// Copyright (c) 2020 Pantor. All rights reserved. #ifndef INCLUDE_INJA_INJA_HPP_ #define INCLUDE_INJA_INJA_HPP_ #include // #include "environment.hpp" // Copyright (c) 2019 Pantor. All rights reserved. #ifndef INCLUDE_INJA_ENVIRONMENT_HPP_ #define INCLUDE_INJA_ENVIRONMENT_HPP_ #include #include #include #include #include #include // #include "config.hpp" // Copyright (c) 2019 Pantor. All rights reserved. #ifndef INCLUDE_INJA_CONFIG_HPP_ #define INCLUDE_INJA_CONFIG_HPP_ #include #include // #include "string_view.hpp" // Copyright 2017-2019 by Martin Moene // // string-view lite, a C++17-like string_view for C++98 and later. // For more information see https://github.com/martinmoene/string-view-lite // // Distributed under the Boost Software License, Version 1.0. // (See accompanying file LICENSE.txt or copy at http://www.boost.org/LICENSE_1_0.txt) #ifndef NONSTD_SV_LITE_H_INCLUDED #define NONSTD_SV_LITE_H_INCLUDED #define string_view_lite_MAJOR 1 #define string_view_lite_MINOR 4 #define string_view_lite_PATCH 0 #define string_view_lite_VERSION \ nssv_STRINGIFY(string_view_lite_MAJOR) "." nssv_STRINGIFY(string_view_lite_MINOR) "." nssv_STRINGIFY( \ string_view_lite_PATCH) #define nssv_STRINGIFY(x) nssv_STRINGIFY_(x) #define nssv_STRINGIFY_(x) #x // string-view lite configuration: #define nssv_STRING_VIEW_DEFAULT 0 #define nssv_STRING_VIEW_NONSTD 1 #define nssv_STRING_VIEW_STD 2 #if !defined(nssv_CONFIG_SELECT_STRING_VIEW) #define nssv_CONFIG_SELECT_STRING_VIEW (nssv_HAVE_STD_STRING_VIEW ? nssv_STRING_VIEW_STD : nssv_STRING_VIEW_NONSTD) #endif #if defined(nssv_CONFIG_SELECT_STD_STRING_VIEW) || defined(nssv_CONFIG_SELECT_NONSTD_STRING_VIEW) #error nssv_CONFIG_SELECT_STD_STRING_VIEW and nssv_CONFIG_SELECT_NONSTD_STRING_VIEW are deprecated and removed, please use nssv_CONFIG_SELECT_STRING_VIEW=nssv_STRING_VIEW_... #endif #ifndef nssv_CONFIG_STD_SV_OPERATOR #define nssv_CONFIG_STD_SV_OPERATOR 0 #endif #ifndef nssv_CONFIG_USR_SV_OPERATOR #define nssv_CONFIG_USR_SV_OPERATOR 1 #endif #ifdef nssv_CONFIG_CONVERSION_STD_STRING #define nssv_CONFIG_CONVERSION_STD_STRING_CLASS_METHODS nssv_CONFIG_CONVERSION_STD_STRING #define nssv_CONFIG_CONVERSION_STD_STRING_FREE_FUNCTIONS nssv_CONFIG_CONVERSION_STD_STRING #endif #ifndef nssv_CONFIG_CONVERSION_STD_STRING_CLASS_METHODS #define nssv_CONFIG_CONVERSION_STD_STRING_CLASS_METHODS 1 #endif #ifndef nssv_CONFIG_CONVERSION_STD_STRING_FREE_FUNCTIONS #define nssv_CONFIG_CONVERSION_STD_STRING_FREE_FUNCTIONS 1 #endif // Control presence of exception handling (try and auto discover): #ifndef nssv_CONFIG_NO_EXCEPTIONS #if defined(__cpp_exceptions) || defined(__EXCEPTIONS) || defined(_CPPUNWIND) #define nssv_CONFIG_NO_EXCEPTIONS 0 #else #define nssv_CONFIG_NO_EXCEPTIONS 1 #endif #endif // C++ language version detection (C++20 is speculative): // Note: VC14.0/1900 (VS2015) lacks too much from C++14. #ifndef nssv_CPLUSPLUS #if defined(_MSVC_LANG) && !defined(__clang__) #define nssv_CPLUSPLUS (_MSC_VER == 1900 ? 201103L : _MSVC_LANG) #else #define nssv_CPLUSPLUS __cplusplus #endif #endif #define nssv_CPP98_OR_GREATER (nssv_CPLUSPLUS >= 199711L) #define nssv_CPP11_OR_GREATER (nssv_CPLUSPLUS >= 201103L) #define nssv_CPP11_OR_GREATER_ (nssv_CPLUSPLUS >= 201103L) #define nssv_CPP14_OR_GREATER (nssv_CPLUSPLUS >= 201402L) #define nssv_CPP17_OR_GREATER (nssv_CPLUSPLUS >= 201703L) #define nssv_CPP20_OR_GREATER (nssv_CPLUSPLUS >= 202000L) // use C++17 std::string_view if available and requested: #if nssv_CPP17_OR_GREATER && defined(__has_include) #if __has_include( ) #define nssv_HAVE_STD_STRING_VIEW 1 #else #define nssv_HAVE_STD_STRING_VIEW 0 #endif #else #define nssv_HAVE_STD_STRING_VIEW 0 #endif #define nssv_USES_STD_STRING_VIEW \ ((nssv_CONFIG_SELECT_STRING_VIEW == nssv_STRING_VIEW_STD) || \ ((nssv_CONFIG_SELECT_STRING_VIEW == nssv_STRING_VIEW_DEFAULT) && nssv_HAVE_STD_STRING_VIEW)) #define nssv_HAVE_STARTS_WITH (nssv_CPP20_OR_GREATER || !nssv_USES_STD_STRING_VIEW) #define nssv_HAVE_ENDS_WITH nssv_HAVE_STARTS_WITH // // Use C++17 std::string_view: // #if nssv_USES_STD_STRING_VIEW #include // Extensions for std::string: #if nssv_CONFIG_CONVERSION_STD_STRING_FREE_FUNCTIONS namespace nonstd { template > std::basic_string to_string(std::basic_string_view v, Allocator const &a = Allocator()) { return std::basic_string(v.begin(), v.end(), a); } template std::basic_string_view to_string_view(std::basic_string const &s) { return std::basic_string_view(s.data(), s.size()); } // Literal operators sv and _sv: #if nssv_CONFIG_STD_SV_OPERATOR using namespace std::literals::string_view_literals; #endif #if nssv_CONFIG_USR_SV_OPERATOR inline namespace literals { inline namespace string_view_literals { constexpr std::string_view operator"" _sv(const char *str, size_t len) noexcept // (1) { return std::string_view {str, len}; } constexpr std::u16string_view operator"" _sv(const char16_t *str, size_t len) noexcept // (2) { return std::u16string_view {str, len}; } constexpr std::u32string_view operator"" _sv(const char32_t *str, size_t len) noexcept // (3) { return std::u32string_view {str, len}; } constexpr std::wstring_view operator"" _sv(const wchar_t *str, size_t len) noexcept // (4) { return std::wstring_view {str, len}; } } // namespace string_view_literals } // namespace literals #endif // nssv_CONFIG_USR_SV_OPERATOR } // namespace nonstd #endif // nssv_CONFIG_CONVERSION_STD_STRING_FREE_FUNCTIONS namespace nonstd { using std::basic_string_view; using std::string_view; using std::u16string_view; using std::u32string_view; using std::wstring_view; // literal "sv" and "_sv", see above using std::operator==; using std::operator!=; using std::operator<; using std::operator<=; using std::operator>; using std::operator>=; using std::operator<<; } // namespace nonstd #else // nssv_HAVE_STD_STRING_VIEW // // Before C++17: use string_view lite: // // Compiler versions: // // MSVC++ 6.0 _MSC_VER == 1200 (Visual Studio 6.0) // MSVC++ 7.0 _MSC_VER == 1300 (Visual Studio .NET 2002) // MSVC++ 7.1 _MSC_VER == 1310 (Visual Studio .NET 2003) // MSVC++ 8.0 _MSC_VER == 1400 (Visual Studio 2005) // MSVC++ 9.0 _MSC_VER == 1500 (Visual Studio 2008) // MSVC++ 10.0 _MSC_VER == 1600 (Visual Studio 2010) // MSVC++ 11.0 _MSC_VER == 1700 (Visual Studio 2012) // MSVC++ 12.0 _MSC_VER == 1800 (Visual Studio 2013) // MSVC++ 14.0 _MSC_VER == 1900 (Visual Studio 2015) // MSVC++ 14.1 _MSC_VER >= 1910 (Visual Studio 2017) #if defined(_MSC_VER) && !defined(__clang__) #define nssv_COMPILER_MSVC_VER (_MSC_VER) #define nssv_COMPILER_MSVC_VERSION (_MSC_VER / 10 - 10 * (5 + (_MSC_VER < 1900))) #else #define nssv_COMPILER_MSVC_VER 0 #define nssv_COMPILER_MSVC_VERSION 0 #endif #define nssv_COMPILER_VERSION(major, minor, patch) (10 * (10 * (major) + (minor)) + (patch)) #if defined(__clang__) #define nssv_COMPILER_CLANG_VERSION nssv_COMPILER_VERSION(__clang_major__, __clang_minor__, __clang_patchlevel__) #else #define nssv_COMPILER_CLANG_VERSION 0 #endif #if defined(__GNUC__) && !defined(__clang__) #define nssv_COMPILER_GNUC_VERSION nssv_COMPILER_VERSION(__GNUC__, __GNUC_MINOR__, __GNUC_PATCHLEVEL__) #else #define nssv_COMPILER_GNUC_VERSION 0 #endif // half-open range [lo..hi): #define nssv_BETWEEN(v, lo, hi) ((lo) <= (v) && (v) < (hi)) // Presence of language and library features: #ifdef _HAS_CPP0X #define nssv_HAS_CPP0X _HAS_CPP0X #else #define nssv_HAS_CPP0X 0 #endif // Unless defined otherwise below, consider VC14 as C++11 for variant-lite: #if nssv_COMPILER_MSVC_VER >= 1900 #undef nssv_CPP11_OR_GREATER #define nssv_CPP11_OR_GREATER 1 #endif #define nssv_CPP11_90 (nssv_CPP11_OR_GREATER_ || nssv_COMPILER_MSVC_VER >= 1500) #define nssv_CPP11_100 (nssv_CPP11_OR_GREATER_ || nssv_COMPILER_MSVC_VER >= 1600) #define nssv_CPP11_110 (nssv_CPP11_OR_GREATER_ || nssv_COMPILER_MSVC_VER >= 1700) #define nssv_CPP11_120 (nssv_CPP11_OR_GREATER_ || nssv_COMPILER_MSVC_VER >= 1800) #define nssv_CPP11_140 (nssv_CPP11_OR_GREATER_ || nssv_COMPILER_MSVC_VER >= 1900) #define nssv_CPP11_141 (nssv_CPP11_OR_GREATER_ || nssv_COMPILER_MSVC_VER >= 1910) #define nssv_CPP14_000 (nssv_CPP14_OR_GREATER) #define nssv_CPP17_000 (nssv_CPP17_OR_GREATER) // Presence of C++11 language features: #define nssv_HAVE_CONSTEXPR_11 nssv_CPP11_140 #define nssv_HAVE_EXPLICIT_CONVERSION nssv_CPP11_140 #define nssv_HAVE_INLINE_NAMESPACE nssv_CPP11_140 #define nssv_HAVE_NOEXCEPT nssv_CPP11_140 #define nssv_HAVE_NULLPTR nssv_CPP11_100 #define nssv_HAVE_REF_QUALIFIER nssv_CPP11_140 #define nssv_HAVE_UNICODE_LITERALS nssv_CPP11_140 #define nssv_HAVE_USER_DEFINED_LITERALS nssv_CPP11_140 #define nssv_HAVE_WCHAR16_T nssv_CPP11_100 #define nssv_HAVE_WCHAR32_T nssv_CPP11_100 #if !((nssv_CPP11_OR_GREATER && nssv_COMPILER_CLANG_VERSION) || nssv_BETWEEN(nssv_COMPILER_CLANG_VERSION, 300, 400)) #define nssv_HAVE_STD_DEFINED_LITERALS nssv_CPP11_140 #else #define nssv_HAVE_STD_DEFINED_LITERALS 0 #endif // Presence of C++14 language features: #define nssv_HAVE_CONSTEXPR_14 nssv_CPP14_000 // Presence of C++17 language features: #define nssv_HAVE_NODISCARD nssv_CPP17_000 // Presence of C++ library features: #define nssv_HAVE_STD_HASH nssv_CPP11_120 // C++ feature usage: #if nssv_HAVE_CONSTEXPR_11 #define nssv_constexpr constexpr #else #define nssv_constexpr /*constexpr*/ #endif #if nssv_HAVE_CONSTEXPR_14 #define nssv_constexpr14 constexpr #else #define nssv_constexpr14 /*constexpr*/ #endif #if nssv_HAVE_EXPLICIT_CONVERSION #define nssv_explicit explicit #else #define nssv_explicit /*explicit*/ #endif #if nssv_HAVE_INLINE_NAMESPACE #define nssv_inline_ns inline #else #define nssv_inline_ns /*inline*/ #endif #if nssv_HAVE_NOEXCEPT #define nssv_noexcept noexcept #else #define nssv_noexcept /*noexcept*/ #endif //#if nssv_HAVE_REF_QUALIFIER //# define nssv_ref_qual & //# define nssv_refref_qual && //#else //# define nssv_ref_qual /*&*/ //# define nssv_refref_qual /*&&*/ //#endif #if nssv_HAVE_NULLPTR #define nssv_nullptr nullptr #else #define nssv_nullptr NULL #endif #if nssv_HAVE_NODISCARD #define nssv_nodiscard [[nodiscard]] #else #define nssv_nodiscard /*[[nodiscard]]*/ #endif // Additional includes: #include #include #include #include #include #include // std::char_traits<> #if !nssv_CONFIG_NO_EXCEPTIONS #include #endif #if nssv_CPP11_OR_GREATER #include #endif // Clang, GNUC, MSVC warning suppression macros: #if defined(__clang__) #pragma clang diagnostic ignored "-Wreserved-user-defined-literal" #pragma clang diagnostic push #pragma clang diagnostic ignored "-Wuser-defined-literals" #elif defined(__GNUC__) #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wliteral-suffix" #endif // __clang__ #if nssv_COMPILER_MSVC_VERSION >= 140 #define nssv_SUPPRESS_MSGSL_WARNING(expr) [[gsl::suppress(expr)]] #define nssv_SUPPRESS_MSVC_WARNING(code, descr) __pragma(warning(suppress : code)) #define nssv_DISABLE_MSVC_WARNINGS(codes) __pragma(warning(push)) __pragma(warning(disable : codes)) #else #define nssv_SUPPRESS_MSGSL_WARNING(expr) #define nssv_SUPPRESS_MSVC_WARNING(code, descr) #define nssv_DISABLE_MSVC_WARNINGS(codes) #endif #if defined(__clang__) #define nssv_RESTORE_WARNINGS() _Pragma("clang diagnostic pop") #elif defined(__GNUC__) #define nssv_RESTORE_WARNINGS() _Pragma("GCC diagnostic pop") #elif nssv_COMPILER_MSVC_VERSION >= 140 #define nssv_RESTORE_WARNINGS() __pragma(warning(pop)) #else #define nssv_RESTORE_WARNINGS() #endif // Suppress the following MSVC (GSL) warnings: // - C4455, non-gsl : 'operator ""sv': literal suffix identifiers that do not // start with an underscore are reserved // - C26472, gsl::t.1 : don't use a static_cast for arithmetic conversions; // use brace initialization, gsl::narrow_cast or gsl::narow // - C26481: gsl::b.1 : don't use pointer arithmetic. Use span instead nssv_DISABLE_MSVC_WARNINGS(4455 26481 26472) // nssv_DISABLE_CLANG_WARNINGS( "-Wuser-defined-literals" ) // nssv_DISABLE_GNUC_WARNINGS( -Wliteral-suffix ) namespace nonstd { namespace sv_lite { #if nssv_CPP11_OR_GREATER namespace detail { // Expect tail call optimization to make length() non-recursive: template inline constexpr std::size_t length(CharT *s, std::size_t result = 0) { return *s == '\0' ? result : length(s + 1, result + 1); } } // namespace detail #endif // nssv_CPP11_OR_GREATER template > class basic_string_view; // // basic_string_view: // template */ > class basic_string_view { public: // Member types: typedef Traits traits_type; typedef CharT value_type; typedef CharT *pointer; typedef CharT const *const_pointer; typedef CharT &reference; typedef CharT const &const_reference; typedef const_pointer iterator; typedef const_pointer const_iterator; typedef std::reverse_iterator reverse_iterator; typedef std::reverse_iterator const_reverse_iterator; typedef std::size_t size_type; typedef std::ptrdiff_t difference_type; // 24.4.2.1 Construction and assignment: nssv_constexpr basic_string_view() nssv_noexcept : data_(nssv_nullptr), size_(0) {} #if nssv_CPP11_OR_GREATER nssv_constexpr basic_string_view(basic_string_view const &other) nssv_noexcept = default; #else nssv_constexpr basic_string_view(basic_string_view const &other) nssv_noexcept : data_(other.data_), size_(other.size_) {} #endif nssv_constexpr basic_string_view(CharT const *s, size_type count) nssv_noexcept // non-standard noexcept : data_(s), size_(count) {} nssv_constexpr basic_string_view(CharT const *s) nssv_noexcept // non-standard noexcept : data_(s) #if nssv_CPP17_OR_GREATER , size_(Traits::length(s)) #elif nssv_CPP11_OR_GREATER , size_(detail::length(s)) #else , size_(Traits::length(s)) #endif { } // Assignment: #if nssv_CPP11_OR_GREATER nssv_constexpr14 basic_string_view &operator=(basic_string_view const &other) nssv_noexcept = default; #else nssv_constexpr14 basic_string_view &operator=(basic_string_view const &other) nssv_noexcept { data_ = other.data_; size_ = other.size_; return *this; } #endif // 24.4.2.2 Iterator support: nssv_constexpr const_iterator begin() const nssv_noexcept { return data_; } nssv_constexpr const_iterator end() const nssv_noexcept { return data_ + size_; } nssv_constexpr const_iterator cbegin() const nssv_noexcept { return begin(); } nssv_constexpr const_iterator cend() const nssv_noexcept { return end(); } nssv_constexpr const_reverse_iterator rbegin() const nssv_noexcept { return const_reverse_iterator(end()); } nssv_constexpr const_reverse_iterator rend() const nssv_noexcept { return const_reverse_iterator(begin()); } nssv_constexpr const_reverse_iterator crbegin() const nssv_noexcept { return rbegin(); } nssv_constexpr const_reverse_iterator crend() const nssv_noexcept { return rend(); } // 24.4.2.3 Capacity: nssv_constexpr size_type size() const nssv_noexcept { return size_; } nssv_constexpr size_type length() const nssv_noexcept { return size_; } nssv_constexpr size_type max_size() const nssv_noexcept { return (std::numeric_limits::max)(); } // since C++20 nssv_nodiscard nssv_constexpr bool empty() const nssv_noexcept { return 0 == size_; } // 24.4.2.4 Element access: nssv_constexpr const_reference operator[](size_type pos) const { return data_at(pos); } nssv_constexpr14 const_reference at(size_type pos) const { #if nssv_CONFIG_NO_EXCEPTIONS assert(pos < size()); #else if (pos >= size()) { throw std::out_of_range("nonstd::string_view::at()"); } #endif return data_at(pos); } nssv_constexpr const_reference front() const { return data_at(0); } nssv_constexpr const_reference back() const { return data_at(size() - 1); } nssv_constexpr const_pointer data() const nssv_noexcept { return data_; } // 24.4.2.5 Modifiers: nssv_constexpr14 void remove_prefix(size_type n) { assert(n <= size()); data_ += n; size_ -= n; } nssv_constexpr14 void remove_suffix(size_type n) { assert(n <= size()); size_ -= n; } nssv_constexpr14 void swap(basic_string_view &other) nssv_noexcept { using std::swap; swap(data_, other.data_); swap(size_, other.size_); } // 24.4.2.6 String operations: size_type copy(CharT *dest, size_type n, size_type pos = 0) const { #if nssv_CONFIG_NO_EXCEPTIONS assert(pos <= size()); #else if (pos > size()) { throw std::out_of_range("nonstd::string_view::copy()"); } #endif const size_type rlen = (std::min)(n, size() - pos); (void)Traits::copy(dest, data() + pos, rlen); return rlen; } nssv_constexpr14 basic_string_view substr(size_type pos = 0, size_type n = npos) const { #if nssv_CONFIG_NO_EXCEPTIONS assert(pos <= size()); #else if (pos > size()) { throw std::out_of_range("nonstd::string_view::substr()"); } #endif return basic_string_view(data() + pos, (std::min)(n, size() - pos)); } // compare(), 6x: nssv_constexpr14 int compare(basic_string_view other) const nssv_noexcept // (1) { if (const int result = Traits::compare(data(), other.data(), (std::min)(size(), other.size()))) { return result; } return size() == other.size() ? 0 : size() < other.size() ? -1 : 1; } nssv_constexpr int compare(size_type pos1, size_type n1, basic_string_view other) const // (2) { return substr(pos1, n1).compare(other); } nssv_constexpr int compare(size_type pos1, size_type n1, basic_string_view other, size_type pos2, size_type n2) const // (3) { return substr(pos1, n1).compare(other.substr(pos2, n2)); } nssv_constexpr int compare(CharT const *s) const // (4) { return compare(basic_string_view(s)); } nssv_constexpr int compare(size_type pos1, size_type n1, CharT const *s) const // (5) { return substr(pos1, n1).compare(basic_string_view(s)); } nssv_constexpr int compare(size_type pos1, size_type n1, CharT const *s, size_type n2) const // (6) { return substr(pos1, n1).compare(basic_string_view(s, n2)); } // 24.4.2.7 Searching: // starts_with(), 3x, since C++20: nssv_constexpr bool starts_with(basic_string_view v) const nssv_noexcept // (1) { return size() >= v.size() && compare(0, v.size(), v) == 0; } nssv_constexpr bool starts_with(CharT c) const nssv_noexcept // (2) { return starts_with(basic_string_view(&c, 1)); } nssv_constexpr bool starts_with(CharT const *s) const // (3) { return starts_with(basic_string_view(s)); } // ends_with(), 3x, since C++20: nssv_constexpr bool ends_with(basic_string_view v) const nssv_noexcept // (1) { return size() >= v.size() && compare(size() - v.size(), npos, v) == 0; } nssv_constexpr bool ends_with(CharT c) const nssv_noexcept // (2) { return ends_with(basic_string_view(&c, 1)); } nssv_constexpr bool ends_with(CharT const *s) const // (3) { return ends_with(basic_string_view(s)); } // find(), 4x: nssv_constexpr14 size_type find(basic_string_view v, size_type pos = 0) const nssv_noexcept // (1) { return assert(v.size() == 0 || v.data() != nssv_nullptr), pos >= size() ? npos : to_pos(std::search(cbegin() + pos, cend(), v.cbegin(), v.cend(), Traits::eq)); } nssv_constexpr14 size_type find(CharT c, size_type pos = 0) const nssv_noexcept // (2) { return find(basic_string_view(&c, 1), pos); } nssv_constexpr14 size_type find(CharT const *s, size_type pos, size_type n) const // (3) { return find(basic_string_view(s, n), pos); } nssv_constexpr14 size_type find(CharT const *s, size_type pos = 0) const // (4) { return find(basic_string_view(s), pos); } // rfind(), 4x: nssv_constexpr14 size_type rfind(basic_string_view v, size_type pos = npos) const nssv_noexcept // (1) { if (size() < v.size()) { return npos; } if (v.empty()) { return (std::min)(size(), pos); } const_iterator last = cbegin() + (std::min)(size() - v.size(), pos) + v.size(); const_iterator result = std::find_end(cbegin(), last, v.cbegin(), v.cend(), Traits::eq); return result != last ? size_type(result - cbegin()) : npos; } nssv_constexpr14 size_type rfind(CharT c, size_type pos = npos) const nssv_noexcept // (2) { return rfind(basic_string_view(&c, 1), pos); } nssv_constexpr14 size_type rfind(CharT const *s, size_type pos, size_type n) const // (3) { return rfind(basic_string_view(s, n), pos); } nssv_constexpr14 size_type rfind(CharT const *s, size_type pos = npos) const // (4) { return rfind(basic_string_view(s), pos); } // find_first_of(), 4x: nssv_constexpr size_type find_first_of(basic_string_view v, size_type pos = 0) const nssv_noexcept // (1) { return pos >= size() ? npos : to_pos(std::find_first_of(cbegin() + pos, cend(), v.cbegin(), v.cend(), Traits::eq)); } nssv_constexpr size_type find_first_of(CharT c, size_type pos = 0) const nssv_noexcept // (2) { return find_first_of(basic_string_view(&c, 1), pos); } nssv_constexpr size_type find_first_of(CharT const *s, size_type pos, size_type n) const // (3) { return find_first_of(basic_string_view(s, n), pos); } nssv_constexpr size_type find_first_of(CharT const *s, size_type pos = 0) const // (4) { return find_first_of(basic_string_view(s), pos); } // find_last_of(), 4x: nssv_constexpr size_type find_last_of(basic_string_view v, size_type pos = npos) const nssv_noexcept // (1) { return empty() ? npos : pos >= size() ? find_last_of(v, size() - 1) : to_pos(std::find_first_of(const_reverse_iterator(cbegin() + pos + 1), crend(), v.cbegin(), v.cend(), Traits::eq)); } nssv_constexpr size_type find_last_of(CharT c, size_type pos = npos) const nssv_noexcept // (2) { return find_last_of(basic_string_view(&c, 1), pos); } nssv_constexpr size_type find_last_of(CharT const *s, size_type pos, size_type count) const // (3) { return find_last_of(basic_string_view(s, count), pos); } nssv_constexpr size_type find_last_of(CharT const *s, size_type pos = npos) const // (4) { return find_last_of(basic_string_view(s), pos); } // find_first_not_of(), 4x: nssv_constexpr size_type find_first_not_of(basic_string_view v, size_type pos = 0) const nssv_noexcept // (1) { return pos >= size() ? npos : to_pos(std::find_if(cbegin() + pos, cend(), not_in_view(v))); } nssv_constexpr size_type find_first_not_of(CharT c, size_type pos = 0) const nssv_noexcept // (2) { return find_first_not_of(basic_string_view(&c, 1), pos); } nssv_constexpr size_type find_first_not_of(CharT const *s, size_type pos, size_type count) const // (3) { return find_first_not_of(basic_string_view(s, count), pos); } nssv_constexpr size_type find_first_not_of(CharT const *s, size_type pos = 0) const // (4) { return find_first_not_of(basic_string_view(s), pos); } // find_last_not_of(), 4x: nssv_constexpr size_type find_last_not_of(basic_string_view v, size_type pos = npos) const nssv_noexcept // (1) { return empty() ? npos : pos >= size() ? find_last_not_of(v, size() - 1) : to_pos(std::find_if(const_reverse_iterator(cbegin() + pos + 1), crend(), not_in_view(v))); } nssv_constexpr size_type find_last_not_of(CharT c, size_type pos = npos) const nssv_noexcept // (2) { return find_last_not_of(basic_string_view(&c, 1), pos); } nssv_constexpr size_type find_last_not_of(CharT const *s, size_type pos, size_type count) const // (3) { return find_last_not_of(basic_string_view(s, count), pos); } nssv_constexpr size_type find_last_not_of(CharT const *s, size_type pos = npos) const // (4) { return find_last_not_of(basic_string_view(s), pos); } // Constants: #if nssv_CPP17_OR_GREATER static nssv_constexpr size_type npos = size_type(-1); #elif nssv_CPP11_OR_GREATER enum : size_type { npos = size_type(-1) }; #else enum { npos = size_type(-1) }; #endif private: struct not_in_view { const basic_string_view v; nssv_constexpr explicit not_in_view(basic_string_view v) : v(v) {} nssv_constexpr bool operator()(CharT c) const { return npos == v.find_first_of(c); } }; nssv_constexpr size_type to_pos(const_iterator it) const { return it == cend() ? npos : size_type(it - cbegin()); } nssv_constexpr size_type to_pos(const_reverse_iterator it) const { return it == crend() ? npos : size_type(crend() - it - 1); } nssv_constexpr const_reference data_at(size_type pos) const { #if nssv_BETWEEN(nssv_COMPILER_GNUC_VERSION, 1, 500) return data_[pos]; #else return assert(pos < size()), data_[pos]; #endif } private: const_pointer data_; size_type size_; public: #if nssv_CONFIG_CONVERSION_STD_STRING_CLASS_METHODS template basic_string_view(std::basic_string const &s) nssv_noexcept : data_(s.data()), size_(s.size()) {} #if nssv_HAVE_EXPLICIT_CONVERSION template explicit operator std::basic_string() const { return to_string(Allocator()); } #endif // nssv_HAVE_EXPLICIT_CONVERSION #if nssv_CPP11_OR_GREATER template > std::basic_string to_string(Allocator const &a = Allocator()) const { return std::basic_string(begin(), end(), a); } #else std::basic_string to_string() const { return std::basic_string(begin(), end()); } template std::basic_string to_string(Allocator const &a) const { return std::basic_string(begin(), end(), a); } #endif // nssv_CPP11_OR_GREATER #endif // nssv_CONFIG_CONVERSION_STD_STRING_CLASS_METHODS }; // // Non-member functions: // // 24.4.3 Non-member comparison functions: // lexicographically compare two string views (function template): template nssv_constexpr bool operator==(basic_string_view lhs, basic_string_view rhs) nssv_noexcept { return lhs.compare(rhs) == 0; } template nssv_constexpr bool operator!=(basic_string_view lhs, basic_string_view rhs) nssv_noexcept { return lhs.compare(rhs) != 0; } template nssv_constexpr bool operator<(basic_string_view lhs, basic_string_view rhs) nssv_noexcept { return lhs.compare(rhs) < 0; } template nssv_constexpr bool operator<=(basic_string_view lhs, basic_string_view rhs) nssv_noexcept { return lhs.compare(rhs) <= 0; } template nssv_constexpr bool operator>(basic_string_view lhs, basic_string_view rhs) nssv_noexcept { return lhs.compare(rhs) > 0; } template nssv_constexpr bool operator>=(basic_string_view lhs, basic_string_view rhs) nssv_noexcept { return lhs.compare(rhs) >= 0; } // Let S be basic_string_view, and sv be an instance of S. // Implementations shall provide sufficient additional overloads marked // constexpr and noexcept so that an object t with an implicit conversion // to S can be compared according to Table 67. #if !nssv_CPP11_OR_GREATER || nssv_BETWEEN(nssv_COMPILER_MSVC_VERSION, 100, 141) // accomodate for older compilers: // == template nssv_constexpr bool operator==(basic_string_view lhs, char const *rhs) nssv_noexcept { return lhs.compare(rhs) == 0; } template nssv_constexpr bool operator==(char const *lhs, basic_string_view rhs) nssv_noexcept { return rhs.compare(lhs) == 0; } template nssv_constexpr bool operator==(basic_string_view lhs, std::basic_string rhs) nssv_noexcept { return lhs.size() == rhs.size() && lhs.compare(rhs) == 0; } template nssv_constexpr bool operator==(std::basic_string rhs, basic_string_view lhs) nssv_noexcept { return lhs.size() == rhs.size() && lhs.compare(rhs) == 0; } // != template nssv_constexpr bool operator!=(basic_string_view lhs, char const *rhs) nssv_noexcept { return lhs.compare(rhs) != 0; } template nssv_constexpr bool operator!=(char const *lhs, basic_string_view rhs) nssv_noexcept { return rhs.compare(lhs) != 0; } template nssv_constexpr bool operator!=(basic_string_view lhs, std::basic_string rhs) nssv_noexcept { return lhs.size() != rhs.size() && lhs.compare(rhs) != 0; } template nssv_constexpr bool operator!