kakoune/src/string.hh

#ifndef string_hh_INCLUDED
#define string_hh_INCLUDED

#include "array_view.hh"
#include "hash.hh"
#include "optional.hh"
#include "units.hh"
#include "utf8.hh"
#include "vector.hh"

#include <string.h>
#include <climits>

namespace Kakoune
{

class StringView;

template<typename Type, typename CharType>
class StringOps
{
public:
    using value_type = CharType;

    friend inline size_t hash_value(const Type& str)
    {
        return hash_data(str.data(), (int)str.length());
    }

    using iterator = CharType*;
    using const_iterator = const CharType*;
    using reverse_iterator = std::reverse_iterator<iterator>;
    using const_reverse_iterator = std::reverse_iterator<const_iterator>;

    [[gnu::always_inline]]
    iterator begin() { return type().data(); }

    [[gnu::always_inline]]
    const_iterator begin() const { return type().data(); }

    [[gnu::always_inline]]
    iterator end() { return type().data() + (int)type().length(); }

    [[gnu::always_inline]]
    const_iterator end() const { return type().data() + (int)type().length(); }

    reverse_iterator rbegin() { return reverse_iterator{end()}; }
    const_reverse_iterator rbegin() const { return const_reverse_iterator{end()}; }

    reverse_iterator rend() { return reverse_iterator{begin()}; }
    const_reverse_iterator rend() const { return const_reverse_iterator{begin()}; }

    CharType& front() { return *type().data(); }
    const CharType& front() const { return *type().data(); }
    CharType& back() { return type().data()[(int)type().length() - 1]; }
    const CharType& back() const { return type().data()[(int)type().length() - 1]; }

    [[gnu::always_inline]]
    CharType& operator[](ByteCount pos) { return type().data()[(int)pos]; }

    [[gnu::always_inline]]
    const CharType& operator[](ByteCount pos) const { return type().data()[(int)pos]; }

    Codepoint operator[](CharCount pos) const
    { return utf8::codepoint(utf8::advance(begin(), end(), pos), end()); }

    CharCount char_length() const { return utf8::distance(begin(), end()); }
    ColumnCount column_length() const { return utf8::column_distance(begin(), end()); }

    [[gnu::always_inline]]
    bool empty() const { return type().length() == 0_byte; }

    ByteCount byte_count_to(CharCount count) const
    { return utf8::advance(begin(), end(), count) - begin(); }

    ByteCount byte_count_to(ColumnCount count) const
    { return utf8::advance(begin(), end(), count) - begin(); }

    CharCount char_count_to(ByteCount count) const
    { return utf8::distance(begin(), begin() + (int)count); }

    ColumnCount column_count_to(ByteCount count) const
    { return utf8::column_distance(begin(), begin() + (int)count); }

    StringView substr(ByteCount from, ByteCount length = INT_MAX) const;
    StringView substr(CharCount from, CharCount length = INT_MAX) const;
    StringView substr(ColumnCount from, ColumnCount length = INT_MAX) const;

private:
    [[gnu::always_inline]]
    Type& type() { return *static_cast<Type*>(this); }
    [[gnu::always_inline]]
    const Type& type() const { return *static_cast<const Type*>(this); }
};

[[gnu::optimize(3)]] // this is recursive for constexpr reason
constexpr ByteCount strlen(const char* s)
{
    return *s == 0 ? 0 : strlen(s+1) + 1;
}

class String : public StringOps<String, char>
{
public:
    String() {}
    String(const char* content) : m_data(content, (size_t)strlen(content)) {}
    String(const char* content, ByteCount len) : m_data(content, (size_t)len) {}
    explicit String(Codepoint cp, CharCount count = 1)
    {
        reserve(utf8::codepoint_size(cp) * (int)count);
        while (count-- > 0)
            utf8::dump(std::back_inserter(*this), cp);
    }
    explicit String(Codepoint cp, ColumnCount count)
    {
        kak_assert(count % codepoint_width(cp) == 0);
        int cp_count = (int)(count / std::max(codepoint_width(cp), 1_col));
        reserve(utf8::codepoint_size(cp) * cp_count);
        while (cp_count-- > 0)
            utf8::dump(std::back_inserter(*this), cp);
    }
    String(const char* begin, const char* end) : m_data(begin, end-begin) {}

