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Migrating from Sourceforge to Codeplex. Initial checkin starting with version 1.1.5.0 source code.

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Jordan Wages 2013-10-20 03:46:38 +00:00
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==========================================================================
Visual Studio Team System: Overview of Authoring and Running Tests
==========================================================================
This overview describes the features for authoring and running tests in
Visual Studio Team System and Visual Studio Team Edition for Software Testers.
Opening Tests
-------------
To open a test, open a test project or a test metadata file (a file with
extension .vsmdi) that contains the definition of the test. You can find
test projects and metadata files in Solution Explorer.
Viewing Tests
-------------
To see which tests are available to you, open the Test View window. Or,
if you have installed Team Edition for Software Testers, you can also open
the Test List Editor window to view tests.
To open the Test View window, click the Test menu, point to Windows, and
then click Test View. To open the Test List Editor window (if you have
installed Team Edition for Software Testers), click Test, point to Windows,
and then click Test List Editor.
Running Tests
-------------
You can run tests from the Test View window and the Test List Editor window.
See Viewing Tests to learn how to open these windows. To run one or more
tests displayed in the Test View window, first select the tests in that
window; to select multiple tests, hold either the Shift or CTRL key while
clicking tests. Then click the Run Tests button in the Test View window
toolbar.
If you have installed Visual Studio Team Edition for Software Testers, you can
also use the Test List Editor window to run tests. To run tests in Test List Editor,
select the check box next to each test that you want to run. Then click the
Run Tests button in the Test List Editor window toolbar.
Viewing Test Results
--------------------
When you run a test or a series of tests, the results of the test run will be
shown in the Test Results window. Each individual test in the run is shown on
a separate line so that you can see its status. The window contains an
embedded status bar in the top half of the window that provides you with
summary details of the complete test run.
To see more detailed results for a particular test result, double-click it in
the Test Results window. This opens a window that provides more information
about the particular test result, such as any specific error messages returned
by the test.
Changing the way that tests are run
-----------------------------------
Each time you run one or more tests, a collection of settings is used to
determine how those tests are run. These settings are contained in a “test
run configuration” file.
Here is a partial list of the changes you can make with a test run
configuration file:
- Change the naming scheme for each test run.
- Change the test controller that the tests are run on so that you can run
tests remotely.
- Gather code coverage data for the code being tested so that you can see
which lines of code are covered by your tests.
- Enable and disable test deployment.
- Specify additional files to deploy before tests are run.
- Select a different host, ASP.NET, for running ASP.NET unit tests.
- Select a different host, the smart device test host, for running smart device unit tests.
- Set various properties for the test agents that run your tests.
- Run custom scripts at the start and end of each test run so that you can
set up the test environment exactly as required each time tests are run.
- Set time limits for tests and test runs.
- Set the browser mix and the number of times to repeat Web tests in the
test run.
By default, a test run configuration file is created whenever you create a
new test project. You make changes to this file by double-clicking it in
Solution Explorer and then changing its settings. (Test run configuration
files have the extension .testrunconfig.)
A solution can contain multiple test run configuration files. Only one of
those files, known as the “Active” test run configuration file, is used to
determine the settings that are currently used for test runs. You select
the active test run configuration by clicking Select Active Test Run
Configuration on the Test menu.
-------------------------------------------------------------------------------
Test Types
----------
Using Visual Studio Team Edition for Software Testers, you can create a number
of different test types:
Unit test: Use a unit test to create a programmatic test in C++, Visual C# or
Visual Basic that exercises source code. A unit test calls the methods of a
class, passing suitable parameters, and verifies that the returned value is
what you expect.
There are three specialized variants of unit tests:
- Data-driven unit tests are created when you configure a unit test to be
called repeatedly for each row of a data source. The data from each row
is used by the unit test as input data.
- ASP.NET unit tests are unit tests that exercise code in an ASP.NET Web
application.
- Smart device unit tests are unit tests that are deployed to a smart device
or emulator and then executed by the smart device test host.
Web Test: Web tests consist of an ordered series of HTTP requests that you
record in a browser session using Microsoft Internet Explorer. You can have
the test report specific details about the pages or sites it requests, such
as whether a particular page contains a specified string.
Load Test: You use a load test to encapsulate non-manual tests, such as
unit, Web, and generic tests, and then run them simultaneously by using
virtual users. Running these tests under load generates test results,
including performance and other counters, in tables and in graphs.
