/* * Copyright 2019 faddenSoft * * Licensed under the Apache License, Version 2.0 (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.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ using System; using System.Collections.Generic; using System.ComponentModel; using System.Diagnostics; using System.IO; using System.Text; using Asm65; using CommonUtil; namespace SourceGen.AsmGen { #region IGenerator /// /// Generate source code compatible with the ACME assembler /// (https://sourceforge.net/projects/acme-crossass/). /// public class GenAcme : IGenerator { // The ACME docs say that ACME sources should use the ".a" extension. However, this // is already used for static libraries on UNIX systems, which means filename // completion in shells tends to ignore them, and it can cause confusion in // makefile rules. Since ".S" is pretty universal for assembly language sources, // I'm sticking with that. private const string ASM_FILE_SUFFIX = "_acme.S"; // must start with underscore // IGenerator public DisasmProject Project { get; private set; } // IGenerator public Formatter SourceFormatter { get; private set; } // IGenerator public AppSettings Settings { get; private set; } // IGenerator public AssemblerQuirks Quirks { get; private set; } // IGenerator public LabelLocalizer Localizer { get { return mLocalizer; } } // IGenerator public int StartOffset { get { return 0; } } /// /// Working directory, i.e. where we write our output file(s). /// private string mWorkDirectory; /// /// Influences whether labels are put on their own line. /// private GenCommon.LabelPlacement mLabelNewLine; /// /// Output column widths. /// private int[] mColumnWidths; /// /// Base filename. Typically the project file name without the ".dis65" extension. /// private string mFileNameBase; /// /// StringBuilder to use when composing a line. Held here to reduce allocations. /// private StringBuilder mLineBuilder = new StringBuilder(100); /// /// Label localization helper. /// private LabelLocalizer mLocalizer; /// /// Stream to send the output to. /// private StreamWriter mOutStream; /// /// Output mode; determines how ORG is handled. /// private enum OutputMode { Unknown = 0, Loadable = 1, Streamable = 2 } private OutputMode mOutputMode; /// /// Current pseudo-PC depth. 0 is the "real" PC. /// private int mPcDepth; private bool mFirstIsOpen; /// /// Holds detected version of configured assembler. /// private CommonUtil.Version mAsmVersion = CommonUtil.Version.NO_VERSION; // Version we're coded against. private static CommonUtil.Version V0_96_4 = new CommonUtil.Version(0, 96, 4); private static CommonUtil.Version V0_97 = new CommonUtil.Version(0, 97); // v0.97 started treating '\' in constants as an escape character. private bool mBackslashEscapes = true; // Pseudo-op string constants. private static PseudoOp.PseudoOpNames sDataOpNames = new PseudoOp.PseudoOpNames(new Dictionary { { "EquDirective", "=" }, //VarDirective { "ArStartDirective", "!pseudopc" }, { "ArEndDirective", "}" }, //RegWidthDirective // !al, !as, !rl, !rs //DataBankDirective { "DefineData1", "!byte" }, { "DefineData2", "!word" }, { "DefineData3", "!24" }, { "DefineData4", "!32" }, //DefineBigData2 //DefineBigData3 //DefineBigData4 { "Fill", "!fill" }, { "Dense", "!hex" }, { "Uninit", "!skip" }, //Junk { "Align", "!align" }, { "StrGeneric", "!text" }, // can use !xor for high ASCII //StrReverse //StrNullTerm //StrLen8 //StrLen16 //StrDci }); // IGenerator public void GetDefaultDisplayFormat(out PseudoOp.PseudoOpNames pseudoOps, out Formatter.FormatConfig formatConfig) { pseudoOps = sDataOpNames; formatConfig = new Formatter.FormatConfig(); SetFormatConfigValues(ref formatConfig); } // IGenerator public void Configure(DisasmProject project, string workDirectory, string