) {
warnln("Not a directory: {}", real_path);
return 1;
}
if (should_switch) {
int rc = chdir(real_path.characters());
if (rc < 0) {
warnln("chdir({}) failed: {}", real_path, strerror(errno));
return 1;
}
cwd = real_path;
}
return 0;
}
int Shell::builtin_pwd(int, char const**)
{
print_path(cwd);
fputc('\n', stdout);
return 0;
}
int Shell::builtin_setopt(int argc, char const** argv)
{
if (argc == 1) {
#define __ENUMERATE_SHELL_OPTION(name, default_, description) \
if (options.name) \
warnln("{}", #name);
ENUMERATE_SHELL_OPTIONS();
#undef __ENUMERATE_SHELL_OPTION
}
Core::ArgsParser parser;
#define __ENUMERATE_SHELL_OPTION(name, default_, description) \
bool name = false; \
bool not_##name = false; \
parser.add_option(name, "Enable: " description, #name, '\0'); \
parser.add_option(not_##name, "Disable: " description, "no_" #name, '\0');
ENUMERATE_SHELL_OPTIONS();
#undef __ENUMERATE_SHELL_OPTION
if (!parser.parse(argc, const_cast<char**>(argv), Core::ArgsParser::FailureBehavior::PrintUsage))
return 1;
#define __ENUMERATE_SHELL_OPTION(name, default_, description) \
if (name) \
options.name = true; \
if (not_##name) \
options.name = false;
ENUMERATE_SHELL_OPTIONS();
#undef __ENUMERATE_SHELL_OPTION
return 0;
}
int Shell::builtin_shift(int argc, char const** argv)
{
int count = 1;
Core::ArgsParser parser;
parser.add_positional_argument(count, "Shift count", "count", Core::ArgsParser::Required::No);
if (!parser.parse(argc, const_cast<char**>(argv), Core::ArgsParser::FailureBehavior::PrintUsage))
return 1;
if (count < 1)
return 0;
auto argv_ = lookup_local_variable("ARGV"sv);
if (!argv_) {
warnln("shift: ARGV is unset");
return 1;
}
if (!argv_->is_list())
argv_ = adopt_ref(*new AST::ListValue({ argv_.release_nonnull() }));
auto& values = static_cast<AST::ListValue*>(argv_.ptr())->values();
if ((size_t)count > values.size()) {
warnln("shift: shift count must not be greater than {}", values.size());
return 1;
}
for (auto i = 0; i < count; ++i)
(void)values.take_first();
return 0;
}
int Shell::builtin_source(int argc, char const** argv)
{
char const* file_to_source = nullptr;
Vector<String> args;
Core::ArgsParser parser;
parser.add_positional_argument(file_to_source, "File to read commands from", "path");
parser.add_positional_argument(args, "ARGV for the sourced file", "args", Core::ArgsParser::Required::No);
if (!parser.parse(argc, const_cast<char**>(argv)))
return 1;
auto previous_argv = lookup_local_variable("ARGV"sv);
ScopeGuard guard { [&] {
if (!args.is_empty())
set_local_variable("ARGV", move(previous_argv));
} };
if (!args.is_empty())
set_local_variable("ARGV", AST::make_ref_counted<AST::ListValue>(move(args)));
if (!run_file(file_to_source, true))
return 126;
return 0;
}
int Shell::builtin_time(int argc, char const** argv)
{
AST::Command command;
int number_of_iterations = 1;
Core::ArgsParser parser;
parser.add_option(number_of_iterations, "Number of iterations", "iterations", 'n', "iterations");
parser.set_stop_on_first_non_option(true);
parser.add_positional_argument(command.argv, "Command to execute with arguments", "command", Core::ArgsParser::Required::Yes);
if (!parser.parse(argc, const_cast<char**>(argv), Core::ArgsParser::FailureBehavior::PrintUsage))
return 1;
if (number_of_iterations < 1)
return 1;
auto commands = expand_aliases({ move(command) });
AK::Statistics iteration_times;
int exit_code = 1;
for (int i = 0; i < number_of_iterations; ++i) {
auto timer = Core::ElapsedTimer::start_new();
for (auto& job : run_commands(commands)) {
block_on_job(job);
exit_code = job.exit_code();
}
iteration_times.add(timer.elapsed());
}
