path: root/src/complete.cpp

/** \file complete.c Functions related to tab-completion.

  These functions are used for storing and retrieving tab-completion data, as well as for performing
  tab-completion.
*/
#include "config.h"  // IWYU pragma: keep

#include <assert.h>
#include <pthread.h>
#include <pwd.h>
#include <stdbool.h>
#include <stddef.h>
#include <wchar.h>
#include <wctype.h>
#include <algorithm>
#include <list>
#include <map>
#include <memory>
#include <set>
#include <string>
#include <utility>

#include "autoload.h"
#include "builtin.h"
#include "common.h"
#include "complete.h"
#include "env.h"
#include "exec.h"
#include "expand.h"
#include "fallback.h"  // IWYU pragma: keep
#include "function.h"
#include "iothread.h"
#include "parse_constants.h"
#include "parse_tree.h"
#include "parse_util.h"
#include "parser.h"
#include "path.h"
#include "proc.h"
#include "util.h"
#include "wildcard.h"
#include "wutil.h"  // IWYU pragma: keep

// Completion description strings, mostly for different types of files, such as sockets, block
// devices, etc.
//
// There are a few more completion description strings defined in expand.c. Maybe all completion
// description strings should be defined in the same file?

/// Description for ~USER completion.
#define COMPLETE_USER_DESC _(L"Home for %ls")

/// Description for short variables. The value is concatenated to this description.
#define COMPLETE_VAR_DESC_VAL _(L"Variable: %ls")

/// The special cased translation macro for completions. The empty string needs to be special cased,
/// since it can occur, and should not be translated. (Gettext returns the version information as
/// the response).
#ifdef USE_GETTEXT
static const wchar_t *C_(const wcstring &s) {
    return s.empty() ? L"" : wgettext(s.c_str()).c_str();
}
#else
static const wcstring &C_(const wcstring &s) { return s; }
#endif

static void complete_load(const wcstring &name, bool reload);

// Testing apparatus.
const wcstring_list_t *s_override_variable_names = NULL;

void complete_set_variable_names(const wcstring_list_t *names) {
    s_override_variable_names = names;
}

static inline wcstring_list_t complete_get_variable_names(void) {
    if (s_override_variable_names != NULL) {
        return *s_override_variable_names;
    }
    return env_get_names(0);
}

/// Struct describing a completion option entry.
///
/// If option is empty, the comp field must not be empty and contains a list of arguments to the
/// command.
///
/// The type field determines how the option is to be interpreted: either empty (args_only) or
/// short, single-long ("old") or double-long ("GNU"). An invariant is that the option is empty if
/// and only if the type is args_only.
///
/// If option is non-empty, it specifies a switch for the command. If \c comp is also not empty, it
/// contains a list of non-switch arguments that may only follow directly after the specified
/// switch.
typedef struct complete_entry_opt {
    // Text of the option (like 'foo').
    wcstring option;
    // Type of the option: args-oly, short, single_long, or double_long.
    complete_option_type_t type;
    // Arguments to the option.
    wcstring comp;
    // Description of the completion.
    wcstring desc;
    // Condition under which to use the option.
    wcstring condition;
    // Must be one of the values SHARED, NO_FILES, NO_COMMON, EXCLUSIVE, and determines how
    // completions should be performed on the argument after the switch.
    int result_mode;
    // Completion flags.
    complete_flags_t flags;

    const wcstring localized_desc() const { return C_(desc); }

    size_t expected_dash_count() const {
        switch (this->type) {
            case option_type_args_only:
                return 0;
            case option_type_short:
            case option_type_single_long:
                return 1;
            case option_type_double_long:
                return 2;
        }
        assert(0 && "Unreachable");
    }

} complete_entry_opt_t;

// Last value used in the order field of completion_entry_t.
static unsigned int kCompleteOrder = 0;

/// Struct describing a command completion.
typedef std::list<complete_entry_opt_t> option_list_t;
class completion_entry_t {
   public:
    /// List of all options.
    option_list_t options;

   public:
    /// Command string.
    const wcstring cmd;
    /// True if command is a path.
    const bool cmd_is_path;
    /// True if no other options than the ones supplied are possible.
    bool authoritative;
    /// Order for when this completion was created. This aids in outputting completions sorted by
    /// time.
    const unsigned int order;

    /// Getters for option list.
    const option_list_t &get_options() const;

    /// Adds or removes an option.
    void add_option(const complete_entry_opt_t &opt);
    bool remove_option(const wcstring &option, complete_option_type_t type);

    completion_entry_t(const wcstring &c, bool type, bool author)
        : cmd(c), cmd_is_path(type), authoritative(author), order(++kCompleteOrder) {}
};

/// Set of all completion entries.
struct completion_entry_set_comparer {
    /** Comparison for std::set */
    bool operator()(const completion_entry_t &p1, const completion_entry_t &p2) const {
        // Paths always come last for no particular reason.
        if (p1.cmd_is_path != p2.cmd_is_path) {
            return p1.cmd_is_path < p2.cmd_is_path;
        }
        return p1.cmd < p2.cmd;
    }
};
typedef std::set<completion_entry_t, completion_entry_set_comparer> completion_entry_set_t;
static completion_entry_set_t completion_set;

// Comparison function to sort completions by their order field.
static bool compare_completions_by_order(const completion_entry_t *p1,
                                         const completion_entry_t *p2) {
    return p1->order < p2->order;
}

/// The lock that guards the list of completion entries.
static pthread_mutex_t completion_lock = PTHREAD_MUTEX_INITIALIZER;

void completion_entry_t::add_option(const complete_entry_opt_t &opt) {
    ASSERT_IS_LOCKED(completion_lock);
    options.push_front(opt);
}

const option_list_t &completion_entry_t::get_options() const {
    ASSERT_IS_LOCKED(completion_lock);
    return options;
}

completion_t::~completion_t() {}

// Clear the COMPLETE_AUTO_SPACE flag, and set COMPLETE_NO_SPACE appropriately depending on the
// suffix of the string.
static complete_flags_t resolve_auto_space(const wcstring &comp, complete_flags_t flags) {
    complete_flags_t new_flags = flags;
    if (flags & COMPLETE_AUTO_SPACE) {
        new_flags &= ~COMPLETE_AUTO_SPACE;
        size_t len = comp.size();
        if (len > 0 && (wcschr(L"/=@:", comp.at(len - 1)) != 0)) new_flags |= COMPLETE_NO_SPACE;
    }
    return new_flags;
}

// completion_t functions. Note that the constructor resolves flags!
completion_t::completion_t(const wcstring &comp, const wcstring &desc, string_fuzzy_match_t mat,
                           complete_flags_t flags_val)
    : completion(comp), description(desc), match(mat), flags(resolve_auto_space(comp, flags_val)) {}

completion_t::completion_t(const completion_t &him)
    : completion(him.completion),
      description(him.description),
      match(him.match),
      flags(him.flags) {}

completion_t &completion_t::operator=(const completion_t &him) {
    if (this != &him) {
        this->completion = him.completion;
        this->description = him.description;
        this->match = him.match;
        this->flags = him.flags;
    }
    return *this;
}

bool completion_t::is_naturally_less_than(const completion_t &a, const completion_t &b) {
    return wcsfilecmp(a.completion.c_str(), b.completion.c_str()) < 0;
}

bool completion_t::is_alphabetically_equal_to(const completion_t &a, const completion_t &b) {
    return a.completion == b.completion;
}

void completion_t::prepend_token_prefix(const wcstring &prefix) {
    if (this->flags & COMPLETE_REPLACES_TOKEN) {
        this->completion.insert(0, prefix);
    }
}

static bool compare_completions_by_match_type(const completion_t &a, const completion_t &b) {
    return a.match.type < b.match.type;
}

void completions_sort_and_prioritize(std::vector<completion_t> *comps) {
    // Find the best match type.
    fuzzy_match_type_t best_type = fuzzy_match_none;
    for (size_t i = 0; i < comps->size(); i++) {
        best_type = std::min(best_type, comps->at(i).match.type);
    }
    // If the best type is an exact match, reduce it to prefix match. Otherwise a tab completion
    // will only show one match if it matches a file exactly. (see issue #959).
    if (best_type == fuzzy_match_exact) {
        best_type = fuzzy_match_prefix;
    }