=(std::basic_string rhs, basic_string_view lhs) nssv_noexcept { return lhs.size() != rhs.size() || rhs.compare(lhs) != 0; } // < template nssv_constexpr bool operator<(basic_string_view lhs, char const *rhs) nssv_noexcept { return lhs.compare(rhs) < 0; } template nssv_constexpr bool operator<(char const *lhs, basic_string_view rhs) nssv_noexcept { return rhs.compare(lhs) > 0; } template nssv_constexpr bool operator<(basic_string_view lhs, std::basic_string rhs) nssv_noexcept { return lhs.compare(rhs) < 0; } template nssv_constexpr bool operator<(std::basic_string rhs, basic_string_view lhs) nssv_noexcept { return rhs.compare(lhs) > 0; } // <= template nssv_constexpr bool operator<=(basic_string_view lhs, char const *rhs) nssv_noexcept { return lhs.compare(rhs) <= 0; } template nssv_constexpr bool operator<=(char const *lhs, basic_string_view rhs) nssv_noexcept { return rhs.compare(lhs) >= 0; } template nssv_constexpr bool operator<=(basic_string_view lhs, std::basic_string rhs) nssv_noexcept { return lhs.compare(rhs) <= 0; } template nssv_constexpr bool operator<=(std::basic_string rhs, basic_string_view lhs) nssv_noexcept { return rhs.compare(lhs) >= 0; } // > template nssv_constexpr bool operator>(basic_string_view lhs, char const *rhs) nssv_noexcept { return lhs.compare(rhs) > 0; } template nssv_constexpr bool operator>(char const *lhs, basic_string_view rhs) nssv_noexcept { return rhs.compare(lhs) < 0; } template nssv_constexpr bool operator>(basic_string_view lhs, std::basic_string rhs) nssv_noexcept { return lhs.compare(rhs) > 0; } template nssv_constexpr bool operator>(std::basic_string rhs, basic_string_view lhs) nssv_noexcept { return rhs.compare(lhs) < 0; } // >= template nssv_constexpr bool operator>=(basic_string_view lhs, char const *rhs) nssv_noexcept { return lhs.compare(rhs) >= 0; } template nssv_constexpr bool operator>=(char const *lhs, basic_string_view rhs) nssv_noexcept { return rhs.compare(lhs) <= 0; } template nssv_constexpr bool operator>=(basic_string_view lhs, std::basic_string rhs) nssv_noexcept { return lhs.compare(rhs) >= 0; } template nssv_constexpr bool operator>=(std::basic_string rhs, basic_string_view lhs) nssv_noexcept { return rhs.compare(lhs) <= 0; } #else // newer compilers: #define nssv_BASIC_STRING_VIEW_I(T, U) typename std::decay>::type #if nssv_BETWEEN(nssv_COMPILER_MSVC_VERSION, 140, 150) #define nssv_MSVC_ORDER(x) , int = x #else #define nssv_MSVC_ORDER(x) /*, int=x*/ #endif // == template nssv_constexpr bool operator==(basic_string_view lhs, nssv_BASIC_STRING_VIEW_I(CharT, Traits) rhs) nssv_noexcept { return lhs.compare(rhs) == 0; } template nssv_constexpr bool operator==(nssv_BASIC_STRING_VIEW_I(CharT, Traits) lhs, basic_string_view rhs) nssv_noexcept { return lhs.size() == rhs.size() && lhs.compare(rhs) == 0; } // != template nssv_constexpr bool operator!=(basic_string_view lhs, nssv_BASIC_STRING_VIEW_I(CharT, Traits) rhs) nssv_noexcept { return lhs.size() != rhs.size() || lhs.compare(rhs) != 0; } template nssv_constexpr bool operator!=(nssv_BASIC_STRING_VIEW_I(CharT, Traits) lhs, basic_string_view rhs) nssv_noexcept { return lhs.compare(rhs) != 0; } // < template nssv_constexpr bool operator<(basic_string_view lhs, nssv_BASIC_STRING_VIEW_I(CharT, Traits) rhs) nssv_noexcept { return lhs.compare(rhs) < 0; } template nssv_constexpr bool operator<(nssv_BASIC_STRING_VIEW_I(CharT, Traits) lhs, basic_string_view rhs) nssv_noexcept { return lhs.compare(rhs) < 0; } // <= template nssv_constexpr bool operator<=(basic_string_view lhs, nssv_BASIC_STRING_VIEW_I(CharT, Traits) rhs) nssv_noexcept { return lhs.compare(rhs) <= 0; } template nssv_constexpr bool operator<=(nssv_BASIC_STRING_VIEW_I(CharT, Traits) lhs, basic_string_view rhs) nssv_noexcept { return lhs.compare(rhs) <= 0; } // > template nssv_constexpr bool operator>(basic_string_view lhs, nssv_BASIC_STRING_VIEW_I(CharT, Traits) rhs) nssv_noexcept { return lhs.compare(rhs) > 0; } template nssv_constexpr bool operator>(nssv_BASIC_STRING_VIEW_I(CharT, Traits) lhs, basic_string_view rhs) nssv_noexcept { return lhs.compare(rhs) > 0; } // >= template nssv_constexpr bool operator>=(basic_string_view lhs, nssv_BASIC_STRING_VIEW_I(CharT, Traits) rhs) nssv_noexcept { return lhs.compare(rhs) >= 0; } template nssv_constexpr bool operator>=(nssv_BASIC_STRING_VIEW_I(CharT, Traits) lhs, basic_string_view rhs) nssv_noexcept { return lhs.compare(rhs) >= 0; } #undef nssv_MSVC_ORDER #undef nssv_BASIC_STRING_VIEW_I #endif // compiler-dependent approach to comparisons // 24.4.4 Inserters and extractors: namespace detail { template void write_padding(Stream &os, std::streamsize n) { for (std::streamsize i = 0; i < n; ++i) os.rdbuf()->sputc(os.fill()); } template Stream &write_to_stream(Stream &os, View const &sv) { typename Stream::sentry sentry(os); if (!os) return os; const std::streamsize length = static_cast(sv.length()); // Whether, and how, to pad: const bool pad = (length < os.width()); const bool left_pad = pad && (os.flags() & std::ios_base::adjustfield) == std::ios_base::right; if (left_pad) write_padding(os, os.width() - length); // Write span characters: os.rdbuf()->sputn(sv.begin(), length); if (pad && !left_pad) write_padding(os, os.width() - length); // Reset output stream width: os.width(0); return os; } } // namespace detail template std::basic_ostream &operator<<(std::basic_ostream &os, basic_string_view sv) { return detail::write_to_stream(os, sv); } // Several typedefs for common character types are provided: typedef basic_string_view string_view; typedef basic_string_view wstring_view; #if nssv_HAVE_WCHAR16_T typedef basic_string_view u16string_view; typedef basic_string_view u32string_view; #endif } // namespace sv_lite } // namespace nonstd::sv_lite // // 24.4.6 Suffix for basic_string_view literals: // #if nssv_HAVE_USER_DEFINED_LITERALS namespace nonstd { nssv_inline_ns namespace literals { nssv_inline_ns namespace string_view_literals { #if nssv_CONFIG_STD_SV_OPERATOR && nssv_HAVE_STD_DEFINED_LITERALS nssv_constexpr nonstd::sv_lite::string_view operator"" sv(const char *str, size_t len) nssv_noexcept // (1) { return nonstd::sv_lite::string_view {str, len}; } nssv_constexpr nonstd::sv_lite::u16string_view operator"" sv(const char16_t *str, size_t len) nssv_noexcept // (2) { return nonstd::sv_lite::u16string_view {str, len}; } nssv_constexpr nonstd::sv_lite::u32string_view operator"" sv(const char32_t *str, size_t len) nssv_noexcept // (3) { return nonstd::sv_lite::u32string_view {str, len}; } nssv_constexpr nonstd::sv_lite::wstring_view operator"" sv(const wchar_t *str, size_t len) nssv_noexcept // (4) { return nonstd::sv_lite::wstring_view {str, len}; } #endif // nssv_CONFIG_STD_SV_OPERATOR && nssv_HAVE_STD_DEFINED_LITERALS #if nssv_CONFIG_USR_SV_OPERATOR nssv_constexpr nonstd::sv_lite::string_view operator"" _sv(const char *str, size_t len) nssv_noexcept // (1) { return nonstd::sv_lite::string_view {str, len}; } nssv_constexpr nonstd::sv_lite::u16string_view operator"" _sv(const char16_t *str, size_t len) nssv_noexcept // (2) { return nonstd::sv_lite::u16string_view {str, len}; } nssv_constexpr nonstd::sv_lite::u32string_view operator"" _sv(const char32_t *str, size_t len) nssv_noexcept // (3) { return nonstd::sv_lite::u32string_view {str, len}; } nssv_constexpr nonstd::sv_lite::wstring_view operator"" _sv(const wchar_t *str, size_t len) nssv_noexcept // (4) { return nonstd::sv_lite::wstring_view {str, len}; } #endif // nssv_CONFIG_USR_SV_OPERATOR } } } // namespace nonstd #endif // // Extensions for std::string: // #if nssv_CONFIG_CONVERSION_STD_STRING_FREE_FUNCTIONS namespace nonstd { namespace sv_lite { // Exclude MSVC 14 (19.00): it yields ambiguous to_string(): #if nssv_CPP11_OR_GREATER && nssv_COMPILER_MSVC_VERSION != 140 template > std::basic_string to_string(basic_string_view v, Allocator const &a = Allocator()) { return std::basic_string(v.begin(), v.end(), a); } #else template std::basic_string to_string(basic_string_view v) { return std::basic_string(v.begin(), v.end()); } template std::basic_string to_string(basic_string_view v, Allocator const &a) { return std::basic_string(v.begin(), v.end(), a); } #endif // nssv_CPP11_OR_GREATER template basic_string_view to_string_view(std::basic_string const &s) { return basic_string_view(s.data(), s.size()); } } // namespace sv_lite } // namespace nonstd #endif // nssv_CONFIG_CONVERSION_STD_STRING_FREE_FUNCTIONS // // make types and algorithms available in namespace nonstd: // namespace nonstd { using sv_lite::basic_string_view; using sv_lite::string_view; using sv_lite::wstring_view; #if nssv_HAVE_WCHAR16_T using sv_lite::u16string_view; #endif #if nssv_HAVE_WCHAR32_T using sv_lite::u32string_view; #endif // literal "sv" using sv_lite::operator==; using sv_lite::operator!=; using sv_lite::operator<; using sv_lite::operator<=; using sv_lite::operator>; using sv_lite::operator>=; using sv_lite::operator<<; #if nssv_CONFIG_CONVERSION_STD_STRING_FREE_FUNCTIONS using sv_lite::to_string; using sv_lite::to_string_view; #endif } // namespace nonstd // 24.4.5 Hash support (C++11): // Note: The hash value of a string view object is equal to the hash value of // the corresponding string object. #if nssv_HAVE_STD_HASH #include namespace std { template <> struct hash { public: std::size_t operator()(nonstd::string_view v) const nssv_noexcept { return std::hash()(std::string(v.data(), v.size())); } }; template <> struct hash { public: std::size_t operator()(nonstd::wstring_view v) const nssv_noexcept { return std::hash()(std::wstring(v.data(), v.size())); } }; template <> struct hash { public: std::size_t operator()(nonstd::u16string_view v) const nssv_noexcept { return std::hash()(std::u16string(v.data(), v.size())); } }; template <> struct hash { public: std::size_t operator()(nonstd::u32string_view v) const nssv_noexcept { return std::hash()(std::u32string(v.data(), v.size())); } }; } // namespace std #endif // nssv_HAVE_STD_HASH nssv_RESTORE_WARNINGS() #endif // nssv_HAVE_STD_STRING_VIEW #endif // NONSTD_SV_LITE_H_INCLUDED namespace inja { /*! * \brief Class for lexer configuration. */ struct LexerConfig { std::string statement_open {"{%"}; std::string statement_open_no_lstrip {"{%+"}; std::string statement_open_force_lstrip {"{%-"}; std::string statement_close {"%}"}; std::string statement_close_force_rstrip {"-%}"}; std::string line_statement {"##"}; std::string expression_open {"{{"}; std::string expression_open_force_lstrip {"{{-"}; std::string expression_close {"}}"}; std::string expression_close_force_rstrip {"-}}"}; std::string comment_open {"{#"}; std::string comment_close {"#}"}; std::string open_chars {"#{"}; bool trim_blocks {false}; bool lstrip_blocks {false}; void update_open_chars() { open_chars = ""; if (open_chars.find(line_statement[0]) == std::string::npos) { open_chars += line_statement[0]; } if (open_chars.find(statement_open[0]) == std::string::npos) { open_chars += statement_open[0]; } if (open_chars.find(statement_open_no_lstrip[0]) == std::string::npos) { open_chars += statement_open_no_lstrip[0]; } if (open_chars.find(statement_open_force_lstrip[0]) == std::string::npos) { open_chars += statement_open_force_lstrip[0]; } if (open_chars.find(expression_open[0]) == std::string::npos) { open_chars += expression_open[0]; } if (open_chars.find(expression_open_force_lstrip[0]) == std::string::npos) { open_chars += expression_open_force_lstrip[0]; } if (open_chars.find(comment_open[0]) == std::string::npos) { open_chars += comment_open[0]; } } }; /*! * \brief Class for parser configuration. */ struct ParserConfig { bool search_included_templates_in_files {true}; }; /*! * \brief Class for render configuration. */ struct RenderConfig { bool throw_at_missing_includes {true}; }; } // namespace inja #endif // INCLUDE_INJA_CONFIG_HPP_ // #include "function_storage.hpp" // Copyright (c) 2020 Pantor. All rights reserved. #ifndef INCLUDE_INJA_FUNCTION_STORAGE_HPP_ #define INCLUDE_INJA_FUNCTION_STORAGE_HPP_ #include // #include "string_view.hpp" namespace inja { using json = nlohmann::json; using Arguments = std::vector; using CallbackFunction = std::function; using VoidCallbackFunction = std::function; /*! * \brief Class for builtin functions and user-defined callbacks. */ class FunctionStorage { public: enum class Operation { Not, And, Or, In, Equal, NotEqual, Greater, GreaterEqual, Less, LessEqual, Add, Subtract, Multiplication, Division, Power, Modulo, AtId, At, Default, DivisibleBy, Even, Exists, ExistsInObject, First, Float, Int, IsArray, IsBoolean, IsFloat, IsInteger, IsNumber, IsObject, IsString, Last, Length, Lower, Max, Min, Odd, Range, Round, Sort, Upper, Callback, ParenLeft, ParenRight, None, }; struct FunctionData { explicit FunctionData(const Operation &op, const CallbackFunction &cb = CallbackFunction{}) : operation(op), callback(cb) {} const Operation operation; const CallbackFunction callback; }; private: const int VARIADIC {-1}; std::map, FunctionData> function_storage = { {std::make_pair("at", 2), FunctionData { Operation::At }}, {std::make_pair("default", 2), FunctionData { Operation::Default }}, {std::make_pair("divisibleBy", 2), FunctionData { Operation::DivisibleBy }}, {std::make_pair("even", 1), FunctionData { Operation::Even }}, {std::make_pair("exists", 1), FunctionData { Operation::Exists }}, {std::make_pair("existsIn", 2), FunctionData { Operation::ExistsInObject }}, {std::make_pair("first", 1), FunctionData { Operation::First }}, {std::make_pair("float", 1), FunctionData { Operation::Float }}, {std::make_pair("int", 