if (number_of_iterations == 1) {
warnln("Time: {} ms", iteration_times.values().first());
} else {
AK::Statistics iteration_times_excluding_first;
for (size_t i = 1; i < iteration_times.size(); i++)
iteration_times_excluding_first.add(iteration_times.values()[i]);
warnln("Timing report: {} ms", iteration_times.sum());
warnln("==============");
warnln("Command: {}", String::join(' ', Span<char const*>(argv, argc)));
warnln("Average time: {:.2} ms (median: {}, stddev: {:.2}, min: {}, max:{})",
iteration_times.average(), iteration_times.median(),
iteration_times.standard_deviation(),
iteration_times.min(), iteration_times.max());
warnln("Excluding first: {:.2} ms (median: {}, stddev: {:.2}, min: {}, max:{})",
iteration_times_excluding_first.average(), iteration_times_excluding_first.median(),
iteration_times_excluding_first.standard_deviation(),
iteration_times_excluding_first.min(), iteration_times_excluding_first.max());
}
return exit_code;
}
int Shell::builtin_umask(int argc, char const** argv)
{
char const* mask_text = nullptr;
Core::ArgsParser parser;
parser.add_positional_argument(mask_text, "New mask (omit to get current mask)", "octal-mask", Core::ArgsParser::Required::No);
if (!parser.parse(argc, const_cast<char**>(argv), Core::ArgsParser::FailureBehavior::PrintUsage))
return 1;
if (!mask_text) {
mode_t old_mask = umask(0);
printf("%#o\n", old_mask);
umask(old_mask);
return 0;
}
unsigned mask;
int matches = sscanf(mask_text, "%o", &mask);
if (matches == 1) {
umask(mask);
return 0;
}
warnln("umask: Invalid mask '{}'", mask_text);
return 1;
}
int Shell::builtin_wait(int argc, char const** argv)
{
Vector<int> job_ids;
Vector<bool> id_is_pid;
Core::ArgsParser parser;
parser.add_positional_argument(Core::ArgsParser::Arg {
.help_string = "Job IDs or Jobspecs to wait for",
.name = "job-id",
.min_values = 0,
.max_values = INT_MAX,
.accept_value = [&](auto const* value_ptr) -> bool {
StringView value { value_ptr, strlen(value_ptr) };
// Check if it's a pid (i.e. literal integer)
if (auto number = value.to_uint(); number.has_value()) {
job_ids.append(number.value());
id_is_pid.append(true);
return true;
}
// Check if it's a jobspec
if (auto id = resolve_job_spec(value); id.has_value()) {
job_ids.append(id.value());
id_is_pid.append(false);
return true;
}
return false;
} });
if (!parser.parse(argc, const_cast<char**>(argv), Core::ArgsParser::FailureBehavior::PrintUsage))
return 1;
Vector<NonnullRefPtr<Job>> jobs_to_wait_for;
for (size_t i = 0; i < job_ids.size(); ++i) {
auto id = job_ids[i];
auto is_pid = id_is_pid[i];
auto job = find_job(id, is_pid);
if (!job)
warnln("wait: Job with id/pid {} not found", id);
else
jobs_to_wait_for.append(*job);
}
if (job_ids.is_empty()) {
for (auto const& it : jobs)
jobs_to_wait_for.append(it.value);
}
for (auto& job : jobs_to_wait_for) {
job->set_running_in_background(false);
block_on_job(job);
}
return 0;
}
int Shell::builtin_unset(int argc, char const** argv)
{
Vector<String> vars;
Core::ArgsParser parser;
parser.add_positional_argument(vars, "List of variables", "variables", Core::ArgsParser::Required::Yes);
if (!parser.parse(argc, const_cast<char**>(argv), Core::ArgsParser::FailureBehavior::PrintUsage))
return 1;
bool did_touch_path = false;
for (auto& value : vars) {
if (!did_touch_path && value == "PATH"sv)
did_touch_path = true;
if (lookup_local_variable(value)) {
unset_local_variable(value);
} else {
unsetenv(value.characters());
}
}
if (did_touch_path)
cache_path();
return 0;
}
int Shell::builtin_not(int argc, char const** argv)
{
// FIXME: Use ArgsParser when it can collect unrelated -arguments too.