fileNameBase, AssemblerVersion asmVersion, AppSettings settings) { Debug.Assert(project != null); Debug.Assert(!string.IsNullOrEmpty(workDirectory)); Debug.Assert(!string.IsNullOrEmpty(fileNameBase)); Project = project; Quirks = new AssemblerQuirks(); if (asmVersion != null) { mAsmVersion = asmVersion.Version; // Use the actual version. } else { mAsmVersion = V0_97; // No assembler installed, use default. } // ACME isn't a single-pass assembler, but the code that determines label widths // only runs in the first pass and doesn't get corrected. So unlike cc65, which // generates correct zero-page acceses once the label's value is known, ACME // uses 16-bit addressing to zero-page labels for backward references if there // are any forward references at all. The easy way to deal with this is to make // all zero-page label references have explicit widths. // // Example: // * = $1000 // jmp zero // !pseudopc $0000 { // zero nop // lda zero // rts // } Quirks.SinglePassAssembler = true; Quirks.SinglePassNoLabelCorrection = true; if (mAsmVersion < V0_97) { Quirks.BlockMoveArgsNoHash = true; mBackslashEscapes = false; } mWorkDirectory = workDirectory; mFileNameBase = fileNameBase; Settings = settings; mLabelNewLine = Settings.GetEnum(AppSettings.SRCGEN_LABEL_NEW_LINE, GenCommon.LabelPlacement.SplitIfTooLong); AssemblerConfig config = AssemblerConfig.GetConfig(settings, AssemblerInfo.Id.Acme); mColumnWidths = (int[])config.ColumnWidths.Clone(); // ACME wants the entire file to be loadable into a 64KB memory area. If the // initial address is too large, a file smaller than 64KB might overrun the bank // boundary and cause a failure. In that case we want to set the initial address // to zero and "stream" the rest. int firstAddr = project.AddrMap.OffsetToAddress(0); if (firstAddr == Address.NON_ADDR) { firstAddr = 0; } if (firstAddr + project.FileDataLength > 65536) { mOutputMode = OutputMode.Streamable; } else { mOutputMode = OutputMode.Loadable; } } /// /// Configures the assembler-specific format items. /// private void SetFormatConfigValues(ref Formatter.FormatConfig config) { config.mSuppressImpliedAcc = true; config.mOperandWrapLen = 64; config.mForceDirectOpcodeSuffix = "+1"; config.mForceAbsOpcodeSuffix = "+2"; config.mForceLongOpcodeSuffix = "+3"; config.mForceDirectOperandPrefix = string.Empty; config.mForceAbsOperandPrefix = string.Empty; config.mForceLongOperandPrefix = string.Empty; config.mLocalVariableLabelPrefix = "."; config.mEndOfLineCommentDelimiter = ";"; config.mFullLineCommentDelimiterBase = ";"; config.mBoxLineCommentDelimiter = ";"; config.mNonUniqueLabelPrefix = "@"; config.mCommaSeparatedDense = false; config.mExpressionMode = Formatter.FormatConfig.ExpressionMode.Common; Formatter.DelimiterSet charSet = new Formatter.DelimiterSet(); charSet.Set(CharEncoding.Encoding.Ascii, Formatter.SINGLE_QUOTE_DELIM); charSet.Set(CharEncoding.Encoding.HighAscii, new Formatter.DelimiterDef(string.Empty, '\'', '\'', " | $80")); config.mCharDelimiters = charSet; } // IGenerator public GenerationResults GenerateSource(BackgroundWorker worker) { List pathNames = new List(1); string fileName = mFileNameBase + ASM_FILE_SUFFIX; string pathName = Path.Combine(mWorkDirectory, fileName); pathNames.Add(pathName); Formatter.FormatConfig config = new Formatter.FormatConfig(); GenCommon.ConfigureFormatterFromSettings(Settings, ref config); SetFormatConfigValues(ref config); SourceFormatter = new Formatter(config); string msg = string.Format(Res.Strings.PROGRESS_GENERATING_FMT, pathName); worker.ReportProgress(0, msg); mLocalizer = new LabelLocalizer(Project); // While '.' labels are limited to the current zone, '@' labels are visible // between global labels. (This is poorly documented.) mLocalizer.LocalPrefix = "@"; mLocalizer.QuirkNoOpcodeMnemonics = true; mLocalizer.ReservedWords = new List() { "NOT" }; mLocalizer.Analyze(); mPcDepth = 0; mFirstIsOpen = true; // Use UTF-8 encoding, without a byte-order mark. using (StreamWriter sw = new StreamWriter(pathName, false, new UTF8Encoding(false))) { mOutStream = sw; if (Settings.GetBool(AppSettings.SRCGEN_ADD_IDENT_COMMENT, false)) { OutputLine(SourceFormatter.FullLineCommentDelimiter + string.Format(Res.Strings.GENERATED_FOR_VERSION_FMT, "acme", mAsmVersion, AsmAcme.OPTIONS)); } if (HasNonZeroBankCode()) { // don't try OutputLine(SourceFormatter.FullLineCommentDelimiter + "ACME can't handle 65816 code that lives outside bank zero"); int firstAddr = Project.AddrMap.OffsetToAddress(0); AddressMap.AddressRegion fakeRegion = new AddressMap.AddressRegion(0, Project.FileData.Length, firstAddr); OutputArDirective(new AddressMap.AddressChange(true, 0, firstAddr, fakeRegion, true)); OutputDenseHex(0, Project.FileData.Length, string.Empty, string.Empty); OutputArDirective(new AddressMap.AddressChange(false, 0, firstAddr, fakeRegion, true)); } else { GenCommon.Generate(this, sw, worker); } } mOutStream = null; return new GenerationResults(pathNames, string.Empty); } /// /// Determines whether the project has any code assembled outside bank zero. /// private bool HasNonZeroBankCode() { if (Project.CpuDef.HasAddr16) { // Not possible on this CPU. return false; } foreach (AddressMap.AddressMapEntry ent in Project.AddrMap) { if (ent.Address > 0xffff) { return true; } } return false; } // IGenerator public void OutputAsmConfig() { CpuDef cpuDef = Project.CpuDef; string cpuStr; if (cpuDef.Type == CpuDef.CpuType.Cpu65816) { cpuStr = "65816"; } else if (cpuDef.Type == CpuDef.CpuType.Cpu65C02) { cpuStr = "65c02"; } else if (cpuDef.Type == CpuDef.CpuType.CpuW65C02) { cpuStr = "w65c02"; } else if (cpuDef.Type == CpuDef.CpuType.Cpu6502 && cpuDef.HasUndocumented) { cpuStr = "6510"; } else { cpuStr = "6502"; } OutputLine(string.Empty, SourceFormatter.FormatPseudoOp("!cpu"), cpuStr, string.Empty); } // IGenerator public string ModifyOpcode(int offset, OpDef op) { if (op.IsUndocumented) { if (Project.CpuDef.Type == CpuDef.CpuType.Cpu65C02 || Project.CpuDef.Type == CpuDef.CpuType.CpuW65C02) { // none of the "LDD" stuff is handled return null; } if ((op.Mnemonic == OpName.ANC && op.Opcode != 0x0b) || (op.Mnemonic == OpName.JAM && op.Opcode != 0x02)) { // There are multiple opcodes that match the mnemonic. Output the // mnemonic for the first one and hex for the rest. return null; } else if (op.Mnemonic == OpName.NOP || op.Mnemonic == OpName.DOP || op.Mnemonic == OpName.TOP) { // the various undocumented no-ops aren't handled return null; } else if (op.Mnemonic == OpName.SBC) { // this is the alternate reference to SBC return null; } else if (op == OpDef.OpALR_Imm) { // ACME wants "ASR" instead for $4b return "asr"; } else if (op == OpDef.OpLAX_Imm) { // ACME spits out an error on $ab return null; } } if (op == OpDef.OpWDM_WDM || op == OpDef.OpBRK_StackInt) { // ACME doesn't like these to have an operand. Output as hex. return null; } return string.Empty; // indicate original is fine } // IGenerator public FormatDescriptor ModifyInstructionOperandFormat(int offset, FormatDescriptor dfd, int operand) { return dfd; } // IGenerator public void UpdateCharacterEncoding(FormatDescriptor dfd) { } // IGenerator public void GenerateShortSequence(int offset, int length, out string opcode, out string operand) { Debug.Assert(length >= 1 && length <= 4); // Use a comma-separated list of individual hex bytes. opcode = sDataOpNames.DefineData1; StringBuilder sb = new StringBuilder(length * 4); for (int i = 0; i < length; i++) { if (i != 0) { sb.Append(','); } sb.Append(SourceFormatter.FormatHexValue(Project.FileData[offset + i], 2)); } operand = sb.ToString(); } // IGenerator