    [[gnu::always_inline]]
    char* data() { return m_data.data(); }

    [[gnu::always_inline]]
    const char* data() const { return m_data.data(); }

    [[gnu::always_inline]]
    ByteCount length() const { return m_data.size(); }

    [[gnu::always_inline]]
    const char* c_str() const { return m_data.data(); }

    [[gnu::always_inline]]
    void append(const char* data, ByteCount count) { m_data.append(data, (size_t)count); }

    void clear() { m_data.clear(); }

    void push_back(char c) { m_data.append(&c, 1); }
    void force_size(ByteCount size) { m_data.force_size((size_t)size); }
    void reserve(ByteCount size) { m_data.reserve((size_t)size); }
    void resize(ByteCount size, char c);

    static const String ms_empty;
    static constexpr const char* option_type_name = "str";

    // String data storage using small string optimization.
    //
    // the LSB of the last byte is used to flag if we are using the small buffer
    // or an allocated one. On big endian systems that means the allocated
    // capacity must be pair, on little endian systems that means the allocated
    // capacity cannot use its most significant byte, so we effectively limit
    // capacity to 2^24 on 32bit arch, and 2^60 on 64.
    union Data
    {
        using Alloc = Allocator<char, MemoryDomain::String>;

        struct Long
        {
            static constexpr size_t max_capacity =
                (size_t)1 << 8 * (sizeof(size_t) - 1);

            char* ptr;
            size_t size;
            size_t capacity;
        } l;

        struct Short
        {
            static constexpr size_t capacity = sizeof(Long) - 2;
            char string[capacity+1];
            unsigned char size;
        } s;

        Data() { set_empty(); }
        Data(const char* data, size_t size, size_t capacity);
        Data(const char* data, size_t size) : Data(data, size, size) {}
        Data(const Data& other) : Data{other.data(), other.size()} {}

        ~Data() { release(); }
        Data(Data&& other) noexcept;
        Data& operator=(const Data& other);
        Data& operator=(Data&& other) noexcept;

        bool is_long() const { return (s.size & 1) == 0; }
        size_t size() const { return is_long() ? l.size : (s.size >> 1); }
        size_t capacity() const { return is_long() ? l.capacity : Short::capacity; }

        const char* data() const { return is_long() ? l.ptr : s.string; }
        char* data() { return is_long() ? l.ptr : s.string; }

	template<bool copy = true>
        void reserve(size_t new_capacity);
        void set_size(size_t size);
        void force_size(size_t new_size);
        void append(const char* str, size_t len);
        void clear();

    private:
        void release();
        void set_empty() { s.size = 1; }
        void set_short(const char* data, size_t size);
    };

private:
    Data m_data;
};

class StringView : public StringOps<StringView, const char>
{
public:
    constexpr StringView() = default;
    constexpr StringView(const char* data, ByteCount length)
        : m_data{data}, m_length{length} {}
    constexpr StringView(const char* data) : m_data{data}, m_length{data ? strlen(data) : 0} {}
    constexpr StringView(const char* begin, const char* end) : m_data{begin}, m_length{(int)(end - begin)} {}
    StringView(const String& str) : m_data{str.data()}, m_length{(int)str.length()} {}
    StringView(const char& c) : m_data(&c), m_length(1) {}
    StringView(int c) = delete;
    StringView(Codepoint c) = delete;

    [[gnu::always_inline]]
    constexpr const char* data() const { return m_data; }

    [[gnu::always_inline]]
    constexpr ByteCount length() const { return m_length; }

    String str() const { return {m_data, m_length}; }

    struct ZeroTerminatedString
    {
        ZeroTerminatedString(const char* begin, const char* end)
        {
            if (*end == '\0')
                unowned = begin;
            else
                owned = String::Data(begin, end - begin);
        }
        operator const char*() const { return unowned ? unowned : owned.data(); }

    private:
        String::Data owned;
        const char* unowned = nullptr;

    };
    ZeroTerminatedString zstr() const { return {begin(), end()}; }

private:
    const char* m_data = nullptr;
    ByteCount m_length = 0;
};

template<typename Type, typename CharType>
inline StringView StringOps<Type, CharType>::substr(ByteCount from, ByteCount length) const
{
    if (length < 0)
        length = INT_MAX;
    const auto str_len = type().length();
    kak_assert(from >= 0 and from <= str_len);
    return StringView{ type().data() + (int)from, std::min(str_len - from, length) };
}

template<typename Type, typename CharType>
inline StringView StringOps<Type, CharType>::substr(CharCount from, CharCount length) const
{
    if (length < 0)
        length = INT_MAX;
    auto beg = utf8::advance(begin(), end(), from);
    return StringView{ beg, utf8::advance(beg, end(), length) };
}

template<typename Type, typename CharType>
inline StringView StringOps<Type, CharType>::substr(ColumnCount from, ColumnCount length) const
{
    if (length < 0)
        length = INT_MAX;
    auto beg = utf8::advance(begin(), end(), from);
    return StringView{ beg, utf8::advance(beg, end(), length) };
}

inline String& operator+=(String& lhs, StringView rhs)
{
    lhs.append(rhs.data(), rhs.length());
    return lhs;
}

inline String operator+(StringView lhs, StringView rhs)
{
    String res;
    res.reserve(lhs.length() + rhs.length());
    res.append(lhs.data(), lhs.length());
    res.append(rhs.data(), rhs.length());
    return res;
}