if (argc == 1)
return 1;
AST::Command command;
for (size_t i = 1; i < (size_t)argc; ++i)
command.argv.append(argv[i]);
auto commands = expand_aliases({ move(command) });
int exit_code = 1;
auto found_a_job = false;
for (auto& job : run_commands(commands)) {
found_a_job = true;
block_on_job(job);
exit_code = job.exit_code();
}
// In case it was a function.
if (!found_a_job)
exit_code = last_return_code.value_or(0);
return exit_code == 0 ? 1 : 0;
}
int Shell::builtin_kill(int argc, char const** argv)
{
// Simply translate the arguments and pass them to `kill'
Vector<String> replaced_values;
auto kill_path = Core::File::resolve_executable_from_environment("kill"sv);
if (!kill_path.has_value()) {
warnln("kill: `kill' not found in PATH");
return 126;
}
replaced_values.append(kill_path.release_value());
for (auto i = 1; i < argc; ++i) {
if (auto job_id = resolve_job_spec({ argv[i], strlen(argv[1]) }); job_id.has_value()) {
auto job = find_job(job_id.value());
if (job) {
replaced_values.append(String::number(job->pid()));
} else {
warnln("kill: Job with pid {} not found", job_id.value());
return 1;
}
} else {
replaced_values.append(argv[i]);
}
}
// Now just run `kill'
AST::Command command;
command.argv = move(replaced_values);
command.position = m_source_position.has_value() ? m_source_position->position : Optional<AST::Position> {};
auto exit_code = 1;
auto job_result = run_command(command);
if (job_result.is_error()) {
warnln("kill: Failed to run {}: {}", command.argv.first(), job_result.error());
return exit_code;
}
if (auto job = job_result.release_value()) {
block_on_job(job);
exit_code = job->exit_code();
}
return exit_code;
}
bool Shell::run_builtin(const AST::Command& command, NonnullRefPtrVector<AST::Rewiring> const& rewirings, int& retval)
{
if (command.argv.is_empty())
return false;
if (!has_builtin(command.argv.first()))
return false;
Vector<char const*> argv;
for (auto& arg : command.argv)
argv.append(arg.characters());
argv.append(nullptr);
StringView name = command.argv.first();
SavedFileDescriptors fds { rewirings };
for (auto& rewiring : rewirings) {
int rc = dup2(rewiring.old_fd, rewiring.new_fd);
if (rc < 0) {
perror("dup2(run)");
return false;
}
}
Core::EventLoop loop;
setup_signals();
if (name == ":"sv)
name = "noop"sv;
#define __ENUMERATE_SHELL_BUILTIN(builtin) \
if (name == #builtin) { \
retval = builtin_##builtin(argv.size() - 1, argv.data()); \
if (!has_error(ShellError::None)) \
raise_error(m_error, m_error_description, command.position); \
fflush(stdout); \
fflush(stderr); \
return true; \
}
ENUMERATE_SHELL_BUILTINS();
#undef __ENUMERATE_SHELL_BUILTIN
return false;
}
int Shell::builtin_argsparser_parse(int argc, char const** argv)
{
// argsparser_parse
// --add-option variable [--type (bool | string | i32 | u32 | double | size)] --help-string "" --long-name "" --short-name "" [--value-name "" <if not --type bool>] --list
// --add-positional-argument variable [--type (bool | string | i32 | u32 | double | size)] ([--min n] [--max n] | [--required]) --help-string "" --value-name ""
// [--general-help ""]
// [--stop-on-first-non-option]
// --
// $args_to_parse
Core::ArgsParser parser;
Core::ArgsParser user_parser;
Vector<char const*> arguments;
Variant<Core::ArgsParser::Option, Core::ArgsParser::Arg, Empty> current;
String current_variable;
// if max > 1 or min < 1, or explicit `--list`.
