// examples/parse translated by mycpp #include "mycpp/examples/parse_preamble.h" // BEGIN mycpp output #include "mycpp/runtime.h" GLOBAL_STR(str0, "("); GLOBAL_STR(str1, ")"); GLOBAL_STR(str2, "_"); GLOBAL_STR(str3, "T"); GLOBAL_STR(str4, "F"); GLOBAL_STR(str5, "\n\n \n Oils AST\n \n \n \n
\n");
GLOBAL_STR(str6, "\n    
\n \n\n "); GLOBAL_STR(str7, "n"); GLOBAL_STR(str8, "s"); GLOBAL_STR(str9, "o"); GLOBAL_STR(str10, "o"); GLOBAL_STR(str11, "o"); GLOBAL_STR(str12, ""); GLOBAL_STR(str13, ""); GLOBAL_STR(str14, " "); GLOBAL_STR(str15, "\n"); GLOBAL_STR(str16, " "); GLOBAL_STR(str17, "]"); GLOBAL_STR(str18, " "); GLOBAL_STR(str19, " "); GLOBAL_STR(str20, "\n"); GLOBAL_STR(str21, "\n"); GLOBAL_STR(str22, " "); GLOBAL_STR(str23, "%s%s: ["); GLOBAL_STR(str24, "\n"); GLOBAL_STR(str25, "\n"); GLOBAL_STR(str26, "%s]"); GLOBAL_STR(str27, "%s%s: "); GLOBAL_STR(str28, "\n"); GLOBAL_STR(str29, "\n"); GLOBAL_STR(str30, " "); GLOBAL_STR(str31, "UNTYPED any"); GLOBAL_STR(str32, "...0x%s"); GLOBAL_STR(str33, " "); GLOBAL_STR(str34, " "); GLOBAL_STR(str35, " %s:"); GLOBAL_STR(str36, "UNTYPED any"); GLOBAL_STR(str37, "["); GLOBAL_STR(str38, " "); GLOBAL_STR(str39, "]"); GLOBAL_STR(str40, "...0x%s"); GLOBAL_STR(str41, "foo"); GLOBAL_STR(str42, "\n"); GLOBAL_STR(str43, "\u001b[0;0m"); GLOBAL_STR(str44, "\u001b[1m"); GLOBAL_STR(str45, "\u001b[4m"); GLOBAL_STR(str46, "\u001b[7m"); GLOBAL_STR(str47, "\u001b[31m"); GLOBAL_STR(str48, "\u001b[32m"); GLOBAL_STR(str49, "\u001b[33m"); GLOBAL_STR(str50, "\u001b[34m"); GLOBAL_STR(str51, "\u001b[35m"); GLOBAL_STR(str52, "\u001b[36m"); GLOBAL_STR(str53, "\u001b[37m"); GLOBAL_STR(str54, "\n"); GLOBAL_STR(str55, ""); GLOBAL_STR(str56, "+-"); GLOBAL_STR(str57, "*/"); GLOBAL_STR(str58, "()"); GLOBAL_STR(str59, ""); GLOBAL_STR(str60, "Expected "); GLOBAL_STR(str61, "("); GLOBAL_STR(str62, ")"); GLOBAL_STR(str63, "Unexpected token "); GLOBAL_STR(str64, "abc"); GLOBAL_STR(str65, "tok_val %s"); GLOBAL_STR(str66, "1+2"); GLOBAL_STR(str67, "1+2*3"); GLOBAL_STR(str68, "1*2+3"); GLOBAL_STR(str69, "(1+2)*3"); GLOBAL_STR(str70, "a+b+c+d"); GLOBAL_STR(str71, "a*b*3*4"); GLOBAL_STR(str72, "1"); GLOBAL_STR(str73, "a"); GLOBAL_STR(str74, "("); GLOBAL_STR(str75, ")"); GLOBAL_STR(str76, "(a+b"); GLOBAL_STR(str77, " "); GLOBAL_STR(str78, " $$ "); GLOBAL_STR(str79, ""); GLOBAL_STR(str80, "--"); GLOBAL_STR(str81, "%s =>"); GLOBAL_STR(str82, "Parse error: %s"); GLOBAL_STR(str83, "\n"); GLOBAL_STR(str84, "Const %d"); GLOBAL_STR(str85, "Var %s"); GLOBAL_STR(str86, "Other"); GLOBAL_STR(str87, "c.i %d"); GLOBAL_STR(str88, "v.name %r"); GLOBAL_STR(str89, "b.op %r"); GLOBAL_STR(str90, "+"); GLOBAL_STR(str91, "\n"); GLOBAL_STR(str92, "a*b*3*4"); GLOBAL_STR(str93, "result = %d"); GLOBAL_STR(str94, "iterations = %d"); GLOBAL_STR(str95, "&"); GLOBAL_STR(str96, "&"); GLOBAL_STR(str97, "<"); GLOBAL_STR(str98, "<"); GLOBAL_STR(str99, ">"); GLOBAL_STR(str100, ">"); namespace runtime { // forward declare class TraversalState; } // forward declare namespace runtime namespace format { // forward declare class ColorOutput; class TextOutput; class HtmlOutput; class AnsiOutput; class _PrettyPrinter; } // forward declare namespace format namespace j8_lite { // forward declare } // forward declare namespace j8_lite namespace ansi { // forward declare } // forward declare namespace ansi namespace pretty { // forward declare class PrettyPrinter; } // forward declare namespace pretty namespace parse { // forward declare class Lexer; class ParseError; class Parser; } // forward declare namespace parse namespace cgi { // forward declare } // forward declare namespace cgi namespace runtime { // declare using hnode_asdl::hnode; extern int NO_SPID; hnode::Record* NewRecord(BigStr* node_type); hnode::Leaf* NewLeaf(BigStr* s, hnode_asdl::color_t e_color); class TraversalState { public: TraversalState(); Dict* seen{}; Dict* ref_count{}; static constexpr ObjHeader obj_header() { return ObjHeader::ClassScanned(2, sizeof(TraversalState)); } DISALLOW_COPY_AND_ASSIGN(TraversalState) }; extern BigStr* TRUE_STR; extern BigStr* FALSE_STR; } // declare namespace runtime namespace format { // declare using hnode_asdl::hnode; format::ColorOutput* DetectConsoleOutput(mylib::Writer* f); class ColorOutput { public: ColorOutput(mylib::Writer* f); virtual format::ColorOutput* NewTempBuffer(); virtual void FileHeader(); virtual void FileFooter(); virtual void