    // Throw out completions whose match types are less suitable than the best.
    size_t i = comps->size();
    while (i--) {
        if (comps->at(i).match.type > best_type) {
            comps->erase(comps->begin() + i);
        }
    }

    // Remove duplicates.
    sort(comps->begin(), comps->end(), completion_t::is_naturally_less_than);
    comps->erase(
        std::unique(comps->begin(), comps->end(), completion_t::is_alphabetically_equal_to),
        comps->end());

    // Sort the remainder by match type. They're already sorted alphabetically.
    stable_sort(comps->begin(), comps->end(), compare_completions_by_match_type);
}

/// Class representing an attempt to compute completions.
class completer_t {
    const completion_request_flags_t flags;
    const wcstring initial_cmd;
    std::vector<completion_t> completions;
    const env_vars_snapshot_t &vars;  // transient, stack-allocated

    /// Table of completions conditions that have already been tested and the corresponding test
    /// results.
    typedef std::map<wcstring, bool> condition_cache_t;
    condition_cache_t condition_cache;

    enum complete_type_t { COMPLETE_DEFAULT, COMPLETE_AUTOSUGGEST };

    complete_type_t type() const {
        return flags & COMPLETION_REQUEST_AUTOSUGGESTION ? COMPLETE_AUTOSUGGEST : COMPLETE_DEFAULT;
    }

    bool wants_descriptions() const { return !!(flags & COMPLETION_REQUEST_DESCRIPTIONS); }

    bool fuzzy() const { return !!(flags & COMPLETION_REQUEST_FUZZY_MATCH); }

    fuzzy_match_type_t max_fuzzy_match_type() const {
        // If we are doing fuzzy matching, request all types; if not request only prefix matching.
        if (flags & COMPLETION_REQUEST_FUZZY_MATCH) return fuzzy_match_none;
        return fuzzy_match_prefix_case_insensitive;
    }

   public:
    completer_t(const wcstring &c, completion_request_flags_t f, const env_vars_snapshot_t &evs)
        : flags(f), initial_cmd(c), vars(evs) {}

    bool empty() const { return completions.empty(); }
    const std::vector<completion_t> &get_completions(void) { return completions; }

    bool try_complete_variable(const wcstring &str);
    bool try_complete_user(const wcstring &str);

    bool complete_param(const wcstring &cmd_orig, const wcstring &popt, const wcstring &str,
                        bool use_switches);

    void complete_param_expand(const wcstring &str, bool do_file,
                               bool handle_as_special_cd = false);

    void complete_special_cd(const wcstring &str);

    void complete_cmd(const wcstring &str, bool use_function, bool use_builtin, bool use_command,
                      bool use_implicit_cd);

    void complete_from_args(const wcstring &str, const wcstring &args, const wcstring &desc,
                            complete_flags_t flags);

    void complete_cmd_desc(const wcstring &str);

    bool complete_variable(const wcstring &str, size_t start_offset);

    bool condition_test(const wcstring &condition);

    void complete_strings(const wcstring &wc_escaped, const wchar_t *desc,
                          wcstring (*desc_func)(const wcstring &),
                          std::vector<completion_t> &possible_comp, complete_flags_t flags);

    expand_flags_t expand_flags() const {
        // Never do command substitution in autosuggestions. Sadly, we also can't yet do job
        // expansion because it's not thread safe.
        expand_flags_t result = 0;
        if (this->type() == COMPLETE_AUTOSUGGEST) result |= EXPAND_SKIP_CMDSUBST;

        // Allow fuzzy matching.
        if (this->fuzzy()) result |= EXPAND_FUZZY_MATCH;

        return result;
    }
};

/// Autoloader for completions.
class completion_autoload_t : public autoload_t {
   public:
    completion_autoload_t();
    virtual void command_removed(const wcstring &cmd);
};

static completion_autoload_t completion_autoloader;

// Constructor
completion_autoload_t::completion_autoload_t() : autoload_t(L"fish_complete_path", NULL, 0) {}

/// Callback when an autoloaded completion is removed.
void completion_autoload_t::command_removed(const wcstring &cmd) {
    complete_remove_all(cmd, false /* not a path */);
}

/// Create a new completion entry.
void append_completion(std::vector<completion_t> *completions, const wcstring &comp,
                       const wcstring &desc, complete_flags_t flags, string_fuzzy_match_t match) {
    // If we just constructed the completion and used push_back, we would get two string copies. Try
    // to avoid that by making a stubby completion in the vector first, and then copying our string
    // in. Note that completion_t's constructor will munge 'flags' so it's important that we pass
    // those to the constructor.
    //
    // Nasty hack for #1241 - since the constructor needs the completion string to resolve
    // AUTO_SPACE, and we aren't providing it with the completion, we have to do the resolution
    // ourselves. We should get this resolving out of the constructor.
    assert(completions != NULL);
    const wcstring empty;
    completions->push_back(completion_t(empty, empty, match, resolve_auto_space(comp, flags)));
    completion_t *last = &completions->back();
    last->completion = comp;
    last->description = desc;
}

/// Test if the specified script returns zero. The result is cached, so that if multiple completions
/// use the same condition, it needs only be evaluated once. condition_cache_clear must be called
/// after a completion run to make sure that there are no stale completions.
bool completer_t::condition_test(const wcstring &condition) {
    if (condition.empty()) {
        // fwprintf( stderr, L"No condition specified\n" );
        return 1;
    }

    if (this->type() == COMPLETE_AUTOSUGGEST) {
        // Autosuggestion can't support conditions.
        return 0;
    }

    ASSERT_IS_MAIN_THREAD();

    bool test_res;
    condition_cache_t::iterator cached_entry = condition_cache.find(condition);
    if (cached_entry == condition_cache.end()) {
        // Compute new value and reinsert it.
        test_res = (0 == exec_subshell(condition, false /* don't apply exit status */));
        condition_cache[condition] = test_res;
    } else {
        // Use the old value.
        test_res = cached_entry->second;
    }
    return test_res;
}

/// Locate the specified entry. Create it if it doesn't exist. Must be called while locked.
static completion_entry_t &complete_get_exact_entry(const wcstring &cmd, bool cmd_is_path) {
    ASSERT_IS_LOCKED(completion_lock);

    std::pair<completion_entry_set_t::iterator, bool> ins =
        completion_set.insert(completion_entry_t(cmd, cmd_is_path, false));