1), FunctionData { Operation::Int }}, {std::make_pair("isArray", 1), FunctionData { Operation::IsArray }}, {std::make_pair("isBoolean", 1), FunctionData { Operation::IsBoolean }}, {std::make_pair("isFloat", 1), FunctionData { Operation::IsFloat }}, {std::make_pair("isInteger", 1), FunctionData { Operation::IsInteger }}, {std::make_pair("isNumber", 1), FunctionData { Operation::IsNumber }}, {std::make_pair("isObject", 1), FunctionData { Operation::IsObject }}, {std::make_pair("isString", 1), FunctionData { Operation::IsString }}, {std::make_pair("last", 1), FunctionData { Operation::Last }}, {std::make_pair("length", 1), FunctionData { Operation::Length }}, {std::make_pair("lower", 1), FunctionData { Operation::Lower }}, {std::make_pair("max", 1), FunctionData { Operation::Max }}, {std::make_pair("min", 1), FunctionData { Operation::Min }}, {std::make_pair("odd", 1), FunctionData { Operation::Odd }}, {std::make_pair("range", 1), FunctionData { Operation::Range }}, {std::make_pair("round", 2), FunctionData { Operation::Round }}, {std::make_pair("sort", 1), FunctionData { Operation::Sort }}, {std::make_pair("upper", 1), FunctionData { Operation::Upper }}, }; public: void add_builtin(nonstd::string_view name, int num_args, Operation op) { function_storage.emplace(std::make_pair(static_cast(name), num_args), FunctionData { op }); } void add_callback(nonstd::string_view name, int num_args, const CallbackFunction &callback) { function_storage.emplace(std::make_pair(static_cast(name), num_args), FunctionData { Operation::Callback, callback }); } FunctionData find_function(nonstd::string_view name, int num_args) const { auto it = function_storage.find(std::make_pair(static_cast(name), num_args)); if (it != function_storage.end()) { return it->second; // Find variadic function } else if (num_args > 0) { it = function_storage.find(std::make_pair(static_cast(name), VARIADIC)); if (it != function_storage.end()) { return it->second; } } return FunctionData { Operation::None }; } }; } // namespace inja #endif // INCLUDE_INJA_FUNCTION_STORAGE_HPP_ // #include "parser.hpp" // Copyright (c) 2020 Pantor. All rights reserved. #ifndef INCLUDE_INJA_PARSER_HPP_ #define INCLUDE_INJA_PARSER_HPP_ #include #include #include #include #include #include // #include "config.hpp" // #include "exceptions.hpp" // Copyright (c) 2020 Pantor. All rights reserved. #ifndef INCLUDE_INJA_EXCEPTIONS_HPP_ #define INCLUDE_INJA_EXCEPTIONS_HPP_ #include #include namespace inja { struct SourceLocation { size_t line; size_t column; }; struct InjaError : public std::runtime_error { const std::string type; const std::string message; const SourceLocation location; explicit InjaError(const std::string &type, const std::string &message) : std::runtime_error("[inja.exception." + type + "] " + message), type(type), message(message), location({0, 0}) {} explicit InjaError(const std::string &type, const std::string &message, SourceLocation location) : std::runtime_error("[inja.exception." + type + "] (at " + std::to_string(location.line) + ":" + std::to_string(location.column) + ") " + message), type(type), message(message), location(location) {} }; struct ParserError : public InjaError { explicit ParserError(const std::string &message, SourceLocation location) : InjaError("parser_error", message, location) {} }; struct RenderError : public InjaError { explicit RenderError(const std::string &message, SourceLocation location) : InjaError("render_error", message, location) {} }; struct FileError : public InjaError { explicit FileError(const std::string &message) : InjaError("file_error", message) {} explicit FileError(const std::string &message, SourceLocation location) : InjaError("file_error", message, location) {} }; struct JsonError : public InjaError { explicit JsonError(const std::string &message, SourceLocation location) : InjaError("json_error", message, location) {} }; } // namespace inja #endif // INCLUDE_INJA_EXCEPTIONS_HPP_ // #include "function_storage.hpp" // #include "lexer.hpp" // Copyright (c) 2020 Pantor. All rights reserved. #ifndef INCLUDE_INJA_LEXER_HPP_ #define INCLUDE_INJA_LEXER_HPP_ #include #include // #include "config.hpp" // #include "token.hpp" // Copyright (c) 2020 Pantor. All rights reserved. #ifndef INCLUDE_INJA_TOKEN_HPP_ #define INCLUDE_INJA_TOKEN_HPP_ #include // #include "string_view.hpp" namespace inja { /*! * \brief Helper-class for the inja Lexer. */ struct Token { enum class Kind { Text, ExpressionOpen, // {{ ExpressionClose, // }} LineStatementOpen, // ## LineStatementClose, // \n StatementOpen, // {% StatementClose, // %} CommentOpen, // {# CommentClose, // #} Id, // this, this.foo Number, // 1, 2, -1, 5.2, -5.3 String, // "this" Plus, // + Minus, // - Times, // * Slash, // / Percent, // % Power, // ^ Comma, // , Dot, // . Colon, // : LeftParen, // ( RightParen, // ) LeftBracket, // [ RightBracket, // ] LeftBrace, // { RightBrace, // } Equal, // == NotEqual, // != GreaterThan, // > GreaterEqual, // >= LessThan, // < LessEqual, // <= Unknown, Eof, }; Kind kind {Kind::Unknown}; nonstd::string_view text; explicit constexpr Token() = default; explicit constexpr Token(Kind kind, nonstd::string_view text) : kind(kind), text(text) {} std::string describe() const { switch (kind) { case Kind::Text: return ""; case Kind::LineStatementClose: return ""; case Kind::Eof: return ""; default: return static_cast(text); } } }; } // namespace inja #endif // INCLUDE_INJA_TOKEN_HPP_ // #include "utils.hpp" // Copyright (c) 2020 Pantor. All rights reserved. #ifndef INCLUDE_INJA_UTILS_HPP_ #define INCLUDE_INJA_UTILS_HPP_ #include #include #include #include // #include "exceptions.hpp" // #include "string_view.hpp" namespace inja { inline void open_file_or_throw(const std::string &path, std::ifstream &file) { file.exceptions(std::ifstream::failbit | std::ifstream::badbit); try { file.open(path); } catch (const std::ios_base::failure & /*e*/) { throw FileError("failed accessing file at '" + path + "'"); } } namespace string_view { inline nonstd::string_view slice(nonstd::string_view view, size_t start, size_t end) { start = std::min(start, view.size()); end = std::min(std::max(start, end), view.size()); return view.substr(start, end - start); } inline std::pair split(nonstd::string_view view, char Separator) { size_t idx = view.find(Separator); if (idx == nonstd::string_view::npos) { return std::make_pair(view, nonstd::string_view()); } return std::make_pair(slice(view, 0, idx), slice(view, idx + 1, nonstd::string_view::npos)); } inline bool starts_with(nonstd::string_view view, nonstd::string_view prefix) { return (view.size() >= prefix.size() && view.compare(0, prefix.size(), prefix) == 0); } } // namespace string_view inline SourceLocation get_source_location(nonstd::string_view content, size_t pos) { // Get line and offset position (starts at 1:1) auto sliced = string_view::slice(content, 0, pos); std::size_t last_newline = sliced.rfind("\n"); if (last_newline == nonstd::string_view::npos) { return {1, sliced.length() + 1}; } // Count newlines size_t count_lines = 0; size_t search_start = 0; while (search_start <= sliced.size()) { search_start = sliced.find("\n", search_start) + 1; if (search_start == 0) { break; } count_lines += 1; } return {count_lines + 1, sliced.length() - last_newline}; } } // namespace inja #endif // INCLUDE_INJA_UTILS_HPP_ namespace inja { /*! * \brief Class for lexing an inja Template. */ class Lexer { enum class State { Text, ExpressionStart, ExpressionStartForceLstrip, ExpressionBody, LineStart, LineBody, StatementStart, StatementStartNoLstrip, StatementStartForceLstrip, StatementBody, CommentStart, CommentBody, }; enum class MinusState { Operator, Number, }; const LexerConfig &config; State state; MinusState minus_state; nonstd::string_view m_in; size_t tok_start; size_t pos; Token scan_body(nonstd::string_view close, Token::Kind closeKind, nonstd::string_view close_trim = nonstd::string_view(), bool trim = false) { again: // skip whitespace (except for \n as it might be a close) if (tok_start >= m_in.size()) { return make_token(Token::Kind::Eof); } char ch = m_in[tok_start]; if (ch == ' ' || ch == '\t' || ch == '\r') { tok_start += 1; goto again; } // check for close if (!close_trim.empty() && inja::string_view::starts_with(m_in.substr(tok_start), close_trim)) { state = State::Text; pos = tok_start + close_trim.size(); Token tok = make_token(closeKind); skip_whitespaces_and_newlines(); return tok; } if (inja::string_view::starts_with(m_in.substr(tok_start), close)) { state = State::Text; pos = tok_start + close.size(); Token tok = make_token(closeKind); if (trim) { skip_whitespaces_and_first_newline(); } return tok; } // skip \n if (ch == '\n') { tok_start += 1; goto again; } pos = tok_start + 1; if (std::isalpha(ch)) { minus_state = MinusState::Operator; return scan_id(); } MinusState current_minus_state = minus_state; if (minus_state == MinusState::Operator) { minus_state = MinusState::Number; } switch (ch) { case '+': return make_token(Token::Kind::Plus); case '-': if (current_minus_state == MinusState::Operator) { return make_token(Token::Kind::Minus); } return scan_number(); case '*': return make_token(Token::Kind::Times); case '/': return make_token(Token::Kind::Slash); case '^': return make_token(Token::Kind::Power); case '%': return make_token(Token::Kind::Percent); case '.': return make_token(Token::Kind::Dot); case ',': return make_token(Token::Kind::Comma); case ':': return make_token(Token::Kind::Colon); case '(': return make_token(Token::Kind::LeftParen); case ')': minus_state = MinusState::Operator; return make_token(Token::Kind::RightParen); case '[': return make_token(Token::Kind::LeftBracket); case ']': minus_state = MinusState::Operator; return make_token(Token::Kind::RightBracket); case '{': return make_token(Token::Kind::LeftBrace); case '}': minus_state = MinusState::Operator; return make_token(Token::Kind::RightBrace); case '>': if (pos < m_in.size() && m_in[pos] == '=') { pos += 1; return make_token(Token::Kind::GreaterEqual); } return make_token(Token::Kind::GreaterThan); case '<': if (pos < m_in.size() && m_in[pos] == '=') { pos += 1; return make_token(Token::Kind::LessEqual); } return make_token(Token::Kind::LessThan); case '=': if (pos < m_in.size() && m_in[pos] == '=') { pos += 1; return make_token(Token::Kind::Equal); } return make_token(Token::Kind::Unknown); case '!': if (pos < m_in.size() && m_in[pos] == '=') { pos += 1; return make_token(Token::Kind::NotEqual); } return make_token(Token::Kind::Unknown); case '\"': return scan_string(); case '0': case '1': case '2': case '3': case '4': case '5': case '6': case '7': case '8': case '9': minus_state = MinusState::Operator; return scan_number(); case '_': minus_state = MinusState::Operator; return scan_id(); default: return make_token(Token::Kind::Unknown); } } Token scan_id() { for (;;) { if (pos >= m_in.size()) { break; } char ch = m_in[pos]; if (!std::isalnum(ch) && ch != '.' && ch != '/' && ch != '_' && ch != '-') { break; } pos += 1; } return make_token(Token::Kind::Id); } Token scan_number() { for (;;) { if (pos >= m_in.size()) { break; } char ch = m_in[pos]; // be very permissive in lexer (we'll catch errors when conversion happens) if (!std::isdigit(ch) && ch != '.' && ch != 'e' && ch != 'E' && ch != '+' && ch != '-') { break; } pos += 1; } return make_token(Token::Kind::Number); } Token scan_string() { bool escape {false}; for (;;) { if (pos >= m_in.size()) { break; } char ch = m_in[pos++]; if (ch == '\\') { escape = true; } else if (!escape && ch == m_in[tok_start]) { break; } else { escape = false; } } return make_token(Token::Kind::String); } Token make_token(Token::Kind kind) const { return Token(kind, string_view::slice(m_in, tok_start, pos)); } void skip_whitespaces_and_newlines() { if (pos < m_in.size()) { while (pos < m_in.size() && (m_in[pos] == ' ' || m_in[pos] == '\t' || m_in[pos] == '\n' || m_in[pos] == '\r')) { pos += 1; } } } void skip_whitespaces_and_first_newline() { if (pos < m_in.size()) { while (pos < m_in.size() && (m_in[pos] == ' ' || m_in[pos] == '\t')) { pos += 1; } } if (pos < m_in.size()) { char ch = m_in[pos]; if (ch == '\n') { pos += 1; } else if (ch == '\r') { pos += 1; if (pos < m_in.size() && m_in[pos] == '\n') { pos += 1; } } } } static nonstd::string_view clear_final_line_if_whitespace(nonstd::string_view text) { nonstd::string_view result = text; while (!result.empty()) { char ch = result.back(); if (ch == ' ' || ch == '\t') { result.remove_suffix(1); } else if (ch == '\n' || ch == '\r') { break; } else { return text; } } return result; } public: explicit Lexer(const LexerConfig &config) : config(config), state(State::Text), minus_state(MinusState::Number) {} SourceLocation current_position() const { return get_source_location(m_in, tok_start); } void start(nonstd::string_view input) { m_in = input; tok_start = 0; pos = 0; state = State::Text; minus_state = MinusState::Number; // Consume byte order mark (BOM) for UTF-8 if (inja::string_view::starts_with(m_in, "\xEF\xBB\xBF")) { m_in = m_in.substr(3); } } Token scan() { tok_start = pos; again: if (tok_start >= m_in.size()) { return make_token(Token::Kind::Eof); } switch (state) { default: case State::Text: { // fast-scan to first open character size_t open_start = m_in.substr(pos).find_first_of(config.open_chars); if (open_start == nonstd::string_view::npos) { // didn't find open, return remaining text as text token pos = m_in.size(); return