PushColor(hnode_asdl::color_t e_color); virtual void PopColor(); virtual void write(BigStr* s); void WriteRaw(Tuple2* raw); int NumChars(); Tuple2 GetRaw(); mylib::Writer* f{}; int num_chars{}; static constexpr uint32_t field_mask() { return maskbit(offsetof(ColorOutput, f)); } static constexpr ObjHeader obj_header() { return ObjHeader::ClassFixed(field_mask(), sizeof(ColorOutput)); } DISALLOW_COPY_AND_ASSIGN(ColorOutput) }; class TextOutput : public ::format::ColorOutput { public: TextOutput(mylib::Writer* f); virtual format::TextOutput* NewTempBuffer(); virtual void PushColor(hnode_asdl::color_t e_color); virtual void PopColor(); static constexpr uint32_t field_mask() { return ::format::ColorOutput::field_mask(); } static constexpr ObjHeader obj_header() { return ObjHeader::ClassFixed(field_mask(), sizeof(TextOutput)); } DISALLOW_COPY_AND_ASSIGN(TextOutput) }; class HtmlOutput : public ::format::ColorOutput { public: HtmlOutput(mylib::Writer* f); virtual format::HtmlOutput* NewTempBuffer(); virtual void FileHeader(); virtual void FileFooter(); virtual void PushColor(hnode_asdl::color_t e_color); virtual void PopColor(); virtual void write(BigStr* s); static constexpr uint32_t field_mask() { return ::format::ColorOutput::field_mask(); } static constexpr ObjHeader obj_header() { return ObjHeader::ClassFixed(field_mask(), sizeof(HtmlOutput)); } DISALLOW_COPY_AND_ASSIGN(HtmlOutput) }; class AnsiOutput : public ::format::ColorOutput { public: AnsiOutput(mylib::Writer* f); virtual format::AnsiOutput* NewTempBuffer(); virtual void PushColor(hnode_asdl::color_t e_color); virtual void PopColor(); static constexpr uint32_t field_mask() { return ::format::ColorOutput::field_mask(); } static constexpr ObjHeader obj_header() { return ObjHeader::ClassFixed(field_mask(), sizeof(AnsiOutput)); } DISALLOW_COPY_AND_ASSIGN(AnsiOutput) }; extern int INDENT; class _PrettyPrinter { public: _PrettyPrinter(int max_col); bool _PrintWrappedArray(List* array, int prefix_len, format::ColorOutput* f, int indent); bool _PrintWholeArray(List* array, int prefix_len, format::ColorOutput* f, int indent); void _PrintRecord(hnode::Record* node, format::ColorOutput* f, int indent); void PrintNode(hnode_asdl::hnode_t* node, format::ColorOutput* f, int indent); int max_col{}; static constexpr ObjHeader obj_header() { return ObjHeader::ClassScanned(0, sizeof(_PrettyPrinter)); } DISALLOW_COPY_AND_ASSIGN(_PrettyPrinter) }; bool _TrySingleLineObj(hnode::Record* node, format::ColorOutput* f, int max_chars); bool _TrySingleLine(hnode_asdl::hnode_t* node, format::ColorOutput* f, int max_chars); void PrintTree(hnode_asdl::hnode_t* node, format::ColorOutput* f); void PrintTree2(hnode_asdl::hnode_t* node, format::ColorOutput* f); } // declare namespace format namespace j8_lite { // declare BigStr* EncodeString(BigStr* s, bool unquoted_ok = false); BigStr* YshEncodeString(BigStr* s); BigStr* MaybeShellEncode(BigStr* s); BigStr* ShellEncode(BigStr* s); BigStr* YshEncode(BigStr* s, bool unquoted_ok = false); } // declare namespace j8_lite namespace ansi { // declare extern BigStr* RESET; extern BigStr* BOLD; extern BigStr* UNDERLINE; extern BigStr* REVERSE; extern BigStr* RED; extern BigStr* GREEN; extern BigStr* YELLOW; extern BigStr* BLUE; extern BigStr* MAGENTA; extern BigStr* CYAN; extern BigStr* WHITE; } // declare namespace ansi namespace pretty { // declare pretty_asdl::Measure* _EmptyMeasure(); pretty_asdl::Measure* _FlattenMeasure(pretty_asdl::Measure* measure); pretty_asdl::Measure* _ConcatMeasure(pretty_asdl::Measure* m1, pretty_asdl::Measure* m2); int _SuffixLen(pretty_asdl::Measure* measure); pretty_asdl::MeasuredDoc* AsciiText(BigStr* string); pretty_asdl::MeasuredDoc* _Break(BigStr* string); pretty_asdl::MeasuredDoc* _Indent(int indent, pretty_asdl::MeasuredDoc* mdoc); pretty_asdl::MeasuredDoc* _Concat(List* mdocs); pretty_asdl::MeasuredDoc* _Group(pretty_asdl::MeasuredDoc* mdoc); pretty_asdl::MeasuredDoc* _IfFlat(pretty_asdl::MeasuredDoc* flat_mdoc, pretty_asdl::MeasuredDoc* nonflat_mdoc); pretty_asdl::MeasuredDoc* _Flat(pretty_asdl::MeasuredDoc* mdoc); class PrettyPrinter { public: PrettyPrinter(int max_width); bool _Fits(int prefix_len, doc::Group* group, pretty_asdl::Measure* suffix_measure); void PrintDoc(pretty_asdl::MeasuredDoc* document, mylib::BufWriter* buf); int max_width{}; static constexpr ObjHeader obj_header() { return