public void OutputDataOp(int offset) { Formatter formatter = SourceFormatter; byte[] data = Project.FileData; Anattrib attr = Project.GetAnattrib(offset); string labelStr = string.Empty; if (attr.Symbol != null) { labelStr = mLocalizer.ConvLabel(attr.Symbol.Label); } string commentStr = SourceFormatter.FormatEolComment(Project.Comments[offset]); string opcodeStr, operandStr; FormatDescriptor dfd = attr.DataDescriptor; Debug.Assert(dfd != null); int length = dfd.Length; Debug.Assert(length > 0); bool multiLine = false; switch (dfd.FormatType) { case FormatDescriptor.Type.Default: if (length != 1) { Debug.Assert(false); length = 1; } opcodeStr = sDataOpNames.DefineData1; int operand = RawData.GetWord(data, offset, length, false); operandStr = formatter.FormatHexValue(operand, length * 2); break; case FormatDescriptor.Type.NumericLE: opcodeStr = sDataOpNames.GetDefineData(length); operand = RawData.GetWord(data, offset, length, false); operandStr = PseudoOp.FormatNumericOperand(formatter, Project.SymbolTable, mLocalizer.LabelMap, dfd, operand, length, PseudoOp.FormatNumericOpFlags.OmitLabelPrefixSuffix); break; case FormatDescriptor.Type.NumericBE: opcodeStr = sDataOpNames.GetDefineBigData(length); if (string.IsNullOrEmpty(opcodeStr)) { // Nothing defined, output as comma-separated single-byte values. GenerateShortSequence(offset, length, out opcodeStr, out operandStr); } else { operand = RawData.GetWord(data, offset, length, true); operandStr = PseudoOp.FormatNumericOperand(formatter, Project.SymbolTable, mLocalizer.LabelMap, dfd, operand, length, PseudoOp.FormatNumericOpFlags.OmitLabelPrefixSuffix); } break; case FormatDescriptor.Type.Fill: opcodeStr = sDataOpNames.Fill; operandStr = length + "," + formatter.FormatHexValue(data[offset], 2); break; case FormatDescriptor.Type.Dense: multiLine = true; opcodeStr = operandStr = null; OutputDenseHex(offset, length, labelStr, commentStr); break; case FormatDescriptor.Type.Uninit: case FormatDescriptor.Type.Junk: bool canAlign = (dfd.FormatType == FormatDescriptor.Type.Junk); int fillVal = Helper.CheckRangeHoldsSingleValue(data, offset, length); if (canAlign && fillVal >= 0 && GenCommon.CheckJunkAlign(offset, dfd, Project.AddrMap)) { // !align ANDVALUE, EQUALVALUE [, FILLVALUE] opcodeStr = sDataOpNames.Align; int alignVal = 1 << FormatDescriptor.AlignmentToPower(dfd.FormatSubType); operandStr = (alignVal - 1).ToString() + ",0," + formatter.FormatHexValue(fillVal, 2); } else if (fillVal >= 0 && (length > 1 || fillVal == 0x00)) { // If multi-byte, or single byte and zero, treat same as Fill. opcodeStr = sDataOpNames.Fill; operandStr = length + "," + formatter.FormatHexValue(fillVal, 2); } else { // treat same as Dense multiLine = true; opcodeStr = operandStr = null; OutputDenseHex(offset, length, labelStr, commentStr); } break; case FormatDescriptor.Type.StringGeneric: case FormatDescriptor.Type.StringReverse: case FormatDescriptor.Type.StringNullTerm: case FormatDescriptor.Type.StringL8: case FormatDescriptor.Type.StringL16: case FormatDescriptor.Type.StringDci: multiLine = true; opcodeStr = operandStr = null; OutputString(offset, labelStr, commentStr); break; default: opcodeStr = "???"; operandStr = "***"; break; } if (!multiLine) { opcodeStr = formatter.FormatPseudoOp(opcodeStr); OutputLine(labelStr, opcodeStr, operandStr, commentStr); } } private void OutputDenseHex(int offset, int length, string labelStr, string commentStr) { Formatter formatter = SourceFormatter; byte[] data = Project.FileData; int maxPerLine = formatter.OperandWrapLen / formatter.CharsPerDenseByte; string opcodeStr = formatter.FormatPseudoOp(sDataOpNames.Dense); for (int i = 0; i < length; i += maxPerLine) { int subLen = length - i; if (subLen > maxPerLine) { subLen = maxPerLine; } string