[[gnu::always_inline]]
inline bool operator==(const StringView& lhs, const StringView& rhs)
{
    return lhs.length() == rhs.length() and
       std::equal(lhs.begin(), lhs.end(), rhs.begin());
}

[[gnu::always_inline]]
inline bool operator!=(const StringView& lhs, const StringView& rhs)
{ return not (lhs == rhs); }

inline bool operator<(const StringView& lhs, const StringView& rhs)
{
    return std::lexicographical_compare(lhs.begin(), lhs.end(),
                                        rhs.begin(), rhs.end());
}

inline String operator"" _str(const char* str, size_t)
{
    return String(str);
}

Vector<String> split(StringView str, char separator, char escape);
Vector<StringView> split(StringView str, char separator);

String escape(StringView str, StringView characters, char escape);
String unescape(StringView str, StringView characters, char escape);

String indent(StringView str, StringView indent = "    ");

String replace(StringView str, StringView substr, StringView replacement);

template<typename Container>
String join(const Container& container, char joiner, bool esc_joiner = true)
{
    const char to_escape[] = { joiner, '\\' };
    String res;
    for (const auto& str : container)
    {
        if (not res.empty())
            res += joiner;
        res += esc_joiner ? escape(str, to_escape, '\\') : str;
    }
    return res;
}

inline bool prefix_match(StringView str, StringView prefix)
{
    return str.substr(0_byte, prefix.length()) == prefix;
}

bool subsequence_match(StringView str, StringView subseq);

String expand_tabs(StringView line, ColumnCount tabstop, ColumnCount col = 0);

Vector<StringView> wrap_lines(StringView text, ColumnCount max_width);

int str_to_int(StringView str); // throws on error
Optional<int> str_to_int_ifp(StringView str);

inline String option_to_string(StringView opt) { return opt.str(); }
inline void option_from_string(StringView str, String& opt) { opt = str.str(); }
inline bool option_add(String& opt, StringView val) { opt += val; return not val.empty(); }

template<size_t N>
struct InplaceString
{
    static_assert(N < 256, "InplaceString cannot handle sizes >= 256");

    constexpr operator StringView() const { return {m_data, ByteCount{m_length}}; }
    operator String() const { return {m_data, ByteCount{m_length}}; }

    unsigned char m_length;
    char m_data[N];
};

struct Hex { size_t val; };
inline Hex hex(size_t val) { return {val}; }

InplaceString<15> to_string(int val);
InplaceString<23> to_string(long int val);
InplaceString<23> to_string(size_t val);
InplaceString<23> to_string(long long int val);
InplaceString<23> to_string(Hex val);
InplaceString<23> to_string(float val);
InplaceString<7>  to_string(Codepoint c);

template<typename RealType, typename ValueType>
decltype(to_string(std::declval<ValueType>()))
to_string(const StronglyTypedNumber<RealType, ValueType>& val)
{
    return to_string((ValueType)val);
}

namespace detail
{

template<typename T> using IsString = std::is_convertible<T, StringView>;

template<typename T, class = typename std::enable_if<!IsString<T>::value>::type>
auto format_param(const T& val) -> decltype(to_string(val)) { return to_string(val); }

template<typename T, class = typename std::enable_if<IsString<T>::value>::type>
StringView format_param(const T& val) { return val; }

}

String format(StringView fmt, ArrayView<const StringView> params);

template<typename... Types>
String format(StringView fmt, Types... params)
{
    return format(fmt, ArrayView<const StringView>{detail::format_param(params)...});
}

StringView format_to(ArrayView<char> buffer, StringView fmt, ArrayView<const StringView> params);

template<typename... Types>
StringView format_to(ArrayView<char> buffer, StringView fmt, Types... params)
{
    return format_to(buffer, fmt, ArrayView<const StringView>{detail::format_param(params)...});
}

}

#endif // string_hh_INCLUDED