ObjHeader::ClassScanned(0, sizeof(PrettyPrinter)); } DISALLOW_COPY_AND_ASSIGN(PrettyPrinter) }; } // declare namespace pretty namespace parse { // declare class Lexer { public: Lexer(BigStr* s); Tuple2 Read(); void _MethodCallingOtherMethod(); BigStr* s{}; int i{}; int n{}; static constexpr ObjHeader obj_header() { return ObjHeader::ClassScanned(1, sizeof(Lexer)); } DISALLOW_COPY_AND_ASSIGN(Lexer) }; class ParseError { public: ParseError(BigStr* msg); BigStr* msg{}; static constexpr ObjHeader obj_header() { return ObjHeader::ClassScanned(1, sizeof(ParseError)); } DISALLOW_COPY_AND_ASSIGN(ParseError) }; class Parser { public: Parser(parse::Lexer* lexer); void Next(); void Eat(BigStr* tok_val); expr_asdl::expr_t* ParseFactor(); expr_asdl::expr_t* ParseTerm(); expr_asdl::expr_t* ParseExpr(); expr_asdl::expr_t* Parse(); parse::Lexer* lexer{}; BigStr* tok_val{}; expr_asdl::tok_t tok_type{}; static constexpr ObjHeader obj_header() { return ObjHeader::ClassScanned(2, sizeof(Parser)); } DISALLOW_COPY_AND_ASSIGN(Parser) }; void TestParse(); void TestCreateNull(); void run_tests(); void run_benchmarks(); } // declare namespace parse namespace cgi { // declare BigStr* escape(BigStr* s); } // declare namespace cgi namespace runtime { // define using hnode_asdl::hnode; using hnode_asdl::color_t; using hnode_asdl::color_e; int NO_SPID = -1; hnode::Record* NewRecord(BigStr* node_type) { StackRoot _root0(&node_type); return Alloc(node_type, Alloc>(), false, str0, str1, Alloc>()); } hnode::Leaf* NewLeaf(BigStr* s, hnode_asdl::color_t e_color) { StackRoot _root0(&s); if (s == nullptr) { return Alloc(str2, color_e::OtherConst); } else { return Alloc(s, e_color); } } TraversalState::TraversalState() { this->seen = Alloc>(); this->ref_count = Alloc>(); } BigStr* TRUE_STR = str3; BigStr* FALSE_STR = str4; } // define namespace runtime namespace format { // define using hnode_asdl::hnode; using hnode_asdl::hnode_e; using hnode_asdl::hnode_t; using hnode_asdl::color_e; using hnode_asdl::color_t; format::ColorOutput* DetectConsoleOutput(mylib::Writer* f) { StackRoot _root0(&f); if (f->isatty()) { return Alloc(f); } else { return Alloc(f); } } ColorOutput::ColorOutput(mylib::Writer* f) { this->f = f; this->num_chars = 0; } format::ColorOutput* ColorOutput::NewTempBuffer() { FAIL(kNotImplemented); // Python NotImplementedError } void ColorOutput::FileHeader() { ; // pass } void ColorOutput::FileFooter() { ; // pass } void ColorOutput::PushColor(hnode_asdl::color_t e_color) { FAIL(kNotImplemented); // Python NotImplementedError } void ColorOutput::PopColor() { FAIL(kNotImplemented); // Python NotImplementedError } void ColorOutput::write(BigStr* s) { StackRoot _root0(&s); this->f->write(s); this->num_chars += len(s); } void ColorOutput::WriteRaw(Tuple2* raw) { BigStr* s = nullptr; int num_chars; StackRoot _root0(&raw); StackRoot _root1(&s); Tuple2* tup0 = raw; s = tup0->at0(); num_chars = tup0->at1(); this->f->write(s); this->num_chars += num_chars; } int ColorOutput::NumChars() { return this->num_chars; } Tuple2 ColorOutput::GetRaw() { mylib::BufWriter* f = nullptr; StackRoot _root0(&f); f = static_cast(this->f); return Tuple2(f->getvalue(), this->num_chars); } TextOutput::TextOutput(mylib::Writer* f) : ::format::ColorOutput(f) { } format::TextOutput* TextOutput::NewTempBuffer() { return Alloc(Alloc()); } void TextOutput::PushColor(hnode_asdl::color_t e_color) { ; // pass } void TextOutput::PopColor() { ; // pass } HtmlOutput::HtmlOutput(mylib::Writer* f) : ::format::ColorOutput(f) { } format::HtmlOutput* HtmlOutput::NewTempBuffer() { return Alloc(Alloc()); } void HtmlOutput::FileHeader() { this->f->write(str5); } void HtmlOutput::FileFooter() { this->f->write(str6); } void HtmlOutput::PushColor(hnode_asdl::color_t e_color) { BigStr* css_class = nullptr; StackRoot _root0(&css_class); if (e_color == color_e::TypeName) { css_class = str7; } else { if (e_color == color_e::StringConst) { css_class = str8; } else { if (e_color == color_e::OtherConst) { css_class = str9; } else { if (e_color == color_e::External) { css_class = str10; } else { if (e_color == color_e::UserType) { css_class = str11; } else { assert(0); // AssertionError } } } } } this->f->write(StrFormat("", css_class)); } void HtmlOutput::PopColor() { this->f->write(str13); } void HtmlOutput::write(BigStr* s) { StackRoot _root0(&s); this->f->write(cgi::escape(s)); this->num_chars += len(s); } AnsiOutput::AnsiOutput(mylib::Writer* f) : ::format::ColorOutput(f) { } format::AnsiOutput* AnsiOutput::NewTempBuffer() { return Alloc(Alloc()); } void AnsiOutput::PushColor(hnode_asdl::color_t e_color) { if (e_color == color_e::TypeName) { this->f->write(ansi::YELLOW); } else { if (e_color == color_e::StringConst) { this->f->write(ansi::BOLD); } else { if (e_color == color_e::OtherConst) { this->f->write(ansi::GREEN); } else { if (e_color == color_e::External) { this->f->write(str_concat(ansi::BOLD, ansi::BLUE)); } else { if (e_color == color_e::UserType) { this->f->write(ansi::GREEN); } else { assert(0); // AssertionError } } } } } } void AnsiOutput::PopColor() { this->f->write(ansi::RESET); } int INDENT = 2; _PrettyPrinter::_PrettyPrinter(int max_col) { this->max_col = max_col; } bool _PrettyPrinter::_PrintWrappedArray(List* array, int prefix_len, format::ColorOutput* f, int indent) { bool all_fit; int chars_so_far; int i; format::ColorOutput* single_f = nullptr; BigStr* s = nullptr; int num_chars; StackRoot _root0(&array); StackRoot _root1(&f); StackRoot _root2(&single_f); StackRoot _root3(&s); all_fit = true; chars_so_far = prefix_len; i = 0; for (ListIter it(array); !it.Done(); it.Next(), ++i) { hnode_asdl::hnode_t* val = it.Value(); StackRoot _for(&val ); if (i != 0) { f->write(str14); } single_f = f->NewTempBuffer(); if (_TrySingleLine(val, single_f, (this->max_col - chars_so_far))) { Tuple2 tup1 = single_f->GetRaw(); s = tup1.at0(); num_chars = tup1.at1(); f->WriteRaw((Alloc>(s, num_chars))); chars_so_far += single_f->NumChars(); } else { f->write(str15); this->PrintNode(val, f, (indent + INDENT)); chars_so_far = 0; all_fit = false; } } return all_fit; } bool _PrettyPrinter::_PrintWholeArray(List* array, int prefix_len, format::ColorOutput* f, int indent) { bool all_fit; List*>* pieces = nullptr; int chars_so_far; format::ColorOutput* single_f = nullptr; BigStr* s = nullptr; int num_chars; int i; StackRoot _root0(&array); StackRoot _root1(&f); StackRoot _root2(&pieces); StackRoot _root3(&single_f); StackRoot _root4(&s); all_fit = true; pieces = Alloc*>>(); chars_so_far = prefix_len; for (ListIter it(array); !it.Done(); it.Next()) { hnode_asdl::hnode_t* item = it.Value(); StackRoot _for(&item ); single_f = f->NewTempBuffer(); if (_TrySingleLine(item, single_f, (this->max_col - chars_so_far))) { Tuple2 tup2 = single_f->GetRaw(); s = tup2.at0(); num_chars = tup2.at1(); pieces->append((Alloc>(s, num_chars))); chars_so_far += single_f->NumChars(); } else { all_fit = false; break; } } if (all_fit) { i = 0; for (ListIter*> it(pieces); !it.Done(); it.Next(), ++i) { Tuple2* p = it.Value(); StackRoot _for(&p ); if (i != 0) { f->write(str16); } f->WriteRaw(p); } f->write(str17); } return all_fit; } void _PrettyPrinter::_PrintRecord(hnode::Record* node, format::ColorOutput* f, int indent) { BigStr* ind = nullptr; BigStr* prefix = nullptr; int prefix_len; bool all_fit; BigStr* name = nullptr; hnode_asdl::hnode_t* val = nullptr; BigStr* ind1 = nullptr; hnode_asdl::hnode_t* UP_val = nullptr; int tag; BigStr* name_str = nullptr; format::ColorOutput* single_f = nullptr; BigStr* s = nullptr; int num_chars; StackRoot _root0(&node); StackRoot _root1(&f); StackRoot _root2(&ind); StackRoot _root3(&prefix); StackRoot _root4(&name); StackRoot _root5(&val); StackRoot _root6(&ind1); StackRoot _root7(&UP_val); StackRoot _root8(&name_str); StackRoot _root9(&single_f); StackRoot _root10(&s); ind = str_repeat(str18, indent); if (node->abbrev) { prefix = str_concat(ind, node->left); f->write(prefix); if (len(node->node_type)) { f->PushColor(color_e::TypeName); f->write(node->node_type); f->PopColor(); f->write(str19); } prefix_len = ((len(prefix) + len(node->node_type)) + 1); all_fit = this->_PrintWrappedArray(node->unnamed_fields, prefix_len, f, indent); if (!all_fit) { f->write(str20); f->write(ind); } f->write(node->right); } else { f->write(str_concat(ind, node->left)); f->PushColor(color_e::TypeName); f->write(node->node_type); f->PopColor(); f->write(str21); for (ListIter it(node->fields); !it.Done(); it.Next()) { hnode_asdl::Field* field = it.Value(); StackRoot _for(&field ); name = field->name; val = field->val; ind1 = str_repeat(str22, (indent + INDENT)); UP_val = val; tag = val->tag(); if (tag == hnode_e::Array) { hnode::Array* val = static_cast(UP_val); name_str = StrFormat("%s%s: [", ind1, name); f->write(name_str); prefix_len = len(name_str); if (!this->_PrintWholeArray(val->children, prefix_len, f, indent)) { f->write(str24); for (ListIter it(val->children); !it.Done(); it.Next()) { hnode_asdl::hnode_t* child = it.Value(); StackRoot _for(&child ); this->PrintNode(child, f, ((indent + INDENT) + INDENT)); f->write(str25); } f->write(StrFormat("%s]", ind1)); } } else { name_str = StrFormat("%s%s: ", ind1, name); f->write(name_str); prefix_len = len(name_str); single_f = f->NewTempBuffer(); if (_TrySingleLine(val, single_f, (this->max_col - prefix_len))) { Tuple2 tup3 = single_f->GetRaw(); s = tup3.at0(); num_chars = tup3.at1(); f->WriteRaw((Alloc>(s, num_chars))); } else { f->write(str28); this->PrintNode(val, f, ((indent + INDENT) + INDENT)); } } f->write(str29); } f->write(str_concat(ind, node->right)); } } void _PrettyPrinter::PrintNode(hnode_asdl::hnode_t* node, format::ColorOutput* f, int indent) { BigStr* ind = nullptr; format::ColorOutput* single_f = nullptr; BigStr* s = nullptr; int num_chars; hnode_asdl::hnode_t* UP_node = nullptr; int tag; StackRoot _root0(&node); StackRoot _root1(&f); StackRoot _root2(&ind); StackRoot _root3(&single_f); StackRoot _root4(&s); StackRoot _root5(&UP_node); ind = str_repeat(str30, indent); single_f = f->NewTempBuffer(); single_f->write(ind); if (_TrySingleLine(node, single_f, (this->max_col - indent))) { Tuple2 tup4 = single_f->GetRaw(); s = tup4.at0(); num_chars = tup4.at1(); f->WriteRaw((Alloc>(s, num_chars))); return ; } UP_node = node; tag = node->tag(); if (tag == hnode_e::Leaf) { hnode::Leaf* node = static_cast(UP_node); f->PushColor(node->color); f->write(j8_lite::EncodeString(node->s, true)); f->PopColor(); } else { if (tag == hnode_e::External) { hnode::External* node = static_cast(UP_node); f->PushColor(color_e::External); // if not PYTHON { f->write(str31); } // endif MYCPP f->PopColor(); } else { if (tag == hnode_e::Record) { hnode::Record* node = static_cast(UP_node); this->_PrintRecord(node, f, indent); } else { if (tag == hnode_e::AlreadySeen) { hnode::AlreadySeen* node = static_cast(UP_node); f->write(StrFormat("...0x%s", mylib::hex_lower(node->heap_id))); } else { assert(0); // AssertionError } } } } } bool _TrySingleLineObj(hnode::Record* node, format::ColorOutput* f, int max_chars) { int i; StackRoot _root0(&node); StackRoot _root1(&f); f->write(node->left); if (node->abbrev) { if (len(node->node_type)) { f->PushColor(color_e::TypeName); f->write(node->node_type); f->PopColor(); f->write(str33); } i = 0; for (ListIter it(node->unnamed_fields); !it.Done(); it.Next(), ++i) { hnode_asdl::hnode_t* val = it.Value(); StackRoot _for(&val ); if (i != 0) { f->write(str34); } if (!_TrySingleLine(val, f, max_chars)) { return false; } } } else { f->PushColor(color_e::TypeName); f->write(node->node_type); f->PopColor(); for (ListIter it(node->fields); !it.Done(); it.Next()) { hnode_asdl::Field* field = it.Value(); StackRoot _for(&field ); f->write(StrFormat(" %s:", field->name)); if (!_TrySingleLine(field->val, f, max_chars)) { return false; } } } f->write(node->right); return true; } bool _TrySingleLine(hnode_asdl::hnode_t* node, format::ColorOutput* f, int max_chars) { hnode_asdl::hnode_t* UP_node = nullptr; int tag; int i; int num_chars_so_far; StackRoot _root0(&node); StackRoot _root1(&f); StackRoot _root2(&UP_node); UP_node = node; tag = node->tag(); if (tag == hnode_e::Leaf) { hnode::Leaf* node = static_cast(UP_node); f->PushColor(node->color); f->write(j8_lite::EncodeString(node->s, true)); f->PopColor(); } else { if (tag == hnode_e::External) { hnode::External* node = static_cast(UP_node); f->PushColor(color_e::External); // if not PYTHON { f->write(str36); } // endif MYCPP f->PopColor(); } else { if (tag == hnode_e::Array) { hnode::Array* node = static_cast(UP_node); f->write(str37); i = 0; for (ListIter it(node->children); !it.Done(); it.Next(), ++i) { hnode_asdl::hnode_t* item = it.Value(); StackRoot _for(&item ); if (i != 0) { f->write(str38); } if (!