{(*} (*------------------------------------------------------------------------------ Delphi Code formatter source code The Original Code is Converter.pas, released April 2000. The Initial Developer of the Original Code is Anthony Steele. Portions created by Anthony Steele are Copyright (C) 1999-2008 Anthony Steele. All Rights Reserved. Contributor(s): Anthony Steele. The contents of this file are subject to the Mozilla Public License Version 1.1 (the "License"). you may not use this file except in compliance with the License. You may obtain a copy of the License at http://www.mozilla.org/NPL/ Software distributed under the License is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY KIND, either express or implied. See the License for the specific language governing rights and limitations under the License. Alternatively, the contents of this file may be used under the terms of the GNU General Public License Version 2 or later (the "GPL") See http://www.gnu.org/licenses/gpl.html ------------------------------------------------------------------------------*) {*)} unit Converter; { 5 July 2004 Rewrote as a simpler sting->string converter. For file or ide, there will be wrapper classes not subclasses. Wrappers will also support the interface IConvert } {$I JcfGlobal.inc} interface uses { delphi } SysUtils, Controls, Forms, { local } ConvertTypes, ParseTreeNode, BuildTokenList, BuildParseTree, BaseVisitor; type TConverter = class(TObject) private { the strings for the in and out code } fsInputCode, fsOutputCode: String; fsFileName: String; { classes to lex and parse the source } fcTokeniser: TBuildTokenList; fcBuildParseTree: TBuildParseTree; { used for testing - just run 1 process } fcSingleProcess: TTreeNodeVisitorType; { state } fiTokenCount: Integer; fbConvertError: Boolean; fOnStatusMessage: TStatusMessageProc; { false for commandline UI - don't put up a parse fail dialog This could be in batch file on a server } fbGuiMessages: Boolean; {$IFNDEF COMMAND_LINE} leOldCursor: TCursor; {$ENDIF} function GetOnStatusMessage: TStatusMessageProc; procedure SetOnStatusMessage(const Value: TStatusMessageProc); procedure SendExceptionMessage(const pe: Exception); { call this to report the current state of the proceedings } procedure SendStatusMessage(const psUnit, psMessage: String; const peMessageType: TStatusMessageType; const piY, piX: Integer); procedure ShowParseTree; function GetRoot: TParseTreeNode; { this does the reformatting. Virtual method so can be overriden for testing } procedure ApplyProcesses; procedure ApplySingleProcess; public constructor Create; destructor Destroy; override; procedure Clear; procedure Convert; procedure ConvertPart(const piStartIndex, piEndIndex: Integer); procedure CollectOutput(const pcRoot: TParseTreeNode); property InputCode: String Read fsInputCode Write fsInputCode; property OutputCode: String Read fsOutputCode Write fsOutputCode; property FileName: String Read fsFileName Write fsFileName; property TokenCount: Integer Read fiTokenCount; property ConvertError: Boolean Read fbConvertError; property GuiMessages: Boolean Read fbGuiMessages Write fbGuiMessages; property Root: TParseTreeNode Read GetRoot; property OnStatusMessage: TStatusMessageProc Read GetOnStatusMessage Write SetOnStatusMessage; property SingleProcess: TTreeNodeVisitorType Read fcSingleProcess Write fcSingleProcess; end; implementation uses AllProcesses, fShowParseTree, JcfRegistrySettings, JcfSettings, JcfStringUtils, ParseError, PreProcessorParseTree, SourceToken, SourceTokenList, TreeWalker, VisitSetNesting, VisitSetXY; function StrInsert(const psSub, psMain: String; const piPos: Integer): String; begin Result := StrLeft(psMain, piPos - 1) + psSub + StrRestOf(psMain, piPos); end; constructor TConverter.Create; begin inherited; { owned objects } fcTokeniser := TBuildTokenList.Create; fcTokeniser.FileName := FileName; fcBuildParseTree := TBuildParseTree.Create; fcSingleProcess := nil; fbGuiMessages := True; // use Ui to show parse errors by default end; destructor TConverter.Destroy; begin FreeAndNil(fcTokeniser); FreeAndNil(fcBuildParseTree); inherited; end; procedure TConverter.Clear; begin fsInputCode := ''; fsOutputCode := ''; fcSingleProcess := nil; end; procedure TConverter.Convert; var lcTokenList: TSourceTokenList; begin fbConvertError := False; {$IFNDEF COMMAND_LINE} leOldCursor := Screen.Cursor; try { finally normal cursor } // this can take a long time for large files Screen.Cursor := crHourGlass; {$ENDIF} // turn text into tokens fcTokeniser.SourceCode := InputCode; fcTokeniser.FileName := FileName; lcTokenList := fcTokeniser.BuildTokenList; try { finally free the list } try { show exceptions } fiTokenCount := lcTokenList.Count; lcTokenList.SetXYPositions; // remove conditional compilation stuph if FormattingSettings.PreProcessor.Enabled then RemoveConditionalCompilation(lcTokenList); // make a parse tree from it fcBuildParseTree.TokenList := lcTokenList; fcBuildParseTree.BuildParseTree; except on E: Exception do begin fbConvertError := True; SendExceptionMessage(E); if GuiMessages and (GetRegSettings.ShowParseTreeOption = eShowOnError) then ShowParseTree; end; end; if fbConvertError then begin { if there was a parse error, the rest of the unit was not parsed there may still be tokens in the list Free them or face a small but annoying memory leak. } lcTokenList.Clear; end; // should not be any tokens left Assert(lcTokenList.Count = 0, 'Surplus tokens'); finally lcTokenList.Free; end; try if not fbConvertError then begin if (GetRegSettings.ShowParseTreeOption = eShowAlways) then ShowParseTree; // do the processes if Assigned(fcSingleProcess) then ApplySingleProcess else ApplyProcesses; // assemble the output string fsOutputCode := ''; CollectOutput(fcBuildParseTree.Root); end; fcBuildParseTree.Clear; except on E: Exception do begin fbConvertError := True; SendExceptionMessage(E); end; end; {$IFNDEF COMMAND_LINE} finally Screen.Cursor := leOldCursor; end; {$ENDIF} end; { this is what alters the code (in parse tree form) from source to output } procedure TConverter.ApplyProcesses; var lcProcess: TAllProcesses; begin lcProcess := TAllProcesses.Create; try lcProcess.OnMessage := SendStatusMessage; lcProcess.Execute(fcBuildParseTree.Root); finally lcProcess.Free; end; end; procedure TConverter.ApplySingleProcess; var lcProcess: TBaseTreeNodeVisitor; lcTreeWalker: TTreeWalker; begin lcTreeWalker := TTreeWalker.Create; try // apply a visit setXY first lcProcess := TVisitSetXY.Create; try lcTreeWalker.Visit(GetRoot, lcProcess); finally lcProcess.Free; end; // and set up nesting levels lcProcess := TVisitSetNestings.Create; try lcTreeWalker.Visit(GetRoot, lcProcess); finally lcProcess.Free; end; // then apply the process lcProcess := SingleProcess.Create; try lcTreeWalker.Visit(GetRoot, lcProcess); finally lcProcess.Free; end; finally lcTreeWalker.Free; end; end; function TConverter.GetRoot: TParseTreeNode; begin Result := fcBuildParseTree.Root; end; procedure TConverter.CollectOutput(const pcRoot: TParseTreeNode); var liLoop: Integer; begin Assert(pcRoot <> nil); // is it a leaf with source? if (pcRoot is TSourceToken) then begin fsOutputCode := fsOutputCode + TSourceToken(pcRoot).SourceCode; end else begin // recurse, write out all child nodes for liLoop := 0 to pcRoot.ChildNodeCount - 1 do begin CollectOutput(pcRoot.ChildNodes[liLoop]); end; end; end; function TConverter.GetOnStatusMessage: TStatusMessageProc; begin Result := fOnStatusMessage; end; procedure TConverter.SetOnStatusMessage(const Value: TStatusMessageProc); begin fOnStatusMessage := Value; end; procedure TConverter.SendExceptionMessage(const pe: Exception); var lsMessage: String; liX, liY: Integer; leParseError: TEParseError; leMessageType: TStatusMessageType; begin lsMessage := 'Exception ' + pe.ClassName + ' ' + pe.Message; if pe is TEParseError then begin leParseError := TEParseError(pe); lsMessage := lsMessage + NativeLineBreak + 'Near ' + leParseError.TokenMessage; liX := leParseError.XPosition; liY := leParseError.YPosition; leMessageType := mtParseError; end else begin liX := -1; liY := -1; leMessageType := mtException; end; SendStatusMessage('', lsMessage, leMessageType, liY, liX); end; procedure TConverter.SendStatusMessage(const psUnit, psMessage: String; const peMessageType: TStatusMessageType; const piY, piX: Integer); begin if Assigned(fOnStatusMessage) then fOnStatusMessage(psUnit, psMessage, peMessageType, piY, piX); end; procedure TConverter.ShowParseTree; begin {$IFNDEF COMMAND_LINE} // This is always called from a Cursor:=crHourGlass block. Restore old cursor. Screen.Cursor := leOldCursor; {$ENDIF} if fcBuildParseTree.Root <> nil then fShowParseTree.ShowParseTree(fcBuildParseTree.Root); end; procedure TConverter.ConvertPart(const piStartIndex, piEndIndex: Integer); const FORMAT_START = '{}'; FORMAT_END = '{}'; var liRealInputStart, liRealInputEnd: Integer; liOutputStart, liOutputEnd: Integer; lsNewOutput: String; begin Assert(piStartIndex >= 0); Assert(piEndIndex >= piStartIndex); Assert(piEndIndex <= Length(InputCode)); { round to nearest end of line } liRealInputStart := piStartIndex; liRealInputEnd := piEndIndex; { get to the start of the line } while (liRealInputStart > 1) and (not CharIsReturn(InputCode[liRealInputStart - 1])) do Dec(liRealInputStart); { get to the start of the next line } while (liRealInputEnd < Length(InputCode)) and (not CharIsReturn(InputCode[liRealInputEnd])) do Inc(liRealInputEnd); while (liRealInputEnd < Length(InputCode)) and (CharIsReturn(InputCode[liRealInputEnd])) do Inc(liRealInputEnd); { put markers into the input } fsInputCode := StrInsert(FORMAT_END, fsInputCode, liRealInputEnd); fsInputCode := StrInsert(FORMAT_START, fsInputCode, liRealInputStart); Convert; { locate the markers in the output, and replace before and after } liOutputStart := Pos(FORMAT_START, fsOutputCode) + Length(FORMAT_START); liOutputEnd := Pos(FORMAT_END, fsOutputCode); { splice } lsNewOutput := StrLeft(fsInputCode, liRealInputStart - 1); lsNewOutput := lsNewOutput + Copy(fsOutputCode, liOutputStart, (liOutputEnd - liOutputStart)); lsNewOutput := lsNewOutput + StrRestOf(fsInputCode, liRealInputEnd + Length(FORMAT_START) + Length(FORMAT_END)); fsOutputCode := lsNewOutput; end; end.