    // NOTE SET_ELEMENTS_ARE_IMMUTABLE: Exposing mutable access here is only okay as long as callers
    // do not change any field that matters to ordering - affecting order without telling std::set
    // invalidates its internal state.
    return const_cast<completion_entry_t &>(*ins.first);
}

void complete_set_authoritative(const wchar_t *cmd, bool cmd_is_path, bool authoritative) {
    CHECK(cmd, );
    scoped_lock lock(completion_lock);  //!OCLINT(has side effects)

    completion_entry_t &c = complete_get_exact_entry(cmd, cmd_is_path);
    c.authoritative = authoritative;
}

void complete_add(const wchar_t *cmd, bool cmd_is_path, const wcstring &option,
                  complete_option_type_t option_type, int result_mode, const wchar_t *condition,
                  const wchar_t *comp, const wchar_t *desc, complete_flags_t flags) {
    CHECK(cmd, );
    // option should be  empty iff the option type is arguments only.
    assert(option.empty() == (option_type == option_type_args_only));

    // Lock the lock that allows us to edit the completion entry list.
    scoped_lock lock(completion_lock);  //!OCLINT(has side effects)

    completion_entry_t &c = complete_get_exact_entry(cmd, cmd_is_path);

    // Create our new option.
    complete_entry_opt_t opt;
    opt.option = option;
    opt.type = option_type;
    opt.result_mode = result_mode;

    if (comp) opt.comp = comp;
    if (condition) opt.condition = condition;
    if (desc) opt.desc = desc;
    opt.flags = flags;

    c.add_option(opt);
}

/// Remove all completion options in the specified entry that match the specified short / long
/// option strings. Returns true if it is now empty and should be deleted, false if it's not empty.
/// Must be called while locked.
bool completion_entry_t::remove_option(const wcstring &option, complete_option_type_t type) {
    ASSERT_IS_LOCKED(completion_lock);
    option_list_t::iterator iter = this->options.begin();
    while (iter != this->options.end()) {
        if (iter->option == option && iter->type == type) {
            iter = this->options.erase(iter);
        } else {
            // Just go to the next one.
            ++iter;
        }
    }
    return this->options.empty();
}

void complete_remove(const wcstring &cmd, bool cmd_is_path, const wcstring &option,
                     complete_option_type_t type) {
    scoped_lock lock(completion_lock);  //!OCLINT(has side effects)

    completion_entry_t tmp_entry(cmd, cmd_is_path, false);
    completion_entry_set_t::iterator iter = completion_set.find(tmp_entry);
    if (iter != completion_set.end()) {
        // const_cast: See SET_ELEMENTS_ARE_IMMUTABLE.
        completion_entry_t &entry = const_cast<completion_entry_t &>(*iter);

        bool delete_it = entry.remove_option(option, type);
        if (delete_it) {
            // Delete this entry.
            completion_set.erase(iter);
        }
    }
}

void complete_remove_all(const wcstring &cmd, bool cmd_is_path) {
    scoped_lock lock(completion_lock);  //!OCLINT(has side effects)

    completion_entry_t tmp_entry(cmd, cmd_is_path, false);
    completion_set.erase(tmp_entry);
}

/// Find the full path and commandname from a command string 'str'.
static void parse_cmd_string(const wcstring &str, wcstring &path, wcstring &cmd) {
    if (!path_get_path(str, &path)) {
        /// Use the empty string as the 'path' for commands that can not be found.
        path = L"";
    }

    // Make sure the path is not included in the command.
    size_t last_slash = str.find_last_of(L'/');
    if (last_slash != wcstring::npos) {
        cmd = str.substr(last_slash + 1);
    } else {
        cmd = str;
    }
}

/// Copy any strings in possible_comp which have the specified prefix to the completer's completion
/// array. The prefix may contain wildcards. The output will consist of completion_t structs.
///
/// There are three ways to specify descriptions for each completion. Firstly, if a description has
/// already been added to the completion, it is _not_ replaced. Secondly, if the desc_func function
/// is specified, use it to determine a dynamic completion. Thirdly, if none of the above are
/// available, the desc string is used as a description.
///
/// \param wc_escaped the prefix, possibly containing wildcards. The wildcard should not have been
/// unescaped, i.e. '*' should be used for any string, not the ANY_STRING character.
/// \param desc the default description, used for completions with no embedded description. The
/// description _may_ contain a COMPLETE_SEP character, if not, one will be prefixed to it
/// \param desc_func the function that generates a description for those completions witout an
/// embedded description
/// \param possible_comp the list of possible completions to iterate over
void completer_t::complete_strings(const wcstring &wc_escaped, const wchar_t *desc,
                                   wcstring (*desc_func)(const wcstring &),
                                   std::vector<completion_t> &possible_comp,
                                   complete_flags_t flags) {
    wcstring tmp = wc_escaped;
    if (!expand_one(tmp, EXPAND_SKIP_CMDSUBST | EXPAND_SKIP_WILDCARDS | this->expand_flags(), NULL))
        return;

    const wcstring wc = parse_util_unescape_wildcards(tmp);

    for (size_t i = 0; i < possible_comp.size(); i++) {
        wcstring temp = possible_comp.at(i).completion;
        const wchar_t *next_str = temp.empty() ? NULL : temp.c_str();

        if (next_str) {
            wildcard_complete(next_str, wc.c_str(), desc, desc_func, &this->completions,
                              this->expand_flags(), flags);
        }
    }
}

/// If command to complete is short enough, substitute the description with the whatis information
/// for the executable.
void completer_t::complete_cmd_desc(const wcstring &str) {
    ASSERT_IS_MAIN_THREAD();

    const wchar_t *cmd_start;
    int skip;
    const wchar_t *const cmd = str.c_str();
    cmd_start = wcsrchr(cmd, L'/');

    if (cmd_start)
        cmd_start++;
    else
        cmd_start = cmd;

    // Using apropos with a single-character search term produces far to many results - require at
    // least two characters if we don't know the location of the whatis-database.
    if (wcslen(cmd_start) < 2) return;

    if (wildcard_has(cmd_start, 0)) {
        return;
    }

    skip = 1;

    for (size_t i = 0; i < this->completions.size(); i++) {
        const completion_t &c = this->completions.at(i);

        if (c.completion.empty() || (c.completion[c.completion.size() - 1] != L'/')) {
            skip = 0;
            break;
        }
    }

    if (skip) {
        return;
    }

    wcstring lookup_cmd(L"__fish_describe_command ");
    lookup_cmd.append(escape_string(cmd_start, 1));

    std::map<wcstring, wcstring> lookup;

    // First locate a list of possible descriptions using a single call to apropos or a direct
    // search if we know the location of the whatis database. This can take some time on slower
    // systems with a large set of manuals, but it should be ok since apropos is only called once.
    wcstring_list_t list;
    if (exec_subshell(lookup_cmd, list, false /* don't apply exit status */) != -1) {
        // Then discard anything that is not a possible completion and put the result into a
        // hashtable with the completion as key and the description as value.
        //
        // Should be reasonably fast, since no memory allocations are needed.
        for (size_t i = 0; i < list.size(); i++) {
            const wcstring &elstr = list.at(i);

            const wcstring fullkey(elstr, wcslen(cmd_start));

            size_t tab_idx = fullkey.find(L'\t');
            if (tab_idx == wcstring::npos) continue;

            const wcstring key(fullkey, 0, tab_idx);
            wcstring val(fullkey, tab_idx + 1);

            // And once again I make sure the first character is uppercased because I like it that
            // way, and I get to decide these things.
            if (!val.empty()) val[0] = towupper(val[0]);
            lookup[key] = val;
        }