Generic test: A generic test is an existing program wrapped to function as a
test in Visual Studio. The following are examples of tests or programs that
you can turn into generic tests:
- An existing test that uses process exit codes to communicate whether the
test passed or failed. 0 indicates passing and any other value indicates
a failure.
- A general program to obtain specific functionality during a test scenario.
- A test or program that uses a special XML file (called a “summary results
file”), to communicate detailed results.
Manual test: The manual test type is used when the test tasks are to be
completed by a test engineer as opposed to an automated script.
Ordered test: Use an ordered test to execute a set of tests in an order you
specify.
-------------------------------------------------------------------------------

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<RootNamespace>CSMICTests</RootNamespace>
<AssemblyName>CSMICTests</AssemblyName>
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<ApplicationRevision>0</ApplicationRevision>
<ApplicationVersion>1.0.0.%2a</ApplicationVersion>
<IsWebBootstrapper>false</IsWebBootstrapper>
<UseApplicationTrust>false</UseApplicationTrust>
<BootstrapperEnabled>true</BootstrapperEnabled>
<SccProjectName>SAK</SccProjectName>
<SccLocalPath>SAK</SccLocalPath>
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<PropertyGroup Condition=" '$(Configuration)|$(Platform)' == 'Debug|AnyCPU' ">
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<CodeAnalysisRuleSet>AllRules.ruleset</CodeAnalysisRuleSet>
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<PropertyGroup Condition=" '$(Configuration)|$(Platform)' == 'Release|AnyCPU' ">
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<DefineConstants>TRACE</DefineConstants>
<ErrorReport>prompt</ErrorReport>
<WarningLevel>4</WarningLevel>
<CodeAnalysisRuleSet>AllRules.ruleset</CodeAnalysisRuleSet>
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<ItemGroup>
<Reference Include="Microsoft.VisualStudio.QualityTools.UnitTestFramework, Version=10.0.0.0, Culture=neutral, PublicKeyToken=b03f5f7f11d50a3a, processorArchitecture=MSIL" />
<Reference Include="System" />
<Reference Include="System.Core">
<RequiredTargetFramework>3.5</RequiredTargetFramework>
</Reference>
<Reference Include="System.Data" />
<Reference Include="System.Data.DataSetExtensions">
<RequiredTargetFramework>3.5</RequiredTargetFramework>
</Reference>
<Reference Include="System.Xml" />
<Reference Include="System.Xml.Linq">
<RequiredTargetFramework>3.5</RequiredTargetFramework>
</Reference>
</ItemGroup>
<ItemGroup>
<Compile Include="InputInterpreterTest.cs" />
<Compile Include="Properties\AssemblyInfo.cs" />
</ItemGroup>
<ItemGroup>
<Content Include="AuthoringTests.txt" />
</ItemGroup>
<ItemGroup>
<ProjectReference Include="..\csmic\csmic.csproj">
<Project>{7BBA4BA2-E885-4D89-8710-F1A609616B7D}</Project>
<Name>csmic</Name>
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</ItemGroup>
<ItemGroup>
<Shadow Include="Test References\csmic.accessor" />
</ItemGroup>
<ItemGroup>
<BootstrapperPackage Include=".NETFramework,Version=v4.0">
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<ProductName>Microsoft .NET Framework 4 %28x86 and x64%29</ProductName>
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<ProductName>.NET Framework 3.5 SP1 Client Profile</ProductName>
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<BootstrapperPackage Include="Microsoft.Windows.Installer.3.1">
<Visible>False</Visible>
<ProductName>Windows Installer 3.1</ProductName>
<Install>true</Install>
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</ItemGroup>
<Import Project="$(MSBuildBinPath)\Microsoft.CSharp.targets" />
<!-- To modify your build process, add your task inside one of the targets below and uncomment it.
Other similar extension points exist, see Microsoft.Common.targets.
<Target Name="BeforeBuild">
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<Target Name="AfterBuild">
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using csmic;
using csmic.Extensions;
using System.Text;
using Microsoft.VisualStudio.TestTools.UnitTesting;
namespace CSMICTests
{
/// <summary>
///This is a test class for InputInterpreterTest and is intended
///to contain all InputInterpreterTest Unit Tests
///</summary>
[TestClass()]
public class InputInterpreterTest
{
private TestContext testContextInstance;
/// <summary>
///Gets or sets the test context which provides
///information about and functionality for the current test run.