bool treat_arg_as_list = false;
enum class Type {
Bool,
String,
I32,
U32,
Double,
Size,
};
auto type = Type::String;
auto try_convert = [](StringView value, Type type) -> Optional<RefPtr<AST::Value>> {
switch (type) {
case Type::Bool:
return AST::make_ref_counted<AST::StringValue>("true");
case Type::String:
return AST::make_ref_counted<AST::StringValue>(value);
case Type::I32:
if (auto number = value.to_int(); number.has_value())
return AST::make_ref_counted<AST::StringValue>(String::number(*number));
warnln("Invalid value for type i32: {}", value);
return {};
case Type::U32:
case Type::Size:
if (auto number = value.to_uint(); number.has_value())
return AST::make_ref_counted<AST::StringValue>(String::number(*number));
warnln("Invalid value for type u32|size: {}", value);
return {};
case Type::Double: {
String string = value;
char* endptr = nullptr;
auto number = strtod(string.characters(), &endptr);
if (endptr != string.characters() + string.length()) {
warnln("Invalid value for type double: {}", value);
return {};
}
return AST::make_ref_counted<AST::StringValue>(String::number(number));
}
default:
VERIFY_NOT_REACHED();
}
};
auto enlist = [&](auto name, auto value) -> NonnullRefPtr<AST::Value> {
auto variable = lookup_local_variable(name);
if (variable) {
auto list = variable->resolve_as_list(*this);
auto new_value = value->resolve_as_string(*this);
list.append(move(new_value));
return make_ref_counted<AST::ListValue>(move(list));
}
return *value;
};
auto commit = [&] {
return current.visit(
[&](Core::ArgsParser::Option& option) {
if (!option.long_name && !option.short_name) {
warnln("Defined option must have at least one of --long-name or --short-name");
return false;
}
option.accept_value = [&, current_variable, treat_arg_as_list, type](auto value) {
auto result = try_convert({ value, strlen(value) }, type);
if (result.has_value()) {
auto value = result.release_value();
if (treat_arg_as_list)
value = enlist(current_variable, move(value));
this->set_local_variable(current_variable, move(value), true);
return true;
}
return false;
};
user_parser.add_option(move(option));
type = Type::String;
treat_arg_as_list = false;
return true;
},
[&](Core::ArgsParser::Arg& arg) {
if (!arg.name) {
warnln("Defined positional argument must have a name");
return false;
}
arg.accept_value = [&, current_variable, treat_arg_as_list, type](auto value) {
auto result = try_convert({ value, strlen(value) }, type);
if (result.has_value()) {
auto value = result.release_value();
if (treat_arg_as_list)
value = enlist(current_variable, move(value));
this->set_local_variable(current_variable, move(value), true);
return true;
}
return false;
};
user_parser.add_positional_argument(move(arg));
type = Type::String;
treat_arg_as_list = false;
return true;
},
[&](Empty) {
return true;
});
};
parser.add_option(Core::ArgsParser::Option {
.argument_mode = Core::ArgsParser::OptionArgumentMode::None,
.help_string = "Stop processing arguments after a non-argument parameter is seen",
.long_name = "stop-on-first-non-option",
.accept_value = [&](auto) {
user_parser.set_stop_on_first_non_option(true);
return true;
},
});
parser.add_option(Core::ArgsParser::Option {
.argument_mode = Core::ArgsParser::OptionArgumentMode::Required,
.help_string = "Set the general help string for the parser",
.long_name = "general-help",
.value_name = "string",
.accept_value = [&](auto value) {
user_parser.set_general_help(value);
return true;
},
});
parser.add_option(Core::ArgsParser::Option {
.argument_mode = Core::ArgsParser::OptionArgumentMode::Required,
.help_string = "Start describing an option",
.long_name = "add-option",
.value_name = "variable-name",
.accept_value = [&](auto name) {
if (!commit())
return false;
current = Core::ArgsParser::Option {};
current_variable = name;
if (current_variable.is_empty() || !all_of(current_variable, [](auto ch) { return ch == '_' || isalnum(ch); })) {
warnln("Option variable name must be a valid identifier");
return false;
}
return true;
},
});