        // Then do a lookup on every completion and if a match is found, change to the new
        // description.
        //
        // This needs to do a reallocation for every description added, but there shouldn't be that
        // many completions, so it should be ok.
        for (size_t i = 0; i < this->completions.size(); i++) {
            completion_t &completion = this->completions.at(i);
            const wcstring &el = completion.completion;
            if (el.empty()) continue;

            std::map<wcstring, wcstring>::iterator new_desc_iter = lookup.find(el);
            if (new_desc_iter != lookup.end()) completion.description = new_desc_iter->second;
        }
    }
}

/// Returns a description for the specified function, or an empty string if none.
static wcstring complete_function_desc(const wcstring &fn) {
    wcstring result;
    bool has_description = function_get_desc(fn, &result);
    if (!has_description) {
        function_get_definition(fn, &result);
    }
    return result;
}

/// Complete the specified command name. Search for executables in the path, executables defined
/// using an absolute path, functions, builtins and directories for implicit cd commands.
///
/// \param str_cmd the command string to find completions for
void completer_t::complete_cmd(const wcstring &str_cmd, bool use_function, bool use_builtin,
                               bool use_command, bool use_implicit_cd) {
    if (str_cmd.empty()) return;

    std::vector<completion_t> possible_comp;

    if (use_command) {
        if (expand_string(str_cmd, &this->completions,
                          EXPAND_SPECIAL_FOR_COMMAND | EXPAND_FOR_COMPLETIONS | EXECUTABLES_ONLY |
                              this->expand_flags(),
                          NULL) != EXPAND_ERROR) {
            if (this->wants_descriptions()) {
                this->complete_cmd_desc(str_cmd);
            }
        }
    }
    if (use_implicit_cd) {
        if (!expand_string(str_cmd, &this->completions,
                           EXPAND_FOR_COMPLETIONS | DIRECTORIES_ONLY | this->expand_flags(),
                           NULL)) {
            // Not valid as implicit cd.
        }
    }
    if (str_cmd.find(L'/') == wcstring::npos && str_cmd.at(0) != L'~') {
        if (use_function) {
            wcstring_list_t names = function_get_names(str_cmd.at(0) == L'_');
            for (size_t i = 0; i < names.size(); i++) {
                append_completion(&possible_comp, names.at(i));
            }

            this->complete_strings(str_cmd, 0, &complete_function_desc, possible_comp, 0);
        }

        possible_comp.clear();

        if (use_builtin) {
            builtin_get_names(&possible_comp);
            this->complete_strings(str_cmd, 0, &builtin_get_desc, possible_comp, 0);
        }
    }
}

/// Evaluate the argument list (as supplied by complete -a) and insert any return matching
/// completions. Matching is done using \c copy_strings_with_prefix, meaning the completion may
/// contain wildcards. Logically, this is not always the right thing to do, but I have yet to come
/// up with a case where this matters.
///
/// \param str The string to complete.
/// \param args The list of option arguments to be evaluated.
/// \param desc Description of the completion
/// \param flags The list into which the results will be inserted
void completer_t::complete_from_args(const wcstring &str, const wcstring &args,
                                     const wcstring &desc, complete_flags_t flags) {
    bool is_autosuggest = (this->type() == COMPLETE_AUTOSUGGEST);

    // If type is COMPLETE_AUTOSUGGEST, it means we're on a background thread, so don't call
    // proc_push_interactive.
    if (!is_autosuggest) {
        proc_push_interactive(0);
    }

    expand_flags_t eflags = 0;
    if (is_autosuggest) {
        eflags |= EXPAND_NO_DESCRIPTIONS | EXPAND_SKIP_CMDSUBST;
    }

    std::vector<completion_t> possible_comp;
    parser_t::expand_argument_list(args, eflags, &possible_comp);

    if (!is_autosuggest) {
        proc_pop_interactive();
    }

    this->complete_strings(escape_string(str, ESCAPE_ALL), desc.c_str(), 0, possible_comp, flags);
}

static size_t leading_dash_count(const wchar_t *str) {
    size_t cursor = 0;
    while (str[cursor] == L'-') {
        cursor++;
    }
    return cursor;
}

/// Match a parameter.
static bool param_match(const complete_entry_opt_t *e, const wchar_t *optstr) {
    bool result = false;
    if (e->type != option_type_args_only) {
        size_t dashes = leading_dash_count(optstr);
        result = (dashes == e->expected_dash_count() && e->option == &optstr[dashes]);
    }
    return result;
}

/// Test if a string is an option with an argument, like --color=auto or -I/usr/include.
static const wchar_t *param_match2(const complete_entry_opt_t *e, const wchar_t *optstr) {
    // We may get a complete_entry_opt_t with no options if it's just arguments.
    if (e->option.empty()) {
        return NULL;
    }

    // Verify leading dashes.
    size_t cursor = leading_dash_count(optstr);
    if (cursor != e->expected_dash_count()) {
        return NULL;
    }

    // Verify options match.
    if (!string_prefixes_string(e->option, &optstr[cursor])) {
        return NULL;
    }
    cursor += e->option.length();

    // Short options are like -DNDEBUG. Long options are like --color=auto. So check for an equal
    // sign for long options.
    if (e->type != option_type_short) {
        if (optstr[cursor] != L'=') {
            return NULL;
        }
        cursor += 1;
    }
    return &optstr[cursor];
}

/// Tests whether a short option is a viable completion. arg_str will be like '-xzv', nextopt will
/// be a character like 'f' options will be the list of all options, used to validate the argument.
static bool short_ok(const wcstring &arg, const complete_entry_opt_t *entry,
                     const option_list_t &options) {
    // Ensure it's a short option.
    if (entry->type != option_type_short || entry->option.empty()) {
        return false;
    }
    const wchar_t nextopt = entry->option.at(0);

    // Empty strings are always 'OK'.
    if (arg.empty()) {
        return true;
    }

    // The argument must start with exactly one dash.
    if (leading_dash_count(arg.c_str()) != 1) {
        return false;
    }

    // Short option must not be already present.
    if (arg.find(nextopt) != wcstring::npos) {
        return false;
    }

    // Verify that all characters in our combined short option list are present as short options in
    // the options list. If we get a short option that can't be combined (NO_COMMON), then we stop.
    bool result = true;
    for (size_t i = 1; i < arg.size(); i++) {
        wchar_t arg_char = arg.at(i);
        const complete_entry_opt_t *match = NULL;
        for (option_list_t::const_iterator iter = options.begin(); iter != options.end(); ++iter) {
            if (iter->type == option_type_short && iter->option.at(0) == arg_char) {
                match = &*iter;
                break;
            }
        }
        if (match == NULL || (match->result_mode & NO_COMMON)) {
            result = false;
            break;
        }
    }
    return result;
}

// Load command-specific completions for the specified command.
static void complete_load(const wcstring &name, bool reload) {
    // We have to load this as a function, since it may define a --wraps or signature.
    // See issue #2466.
    function_load(name);
    completion_autoloader.load(name, reload);
}

// Performed on main thread, from background thread. Return type is ignored.
static int complete_load_no_reload(wcstring *name) {
    assert(name != NULL);
    ASSERT_IS_MAIN_THREAD();
    complete_load(*name, false);
    return 0;
}