operandStr = formatter.FormatDenseHex(data, offset + i, subLen); OutputLine(labelStr, opcodeStr, operandStr, commentStr); labelStr = commentStr = string.Empty; } } /// /// Outputs formatted data in an unformatted way, because the code generator couldn't /// figure out how to do something better. /// private void OutputNoJoy(int offset, int length, string labelStr, string commentStr) { byte[] data = Project.FileData; Debug.Assert(length > 0); Debug.Assert(offset >= 0 && offset < data.Length); bool singleValue = true; byte val = data[offset]; for (int i = 1; i < length; i++) { if (data[offset + i] != val) { singleValue = false; break; } } if (singleValue && length > 1) { string opcodeStr = SourceFormatter.FormatPseudoOp(sDataOpNames.Fill); string operandStr = length + "," + SourceFormatter.FormatHexValue(val, 2); OutputLine(labelStr, opcodeStr, operandStr, commentStr); } else { OutputDenseHex(offset, length, labelStr, commentStr); } } // IGenerator public void OutputEquDirective(string name, string valueStr, string comment) { OutputLine(name, SourceFormatter.FormatPseudoOp(sDataOpNames.EquDirective), valueStr, SourceFormatter.FormatEolComment(comment)); } // IGenerator public void OutputLocalVariableTable(int offset, List newDefs, LocalVariableTable allDefs) { // We can do better here, but it requires knowing whether anything in "newDefs" // overwrote a previous entry. If everything is new, we don't need to start // a new zone, and can just output newDefs. (We don't need to start a new zone // on a "clear previous".) OutputLine(string.Empty, "!zone", "Z" + offset.ToString("x6"), string.Empty); for (int i = 0; i < allDefs.Count; i++) { DefSymbol defSym = allDefs[i]; string valueStr = PseudoOp.FormatNumericOperand(SourceFormatter, Project.SymbolTable, null, defSym.DataDescriptor, defSym.Value, 1, PseudoOp.FormatNumericOpFlags.OmitLabelPrefixSuffix); OutputEquDirective(SourceFormatter.FormatVariableLabel(defSym.Label), valueStr, defSym.Comment); } } // IGenerator public void OutputArDirective(CommonUtil.AddressMap.AddressChange change) { // This is similar in operation to the AsmTass64 implementation. See comments there. Debug.Assert(mPcDepth >= 0); int nextAddress = change.Address; if (nextAddress == Address.NON_ADDR) { // Start non-addressable regions at zero to ensure they don't overflow bank. nextAddress = 0; } if (change.IsStart) { if (change.Region.HasValidPreLabel) { string labelStr = mLocalizer.ConvLabel(change.Region.PreLabel); OutputLine(labelStr, string.Empty, string.Empty, string.Empty); } if (mPcDepth == 0 && mFirstIsOpen) { mPcDepth++; // Set the "real" PC for the first address change. If we're in "loadable" // mode, just set "*=". If we're in "streaming" mode, we set "*=" to zero // and then use a pseudo-PC. if (mOutputMode == OutputMode.Loadable) { OutputLine("*", "=", SourceFormatter.FormatHexValue(nextAddress, 4), string.Empty); return; } else { // set the real PC to address zero to ensure we get a full 64KB OutputLine("*", "=", SourceFormatter.FormatHexValue(0, 4), string.Empty); } } AddressMap.AddressRegion region = change.Region; string addrStr; if (region.HasValidIsRelative) { int diff = nextAddress - region.PreLabelAddress; string pfxStr; if (diff >= 0) { pfxStr = "*+"; } else { pfxStr = "*-"; diff = -diff; } addrStr = pfxStr + SourceFormatter.FormatHexValue(diff, 4); } else { addrStr = SourceFormatter.FormatHexValue(nextAddress, 4); } OutputLine(string.Empty, SourceFormatter.FormatPseudoOp(sDataOpNames.ArStartDirective), addrStr + " {", string.Empty); mPcDepth++; } else { mPcDepth--; if (mPcDepth > 0 || !mFirstIsOpen) { // close previous block OutputLine(string.Empty, SourceFormatter.FormatPseudoOp(sDataOpNames.ArEndDirective), string.Empty, string.Empty); //";" + SourceFormatter.FormatPseudoOp(sDataOpNames.ArStartDirective)); } else { // mark initial "*=" region as closed, but don't output anything mFirstIsOpen = false; } } } // IGenerator public void FlushArDirectives() { } // IGenerator public void OutputRegWidthDirective(int offset, int prevM, int prevX, int newM, int newX) { if (prevM != newM) { string mop = (newM == 0) ? "!al" : "!as"; OutputLine(string.Empty, SourceFormatter.FormatPseudoOp(mop), string.Empty, string.Empty); } if (prevX != newX) { string xop = (newX == 0) ? "!rl" : "!rs"; OutputLine(string.Empty, SourceFormatter.FormatPseudoOp(xop), string.Empty, string.Empty); } } // IGenerator public void OutputLine(string fullLine) { mOutStream.WriteLine(fullLine); } // IGenerator public void OutputLine(string label, string opcode, string operand, string comment) { // Break the line if the label is long and it's not a .EQ directive. if (!string.IsNullOrEmpty(label) && !string.IsNullOrEmpty(opcode) && !string.Equals(opcode, sDataOpNames.EquDirective, StringComparison.InvariantCultureIgnoreCase)) { if (mLabelNewLine == GenCommon.LabelPlacement.PreferSeparateLine || (mLabelNewLine == GenCommon.LabelPlacement.SplitIfTooLong && label.Length >= mColumnWidths[0])) { mOutStream.WriteLine(label); label = string.Empty; } } mLineBuilder.Clear(); TextUtil.AppendPaddedString(mLineBuilder, label, 0); TextUtil.AppendPaddedString(mLineBuilder, opcode, mColumnWidths[0]); TextUtil.AppendPaddedString(mLineBuilder, operand, mColumnWidths[0] + mColumnWidths[1]); TextUtil.AppendPaddedString(mLineBuilder, comment, mColumnWidths[0] + mColumnWidths[1] + mColumnWidths[2]); mOutStream.WriteLine(mLineBuilder.ToString()); } private void OutputString(int offset, string labelStr, string commentStr) { Formatter formatter = SourceFormatter; byte[] data = Project.FileData; Anattrib attr = Project.GetAnattrib(offset); FormatDescriptor dfd = attr.DataDescriptor; Debug.Assert(dfd != null); Debug.Assert(dfd.IsString); Debug.Assert(dfd.Length > 0); string opcodeStr; CharEncoding.Convert charConv; switch (dfd.FormatSubType) { case FormatDescriptor.SubType.Ascii: opcodeStr = sDataOpNames.StrGeneric; charConv = CharEncoding.ConvertAscii; break; case FormatDescriptor.SubType.HighAscii: opcodeStr = sDataOpNames.StrGeneric; charConv = CharEncoding.ConvertHighAscii; break; case FormatDescriptor.SubType.C64Petscii: opcodeStr = "!pet"; charConv = CharEncoding.ConvertC64Petscii; break; case FormatDescriptor.SubType.C64Screen: opcodeStr = "!scr"; charConv = CharEncoding.ConvertC64ScreenCode; break; default: Debug.Assert(false); OutputNoJoy(offset, dfd.Length, labelStr, commentStr); return; } int leadingBytes = 0; switch (dfd.FormatType) { case FormatDescriptor.Type.StringGeneric: case FormatDescriptor.Type.StringReverse: case FormatDescriptor.Type.StringNullTerm: case FormatDescriptor.Type.StringDci: // Last byte may be output as hex. break; case FormatDescriptor.Type.StringL8: // Length byte will be output as hex. leadingBytes = 1; break; case FormatDescriptor.Type.StringL16: // Length byte will be output as hex. leadingBytes = 2; break; default: Debug.Assert(false); return; } StringOpFormatter stropf = new StringOpFormatter(SourceFormatter, Formatter.DOUBLE_QUOTE_DELIM, StringOpFormatter.RawOutputStyle.CommaSep, charConv, mBackslashEscapes); stropf.FeedBytes(data, offset, dfd.Length, leadingBytes, StringOpFormatter.ReverseMode.Forward); if (dfd.FormatSubType == FormatDescriptor.SubType.HighAscii && stropf.HasEscapedText) { // Can't !xor the output, because while it works for string data it // also flips the high bits on the unprintable bytes we output as raw hex. // We'd need to tell the string formatter to flip the high bit on the byte. OutputNoJoy(offset, dfd.Length, labelStr, commentStr); return; } if (dfd.FormatSubType == FormatDescriptor.SubType.HighAscii) { OutputLine(string.Empty, "!xor", "$80 {", string.Empty); } foreach (string str in stropf.Lines) { OutputLine(labelStr, opcodeStr, str, commentStr); labelStr = commentStr = string.Empty; // only show on first } if (dfd.FormatSubType == FormatDescriptor.SubType.HighAscii) { OutputLine(string.Empty, "}", string.Empty, string.Empty); } } } #endregion IGenerator #region IAssembler /// /// Cross-assembler execution interface. /// public class AsmAcme : IAssembler { public const string OPTIONS = ""; // Paths from generator. private List mPathNames; // Directory to make current before executing assembler. private string mWorkDirectory; // IAssembler public void GetExeIdentifiers(out string humanName, out string exeName) { humanName = "ACME Assembler"; exeName = "acme"; } // IAssembler public AssemblerConfig GetDefaultConfig() { return new AssemblerConfig(string.Empty, new int[] { 8, 8, 11, 73 }); } // IAssembler public AssemblerVersion QueryVersion() { AssemblerConfig config = AssemblerConfig.GetConfig(AppSettings.Global, AssemblerInfo.Id.Acme); if (config == null || string.IsNullOrEmpty(config.ExecutablePath)) { return null; } ShellCommand cmd = new ShellCommand(config.ExecutablePath, "--version", Directory.GetCurrentDirectory(), null); cmd.Execute(); if (string.IsNullOrEmpty(cmd.Stdout)) { return null; } // Windows - Stdout: "This is ACME, release 0.96.4 ("Fenchurch"), 22 Dec 2017 ..." // Linux - Stderr: "This is ACME, release 0.96.4 ("Fenchurch"), 20 Apr 2019 ..." const string PREFIX = "release "; string str = cmd.Stdout; int start = str.IndexOf(PREFIX); int end = (start < 0) ? -1 : str.IndexOf(' ', start + PREFIX.Length + 1); if (start < 0 || end < 0 || start + PREFIX.Length >= end) { Debug.WriteLine("Couldn't find version in " + str); return null; } start += PREFIX.Length; string versionStr = str.Substring(start, end - start); CommonUtil.Version version = CommonUtil.Version.Parse(versionStr); if (!version.IsValid) { return null; } return new AssemblerVersion(versionStr, version); } // IAssembler public void Configure(GenerationResults results, string workDirectory) { // Clone pathNames, in case the caller decides to modify the original. mPathNames = CommonUtil.Container.CopyStringList(results.PathNames); mWorkDirectory = workDirectory; } // IAssembler public AssemblerResults RunAssembler(BackgroundWorker worker) { // Reduce input file to a partial path if possible. This is really just to make // what we display to the user a little easier to read. string pathName = mPathNames[0]; if (pathName.StartsWith(mWorkDirectory)) { pathName = pathName.Remove(0, mWorkDirectory.Length + 1); } else { // Unexpected, but shouldn't be a problem. Debug.WriteLine("NOTE: source file is not in work directory"); } AssemblerConfig config = AssemblerConfig.GetConfig(AppSettings.Global, AssemblerInfo.Id.Acme); if (string.IsNullOrEmpty(config.ExecutablePath)) { Debug.WriteLine("Assembler not configured"); return null; } worker.ReportProgress(0, Res.Strings.PROGRESS_ASSEMBLING); // Output file name is source file name with the ".a". string outFileName = pathName.Substring(0, pathName.Length - 2); // Wrap pathname in quotes in case it has spaces. // (Do we need to shell-escape quotes in the pathName?) ShellCommand cmd = new ShellCommand(config.ExecutablePath, OPTIONS + " -o \"" + outFileName + "\"" + " \"" + pathName + "\"" , mWorkDirectory, null); cmd.Execute(); // Can't really do anything with a "cancel" request. // Output filename is the input filename without the ".a". Since the filename // was generated by us we can be confident in the format. string outputFile = mPathNames[0].Substring(0, mPathNames[0].Length - 2); return new AssemblerResults(cmd.FullCommandLine, cmd.ExitCode, cmd.Stdout, cmd.Stderr, outputFile); } } #endregion IAssembler }