make_token(Token::Kind::Text); } pos += open_start; // try to match one of the opening sequences, and get the close nonstd::string_view open_str = m_in.substr(pos); bool must_lstrip = false; if (inja::string_view::starts_with(open_str, config.expression_open)) { if (inja::string_view::starts_with(open_str, config.expression_open_force_lstrip)) { state = State::ExpressionStartForceLstrip; must_lstrip = true; } else { state = State::ExpressionStart; } } else if (inja::string_view::starts_with(open_str, config.statement_open)) { if (inja::string_view::starts_with(open_str, config.statement_open_no_lstrip)) { state = State::StatementStartNoLstrip; } else if (inja::string_view::starts_with(open_str, config.statement_open_force_lstrip )) { state = State::StatementStartForceLstrip; must_lstrip = true; } else { state = State::StatementStart; must_lstrip = config.lstrip_blocks; } } else if (inja::string_view::starts_with(open_str, config.comment_open)) { state = State::CommentStart; must_lstrip = config.lstrip_blocks; } else if ((pos == 0 || m_in[pos - 1] == '\n') && inja::string_view::starts_with(open_str, config.line_statement)) { state = State::LineStart; } else { pos += 1; // wasn't actually an opening sequence goto again; } nonstd::string_view text = string_view::slice(m_in, tok_start, pos); if (must_lstrip) { text = clear_final_line_if_whitespace(text); } if (text.empty()) { goto again; // don't generate empty token } return Token(Token::Kind::Text, text); } case State::ExpressionStart: { state = State::ExpressionBody; pos += config.expression_open.size(); return make_token(Token::Kind::ExpressionOpen); } case State::ExpressionStartForceLstrip: { state = State::ExpressionBody; pos += config.expression_open_force_lstrip.size(); return make_token(Token::Kind::ExpressionOpen); } case State::LineStart: { state = State::LineBody; pos += config.line_statement.size(); return make_token(Token::Kind::LineStatementOpen); } case State::StatementStart: { state = State::StatementBody; pos += config.statement_open.size(); return make_token(Token::Kind::StatementOpen); } case State::StatementStartNoLstrip: { state = State::StatementBody; pos += config.statement_open_no_lstrip.size(); return make_token(Token::Kind::StatementOpen); } case State::StatementStartForceLstrip: { state = State::StatementBody; pos += config.statement_open_force_lstrip.size(); return make_token(Token::Kind::StatementOpen); } case State::CommentStart: { state = State::CommentBody; pos += config.comment_open.size(); return make_token(Token::Kind::CommentOpen); } case State::ExpressionBody: return scan_body(config.expression_close, Token::Kind::ExpressionClose, config.expression_close_force_rstrip); case State::LineBody: return scan_body("\n", Token::Kind::LineStatementClose); case State::StatementBody: return scan_body(config.statement_close, Token::Kind::StatementClose, config.statement_close_force_rstrip, config.trim_blocks); case State::CommentBody: { // fast-scan to comment close size_t end = m_in.substr(pos).find(config.comment_close); if (end == nonstd::string_view::npos) { pos = m_in.size(); return make_token(Token::Kind::Eof); } // return the entire comment in the close token state = State::Text; pos += end + config.comment_close.size(); Token tok = make_token(Token::Kind::CommentClose); if (config.trim_blocks) { skip_whitespaces_and_first_newline(); } return tok; } } } const LexerConfig &get_config() const { return config; } }; } // namespace inja #endif // INCLUDE_INJA_LEXER_HPP_ // #include "node.hpp" // Copyright (c) 2020 Pantor. All rights reserved. #ifndef INCLUDE_INJA_NODE_HPP_ #define INCLUDE_INJA_NODE_HPP_ #include #include #include // #include "function_storage.hpp" // #include "string_view.hpp" namespace inja { class NodeVisitor; class BlockNode; class TextNode; class ExpressionNode; class LiteralNode; class JsonNode; class FunctionNode; class ExpressionListNode; class StatementNode; class ForStatementNode; class ForArrayStatementNode; class ForObjectStatementNode; class IfStatementNode; class IncludeStatementNode; class SetStatementNode; class NodeVisitor { public: virtual void visit(const BlockNode& node) = 0; virtual void visit(const TextNode& node) = 0; virtual void visit(const ExpressionNode& node) = 0; virtual void visit(const LiteralNode& node) = 0; virtual void visit(const JsonNode& node) = 0; virtual void visit(const FunctionNode& node) = 0; virtual void visit(const ExpressionListNode& node) = 0; virtual void visit(const StatementNode& node) = 0; virtual void visit(const ForStatementNode& node) = 0; virtual void visit(const ForArrayStatementNode& node) = 0; virtual void visit(const ForObjectStatementNode& node) = 0; virtual void visit(const IfStatementNode& node) = 0; virtual void visit(const IncludeStatementNode& node) = 0; virtual void visit(const SetStatementNode& node) = 0; }; /*! * \brief Base node class for the abstract syntax tree (AST). */ class AstNode { public: virtual void accept(NodeVisitor& v) const = 0; size_t pos; AstNode(size_t pos) : pos(pos) { } virtual ~AstNode() { }; }; class BlockNode : public AstNode { public: std::vector> nodes; explicit BlockNode() : AstNode(0) {} void accept(NodeVisitor& v) const { v.visit(*this); } }; class TextNode : public AstNode { public: const size_t length; explicit TextNode(size_t pos, size_t length): AstNode(pos), length(length) { } void accept(NodeVisitor& v) const { v.visit(*this); } }; class ExpressionNode : public AstNode { public: explicit ExpressionNode(size_t pos) : AstNode(pos) {} void accept(NodeVisitor& v) const { v.visit(*this); } }; class LiteralNode : public ExpressionNode { public: const nlohmann::json value; explicit LiteralNode(const nlohmann::json& value, size_t pos) : ExpressionNode(pos), value(value) { } void accept(NodeVisitor& v) const { v.visit(*this); } }; class JsonNode : public ExpressionNode { public: const std::string name; const json::json_pointer ptr; static std::string convert_dot_to_json_ptr(nonstd::string_view ptr_name) { std::string result; do { nonstd::string_view part; std::tie(part, ptr_name) = string_view::split(ptr_name, '.'); result.push_back('/'); result.append(part.begin(), part.end()); } while (!ptr_name.empty()); return result; } explicit JsonNode(nonstd::string_view ptr_name, size_t pos) : ExpressionNode(pos), name(ptr_name), ptr(json::json_pointer(convert_dot_to_json_ptr(ptr_name))) { } void accept(NodeVisitor& v) const { v.visit(*this); } }; class FunctionNode : public ExpressionNode { using Op = FunctionStorage::Operation; public: enum class Associativity { Left, Right, }; unsigned int precedence; Associativity associativity; Op operation; std::string name; int number_args; // Should also be negative -> -1 for unknown number CallbackFunction callback; explicit FunctionNode(nonstd::string_view name, size_t pos) : ExpressionNode(pos), precedence(8), associativity(Associativity::Left), operation(Op::Callback), name(name), number_args(1) { } explicit FunctionNode(Op operation, size_t pos) : ExpressionNode(pos), operation(operation), number_args(1) { switch (operation) { case Op::Not: { precedence = 4; associativity = Associativity::Left; } break; case Op::And: { precedence = 1; associativity = Associativity::Left; } break; case Op::Or: { precedence = 1; associativity = Associativity::Left; } break; case Op::In: { precedence = 2; associativity = Associativity::Left; } break; case Op::Equal: { precedence = 2; associativity = Associativity::Left; } break; case Op::NotEqual: { precedence = 2; associativity = Associativity::Left; } break; case Op::Greater: { precedence = 2; associativity = Associativity::Left; } break; case Op::GreaterEqual: { precedence = 2; associativity = Associativity::Left; } break; case Op::Less: { precedence = 2; associativity = Associativity::Left; } break; case Op::LessEqual: { precedence = 2; associativity = Associativity::Left; } break; case Op::Add: { precedence = 3; associativity = Associativity::Left; } break; case Op::Subtract: { precedence = 3; associativity = Associativity::Left; } break; case Op::Multiplication: { precedence = 4; associativity = Associativity::Left; } break; case Op::Division: { precedence = 4; associativity = Associativity::Left; } break; case Op::Power: { precedence = 5; associativity = Associativity::Right; } break; case Op::Modulo: { precedence = 4; associativity = Associativity::Left; } break; case Op::AtId: { precedence = 8; associativity = Associativity::Left; } break; default: { precedence = 1; associativity = Associativity::Left; } } } void accept(NodeVisitor& v) const { v.visit(*this); } }; class ExpressionListNode : public AstNode { public: std::vector> rpn_output; explicit ExpressionListNode() : AstNode(0) { } explicit ExpressionListNode(size_t pos) : AstNode(pos) { } void accept(NodeVisitor& v) const { v.visit(*this); } }; class StatementNode : public AstNode { public: StatementNode(size_t pos) : AstNode(pos) { } virtual void accept(NodeVisitor& v) const = 0; }; class ForStatementNode : public StatementNode { public: ExpressionListNode condition; BlockNode body; BlockNode *const parent; ForStatementNode(BlockNode *const parent, size_t pos) : StatementNode(pos), parent(parent) { } virtual void accept(NodeVisitor& v) const = 0; }; class ForArrayStatementNode : public ForStatementNode { public: const std::string value; explicit ForArrayStatementNode(const std::string& value, BlockNode *const parent, size_t pos) : ForStatementNode(parent, pos), value(value) { } void accept(NodeVisitor& v) const { v.visit(*this); } }; class ForObjectStatementNode : public ForStatementNode { public: const std::string key; const std::string value; explicit ForObjectStatementNode(const std::string& key, const std::string& value, BlockNode *const parent, size_t pos) : ForStatementNode(parent, pos), key(key), value(value) { } void accept(NodeVisitor& v) const { v.visit(*this); } }; class IfStatementNode : public StatementNode { public: ExpressionListNode condition; BlockNode true_statement; BlockNode false_statement; BlockNode *const parent; const bool is_nested; bool has_false_statement {false}; explicit IfStatementNode(BlockNode *const parent, size_t pos) : StatementNode(pos), parent(parent), is_nested(false) { } explicit IfStatementNode(bool is_nested, BlockNode *const parent, size_t pos) : StatementNode(pos), parent(parent), is_nested(is_nested) { } void accept(NodeVisitor& v) const { v.visit(*this); } }; class IncludeStatementNode : public StatementNode { public: const std::string file; explicit IncludeStatementNode(const std::string& file, size_t pos) : StatementNode(pos), file(file) { } void accept(NodeVisitor& v) const { v.visit(*this); }; }; class SetStatementNode : public StatementNode { public: const std::string key; ExpressionListNode expression; explicit SetStatementNode(const std::string& key, size_t pos) : StatementNode(pos), key(key) { } void accept(NodeVisitor& v) const { v.visit(*this); }; }; } // namespace inja #endif // INCLUDE_INJA_NODE_HPP_ // #include "template.hpp" // Copyright (c) 2019 Pantor. All rights reserved. #ifndef INCLUDE_INJA_TEMPLATE_HPP_ #define INCLUDE_INJA_TEMPLATE_HPP_ #include #include #include #include // #include "node.hpp" // #include "statistics.hpp" // Copyright (c) 2019 Pantor. All rights reserved. #ifndef INCLUDE_INJA_STATISTICS_HPP_ #define INCLUDE_INJA_STATISTICS_HPP_ // #include "node.hpp" namespace inja { /*! * \brief A class for counting statistics on a Template. */ class StatisticsVisitor : public NodeVisitor { void visit(const BlockNode& node) { for (auto& n : node.nodes) { n->accept(*this); } } void visit(const TextNode&) { } void visit(const ExpressionNode&) { } void visit(const LiteralNode&) { } void visit(const JsonNode&) { variable_counter += 1; } void visit(const FunctionNode&) { } void visit(const ExpressionListNode& node) { for (auto& n : node.rpn_output) { n->accept(*this); } } void visit(const StatementNode&) { } void visit(const ForStatementNode&) { } void visit(const ForArrayStatementNode& node) { node.condition.accept(*this); node.body.accept(*this); } void visit(const ForObjectStatementNode& node) { node.condition.accept(*this); node.body.accept(*this); } void visit(const IfStatementNode& node) { node.condition.accept(*this); node.true_statement.accept(*this); node.false_statement.accept(*this); } void visit(const IncludeStatementNode&) { } void visit(const SetStatementNode&) { } public: unsigned int variable_counter; explicit StatisticsVisitor() : variable_counter(0) { } }; } // namespace inja #endif // INCLUDE_INJA_STATISTICS_HPP_ namespace inja { /*! * \brief The main inja Template. */ struct Template { BlockNode root; std::string content; explicit Template() { } explicit Template(const std::string& content): content(content) { } /// Return number of variables (total number, not distinct ones) in the template int count_variables() { auto statistic_visitor = StatisticsVisitor(); root.accept(statistic_visitor); return statistic_visitor.variable_counter; } }; using TemplateStorage = std::map; } // namespace inja #endif // INCLUDE_INJA_TEMPLATE_HPP_ // #include "token.hpp" // #include "utils.hpp" #include namespace inja { /*! * \brief Class for parsing an inja Template. */ class Parser { const ParserConfig &config; Lexer lexer; TemplateStorage &template_storage; const FunctionStorage &function_storage; Token tok, peek_tok; bool have_peek_tok {false}; size_t current_paren_level {0}; size_t current_bracket_level {0}; size_t