/// complete_param: Given a command, find completions for the argument str of command cmd_orig with
/// previous option popt.
///
/// Examples in format (cmd, popt, str):
///
///   echo hello world <tab> -> ("echo", "world", "")
///   echo hello world<tab> -> ("echo", "hello", "world")
///
/// Insert results into comp_out. Return true to perform file completion, false to disable it.
bool completer_t::complete_param(const wcstring &scmd_orig, const wcstring &spopt,
                                 const wcstring &sstr, bool use_switches) {
    const wchar_t *const cmd_orig = scmd_orig.c_str();
    const wchar_t *const popt = spopt.c_str();
    const wchar_t *const str = sstr.c_str();

    bool use_common = 1, use_files = 1;

    wcstring cmd, path;
    parse_cmd_string(cmd_orig, path, cmd);

    if (this->type() == COMPLETE_DEFAULT) {
        ASSERT_IS_MAIN_THREAD();
        complete_load(cmd, true);
    } else if (this->type() == COMPLETE_AUTOSUGGEST) {
        // Maybe load this command (on the main thread).
        if (!completion_autoloader.has_tried_loading(cmd)) {
            iothread_perform_on_main(complete_load_no_reload, &cmd);
        }
    }

    // Make a list of lists of all options that we care about.
    std::vector<option_list_t> all_options;
    {
        scoped_lock lock(completion_lock);
        for (completion_entry_set_t::const_iterator iter = completion_set.begin();
             iter != completion_set.end(); ++iter) {
            const completion_entry_t &i = *iter;
            const wcstring &match = i.cmd_is_path ? path : cmd;
            if (wildcard_match(match, i.cmd)) {
                // Copy all of their options into our list.
                all_options.push_back(i.get_options());  // Oof, this is a lot of copying
            }
        }
    }

    // Now release the lock and test each option that we captured above. We have to do this outside
    // the lock because callouts (like the condition) may add or remove completions. See issue 2.
    for (std::vector<option_list_t>::const_iterator iter = all_options.begin();
         iter != all_options.end(); ++iter) {
        const option_list_t &options = *iter;
        use_common = 1;
        if (use_switches) {
            if (str[0] == L'-') {
                // Check if we are entering a combined option and argument (like --color=auto or
                // -I/usr/include).
                for (option_list_t::const_iterator oiter = options.begin(); oiter != options.end();
                     ++oiter) {
                    const complete_entry_opt_t *o = &*oiter;
                    const wchar_t *arg = param_match2(o, str);
                    if (arg != NULL && this->condition_test(o->condition)) {
                        if (o->result_mode & NO_COMMON) use_common = false;
                        if (o->result_mode & NO_FILES) use_files = false;
                        complete_from_args(arg, o->comp, o->localized_desc(), o->flags);
                    }
                }
            } else if (popt[0] == L'-') {
                // Set to true if we found a matching old-style switch.
                bool old_style_match = false;

                // If we are using old style long options, check for them first.
                for (option_list_t::const_iterator oiter = options.begin(); oiter != options.end();
                     ++oiter) {
                    const complete_entry_opt_t *o = &*oiter;
                    if (o->type == option_type_single_long) {
                        if (param_match(o, popt) && this->condition_test(o->condition)) {
                            old_style_match = true;
                            if (o->result_mode & NO_COMMON) use_common = false;
                            if (o->result_mode & NO_FILES) use_files = false;
                            complete_from_args(str, o->comp, o->localized_desc(), o->flags);
                        }
                    }
                }

                // No old style option matched, or we are not using old style options. We check if
                // any short (or gnu style options do.
                if (!old_style_match) {
                    for (option_list_t::const_iterator oiter = options.begin();
                         oiter != options.end(); ++oiter) {
                        const complete_entry_opt_t *o = &*oiter;
                        // Gnu-style options with _optional_ arguments must be specified as a single
                        // token, so that it can be differed from a regular argument.
                        if (o->type == option_type_double_long && !(o->result_mode & NO_COMMON))
                            continue;

                        if (param_match(o, popt) && this->condition_test(o->condition)) {
                            if (o->result_mode & NO_COMMON) use_common = false;
                            if (o->result_mode & NO_FILES) use_files = false;
                            complete_from_args(str, o->comp, o->localized_desc(), o->flags);
                        }
                    }
                }
            }
        }

        if (use_common) {
            for (option_list_t::const_iterator oiter = options.begin(); oiter != options.end();
                 ++oiter) {
                const complete_entry_opt_t *o = &*oiter;
                // If this entry is for the base command, check if any of the arguments match.
                if (!this->condition_test(o->condition)) continue;
                if (o->option.empty()) {
                    use_files = use_files && ((o->result_mode & NO_FILES) == 0);
                    complete_from_args(str, o->comp, o->localized_desc(), o->flags);
                }

                if (wcslen(str) > 0 && use_switches) {
                    // Check if the short style option matches.
                    if (short_ok(str, o, options)) {
                        // It's a match.
                        const wcstring desc = o->localized_desc();
                        append_completion(&this->completions, o->option, desc, 0);
                    }

                    // Check if the long style option matches.
                    if (o->type == option_type_single_long || o->type == option_type_double_long) {
                        int match = 0, match_no_case = 0;

                        wcstring whole_opt(o->expected_dash_count(), L'-');
                        whole_opt.append(o->option);

                        match = string_prefixes_string(str, whole_opt);

                        if (!match) {
                            match_no_case = wcsncasecmp(str, whole_opt.c_str(), wcslen(str)) == 0;
                        }

                        if (match || match_no_case) {
                            int has_arg = 0;  // does this switch have any known arguments
                            int req_arg = 0;  // does this switch _require_ an argument

                            size_t offset = 0;
                            complete_flags_t flags = 0;

                            if (match) {
                                offset = wcslen(str);
                            } else {
                                flags = COMPLETE_REPLACES_TOKEN;
                            }

                            has_arg = !o->comp.empty();
                            req_arg = (o->result_mode & NO_COMMON);

                            if (o->type == option_type_double_long && (has_arg && !req_arg)) {
                                // Optional arguments to a switch can only be handled using the '=',
                                // so we add it as a completion. By default we avoid using '=' and
                                // instead rely on '--switch switch-arg', since it is more commonly
                                // supported by homebrew getopt-like functions.
                                wcstring completion =
                                    format_string(L"%ls=", whole_opt.c_str() + offset);
                                append_completion(&this->completions, completion, C_(o->desc),
                                                  flags);
                            }

                            append_completion(&this->completions, whole_opt.c_str() + offset,
                                              C_(o->desc), flags);
                        }
                    }
                }
            }
        }
    }

    return use_files;
}

/// Perform generic (not command-specific) expansions on the specified string.
void completer_t::complete_param_expand(const wcstring &str, bool do_file,
                                        bool handle_as_special_cd) {
    expand_flags_t flags = EXPAND_SKIP_CMDSUBST | EXPAND_FOR_COMPLETIONS | this->expand_flags();

    if (!do_file) flags |= EXPAND_SKIP_WILDCARDS;

    if (handle_as_special_cd && do_file) {
        flags |= DIRECTORIES_ONLY | EXPAND_SPECIAL_FOR_CD | EXPAND_NO_DESCRIPTIONS;
    }

    // Squelch file descriptions per issue #254.
    if (this->type() == COMPLETE_AUTOSUGGEST || do_file) flags |= EXPAND_NO_DESCRIPTIONS;

    // We have the following cases:
    //
    // --foo=bar => expand just bar
    // -foo=bar => expand just bar
    // foo=bar => expand the whole thing, and also just bar
    //
    // We also support colon separator (#2178). If there's more than one, prefer the last one.
    size_t sep_index = str.find_last_of(L"=:");
    bool complete_from_separator = (sep_index != wcstring::npos);
    bool complete_from_start = !complete_from_separator || !string_prefixes_string(L"-", str);

    if (complete_from_separator) {
        const wcstring sep_string = wcstring(str, sep_index + 1);
        std::vector<completion_t> local_completions;
        if (expand_string(sep_string, &local_completions, flags, NULL) == EXPAND_ERROR) {
            debug(3, L"Error while expanding string '%ls'", sep_string.c_str());
        }