_TrySingleLine(item, f, max_chars)) { return false; } } f->write(str39); } else { if (tag == hnode_e::Record) { hnode::Record* node = static_cast(UP_node); return _TrySingleLineObj(node, f, max_chars); } else { if (tag == hnode_e::AlreadySeen) { hnode::AlreadySeen* node = static_cast(UP_node); f->write(StrFormat("...0x%s", mylib::hex_lower(node->heap_id))); } else { assert(0); // AssertionError } } } } } num_chars_so_far = f->NumChars(); if (num_chars_so_far > max_chars) { return false; } return true; } void PrintTree(hnode_asdl::hnode_t* node, format::ColorOutput* f) { format::_PrettyPrinter* pp = nullptr; StackRoot _root0(&node); StackRoot _root1(&f); StackRoot _root2(&pp); pp = Alloc<_PrettyPrinter>(100); pp->PrintNode(node, f, 0); } void PrintTree2(hnode_asdl::hnode_t* node, format::ColorOutput* f) { pretty_asdl::MeasuredDoc* doc = nullptr; pretty::PrettyPrinter* printer = nullptr; mylib::BufWriter* buf = nullptr; StackRoot _root0(&node); StackRoot _root1(&f); StackRoot _root2(&doc); StackRoot _root3(&printer); StackRoot _root4(&buf); doc = pretty::AsciiText(str41); printer = Alloc(20); buf = Alloc(); printer->PrintDoc(doc, buf); f->write(buf->getvalue()); f->write(str42); } } // define namespace format namespace j8_lite { // define BigStr* EncodeString(BigStr* s, bool unquoted_ok) { StackRoot _root0(&s); if ((unquoted_ok and fastfunc::CanOmitQuotes(s))) { return s; } return fastfunc::J8EncodeString(s, 1); } BigStr* YshEncodeString(BigStr* s) { StackRoot _root0(&s); return fastfunc::ShellEncodeString(s, 1); } BigStr* MaybeShellEncode(BigStr* s) { StackRoot _root0(&s); if (fastfunc::CanOmitQuotes(s)) { return s; } return fastfunc::ShellEncodeString(s, 0); } BigStr* ShellEncode(BigStr* s) { StackRoot _root0(&s); return fastfunc::ShellEncodeString(s, 0); } BigStr* YshEncode(BigStr* s, bool unquoted_ok) { StackRoot _root0(&s); if ((unquoted_ok and fastfunc::CanOmitQuotes(s))) { return s; } return fastfunc::ShellEncodeString(s, 1); } } // define namespace j8_lite namespace ansi { // define BigStr* RESET = str43; BigStr* BOLD = str44; BigStr* UNDERLINE = str45; BigStr* REVERSE = str46; BigStr* RED = str47; BigStr* GREEN = str48; BigStr* YELLOW = str49; BigStr* BLUE = str50; BigStr* MAGENTA = str51; BigStr* CYAN = str52; BigStr* WHITE = str53; } // define namespace ansi namespace pretty { // define using pretty_asdl::doc; using pretty_asdl::doc_e; using pretty_asdl::DocFragment; using pretty_asdl::Measure; using pretty_asdl::MeasuredDoc; using mylib::BufWriter; pretty_asdl::Measure* _EmptyMeasure() { return Alloc(0, -1); } pretty_asdl::Measure* _FlattenMeasure(pretty_asdl::Measure* measure) { StackRoot _root0(&measure); return Alloc(measure->flat, -1); } pretty_asdl::Measure* _ConcatMeasure(pretty_asdl::Measure* m1, pretty_asdl::Measure* m2) { StackRoot _root0(&m1); StackRoot _root1(&m2); if (m1->nonflat != -1) { return Alloc((m1->flat + m2->flat), m1->nonflat); } else { if (m2->nonflat != -1) { return Alloc((m1->flat + m2->flat), (m1->flat + m2->nonflat)); } else { return Alloc((m1->flat + m2->flat), -1); } } } int _SuffixLen(pretty_asdl::Measure* measure) { StackRoot _root0(&measure); if (measure->nonflat != -1) { return measure->nonflat; } else { return measure->flat; } } pretty_asdl::MeasuredDoc* AsciiText(BigStr* string) { StackRoot _root0(&string); return Alloc(Alloc(string), Alloc(len(string), -1)); } pretty_asdl::MeasuredDoc* _Break(BigStr* string) { StackRoot _root0(&string); return Alloc(Alloc(string), Alloc(len(string), 0)); } pretty_asdl::MeasuredDoc* _Indent(int indent, pretty_asdl::MeasuredDoc* mdoc) { StackRoot _root0(&mdoc); return Alloc(Alloc(indent, mdoc), mdoc->measure); } pretty_asdl::MeasuredDoc* _Concat(List* mdocs) { pretty_asdl::Measure* measure = nullptr; StackRoot _root0(&mdocs); StackRoot _root1(&measure); measure = _EmptyMeasure(); for (ListIter it(mdocs); !it.Done(); it.Next()) { pretty_asdl::MeasuredDoc* mdoc = it.Value(); StackRoot _for(&mdoc ); measure = _ConcatMeasure(measure, mdoc->measure); } return Alloc(Alloc(mdocs), measure); } pretty_asdl::MeasuredDoc* _Group(pretty_asdl::MeasuredDoc* mdoc) { StackRoot _root0(&mdoc); return Alloc(Alloc(mdoc), mdoc->measure); } pretty_asdl::MeasuredDoc* _IfFlat(pretty_asdl::MeasuredDoc* flat_mdoc, pretty_asdl::MeasuredDoc* nonflat_mdoc) { StackRoot _root0(&flat_mdoc); StackRoot _root1(&nonflat_mdoc); return Alloc(Alloc(flat_mdoc, nonflat_mdoc), Alloc(flat_mdoc->measure->flat, nonflat_mdoc->measure->nonflat)); } pretty_asdl::MeasuredDoc* _Flat(pretty_asdl::MeasuredDoc* mdoc) { StackRoot _root0(&mdoc); return Alloc(Alloc(mdoc), _FlattenMeasure(mdoc->measure)); } PrettyPrinter::PrettyPrinter(int max_width) { this->max_width = max_width; } bool PrettyPrinter::_Fits(int prefix_len, doc::Group* group, pretty_asdl::Measure* suffix_measure) { pretty_asdl::Measure* measure = nullptr; StackRoot _root0(&group); StackRoot _root1(&suffix_measure); StackRoot _root2(&measure); measure = _ConcatMeasure(_FlattenMeasure(group->mdoc->measure), suffix_measure); return (prefix_len + _SuffixLen(measure)) <= this->max_width; } void PrettyPrinter::PrintDoc(pretty_asdl::MeasuredDoc* document, mylib::BufWriter* buf) { int prefix_len; List* fragments = nullptr; pretty_asdl::DocFragment* frag = nullptr; doc::Text* text = nullptr; BigStr* break_str = nullptr; doc::Indent* indented = nullptr; doc::Concat* concat = nullptr; pretty_asdl::Measure* measure = nullptr; doc::Group* group = nullptr; bool flat; doc::IfFlat* if_flat = nullptr; pretty_asdl::MeasuredDoc* subdoc = nullptr; doc::Flat* flat_doc = nullptr; StackRoot _root0(&document); StackRoot _root1(&buf); StackRoot _root2(&fragments); StackRoot _root3(&frag); StackRoot _root4(&text); StackRoot _root5(&break_str); StackRoot _root6(&indented); StackRoot _root7(&concat); StackRoot _root8(&measure); StackRoot _root9(&group); StackRoot _root10(&if_flat); StackRoot _root11(&subdoc); StackRoot _root12(&flat_doc); prefix_len = 0; fragments = NewList(std::initializer_list{Alloc(_Group(document), 0, false, _EmptyMeasure())}); while (len(fragments) > 0) { frag = fragments->pop(); switch (frag->mdoc->doc->tag()) { case doc_e::Text: { text = static_cast(frag->mdoc->doc); buf->write(text->string); prefix_len += frag->mdoc->measure->flat; } break; case doc_e::Break: { if (frag->is_flat) { break_str = static_cast(frag->mdoc->doc)->string; buf->write(break_str); prefix_len += frag->mdoc->measure->flat; } else { buf->write(str54); buf->write_spaces(frag->indent); prefix_len = frag->indent; } } break; case doc_e::Indent: { indented = static_cast(frag->mdoc->doc); fragments->append(Alloc(indented->mdoc, (frag->indent + indented->indent), frag->is_flat, frag->measure)); } break; case doc_e::Concat: { concat = static_cast(frag->mdoc->doc); measure = frag->measure; for (ReverseListIter it(concat->mdocs); !it.Done(); it.Next()) { pretty_asdl::MeasuredDoc* mdoc = it.Value(); StackRoot _for(&mdoc ); fragments->append(Alloc(mdoc, frag->indent, frag->is_flat, measure)); measure = _ConcatMeasure(mdoc->measure, measure); } } break; case doc_e::Group: { group = static_cast(frag->mdoc->doc); flat = this->_Fits(prefix_len, group, frag->measure); fragments->append(Alloc(group->mdoc, frag->indent, flat, frag->measure)); } break; case doc_e::IfFlat: { if_flat = static_cast(frag->mdoc->doc); if (frag->is_flat) { subdoc = if_flat->flat_mdoc; } else { subdoc = if_flat->nonflat_mdoc; } fragments->append(Alloc(subdoc, frag->indent, frag->is_flat, frag->measure)); } break; case doc_e::Flat: { flat_doc = static_cast(frag->mdoc->doc); fragments->append(Alloc(flat_doc->mdoc, frag->indent, true, frag->measure)); } break; } } } } // define namespace pretty namespace parse { // define using expr_asdl::expr; using expr_asdl::expr_e; using expr_asdl::expr_t; using expr_asdl::tok_e; using expr_asdl::tok_t; namespace fmt = format; Lexer::Lexer(BigStr* s) { this->s = s; this->i = 0; this->n = len(s); } Tuple2 Lexer::Read() { BigStr* tok = nullptr; StackRoot _root0(&tok); if (this->i >= this->n) { return Tuple2(tok_e::Eof, str55); } tok = this->s->at(this->i); this->i += 1; if (tok->isdigit()) { return Tuple2(tok_e::Const, tok); } if (tok->isalpha()) { return Tuple2(tok_e::Var, tok); } if (str_contains(str56, tok)) { return Tuple2(tok_e::Op1, tok); } if (str_contains(str57, tok)) { return Tuple2(tok_e::Op2, tok); } if (str_contains(str58, tok)) { return Tuple2(tok_e::Paren, tok); } return Tuple2(tok_e::Invalid, tok); } void Lexer::_MethodCallingOtherMethod() { this->Read(); } ParseError::ParseError(BigStr* msg) { this->msg = msg; } Parser::Parser(parse::Lexer* lexer) { this->lexer = lexer; this->tok_type = tok_e::Eof; this->tok_val = str59; } void Parser::Next() { Tuple2 tup0 = this->lexer->Read(); this->tok_type = tup0.at0(); this->tok_val = tup0.at1(); } void Parser::Eat(BigStr* tok_val) { StackRoot _root0(&tok_val); if (!