parser.add_option(Core::ArgsParser::Option {
.argument_mode = Core::ArgsParser::OptionArgumentMode::None,
.help_string = "Accept multiple of the current option being given",
.long_name = "list",
.accept_value = [&](auto) {
if (!current.has<Core::ArgsParser::Option>()) {
warnln("Must be defining an option to use --list");
return false;
}
treat_arg_as_list = true;
return true;
},
});
parser.add_option(Core::ArgsParser::Option {
.argument_mode = Core::ArgsParser::OptionArgumentMode::Required,
.help_string = "Define the type of the option or argument being described",
.long_name = "type",
.value_name = "type",
.accept_value = [&](auto name) {
if (current.has<Empty>()) {
warnln("Must be defining an argument or option to use --type");
return false;
}
StringView ty { name, strlen(name) };
if (ty == "bool") {
if (auto option = current.get_pointer<Core::ArgsParser::Option>()) {
if (option->value_name != nullptr) {
warnln("Type 'bool' does not apply to options with a value (value name is set to {})", option->value_name);
return false;
}
}
type = Type::Bool;
} else if (ty == "string") {
type = Type::String;
} else if (ty == "i32") {
type = Type::I32;
} else if (ty == "u32") {
type = Type::U32;
} else if (ty == "double") {
type = Type::Double;
} else if (ty == "size") {
type = Type::Size;
} else {
warnln("Invalid type '{}', expected one of bool | string | i32 | u32 | double | size", ty);
return false;
}
if (type == Type::Bool)
set_local_variable(current_variable, make_ref_counted<AST::StringValue>("false"), true);
return true;
},
});
parser.add_option(Core::ArgsParser::Option {
.argument_mode = Core::ArgsParser::OptionArgumentMode::Required,
.help_string = "Set the help string of the option or argument being defined",
.long_name = "help-string",
.value_name = "string",
.accept_value = [&](auto value) {
return current.visit(
[](Empty) {
warnln("Must be defining an option or argument to use --help-string");
return false;
},
[&](auto& option) {
option.help_string = value;
return true;
});
},
});
parser.add_option(Core::ArgsParser::Option {
.argument_mode = Core::ArgsParser::OptionArgumentMode::Required,
.help_string = "Set the long name of the option being defined",
.long_name = "long-name",
.value_name = "name",
.accept_value = [&](auto value) {
auto option = current.get_pointer<Core::ArgsParser::Option>();
if (!option) {
warnln("Must be defining an option to use --long-name");
return false;
}
if (option->long_name) {
warnln("Repeated application of --long-name is not allowed, current option has long name set to \"{}\"", option->long_name);
return false;
}
option->long_name = value;
return true;
},
});
parser.add_option(Core::ArgsParser::Option {
.argument_mode = Core::ArgsParser::OptionArgumentMode::Required,
.help_string = "Set the short name of the option being defined",
.long_name = "short-name",
.value_name = "char",
.accept_value = [&](auto value) {
auto option = current.get_pointer<Core::ArgsParser::Option>();
if (!option) {
warnln("Must be defining an option to use --short-name");
return false;
}
if (strlen(value) != 1) {
warnln("Option short name ('{}') must be exactly one character long", value);
return false;
}
if (option->short_name) {
warnln("Repeated application of --short-name is not allowed, current option has short name set to '{}'", option->short_name);
return false;
}
option->short_name = value[0];
return true;
},
});
parser.add_option(Core::ArgsParser::Option {
.argument_mode = Core::ArgsParser::OptionArgumentMode::Required,
.help_string = "Set the value name of the option being defined",
.long_name = "value-name",
.value_name = "string",
.accept_value = [&](auto value) {
return current.visit(
[](Empty) {
warnln("Must be defining an option or a positional argument to use --value-name");
return false;
},
[&](Core::ArgsParser::Option& option) {
if (option.value_name) {
warnln("Repeated application of --value-name is not allowed, current option has value name set to \"{}\"", option.value_name);
return false;
}
if (type == Type::Bool) {