        // Any COMPLETE_REPLACES_TOKEN will also stomp the separator. We need to "repair" them by
        // inserting our separator and prefix.
        const wcstring prefix_with_sep = wcstring(str, 0, sep_index + 1);
        for (size_t i = 0; i < local_completions.size(); i++) {
            local_completions.at(i).prepend_token_prefix(prefix_with_sep);
        }
        this->completions.insert(this->completions.end(), local_completions.begin(),
                                 local_completions.end());
    }

    if (complete_from_start) {
        // Don't do fuzzy matching for files if the string begins with a dash (issue #568). We could
        // consider relaxing this if there was a preceding double-dash argument.
        if (string_prefixes_string(L"-", str)) flags &= ~EXPAND_FUZZY_MATCH;

        if (expand_string(str, &this->completions, flags, NULL) == EXPAND_ERROR) {
            debug(3, L"Error while expanding string '%ls'", str.c_str());
        }
    }
}

/// Complete the specified string as an environment variable.
bool completer_t::complete_variable(const wcstring &str, size_t start_offset) {
    const wchar_t *const whole_var = str.c_str();
    const wchar_t *var = &whole_var[start_offset];
    size_t varlen = wcslen(var);
    bool res = false;

    const wcstring_list_t names = complete_get_variable_names();
    for (size_t i = 0; i < names.size(); i++) {
        const wcstring &env_name = names.at(i);

        string_fuzzy_match_t match =
            string_fuzzy_match_string(var, env_name, this->max_fuzzy_match_type());
        if (match.type == fuzzy_match_none) {
            continue;  // no match
        }

        wcstring comp;
        int flags = 0;

        if (!match_type_requires_full_replacement(match.type)) {
            // Take only the suffix.
            comp.append(env_name.c_str() + varlen);
        } else {
            comp.append(whole_var, start_offset);
            comp.append(env_name);
            flags = COMPLETE_REPLACES_TOKEN | COMPLETE_DONT_ESCAPE;
        }

        wcstring desc;
        if (this->wants_descriptions()) {
            // Can't use this->vars here, it could be any variable.
            env_var_t value_unescaped = env_get_string(env_name);
            if (value_unescaped.missing()) continue;

            wcstring value = expand_escape_variable(value_unescaped);
            if (this->type() != COMPLETE_AUTOSUGGEST)
                desc = format_string(COMPLETE_VAR_DESC_VAL, value.c_str());
        }

        append_completion(&this->completions, comp, desc, flags, match);

        res = true;
    }

    return res;
}

bool completer_t::try_complete_variable(const wcstring &str) {
    enum { e_unquoted, e_single_quoted, e_double_quoted } mode = e_unquoted;
    const size_t len = str.size();

    // Get the position of the dollar heading a (possibly empty) run of valid variable characters.
    // npos means none.
    size_t variable_start = wcstring::npos;

    for (size_t in_pos = 0; in_pos < len; in_pos++) {
        wchar_t c = str.at(in_pos);
        if (!wcsvarchr(c)) {
            // This character cannot be in a variable, reset the dollar.
            variable_start = -1;
        }

        switch (c) {
            case L'\\':
                in_pos++;
                break;

            case L'$':
                if (mode == e_unquoted || mode == e_double_quoted) {
                    variable_start = in_pos;
                }
                break;

            case L'\'':
                if (mode == e_single_quoted) {
                    mode = e_unquoted;
                } else if (mode == e_unquoted) {
                    mode = e_single_quoted;
                }
                break;

            case L'"':
                if (mode == e_double_quoted) {
                    mode = e_unquoted;
                } else if (mode == e_unquoted) {
                    mode = e_double_quoted;
                }
                break;
        }
    }

    // Now complete if we have a variable start. Note the variable text may be empty; in that case
    // don't generate an autosuggestion, but do allow tab completion.
    bool allow_empty = !(this->flags & COMPLETION_REQUEST_AUTOSUGGESTION);
    bool text_is_empty = (variable_start == len);
    bool result = false;
    if (variable_start != wcstring::npos && (allow_empty || !text_is_empty)) {
        result = this->complete_variable(str, variable_start + 1);
    }
    return result;
}

/// Try to complete the specified string as a username. This is used by ~USER type expansion.
///
/// \return 0 if unable to complete, 1 otherwise
bool completer_t::try_complete_user(const wcstring &str) {
    const wchar_t *cmd = str.c_str();
    const wchar_t *first_char = cmd;
    int res = 0;
    double start_time = timef();

    if (*first_char == L'~' && !wcschr(first_char, L'/')) {
        const wchar_t *user_name = first_char + 1;
        const wchar_t *name_end = wcschr(user_name, L'~');
        if (name_end == 0) {
            struct passwd *pw;
            size_t name_len = wcslen(user_name);

            setpwent();

            while ((pw = getpwent()) != 0) {
                double current_time = timef();

                if (current_time - start_time > 0.2) {
                    return 1;
                }

                if (pw->pw_name) {
                    const wcstring pw_name_str = str2wcstring(pw->pw_name);
                    const wchar_t *pw_name = pw_name_str.c_str();
                    if (wcsncmp(user_name, pw_name, name_len) == 0) {
                        wcstring desc = format_string(COMPLETE_USER_DESC, pw_name);
                        append_completion(&this->completions, &pw_name[name_len], desc,
                                          COMPLETE_NO_SPACE);

                        res = 1;
                    } else if (wcsncasecmp(user_name, pw_name, name_len) == 0) {
                        wcstring name = format_string(L"~%ls", pw_name);
                        wcstring desc = format_string(COMPLETE_USER_DESC, pw_name);

                        append_completion(&this->completions, name, desc, COMPLETE_REPLACES_TOKEN |
                                                                              COMPLETE_DONT_ESCAPE |
                                                                              COMPLETE_NO_SPACE);
                        res = 1;
                    }
                }
            }
            endpwent();
        }
    }

    return res;
}

void complete(const wcstring &cmd_with_subcmds, std::vector<completion_t> *out_comps,
              completion_request_flags_t flags, const env_vars_snapshot_t &vars) {
    // Determine the innermost subcommand.
    const wchar_t *cmdsubst_begin, *cmdsubst_end;
    parse_util_cmdsubst_extent(cmd_with_subcmds.c_str(), cmd_with_subcmds.size(), &cmdsubst_begin,
                               &cmdsubst_end);
    assert(cmdsubst_begin != NULL && cmdsubst_end != NULL && cmdsubst_end >= cmdsubst_begin);
    const wcstring cmd = wcstring(cmdsubst_begin, cmdsubst_end - cmdsubst_begin);

    // Make our completer.
    completer_t completer(cmd, flags, vars);

    wcstring current_command;
    const size_t pos = cmd.size();
    bool done = false;
    bool use_command = 1;
    bool use_function = 1;
    bool use_builtin = 1;
    bool use_implicit_cd = 1;

    // debug( 1, L"Complete '%ls'", cmd.c_str() );

    const wchar_t *cmd_cstr = cmd.c_str();
    const wchar_t *tok_begin = NULL, *prev_begin = NULL, *prev_end = NULL;
    parse_util_token_extent(cmd_cstr, cmd.size(), &tok_begin, NULL, &prev_begin, &prev_end);