///</summary>
public TestContext TestContext
{
get
{
return testContextInstance;
}
set
{
testContextInstance = value;
}
}
#region Additional test attributes
//
//You can use the following additional attributes as you write your tests:
//
//Use ClassInitialize to run code before running the first test in the class
//[ClassInitialize()]
//public static void MyClassInitialize(TestContext testContext)
//{
//}
//
//Use ClassCleanup to run code after all tests in a class have run
//[ClassCleanup()]
//public static void MyClassCleanup()
//{
//}
//
//Use TestInitialize to run code before running each test
//[TestInitialize()]
//public void MyTestInitialize()
//{
//}
//
//Use TestCleanup to run code after each test has run
//[TestCleanup()]
//public void MyTestCleanup()
//{
//}
//
#endregion
/// <summary>
///A test for Interpret
///</summary>
[TestMethod()]
public void InterpretTest()
{
InputInterpreter target = new InputInterpreter();
target.CodedFunctions.Add(CodedFunctionFactory.Create("addfive", 1, rf => rf[0] + 5));
//HighLoadTest(target, "+1");
//HighLoadTest(target, "+sin(1)");
//HighLoadTest(target, "+precision(0.123456789, 7)");
//HighLoadTest(target, "+2*(2 + 5)/tan(sin(4))");
//HighLoadTest(target, "+2*2/3-1.23456");
ExpressionDecimalTest(target, "2+2", 4);
ExpressionDecimalTest(target, "1 + 2 + 3 + 4 + 5 + 6 + 7 + 8 + 9 + 10", 55);
ExpressionDecimalTest(target, "4 + 2 / 1 - 3 * 2", 0);
ExpressionDecimalTest(target, "16*2 - 2*3", 26);
ExpressionDecimalTest(target, "7-6+3*2", 7);
ExpressionDecimalTest(target, "1/-2*-1", 0.5M);
ExpressionDecimalTest(target, "12 + 26 / -2 + 3", 2);
ExpressionDecimalTest(target, "0.02395/1000", 0.00002395M);
ExpressionDecimalTest(target, "0100010101b", 277);
ExpressionDecimalTest(target, "0xabcdef", 11259375);
ExpressionDecimalTest(target, "11111111b + 0xFF", 510);
ExpressionDecimalTest(target, "10011001b * 0x01bAc", 1083852);
ExpressionDecimalTest(target, "log(sin(((25*200) - 5000)^1943),2)", decimal.MinValue);
ExpressionDecimalTest(target, "log(cos(((25*200) - 5000)^1943),2)", 0);
ExpressionDecimalTest(target, "cos(2^3)", -0.145500033808614M);
ExpressionDecimalTest(target, "addfive(30)", 35);
ExpressionDecimalTest(target, "precision(1.23456789, 4)", 1.2346M);
ExpressionDecimalTest(target, "3000 * (log(1 + 3162, 2))", 34881.2335215522M);
ExpressionDecimalTest(target, "(((12)))", 12);
ExpressionOutputTest(target, "z := (3*x) - (2*y)", "(3*x)-(2*y)");
ExpressionOutputTest(target, "x :: 3", "3");
ExpressionOutputTest(target, "y :: 2", "2");
ExpressionOutputTest(target, "x", "3");
ExpressionOutputTest(target, "y", "2");
ExpressionOutputTest(target, "z", "5");
ExpressionOutputTest(target, "z + 2", "7");
ExpressionOutputTest(target, "y :: 3", "3");
ExpressionOutputTest(target, "z", "3");
ExpressionOutputTest(target, "arr -> [3,6,9,12]", "3,6,9,12");
ExpressionOutputTest(target, "arr[1]", "6");
ExpressionOutputTest(target, "arr[1+1]", "9");
ExpressionOutputTest(target, "arr[2+44]", "0");
ExpressionOutputTest(target, "log(sin(((25*200) - 5000)^1943),2)", "log(sin(((25*200) - 5000)^1943),2)".Interpret());
ExpressionOutputTest(target, "log(cos(((25*200) - 5000)^1943),2)", "log(cos(((25*200) - 5000)^1943),2)".Interpret());
}
[TestMethod]
public void AsyncTest()
{
InputInterpreter interpreter = new InputInterpreter();
interpreter.InterpretAsync("2 + 2", i =>
{
Assert.IsTrue(i.Output == "4");
});
}
[TestMethod]
public void ComputableTest()
{
InputInterpreter interpreter = new InputInterpreter();
interpreter.Interpret("1");
Assert.IsTrue(interpreter.AsComputable(c => c.Add(5)).Resolve().Decimal == 6);
Assert.IsTrue(interpreter.AsComputable(c => c.Subtract(5)).Resolve().Decimal == 1);
Assert.IsTrue(interpreter.AsComputable(c => c.Multiply(5)).Resolve().Decimal == 5);