current_brace_level {0}; nonstd::string_view json_literal_start; BlockNode *current_block {nullptr}; ExpressionListNode *current_expression_list {nullptr}; std::stack> function_stack; std::stack> operator_stack; std::stack if_statement_stack; std::stack for_statement_stack; void throw_parser_error(const std::string &message) { throw ParserError(message, lexer.current_position()); } void get_next_token() { if (have_peek_tok) { tok = peek_tok; have_peek_tok = false; } else { tok = lexer.scan(); } } void get_peek_token() { if (!have_peek_tok) { peek_tok = lexer.scan(); have_peek_tok = true; } } void add_json_literal(const char* content_ptr) { nonstd::string_view json_text(json_literal_start.data(), tok.text.data() - json_literal_start.data() + tok.text.size()); current_expression_list->rpn_output.emplace_back(std::make_shared(json::parse(json_text), json_text.data() - content_ptr)); } bool parse_expression(Template &tmpl, Token::Kind closing) { while (tok.kind != closing && tok.kind != Token::Kind::Eof) { // Literals switch (tok.kind) { case Token::Kind::String: { if (current_brace_level == 0 && current_bracket_level == 0) { json_literal_start = tok.text; add_json_literal(tmpl.content.c_str()); } } break; case Token::Kind::Number: { if (current_brace_level == 0 && current_bracket_level == 0) { json_literal_start = tok.text; add_json_literal(tmpl.content.c_str()); } } break; case Token::Kind::LeftBracket: { if (current_brace_level == 0 && current_bracket_level == 0) { json_literal_start = tok.text; } current_bracket_level += 1; } break; case Token::Kind::LeftBrace: { if (current_brace_level == 0 && current_bracket_level == 0) { json_literal_start = tok.text; } current_brace_level += 1; } break; case Token::Kind::RightBracket: { if (current_bracket_level == 0) { throw_parser_error("unexpected ']'"); } current_bracket_level -= 1; if (current_brace_level == 0 && current_bracket_level == 0) { add_json_literal(tmpl.content.c_str()); } } break; case Token::Kind::RightBrace: { if (current_brace_level == 0) { throw_parser_error("unexpected '}'"); } current_brace_level -= 1; if (current_brace_level == 0 && current_bracket_level == 0) { add_json_literal(tmpl.content.c_str()); } } break; case Token::Kind::Id: { get_peek_token(); // Json Literal if (tok.text == static_cast("true") || tok.text == static_cast("false") || tok.text == static_cast("null")) { if (current_brace_level == 0 && current_bracket_level == 0) { json_literal_start = tok.text; add_json_literal(tmpl.content.c_str()); } // Operator } else if (tok.text == "and" || tok.text == "or" || tok.text == "in" || tok.text == "not") { goto parse_operator; // Functions } else if (peek_tok.kind == Token::Kind::LeftParen) { operator_stack.emplace(std::make_shared(static_cast(tok.text), tok.text.data() - tmpl.content.c_str())); function_stack.emplace(operator_stack.top().get(), current_paren_level); // Variables } else { current_expression_list->rpn_output.emplace_back(std::make_shared(static_cast(tok.text), tok.text.data() - tmpl.content.c_str())); } // Operators } break; case Token::Kind::Equal: case Token::Kind::NotEqual: case Token::Kind::GreaterThan: case Token::Kind::GreaterEqual: case Token::Kind::LessThan: case Token::Kind::LessEqual: case Token::Kind::Plus: case Token::Kind::Minus: case Token::Kind::Times: case Token::Kind::Slash: case Token::Kind::Power: case Token::Kind::Percent: case Token::Kind::Dot: { parse_operator: FunctionStorage::Operation operation; switch (tok.kind) { case Token::Kind::Id: { if (tok.text == "and") { operation = FunctionStorage::Operation::And; } else if (tok.text == "or") { operation = FunctionStorage::Operation::Or; } else if (tok.text == "in") { operation = FunctionStorage::Operation::In; } else if (tok.text == "not") { operation = FunctionStorage::Operation::Not; } else { throw_parser_error("unknown operator in parser."); } } break; case Token::Kind::Equal: { operation = FunctionStorage::Operation::Equal; } break; case Token::Kind::NotEqual: { operation = FunctionStorage::Operation::NotEqual; } break; case Token::Kind::GreaterThan: { operation = FunctionStorage::Operation::Greater; } break; case Token::Kind::GreaterEqual: { operation = FunctionStorage::Operation::GreaterEqual; } break; case Token::Kind::LessThan: { operation = FunctionStorage::Operation::Less; } break; case Token::Kind::LessEqual: { operation = FunctionStorage::Operation::LessEqual; } break; case Token::Kind::Plus: { operation = FunctionStorage::Operation::Add; } break; case Token::Kind::Minus: { operation = FunctionStorage::Operation::Subtract; } break; case Token::Kind::Times: { operation = FunctionStorage::Operation::Multiplication; } break; case Token::Kind::Slash: { operation = FunctionStorage::Operation::Division; } break; case Token::Kind::Power: { operation = FunctionStorage::Operation::Power; } break; case Token::Kind::Percent: { operation = FunctionStorage::Operation::Modulo; } break; case Token::Kind::Dot: { operation = FunctionStorage::Operation::AtId; } break; default: { throw_parser_error("unknown operator in parser."); } } auto function_node = std::make_shared(operation, tok.text.data() - tmpl.content.c_str()); while (!operator_stack.empty() && ((operator_stack.top()->precedence > function_node->precedence) || (operator_stack.top()->precedence == function_node->precedence && function_node->associativity == FunctionNode::Associativity::Left)) && (operator_stack.top()->operation != FunctionStorage::Operation::ParenLeft)) { current_expression_list->rpn_output.emplace_back(operator_stack.top()); operator_stack.pop(); } operator_stack.emplace(function_node); } break; case Token::Kind::Comma: { if (current_brace_level == 0 && current_bracket_level == 0) { if (function_stack.empty()) { throw_parser_error("unexpected ','"); } function_stack.top().first->number_args += 1; } } break; case Token::Kind::Colon: { if (current_brace_level == 0 && current_bracket_level == 0) { throw_parser_error("unexpected ':'"); } } break; case Token::Kind::LeftParen: { current_paren_level += 1; operator_stack.emplace(std::make_shared(FunctionStorage::Operation::ParenLeft, tok.text.data() - tmpl.content.c_str())); get_peek_token(); if (peek_tok.kind == Token::Kind::RightParen) { if (!function_stack.empty() && function_stack.top().second == current_paren_level - 1) { function_stack.top().first->number_args = 0; } } } break; case Token::Kind::RightParen: { current_paren_level -= 1; while (!operator_stack.empty() && operator_stack.top()->operation != FunctionStorage::Operation::ParenLeft) { current_expression_list->rpn_output.emplace_back(operator_stack.top()); operator_stack.pop(); } if (!operator_stack.empty() && operator_stack.top()->operation == FunctionStorage::Operation::ParenLeft) { operator_stack.pop(); } if (!function_stack.empty() && function_stack.top().second == current_paren_level) { auto func = function_stack.top().first; auto function_data = function_storage.find_function(func->name, func->number_args); if (function_data.operation == FunctionStorage::Operation::None) { throw_parser_error("unknown function " + func->name); } func->operation = function_data.operation; if (function_data.operation == FunctionStorage::Operation::Callback) { func->callback = function_data.callback; } if (operator_stack.empty()) { throw_parser_error("internal error at function " + func->name); } current_expression_list->rpn_output.emplace_back(operator_stack.top()); operator_stack.pop(); function_stack.pop(); } } default: break; } get_next_token(); } while (!operator_stack.empty()) { current_expression_list->rpn_output.emplace_back(operator_stack.top()); operator_stack.pop(); } return true; } bool parse_statement(Template &tmpl, Token::Kind closing, nonstd::string_view path) { if (tok.kind != Token::Kind::Id) { return false; } if (tok.text == static_cast("if")) { get_next_token(); auto if_statement_node = std::make_shared(current_block, tok.text.data() - tmpl.content.c_str()); current_block->nodes.emplace_back(if_statement_node); if_statement_stack.emplace(if_statement_node.get()); current_block = &if_statement_node->true_statement; current_expression_list = &if_statement_node->condition; if (!parse_expression(tmpl, closing)) { return false; } } else if (tok.text == static_cast("else")) { if (if_statement_stack.empty()) { throw_parser_error("else without matching if"); } auto &if_statement_data = if_statement_stack.top(); get_next_token(); if_statement_data->has_false_statement = true; current_block = &if_statement_data->false_statement; // Chained else if if (tok.kind == Token::Kind::Id && tok.text == static_cast("if")) { get_next_token(); auto if_statement_node = std::make_shared(true, current_block, tok.text.data() - tmpl.content.c_str()); current_block->nodes.emplace_back(if_statement_node); if_statement_stack.emplace(if_statement_node.get()); current_block = &if_statement_node->true_statement; current_expression_list = &if_statement_node->condition; if (!parse_expression(tmpl, closing)) { return false; } } } else if (tok.text == static_cast("endif")) { if (if_statement_stack.empty()) { throw_parser_error("endif without matching if"); } // Nested if statements while (if_statement_stack.top()->is_nested) { if_statement_stack.pop(); } auto &if_statement_data = if_statement_stack.top(); get_next_token(); current_block = if_statement_data->parent; if_statement_stack.pop(); } else if (tok.text == static_cast("for")) { get_next_token(); // options: for a in arr; for a, b in obj if (tok.kind != Token::Kind::Id) { throw_parser_error("expected id, got '" + tok.describe() + "'"); } Token value_token = tok; get_next_token(); // Object type std::shared_ptr for_statement_node; if (tok.kind == Token::Kind::Comma) { get_next_token(); if (tok.kind != Token::Kind::Id) { throw_parser_error("expected id, got '" + tok.describe() + "'"); } Token key_token = std::move(value_token); value_token = tok; get_next_token(); for_statement_node = std::make_shared(static_cast(key_token.text), static_cast(value_token.text), current_block, tok.text.data() - tmpl.content.c_str()); // Array type } else { for_statement_node = std::make_shared(static_cast(value_token.text), current_block, tok.text.data() - tmpl.content.c_str()); } current_block->nodes.emplace_back(for_statement_node); for_statement_stack.emplace(for_statement_node.get()); current_block = &for_statement_node->body; current_expression_list = &for_statement_node->condition; if (tok.kind != Token::Kind::Id || tok.text != static_cast("in")) { throw_parser_error("expected 'in', got '" + tok.describe() + "'"); } get_next_token(); if (!parse_expression(tmpl, closing)) { return false; } } else if (tok.text == static_cast("endfor")) { if (for_statement_stack.empty()) { throw_parser_error("endfor without matching for"); } auto &for_statement_data = for_statement_stack.top(); get_next_token(); current_block = for_statement_data->parent; for_statement_stack.pop(); } else if (tok.text == static_cast("include")) { get_next_token(); if (tok.kind != Token::Kind::String) { throw_parser_error("expected string, got '" + tok.describe() + "'"); } // Build the relative path json json_name = json::parse(tok.text); std::string pathname = static_cast(path); pathname += json_name.get_ref(); if (pathname.compare(0, 2, "./") == 0) { pathname.erase(0, 2); } // sys::path::remove_dots(pathname, true, sys::path::Style::posix); if (config.search_included_templates_in_files && template_storage.find(pathname) == template_storage.end()) { auto include_template = Template(load_file(pathname)); template_storage.emplace(pathname, include_template); parse_into_template(template_storage[pathname], pathname); } current_block->nodes.emplace_back(std::make_shared(pathname, tok.text.data() - tmpl.content.c_str())); get_next_token(); } else if (tok.text == static_cast("set")) { get_next_token(); if (tok.kind != Token::Kind::Id) { throw_parser_error("expected variable name, got '" + tok.describe() + "'"); } std::string key = static_cast(tok.text); get_next_token(); auto set_statement_node = std::make_shared(key, tok.text.data() - tmpl.content.c_str()); current_block->nodes.emplace_back(set_statement_node); current_expression_list = &set_statement_node->expression; if (tok.text != static_cast("=")) { throw_parser_error("expected '=', got '" + tok.describe() + "'"); } get_next_token(); if (!parse_expression(tmpl, closing)) { return false; } } else { return false; } return true; } void parse_into(Template &tmpl, nonstd::string_view path) { lexer.start(tmpl.content); current_block = &tmpl.root; for (;;) { get_next_token(); switch (tok.kind) { case Token::Kind::Eof: { if (!if_statement_stack.empty()) { throw_parser_error("unmatched if"); } if (!for_statement_stack.empty()) { throw_parser_error("unmatched for"); } } return; case Token::Kind::Text: { current_block->nodes.emplace_back(std::make_shared(tok.text.data() - tmpl.content.c_str(), tok.text.size())); } break; case Token::Kind::StatementOpen: { get_next_token(); if (!parse_statement(tmpl, Token::Kind::StatementClose, path)) { throw_parser_error("expected statement, got '" + tok.describe() + "'"); } if (tok.kind != Token::Kind::StatementClose) { throw_parser_error("expected statement close, got '" + tok.describe() + "'"); } } break; case Token::Kind::LineStatementOpen: { get_next_token(); if (!parse_statement(tmpl, Token::Kind::LineStatementClose, path)) { throw_parser_error("expected statement, got '" + tok.describe() + "'"); } if (tok.kind != Token::Kind::LineStatementClose && tok.kind != Token::Kind::Eof) { throw_parser_error("expected line statement close, got '" + tok.describe() + "'"); } } break; case Token::Kind::ExpressionOpen: { get_next_token(); auto expression_list_node = std::make_shared(tok.text.data() - tmpl.content.c_str()); current_block->nodes.emplace_back(expression_list_node); current_expression_list = expression_list_node.get(); if (!parse_expression(tmpl, Token::Kind::ExpressionClose)) { throw_parser_error("expected expression, got '" + tok.describe() + "'"); } if (tok.kind != Token::Kind::ExpressionClose) { throw_parser_error("expected expression close, got '" + tok.describe() + "'"); } } break; case Token::Kind::CommentOpen: { get_next_token(); if (tok.kind != Token::Kind::CommentClose) { throw_parser_error("expected comment close, got '" + tok.describe() + "'"); } } break; default: { throw_parser_error("unexpected token '" + tok.describe() + "'"); } break; } } } public: explicit Parser(const ParserConfig &parser_config, const LexerConfig &lexer_config, TemplateStorage &template_storage, const FunctionStorage &function_storage) : config(parser_config), lexer(lexer_config), template_storage(template_storage), function_storage(function_storage) { } Template parse(nonstd::string_view input, nonstd::string_view path) { auto result = Template(static_cast(input)); parse_into(result, path); return result; } Template parse(nonstd::string_view input) { return parse(input, "./"); } void parse_into_template(Template& tmpl, nonstd::string_view filename) { nonstd::string_view path = filename.substr(0, filename.find_last_of("/\\") + 1); // StringRef path = sys::path::parent_path(filename); auto sub_parser = Parser(config, lexer.get_config(), template_storage, function_storage); sub_parser.parse_into(tmpl, path); } std::string load_file(nonstd::string_view filename) { std::ifstream file; open_file_or_throw(static_cast(filename), file); std::string text((std::istreambuf_iterator(file)), std::istreambuf_iterator()); return text; } }; } // namespace inja #endif // INCLUDE_INJA_PARSER_HPP_ // #include "renderer.hpp" // Copyright (c) 2020 Pantor. All rights reserved. #ifndef INCLUDE_INJA_RENDERER_HPP_ #define INCLUDE_INJA_RENDERER_HPP_ #include #include #include #include #include #include // #include "config.hpp" // #include "exceptions.hpp" // #include "node.hpp" // #include "template.hpp" // #include "utils.hpp" namespace inja { /*! * \brief Class for rendering a Template with data. */ class Renderer : public NodeVisitor { using Op = FunctionStorage::Operation; const RenderConfig config; const Template *current_template; const TemplateStorage &template_storage; const FunctionStorage &function_storage; const json *json_input; std::ostream *output_stream; json json_additional_data; json* current_loop_data = &json_additional_data["loop"]; std::vector> json_tmp_stack; std::stack json_eval_stack; std::stack not_found_stack; bool truthy(const json* data) const { if (data->is_boolean()) { return data->get(); } else if (data->is_number()) { return (*data != 0); } else if (data->is_null()) { return false; } return !data->empty(); } void print_json(const std::shared_ptr value) { if (value->is_string()) { *output_stream << value->get_ref(); } else if (value->is_number_integer()) { *output_stream << value->get(); } else if (value->is_null()) { } else { *output_stream << value->dump(); } } const std::shared_ptr eval_expression_list(const ExpressionListNode& expression_list) { for (auto& expression : expression_list.rpn_output) { expression->accept(*this); } if (json_eval_stack.empty()) { throw_renderer_error("empty expression", expression_list); } else if (json_eval_stack.size() != 1) { throw_renderer_error("malformed expression", expression_list); } auto result = json_eval_stack.top(); json_eval_stack.pop(); if (!result) { if (not_found_stack.empty()) { throw_renderer_error("expression could not be evaluated", expression_list); } auto node = not_found_stack.top(); not_found_stack.pop(); throw_renderer_error("variable '" + static_cast(node->name) + "' not found", *node); } return std::make_shared(*result); } void throw_renderer_error(const std::string &message, const AstNode& node) { SourceLocation loc = get_source_location(current_template->content, node.pos); throw RenderError(message, loc); } template std::array get_arguments(const AstNode& node) { if (json_eval_stack.size() < N) { throw_renderer_error("function needs " + std::to_string(N) + " variables, but has only found " + std::to_string(json_eval_stack.size()), node); } std::array result; for (size_t i = 0; i < N; i += 1) { result[N - i - 1] = json_eval_stack.top(); json_eval_stack.pop(); if (!result[N - i - 1]) { auto json_node = not_found_stack.top(); not_found_stack.pop(); if (throw_not_found) { throw_renderer_error("variable '" + static_cast(json_node->name) + "' not found", *json_node); } } } return result; } template Arguments get_argument_vector(size_t N, const AstNode& node) { Arguments result {N}; for (size_t i = 0; i < N; i += 1) { result[N - i - 1] = json_eval_stack.top(); json_eval_stack.pop(); if (!result[N - i - 1]) { auto json_node = not_found_stack.top(); not_found_stack.pop(); if (throw_not_found) { throw_renderer_error("variable '" + static_cast(json_node->name) + "' not found", *json_node); } } } return result; } void visit(const BlockNode& node) { for (auto& n : node.nodes) { n->accept(*this); } } void visit(const TextNode& node) { output_stream->write(current_template->content.c_str() + node.pos, node.length); } void visit(const ExpressionNode&) { } void visit(const LiteralNode& node) { json_eval_stack.push(&node.value); } void visit(const JsonNode& node) { if (json_additional_data.contains(node.ptr)) { json_eval_stack.push(&(json_additional_data[node.ptr])); } else if (json_input->contains(node.ptr)) { json_eval_stack.push(&(*json_input)[node.ptr]); } else { // Try to evaluate as a no-argument callback auto function_data = function_storage.find_function(node.name, 0); if (function_data.operation == FunctionStorage::Operation::Callback) { Arguments empty_args {}; auto value = std::make_shared(function_data.callback(empty_args)); json_tmp_stack.push_back(value); json_eval_stack.push(value.get()); } else { json_eval_stack.push(nullptr); not_found_stack.emplace(&node); } } } void visit(const FunctionNode& node) { std::shared_ptr result_ptr; switch (node.operation) { case Op::Not: { auto args = get_arguments<1>(node); result_ptr = std::make_shared(!truthy(args[0])); json_tmp_stack.push_back(result_ptr); json_eval_stack.push(result_ptr.get()); } break; case Op::And: { auto args = get_arguments<2>(node); result_ptr = std::make_shared(truthy(args[0]) && truthy(args[1])); json_tmp_stack.push_back(result_ptr); json_eval_stack.push(result_ptr.get()); } break; case Op::Or: { auto args = get_arguments<2>(node); result_ptr = std::make_shared(truthy(args[0]) || truthy(args[1])); json_tmp_stack.push_back(result_ptr); json_eval_stack.push(result_ptr.get()); } break; case Op::In: { auto args = get_arguments<2>(node); result_ptr = std::make_shared(std::find(args[1]->begin(), args[1]->end(), *args[0]) != args[1]->end()); json_tmp_stack.push_back(result_ptr); json_eval_stack.push(result_ptr.get()); } break; case Op::Equal: { auto args = get_arguments<2>(node); result_ptr = std::make_shared(*args[0] == *args[1]); json_tmp_stack.push_back(result_ptr); json_eval_stack.push(result_ptr.get()); } break; case Op::NotEqual: { auto args = get_arguments<2>(node); result_ptr = std::make_shared(*args[0] != *args[1]); json_tmp_stack.push_back(result_ptr); json_eval_stack.push(result_ptr.get()); } break; case Op::Greater: { auto args = get_arguments<2>(node); result_ptr = std::make_shared(*args[0] > *args[1]); json_tmp_stack.push_back(result_ptr); json_eval_stack.push(result_ptr.get()); } break; case Op::GreaterEqual: { auto args = get_arguments<2>(node); result_ptr = std::make_shared(*args[0] >= *args[1]); json_tmp_stack.push_back(result_ptr); json_eval_stack.push(result_ptr.get()); } break; case Op::Less: { auto args = get_arguments<2>(node); result_ptr = std::make_shared(*args[0] < *args[1]); json_tmp_stack.push_back(result_ptr); json_eval_stack.push(result_ptr.get()); } break; case Op::LessEqual: { auto args = get_arguments<2>(node); result_ptr = std::make_shared(*args[0] <= *args[1]); json_tmp_stack.push_back(result_ptr); json_eval_stack.push(result_ptr.get()); } break; case Op::Add: { auto args = get_arguments<2>(node); if (args[0]->is_string() && args[1]->is_string()) { result_ptr = std::make_shared(args[0]->get_ref() + args[1]->get_ref()); json_tmp_stack.push_back(result_ptr); } else if (args[0]->is_number_integer() && args[1]->is_number_integer()) { result_ptr = std::make_shared(args[0]->get() + args[1]->get()); json_tmp_stack.push_back(result_ptr); } else { result_ptr = std::make_shared(args[0]->get() + args[1]->get()); json_tmp_stack.push_back(result_ptr); } json_eval_stack.push(result_ptr.get()); } break; case Op::Subtract: { auto args = get_arguments<2>(node); if (args[0]->is_number_integer() && args[1]->is_number_integer()) { result_ptr = std::make_shared(args[0]->get() - args[1]->get()); json_tmp_stack.push_back(result_ptr); } else { result_ptr = std::make_shared(args[0]->get() - args[1]->get()); json_tmp_stack.push_back(result_ptr); } json_eval_stack.push(result_ptr.get()); } break; case Op::Multiplication: { auto args = get_arguments<2>(node); if (args[0]->is_number_integer() && args[1]->is_number_integer()) { result_ptr = std::make_shared(args[0]->get() * args[1]->get()); json_tmp_stack.push_back(result_ptr); } else { result_ptr = std::make_shared(args[0]->get() * args[1]->get()); json_tmp_stack.push_back(result_ptr); } json_eval_stack.push(result_ptr.get()); } break; case Op::Division: { auto args = get_arguments<2>(node); if (args[1]->get() == 0) { throw_renderer_error("division by zero", node); } result_ptr = std::make_shared(args[0]->get() / args[1]->get()); json_tmp_stack.push_back(result_ptr); json_eval_stack.push(result_ptr.get()); } break; case Op::Power: { auto args = get_arguments<2>(node); if (args[0]->is_number_integer() && args[1]->get() >= 0) { int result = std::pow(args[0]->get(), args[1]->get()); result_ptr = std::make_shared(std::move(result)); json_tmp_stack.push_back(result_ptr); } else { double result = std::pow(args[0]->get(), args[1]->get()); result_ptr = std::make_shared(std::move(result)); json_tmp_stack.push_back(result_ptr); } json_eval_stack.push(result_ptr.get()); } break; case Op::Modulo: { auto args = get_arguments<2>(node); result_ptr = std::make_shared(args[0]->get() % args[1]->get()); json_tmp_stack.push_back(result_ptr); json_eval_stack.push(result_ptr.get()); } break; case Op::AtId: { json_eval_stack.pop(); // Pop id nullptr auto container = get_arguments<1, false>(node)[0]; if (not_found_stack.empty()) { throw_renderer_error("could not find element with given name", node); } auto id_node = not_found_stack.top(); not_found_stack.pop(); json_eval_stack.push(&container->at(id_node->name)); } break; case Op::At: { auto args = get_arguments<2>(node); json_eval_stack.push(&args[0]->at(args[1]->get())); } break; case Op::Default: { auto default_arg = get_arguments<1>(node)[0]; auto test_arg = get_arguments<1, false>(node)[0]; json_eval_stack.push(test_arg ? test_arg : default_arg); } break; case Op::DivisibleBy: { auto args = get_arguments<2>(node); int divisor = args[1]->get(); result_ptr = std::make_shared((divisor != 0) && (args[0]->get() % divisor == 0)); json_tmp_stack.push_back(result_ptr); json_eval_stack.push(result_ptr.get()); } break; case Op::Even: { result_ptr = std::make_shared(get_arguments<1>(node)[0]->get() % 2 == 0); json_tmp_stack.push_back(result_ptr); json_eval_stack.push(result_ptr.get()); } break; case Op::Exists: { auto &&name = get_arguments<1>(node)[0]->get_ref(); result_ptr = std::make_shared(json_input->contains(json::json_pointer(JsonNode::convert_dot_to_json_ptr(name)))); json_tmp_stack.push_back(result_ptr); json_eval_stack.push(result_ptr.get()); } break; case Op::ExistsInObject: { auto args = get_arguments<2>(node); auto &&name = args[1]->get_ref(); result_ptr = std::make_shared(args[0]->find(name) != args[0]->end()); json_tmp_stack.push_back(result_ptr); json_eval_stack.push(result_ptr.get()); } break; case Op::First: { auto result = &get_arguments<1>(node)[0]->front(); json_eval_stack.push(result); } break; case Op::Float: { result_ptr = std::make_shared(std::stod(get_arguments<1>(node)[0]->get_ref())); json_tmp_stack.push_back(result_ptr); json_eval_stack.push(result_ptr.get()); } break; case Op::Int: { result_ptr = std::make_shared(std::stoi(get_arguments<1>(node)[0]->get_ref())); json_tmp_stack.push_back(result_ptr); json_eval_stack.push(result_ptr.get()); } break; case Op::Last: { auto result = &get_arguments<1>(node)[0]->back(); json_eval_stack.push(result); } break; case Op::Length: { auto val = get_arguments<1>(node)[0]; if (val->is_string()) { result_ptr = std::make_shared(val->get_ref().length()); } else { result_ptr = std::make_shared(val->size()); } json_tmp_stack.push_back(result_ptr); json_eval_stack.push(result_ptr.get()); } break; case Op::Lower: { std::string result = get_arguments<1>(node)[0]->get(); std::transform(result.begin(), result.end(), result.begin(), ::tolower); result_ptr = std::make_shared(std::move(result)); json_tmp_stack.push_back(result_ptr); json_eval_stack.push(result_ptr.get()); } break; case Op::Max: { auto args = get_arguments<1>(node); auto result = std::max_element(args[0]->begin(), args[0]->end()); json_eval_stack.push(&(*result)); } break; case Op::Min: { auto args = get_arguments<1>(node); auto result = std::min_element(args[0]->begin(), args[0]->end()); json_eval_stack.push(&(*result)); } break; case Op::Odd: { result_ptr = std::make_shared(get_arguments<1>(node)[0]->get() % 2 != 0); json_tmp_stack.push_back(result_ptr); json_eval_stack.push(result_ptr.get()); } break; case Op::Range: { std::vector result(get_arguments<1>(node)[0]->get()); std::iota(result.begin(), result.end(), 0); result_ptr = std::make_shared(std::move(result)); json_tmp_stack.push_back(result_ptr); json_eval_stack.push(result_ptr.get()); } break; case Op::Round: { auto args = get_arguments<2>(node); int precision = args[1]->get(); double result = std::round(args[0]->get() * std::pow(10.0, precision)) / std::pow(10.0, precision); result_ptr = std::make_shared(std::move(result)); json_tmp_stack.push_back(result_ptr); json_eval_stack.push(result_ptr.get()); } break; case Op::Sort: { result_ptr = std::make_shared(get_arguments<1>(node)[0]->get>()); std::sort(result_ptr->begin(), result_ptr->end()); json_tmp_stack.push_back(result_ptr); json_eval_stack.push(result_ptr.get()); } break; case Op::Upper: { std::string result = get_arguments<1>(node)[0]->get(); std::transform(result.begin(), result.end(), result.begin(), ::toupper); result_ptr = std::make_shared(std::move(result)); json_tmp_stack.push_back(result_ptr); json_eval_stack.push(result_ptr.get()); } break; case Op::IsBoolean: { result_ptr = std::make_shared(get_arguments<1>(node)[0]->is_boolean()); json_tmp_stack.push_back(result_ptr); json_eval_stack.push(result_ptr.get()); } break; case Op::IsNumber: { result_ptr = std::make_shared(get_arguments<1>(node)[0]->is_number()); json_tmp_stack.push_back(result_ptr); json_eval_stack.push(result_ptr.get()); } break; case Op::IsInteger: { result_ptr = std::make_shared(get_arguments<1>(node)[0]->is_number_integer()); json_tmp_stack.push_back(result_ptr); json_eval_stack.push(result_ptr.get()); } break; case Op::IsFloat: { result_ptr = std::make_shared(get_arguments<1>(node)[0]->is_number_float()); json_tmp_stack.push_back(result_ptr); json_eval_stack.push(result_ptr.get()); } break; case Op::IsObject: { result_ptr = std::make_shared(get_arguments<1>(node)[0]->is_object()); json_tmp_stack.push_back(result_ptr); json_eval_stack.push(result_ptr.get()); } break; case Op::IsArray: { result_ptr = std::make_shared(get_arguments<1>(node)[0]->is_array()); json_tmp_stack.push_back(result_ptr); json_eval_stack.push(result_ptr.get()); } break; case Op::IsString: { result_ptr = std::make_shared(get_arguments<1>(node)[0]->is_string()); json_tmp_stack.push_back(result_ptr); json_eval_stack.push(result_ptr.get()); } break; case Op::Callback: { auto args = get_argument_vector(node.number_args, node); result_ptr = std::make_shared(node.callback(args)); json_tmp_stack.push_back(result_ptr); json_eval_stack.push(result_ptr.get()); } break; case Op::ParenLeft: case Op::ParenRight: case Op::None: break; } } void visit(const ExpressionListNode& node) { print_json(eval_expression_list(node)); } void visit(const StatementNode&) { } void visit(const ForStatementNode&) { } void visit(const ForArrayStatementNode& node) { auto result = eval_expression_list(node.condition); if (!result->is_array()) { throw_renderer_error("object must be an array", node); } if (!current_loop_data->empty()) { auto tmp = *current_loop_data; // Because of clang-3 (*current_loop_data)["parent"] = std::move(tmp); } size_t index = 0; (*current_loop_data)["is_first"] = true; (*current_loop_data)["is_last"] = (result->size() <= 1); for (auto it = result->begin(); it != result->end(); ++it) { json_additional_data[static_cast(node.value)] = *it; (*current_loop_data)["index"] = index; (*current_loop_data)["index1"] = index + 1; if (index == 1) { (*current_loop_data)["is_first"] = false; } if (index == result->size() - 1) { (*current_loop_data)["is_last"] = true; } node.body.accept(*this); ++index; } json_additional_data[static_cast(node.value)].clear(); if (!(*current_loop_data)["parent"].empty()) { auto tmp = (*current_loop_data)["parent"]; *current_loop_data = std::move(tmp); } else { current_loop_data = &json_additional_data["loop"]; } } void visit(const ForObjectStatementNode& node) { auto result = eval_expression_list(node.condition); if (!result->is_object()) { throw_renderer_error("object must be an object", node); } if (!current_loop_data->empty()) { (*current_loop_data)["parent"] = std::move(*current_loop_data); } size_t index = 0; (*current_loop_data)["is_first"] = true; (*current_loop_data)["is_last"] = (result->size() <= 1); for (auto it = result->begin(); it != result->end(); ++it) { json_additional_data[static_cast(node.key)] = it.key(); json_additional_data[static_cast(node.value)] = it.value(); (*current_loop_data)["index"] = index; (*current_loop_data)["index1"] = index + 1; if (index == 1) { (*current_loop_data)["is_first"] = false; } if (index == result->size() - 1) { (*current_loop_data)["is_last"] = true; } node.body.accept(*this); ++index; } json_additional_data[static_cast(node.key)].clear(); json_additional_data[static_cast(node.value)].clear(); if (!(*current_loop_data)["parent"].empty()) { *current_loop_data = std::move((*current_loop_data)["parent"]); } else { current_loop_data = &json_additional_data["loop"]; } } void visit(const IfStatementNode& node) { auto result = eval_expression_list(node.condition); if (truthy(result.get())) { node.true_statement.accept(*this); } else if (node.has_false_statement) { node.false_statement.accept(*this); } } void visit(const IncludeStatementNode& node) { auto sub_renderer = Renderer(config, template_storage, function_storage); auto included_template_it = template_storage.find(node.file); if (included_template_it != template_storage.end()) { sub_renderer.render_to(*output_stream, included_template_it->second, *json_input, &json_additional_data); } else if (config.throw_at_missing_includes) { throw_renderer_error("include '" + node.file + "' not found", node); } } void visit(const SetStatementNode& node) { json_additional_data[node.key] = *eval_expression_list(node.expression); } public: Renderer(const RenderConfig& config, const TemplateStorage &template_storage, const FunctionStorage &function_storage) : config(config), template_storage(template_storage), function_storage(function_storage) { } void render_to(std::ostream &os, const Template &tmpl, const json &data, json *loop_data = nullptr) { output_stream = &os; current_template = &tmpl; json_input = &data; if (loop_data) { json_additional_data = *loop_data; current_loop_data = &json_additional_data["loop"]; } current_template->root.accept(*this); json_tmp_stack.clear(); } }; } // namespace inja #endif // INCLUDE_INJA_RENDERER_HPP_ // #include "string_view.hpp" // #include "template.hpp" // #include "utils.hpp" namespace inja { using json = nlohmann::json; /*! * \brief Class for changing the configuration. */ class Environment { std::string input_path; std::string output_path; LexerConfig lexer_config; ParserConfig parser_config; RenderConfig render_config; FunctionStorage function_storage; TemplateStorage template_storage; public: Environment() : Environment("") {} explicit Environment(const std::string &global_path) : input_path(global_path), output_path(global_path) {} Environment(const std::string &input_path, const std::string &output_path) : input_path(input_path), output_path(output_path) {} /// Sets the opener and closer for template statements void set_statement(const std::string &open, const std::string &close) { lexer_config.statement_open = open; lexer_config.statement_open_no_lstrip = open + "+"; lexer_config.statement_open_force_lstrip = open + "-"; lexer_config.statement_close = close; lexer_config.statement_close_force_rstrip = "-" + close; lexer_config.update_open_chars(); } /// Sets the opener for template line statements void set_line_statement(const std::string &open) { lexer_config.line_statement = open; lexer_config.update_open_chars(); } /// Sets the opener and closer for template expressions void set_expression(const std::string &open, const std::string &close) { lexer_config.expression_open = open; lexer_config.expression_open_force_lstrip = open + "-"; lexer_config.expression_close = close; lexer_config.expression_close_force_rstrip = "-" + close; lexer_config.update_open_chars(); } /// Sets the opener and closer for template comments void set_comment(const std::string &open, const std::string &close) { lexer_config.comment_open = open; lexer_config.comment_close = close; lexer_config.update_open_chars(); } /// Sets whether to remove the first newline after a block void set_trim_blocks(bool trim_blocks) { lexer_config.trim_blocks = trim_blocks; } /// Sets whether to strip the spaces and tabs from the start of a line to a block void set_lstrip_blocks(bool lstrip_blocks) { lexer_config.lstrip_blocks = lstrip_blocks; } /// Sets the element notation syntax void set_search_included_templates_in_files(bool search_in_files) { parser_config.search_included_templates_in_files = search_in_files; } /// Sets whether a missing include will throw an error void set_throw_at_missing_includes(bool will_throw) { render_config.throw_at_missing_includes = will_throw; } Template parse(nonstd::string_view input) { Parser parser(parser_config, lexer_config, template_storage, function_storage); return parser.parse(input); } Template parse_template(const std::string &filename) { Parser parser(parser_config, lexer_config, template_storage, function_storage); auto result = Template(parser.load_file(input_path + static_cast(filename))); parser.parse_into_template(result, input_path + static_cast(filename)); return result; } Template parse_file(const std::string &filename) { return parse_template(filename); } std::string render(nonstd::string_view input, const json &data) { return render(parse(input), data); } std::string render(const Template &tmpl, const json &data) { std::stringstream os; render_to(os, tmpl, data); return os.str(); } std::string render_file(const std::string &filename, const json &data) { return render(parse_template(filename), data); } std::string render_file_with_json_file(const std::string &filename, const std::string &filename_data) { const json data = load_json(filename_data); return render_file(filename, data); } void write(const std::string &filename, const json &data, const std::string &filename_out) { std::ofstream file(output_path + filename_out); file << render_file(filename, data); file.close(); } void write(const Template &temp, const json &data, const std::string &filename_out) { std::ofstream file(output_path + filename_out); file << render(temp, data); file.close(); } void write_with_json_file(const std::string &filename, const std::string &filename_data, const std::string &filename_out) { const json data = load_json(filename_data); write(filename, data, filename_out); } void write_with_json_file(const Template &temp, const std::string &filename_data, const std::string &filename_out) { const json data = load_json(filename_data); write(temp, data, filename_out); } std::ostream &render_to(std::ostream &os, const Template &tmpl, const json &data) { Renderer(render_config, template_storage, function_storage).render_to(os, tmpl, data); return os; } std::string load_file(const std::string &filename) { Parser parser(parser_config, lexer_config, template_storage, function_storage); return parser.load_file(input_path + filename); } json load_json(const std::string &filename) { std::ifstream file; open_file_or_throw(input_path + filename, file); json j; file >> j; return j; } /*! @brief Adds a variadic callback */ void add_callback(const std::string &name, const CallbackFunction &callback) { add_callback(name, -1, callback); } /*! @brief Adds a variadic void callback */ void add_void_callback(const std::string &name, const VoidCallbackFunction &callback) { add_void_callback(name, -1, callback); } /*! @brief Adds a callback with given number or arguments */ void add_callback(const std::string &name, int num_args, const CallbackFunction &callback) { function_storage.add_callback(name, num_args, callback); } /*! @brief Adds a void callback with given number or arguments */ void add_void_callback(const std::string &name, int num_args, const VoidCallbackFunction &callback) { function_storage.add_callback(name, num_args, [callback](Arguments& args) { callback(args); return json(); }); } /** Includes a template with a given name into the environment. * Then, a template can be rendered in another template using the * include "" syntax. */ void include_template(const std::string &name, const Template &tmpl) { template_storage[name] = tmpl; } }; /*! @brief render with default settings to a string */ inline std::string render(nonstd::string_view input, const json &data) { return Environment().render(input, data); } /*! @brief render with default settings to the given output stream */ inline void render_to(std::ostream &os, nonstd::string_view input, const json &data) { Environment env; env.render_to(os, env.parse(input), data); } } // namespace inja #endif // INCLUDE_INJA_ENVIRONMENT_HPP_ // #include "exceptions.hpp" // #include "parser.hpp" // #include "renderer.hpp" // #include "string_view.hpp" // #include "template.hpp" #endif // INCLUDE_INJA_INJA_HPP_