    // If we are completing a variable name or a tilde expansion user name, we do that and return.
    // No need for any other completions.
    const wcstring current_token = tok_begin;

    // Unconditionally complete variables and processes. This is a little weird since we will
    // happily complete variables even in e.g. command position, despite the fact that they are
    // invalid there. */
    if (!done) {
        done = completer.try_complete_variable(current_token) ||
               completer.try_complete_user(current_token);
    }

    if (!done) {
        parse_node_tree_t tree;
        parse_tree_from_string(cmd, parse_flag_continue_after_error |
                                        parse_flag_accept_incomplete_tokens |
                                        parse_flag_include_comments,
                               &tree, NULL);

        // Find any plain statement that contains the position. We have to backtrack past spaces
        // (issue #1261). So this will be at either the last space character, or after the end of
        // the string.
        size_t adjusted_pos = pos;
        while (adjusted_pos > 0 && cmd.at(adjusted_pos - 1) == L' ') {
            adjusted_pos--;
        }

        const parse_node_t *plain_statement =
            tree.find_node_matching_source_location(symbol_plain_statement, adjusted_pos, NULL);
        if (plain_statement == NULL) {
            // Not part of a plain statement. This could be e.g. a for loop header, case expression,
            // etc. Do generic file completions (issue #1309). If we had to backtrack, it means
            // there was whitespace; don't do an autosuggestion in that case. Also don't do it if we
            // are just after a pipe, semicolon, or & (issue #1631), or in a comment.
            //
            // Overall this logic is a total mess. A better approach would be to return the
            // "possible next token" from the parse tree directly (this data is available as the
            // first of the sequence of nodes without source locations at the very end of the parse
            // tree).
            bool do_file = true;
            if (flags & COMPLETION_REQUEST_AUTOSUGGESTION) {
                if (adjusted_pos < pos) {
                    do_file = false;
                } else if (pos > 0) {
                    // If the previous character is in one of these types, we don't do file
                    // suggestions.
                    parse_token_type_t bad_types[] = {parse_token_type_pipe, parse_token_type_end,
                                                      parse_token_type_background,
                                                      parse_special_type_comment};
                    for (size_t i = 0; i < sizeof bad_types / sizeof *bad_types; i++) {
                        if (tree.find_node_matching_source_location(bad_types[i], pos - 1, NULL)) {
                            do_file = false;
                            break;
                        }
                    }
                }
            }
            completer.complete_param_expand(current_token, do_file);
        } else {
            assert(plain_statement->has_source() &&
                   plain_statement->type == symbol_plain_statement);

            // Get the command node.
            const parse_node_t *cmd_node =
                tree.get_child(*plain_statement, 0, parse_token_type_string);

            // Get the actual command string.
            if (cmd_node) current_command = cmd_node->get_source(cmd);

            // Check the decoration.
            switch (tree.decoration_for_plain_statement(*plain_statement)) {
                case parse_statement_decoration_none: {
                    use_command = true;
                    use_function = true;
                    use_builtin = true;
                    use_implicit_cd = true;
                    break;
                }
                case parse_statement_decoration_command:
                case parse_statement_decoration_exec: {
                    use_command = true;
                    use_function = false;
                    use_builtin = false;
                    use_implicit_cd = false;
                    break;
                }
                case parse_statement_decoration_builtin: {
                    use_command = false;
                    use_function = false;
                    use_builtin = true;
                    use_implicit_cd = false;
                    break;
                }
            }

            // cppcheck-suppress nullPointerRedundantCheck
            if (cmd_node && cmd_node->location_in_or_at_end_of_source_range(pos)) {
                // Complete command filename.
                completer.complete_cmd(current_token, use_function, use_builtin, use_command,
                                       use_implicit_cd);
            } else {
                // Get all the arguments.
                const parse_node_tree_t::parse_node_list_t all_arguments =
                    tree.find_nodes(*plain_statement, symbol_argument);

                // See whether we are in an argument. We may also be in a redirection, or nothing at
                // all.
                size_t matching_arg_index = -1;
                for (size_t i = 0; i < all_arguments.size(); i++) {
                    const parse_node_t *node = all_arguments.at(i);
                    if (node->location_in_or_at_end_of_source_range(adjusted_pos)) {
                        matching_arg_index = i;
                        break;
                    }
                }

                bool had_ddash = false;
                wcstring current_argument, previous_argument;
                if (matching_arg_index != (size_t)(-1)) {
                    const wcstring matching_arg =
                        all_arguments.at(matching_arg_index)->get_source(cmd);

                    // If the cursor is in whitespace, then the "current" argument is empty and the
                    // previous argument is the matching one. But if the cursor was in or at the end
                    // of the argument, then the current argument is the matching one, and the
                    // previous argument is the one before it.
                    bool cursor_in_whitespace = (adjusted_pos < pos);
                    if (cursor_in_whitespace) {
                        current_argument = L"";
                        previous_argument = matching_arg;
                    } else {
                        current_argument = matching_arg;
                        if (matching_arg_index > 0) {
                            previous_argument =
                                all_arguments.at(matching_arg_index - 1)->get_source(cmd);
                        }
                    }

                    // Check to see if we have a preceding double-dash.
                    for (size_t i = 0; i < matching_arg_index; i++) {
                        if (all_arguments.at(i)->get_source(cmd) == L"--") {
                            had_ddash = true;
                            break;
                        }
                    }
                }

                // If we are not in an argument, we may be in a redirection.
                bool in_redirection = false;
                if (matching_arg_index == (size_t)(-1)) {
                    const parse_node_t *redirection = tree.find_node_matching_source_location(
                        symbol_redirection, adjusted_pos, plain_statement);
                    in_redirection = (redirection != NULL);
                }

                bool do_file = false, handle_as_special_cd = false;
                if (in_redirection) {
                    do_file = true;
                } else {
                    // Try completing as an argument.
                    wcstring current_command_unescape, previous_argument_unescape,
                        current_argument_unescape;
                    if (unescape_string(current_command, &current_command_unescape,
                                        UNESCAPE_DEFAULT) &&
                        unescape_string(previous_argument, &previous_argument_unescape,
                                        UNESCAPE_DEFAULT) &&
                        unescape_string(current_argument, &current_argument_unescape,
                                        UNESCAPE_INCOMPLETE)) {
                        // Have to walk over the command and its entire wrap chain. If any command
                        // disables do_file, then they all do.
                        do_file = true;
                        const wcstring_list_t wrap_chain =
                            complete_get_wrap_chain(current_command_unescape);
                        for (size_t i = 0; i < wrap_chain.size(); i++) {
                            // Hackish, this. The first command in the chain is always the given
                            // command. For every command past the first, we need to create a
                            // transient commandline for builtin_commandline. But not for
                            // COMPLETION_REQUEST_AUTOSUGGESTION, which may occur on background
                            // threads.
                            builtin_commandline_scoped_transient_t *transient_cmd = NULL;
                            if (i == 0) {
                                assert(wrap_chain.at(i) == current_command_unescape);
                            } else if (!(flags & COMPLETION_REQUEST_AUTOSUGGESTION)) {
                                assert(cmd_node != NULL);
                                wcstring faux_cmdline = cmd;
                                faux_cmdline.replace(cmd_node->source_start,
                                                     cmd_node->source_length, wrap_chain.at(i));
                                transient_cmd =
                                    new builtin_commandline_scoped_transient_t(faux_cmdline);
                            }
                            if (!completer.complete_param(wrap_chain.at(i),
                                                          previous_argument_unescape,
                                                          current_argument_unescape, !had_ddash)) {
                                do_file = false;
                            }
                            delete transient_cmd;  // may be null
                        }
                    }