warnln("Options of type bool cannot have a value name");
return false;
}
option.value_name = value;
return true;
},
[&](Core::ArgsParser::Arg& arg) {
if (arg.name) {
warnln("Repeated application of --value-name is not allowed, current argument has value name set to \"{}\"", arg.name);
return false;
}
arg.name = value;
return true;
});
},
});
parser.add_option(Core::ArgsParser::Option {
.argument_mode = Core::ArgsParser::OptionArgumentMode::Required,
.help_string = "Start describing a positional argument",
.long_name = "add-positional-argument",
.value_name = "variable",
.accept_value = [&](auto value) {
if (!commit())
return false;
current = Core::ArgsParser::Arg {};
current_variable = value;
if (current_variable.is_empty() || !all_of(current_variable, [](auto ch) { return ch == '_' || isalnum(ch); })) {
warnln("Argument variable name must be a valid identifier");
return false;
}
return true;
},
});
parser.add_option(Core::ArgsParser::Option {
.argument_mode = Core::ArgsParser::OptionArgumentMode::Required,
.help_string = "Set the minimum required number of positional arguments for the argument being described",
.long_name = "min",
.value_name = "n",
.accept_value = [&](auto value) {
auto arg = current.get_pointer<Core::ArgsParser::Arg>();
if (!arg) {
warnln("Must be describing a positional argument to use --min");
return false;
}
auto number = StringView { value, strlen(value) }.to_uint();
if (!number.has_value()) {
warnln("Invalid value for --min: '{}', expected a non-negative number", value);
return false;
}
if (static_cast<unsigned>(arg->max_values) < *number) {
warnln("Invalid value for --min: {}, min must not be larger than max ({})", *number, arg->max_values);
return false;
}
arg->min_values = *number;
treat_arg_as_list = arg->max_values > 1 || arg->min_values < 1;
return true;
},
});
parser.add_option(Core::ArgsParser::Option {
.argument_mode = Core::ArgsParser::OptionArgumentMode::Required,
.help_string = "Set the maximum required number of positional arguments for the argument being described",
.long_name = "max",
.value_name = "n",
.accept_value = [&](auto value) {
auto arg = current.get_pointer<Core::ArgsParser::Arg>();
if (!arg) {
warnln("Must be describing a positional argument to use --max");
return false;
}
auto number = StringView { value, strlen(value) }.to_uint();
if (!number.has_value()) {
warnln("Invalid value for --max: '{}', expected a non-negative number", value);
return false;
}
if (static_cast<unsigned>(arg->min_values) > *number) {
warnln("Invalid value for --max: {}, max must not be smaller than min ({})", *number, arg->min_values);
return false;
}
arg->max_values = *number;
treat_arg_as_list = arg->max_values > 1 || arg->min_values < 1;
return true;
},
});
parser.add_option(Core::ArgsParser::Option {
.argument_mode = Core::ArgsParser::OptionArgumentMode::None,
.help_string = "Mark the positional argument being described as required (shorthand for --min 1)",
.long_name = "required",
.accept_value = [&](auto) {
auto arg = current.get_pointer<Core::ArgsParser::Arg>();
if (!arg) {
warnln("Must be describing a positional argument to use --required");
return false;
}
arg->min_values = 1;
if (arg->max_values < arg->min_values)
arg->max_values = 1;
treat_arg_as_list = arg->max_values > 1 || arg->min_values < 1;
return true;
},
});
parser.add_positional_argument(arguments, "Arguments to parse via the described ArgsParser configuration", "arg", Core::ArgsParser::Required::No);
if (!parser.parse(argc, const_cast<char* const*>(argv), Core::ArgsParser::FailureBehavior::Ignore))
return 2;
if (!commit())
return 2;
if (!user_parser.parse(static_cast<int>(arguments.size()), const_cast<char* const*>(arguments.data()), Core::ArgsParser::FailureBehavior::Ignore))
return 1;
return 0;
}
bool Shell::has_builtin(StringView name) const
{
if (name == ":"sv)
return true;
#define __ENUMERATE_SHELL_BUILTIN(builtin) \
if (name == #builtin) { \
return true; \
}
ENUMERATE_SHELL_BUILTINS();
#undef __ENUMERATE_SHELL_BUILTIN
return false;
}
}