(str_equals(this->tok_val, tok_val))) { throw Alloc(str_concat(str60, tok_val)); } this->Next(); } expr_asdl::expr_t* Parser::ParseFactor() { expr::Var* n1 = nullptr; expr::Const* n2 = nullptr; expr_asdl::expr_t* n3 = nullptr; StackRoot _root0(&n1); StackRoot _root1(&n2); StackRoot _root2(&n3); if (this->tok_type == tok_e::Var) { n1 = Alloc(this->tok_val); this->Next(); return n1; } if (this->tok_type == tok_e::Const) { n2 = Alloc(to_int(this->tok_val)); this->Next(); return n2; } if (this->tok_type == tok_e::Paren) { this->Eat(str61); n3 = this->ParseExpr(); this->Eat(str62); return n3; } throw Alloc(str_concat(str63, this->tok_val)); } expr_asdl::expr_t* Parser::ParseTerm() { expr_asdl::expr_t* node = nullptr; BigStr* op = nullptr; expr_asdl::expr_t* n2 = nullptr; StackRoot _root0(&node); StackRoot _root1(&op); StackRoot _root2(&n2); node = this->ParseFactor(); while (this->tok_type == tok_e::Op2) { op = this->tok_val; this->Next(); n2 = this->ParseFactor(); node = Alloc(op, node, n2); } return node; } expr_asdl::expr_t* Parser::ParseExpr() { expr_asdl::expr_t* node = nullptr; BigStr* op = nullptr; expr_asdl::expr_t* n2 = nullptr; StackRoot _root0(&node); StackRoot _root1(&op); StackRoot _root2(&n2); node = this->ParseTerm(); while (this->tok_type == tok_e::Op1) { op = this->tok_val; this->Next(); n2 = this->ParseTerm(); node = Alloc(op, node, n2); } return node; } expr_asdl::expr_t* Parser::Parse() { this->Next(); return this->ParseExpr(); } void TestParse() { parse::Lexer* lex = nullptr; expr_asdl::tok_t tok_type; BigStr* tok_val = nullptr; List* CASES = nullptr; parse::Parser* p = nullptr; expr_asdl::expr_t* node = nullptr; hnode_asdl::hnode_t* htree = nullptr; format::AnsiOutput* ast_f = nullptr; expr_asdl::expr_t* UP_node = nullptr; StackRoot _root0(&lex); StackRoot _root1(&tok_val); StackRoot _root2(&CASES); StackRoot _root3(&p); StackRoot _root4(&node); StackRoot _root5(&htree); StackRoot _root6(&ast_f); StackRoot _root7(&UP_node); lex = Alloc(str64); while (true) { Tuple2 tup1 = lex->Read(); tok_type = tup1.at0(); tok_val = tup1.at1(); if (tok_type == tok_e::Eof) { break; } mylib::print_stderr(StrFormat("tok_val %s", tok_val)); } CASES = NewList(std::initializer_list{str66, str67, str68, str69, str70, str71, str72, str73, str74, str75, str76, str77, str78}); for (ListIter it(CASES); !it.Done(); it.Next()) { BigStr* expr_ = it.Value(); StackRoot _for(&expr_ ); lex = Alloc(expr_); p = Alloc(lex); mylib::print_stderr(str79); mylib::print_stderr(str80); mylib::print_stderr(StrFormat("%s =>", expr_)); node = nullptr; try { node = p->Parse(); } catch (ParseError* e) { mylib::print_stderr(StrFormat("Parse error: %s", e->msg)); continue; } htree = node->PrettyTree(); ast_f = Alloc(mylib::Stdout()); fmt::PrintTree(htree, ast_f); ast_f->write(str83); UP_node = node; switch (UP_node->tag()) { case expr_e::Const: { expr::Const* node = static_cast(UP_node); mylib::print_stderr(StrFormat("Const %d", node->i)); } break; case expr_e::Var: { expr::Var* node = static_cast(UP_node); mylib::print_stderr(StrFormat("Var %s", node->name)); } break; default: { mylib::print_stderr(str86); } } } } void TestCreateNull() { expr::Const* c = nullptr; expr::Var* v = nullptr; expr::Binary* b = nullptr; hnode_asdl::hnode_t* htree = nullptr; format::AnsiOutput* ast_f = nullptr; StackRoot _root0(&c); StackRoot _root1(&v); StackRoot _root2(&b); StackRoot _root3(&htree); StackRoot _root4(&ast_f); c = expr::Const::CreateNull(true); mylib::print_stderr(StrFormat("c.i %d", c->i)); v = expr::Var::CreateNull(true); mylib::print_stderr(StrFormat("v.name %r", v->name)); b = expr::Binary::CreateNull(true); mylib::print_stderr(StrFormat("b.op %r", b->op)); b->op = str90; b->left = c; b->right = v; htree = b->PrettyTree(); ast_f = Alloc(mylib::Stdout()); fmt::PrintTree(htree, ast_f); ast_f->write(str91); } void run_tests() { TestParse(); TestCreateNull(); } void run_benchmarks() { int n; int result; int i; parse::Lexer* lex = nullptr; parse::Parser* p = nullptr; expr_asdl::expr_t* tree = nullptr; StackRoot _root0(&lex); StackRoot _root1(&p); StackRoot _root2(&tree); n = 100000; result = 0; i = 0; while (i < n) { lex = Alloc(str92); p = Alloc(lex); tree = p->Parse(); i += 1; mylib::MaybeCollect(); } mylib::print_stderr(StrFormat("result = %d", result)); mylib::print_stderr(StrFormat("iterations = %d", n)); } } // define namespace parse namespace cgi { // define BigStr* escape(BigStr* s) { StackRoot _root0(&s); s = s->replace(str95, str96); s = s->replace(str97, str98); s = s->replace(str99, str100); return s; } } // define namespace cgi int main(int argc, char **argv) { gHeap.Init(); char* b = getenv("BENCHMARK"); if (b && strlen(b)) { // match Python's logic fprintf(stderr, "Benchmarking...\n"); parse::run_benchmarks(); } else { parse::run_tests(); } gHeap.CleanProcessExit(); }