                    // If we have found no command specific completions at all, fall back to using
                    // file completions.
                    if (completer.empty()) do_file = true;

                    // Hack. If we're cd, handle it specially (issue #1059, others).
                    handle_as_special_cd = (current_command_unescape == L"cd");

                    // And if we're autosuggesting, and the token is empty, don't do file
                    // suggestions.
                    if ((flags & COMPLETION_REQUEST_AUTOSUGGESTION) &&
                        current_argument_unescape.empty()) {
                        do_file = false;
                    }
                }

                // This function wants the unescaped string.
                completer.complete_param_expand(current_token, do_file, handle_as_special_cd);
            }
        }
    }

    *out_comps = completer.get_completions();
}

/// Print the GNU longopt style switch \c opt, and the argument \c argument to the specified
/// stringbuffer, but only if arguemnt is non-null and longer than 0 characters.
static void append_switch(wcstring &out, const wcstring &opt, const wcstring &argument) {
    if (argument.empty()) return;

    wcstring esc = escape_string(argument, 1);
    append_format(out, L" --%ls %ls", opt.c_str(), esc.c_str());
}

wcstring complete_print() {
    wcstring out;
    scoped_lock locker(completion_lock);  //!OCLINT(side-effect)

    // Get a list of all completions in a vector, then sort it by order.
    std::vector<const completion_entry_t *> all_completions;
    for (completion_entry_set_t::const_iterator i = completion_set.begin();
         i != completion_set.end(); ++i) {
        all_completions.push_back(&*i);
    }
    sort(all_completions.begin(), all_completions.end(), compare_completions_by_order);

    for (std::vector<const completion_entry_t *>::const_iterator iter = all_completions.begin();
         iter != all_completions.end(); ++iter) {
        const completion_entry_t *e = *iter;
        const option_list_t &options = e->get_options();
        for (option_list_t::const_iterator oiter = options.begin(); oiter != options.end();
             ++oiter) {
            const complete_entry_opt_t *o = &*oiter;
            const wchar_t *modestr[] = {L"", L" --no-files", L" --require-parameter",
                                        L" --exclusive"};

            append_format(out, L"complete%ls", modestr[o->result_mode]);

            append_switch(out, e->cmd_is_path ? L"path" : L"command",
                          escape_string(e->cmd, ESCAPE_ALL));

            switch (o->type) {
                case option_type_args_only: {
                    break;
                }
                case option_type_short: {
                    assert(!o->option.empty());
                    append_format(out, L" --short-option '%lc'", o->option.at(0));
                    break;
                }
                case option_type_single_long:
                case option_type_double_long: {
                    append_switch(
                        out, o->type == option_type_single_long ? L"old-option" : L"long-option",
                        o->option);
                    break;
                }
            }

            append_switch(out, L"description", C_(o->desc));
            append_switch(out, L"arguments", o->comp);
            append_switch(out, L"condition", o->condition);
            out.append(L"\n");
        }
    }

    // Append wraps. This is a wonky interface where even values are the commands, and odd values
    // are the targets that they wrap.
    const wcstring_list_t wrap_pairs = complete_get_wrap_pairs();
    assert(wrap_pairs.size() % 2 == 0);
    for (size_t i = 0; i < wrap_pairs.size();) {
        const wcstring &cmd = wrap_pairs.at(i++);
        const wcstring &target = wrap_pairs.at(i++);
        append_format(out, L"complete --command %ls --wraps %ls\n", cmd.c_str(), target.c_str());
    }
    return out;
}

// Completion "wrapper" support. The map goes from wrapping-command to wrapped-command-list.
static pthread_mutex_t wrapper_lock = PTHREAD_MUTEX_INITIALIZER;
typedef std::map<wcstring, wcstring_list_t> wrapper_map_t;
static wrapper_map_t &wrap_map() {
    ASSERT_IS_LOCKED(wrapper_lock);
    // A pointer is a little more efficient than an object as a static because we can elide the
    // thread-safe initialization.
    static wrapper_map_t *wrapper_map = NULL;
    if (wrapper_map == NULL) {
        wrapper_map = new wrapper_map_t();
    }
    return *wrapper_map;
}

// Add a new target that is wrapped by command. Example: __fish_sgrep (command) wraps grep (target).
bool complete_add_wrapper(const wcstring &command, const wcstring &new_target) {
    if (command.empty() || new_target.empty()) {
        return false;
    }

    scoped_lock locker(wrapper_lock);
    wrapper_map_t &wraps = wrap_map();
    wcstring_list_t *targets = &wraps[command];
    // If it's already present, we do nothing.
    if (std::find(targets->begin(), targets->end(), new_target) == targets->end()) {
        targets->push_back(new_target);
    }
    return true;
}

bool complete_remove_wrapper(const wcstring &command, const wcstring &target_to_remove) {
    if (command.empty() || target_to_remove.empty()) {
        return false;
    }

    scoped_lock locker(wrapper_lock);
    wrapper_map_t &wraps = wrap_map();
    bool result = false;
    wrapper_map_t::iterator current_targets_iter = wraps.find(command);
    if (current_targets_iter != wraps.end()) {
        wcstring_list_t *targets = &current_targets_iter->second;
        wcstring_list_t::iterator where =
            std::find(targets->begin(), targets->end(), target_to_remove);
        if (where != targets->end()) {
            targets->erase(where);
            result = true;
        }
    }
    return result;
}

wcstring_list_t complete_get_wrap_chain(const wcstring &command) {
    if (command.empty()) {
        return wcstring_list_t();
    }
    scoped_lock locker(wrapper_lock);  //!OCLINT(side-effect)
    const wrapper_map_t &wraps = wrap_map();

    wcstring_list_t result;
    std::set<wcstring> visited;            // set of visited commands
    wcstring_list_t to_visit(1, command);  // stack of remaining-to-visit commands

    wcstring target;
    while (!to_visit.empty()) {
        // Grab the next command to visit, put it in target.
        target.swap(to_visit.back());
        to_visit.pop_back();

        // Try inserting into visited. If it was already present, we skip it; this is how we avoid
        // loops.
        if (!visited.insert(target).second) {
            continue;
        }

        // Insert the target in the result. Note this is the command itself, if this is the first
        // iteration of the loop.
        result.push_back(target);

        // Enqueue its children.
        wrapper_map_t::const_iterator target_children_iter = wraps.find(target);
        if (target_children_iter != wraps.end()) {
            const wcstring_list_t &children = target_children_iter->second;
            to_visit.insert(to_visit.end(), children.begin(), children.end());
        }
    }

    return result;
}

wcstring_list_t complete_get_wrap_pairs() {
    wcstring_list_t result;
    scoped_lock locker(wrapper_lock);  //!OCLINT(side-effect)
    const wrapper_map_t &wraps = wrap_map();
    for (wrapper_map_t::const_iterator outer = wraps.begin(); outer != wraps.end(); ++outer) {
        const wcstring &cmd = outer->first;
        const wcstring_list_t &targets = outer->second;
        for (size_t i = 0; i < targets.size(); i++) {
            result.push_back(cmd);
            result.push_back(targets.at(i));
        }
    }
    return result;
}