Assert.IsTrue(interpreter.AsComputable(c => c.Divide(1)).Resolve().Decimal == 5);
Assert.IsTrue(interpreter.AsComputable(c => c.Mod(1)).Resolve().Decimal == 0);
Assert.IsTrue(interpreter.AsComputable(c => c.RaiseToPower(5)).Resolve().Decimal == 0);
interpreter.Interpret("1");
Assert.IsTrue(interpreter.ToComputable().Add(5).Resolve().Decimal == 6);
Assert.IsTrue(interpreter.ToComputable().Subtract(5).Resolve().Decimal == 1);
Assert.IsTrue(interpreter.ToComputable().Multiply(5).Resolve().Decimal == 5);
Assert.IsTrue(interpreter.ToComputable().Divide(1).Resolve().Decimal == 5);
Assert.IsTrue(interpreter.ToComputable().Mod(1).Resolve().Decimal == 0);
Assert.IsTrue(interpreter.ToComputable().RaiseToPower(5).Resolve().Decimal == 0);
interpreter.Interpret("1");
Assert.IsTrue(interpreter.AsComputable(c => c.Add(5)).ResolveTo(i => i.Decimal) == 6);
Assert.IsTrue(interpreter.AsComputable(c => c.Subtract(5)).ResolveTo(i => i.Int) == 1);
interpreter.Interpret("5");
int[] ia = new int[] { 1,2,3 };
var test = interpreter.AsComputable(computable => computable.ForAll(ia, sub => sub.RaiseToPower)).Resolve();
Assert.IsTrue(test.Output == "15625");
}
/// <summary>
/// Tests a value repeated 10,000 times and checks for an execution time less than 200 milliseconds.
/// </summary>
/// <param name="target">The input interpreter.</param>
/// <param name="value">The value to repeat and test.</param>
public void HighLoadTest(InputInterpreter target, string value)
{
StringBuilder builder = new StringBuilder();
string input = string.Empty;
System.TimeSpan baseTime = new System.TimeSpan();
for (int i = 0; i < 1000; i++)
{
builder.Append(value);
}
input = builder.ToString();
target.Interpret(input);
baseTime = target.LastExecutionTime;
builder = new StringBuilder();
for (int i = 0; i < 100000; i++)
{
builder.Append(value);
}
input = builder.ToString();
target.Interpret(input);
Assert.IsTrue(target.LastExecutionTime <= System.TimeSpan.FromTicks((baseTime.Ticks + 1 * 100) + 100), string.Format("{0} failed the high load test.", value));
}
/// <summary>
/// Tests a given expression for a decimal result.
/// </summary>
/// <param name="target">The input interpreter.</param>
/// <param name="input">The input to execute.</param>
/// <param name="expected">The expected value.</param>
public void ExpressionDecimalTest(InputInterpreter target, string input, decimal expected)
{
target.Interpret(input);
Assert.AreEqual(expected, target.Decimal, string.Format("{0} returned {1} but {2} was expected.", input, target.Decimal, expected));
}
/// <summary>
/// Tests a given expression for a string result.
/// </summary>
/// <param name="target">The input interpreter.</param>
/// <param name="input">The input to execute.</param>
/// <param name="expected">The expected value.</param>
public void ExpressionOutputTest(InputInterpreter target, string input, string expected)
{
target.Interpret(input);
Assert.AreEqual(expected, target.Output, string.Format("{0} returned {1} but {2} was expected.", input, target.Decimal, expected));
}
}
}

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using System.Reflection;
using System.Runtime.CompilerServices;
using System.Runtime.InteropServices;
// General Information about an assembly is controlled through the following
// set of attributes. Change these attribute values to modify the information
// associated with an assembly.
[assembly: AssemblyTitle("CSMICTests")]
[assembly: AssemblyDescription("")]
[assembly: AssemblyConfiguration("")]
[assembly: AssemblyCompany("")]
[assembly: AssemblyProduct("CSMICTests")]
[assembly: AssemblyCopyright("Copyright © 2010")]
[assembly: AssemblyTrademark("")]
[assembly: AssemblyCulture("")]
// Setting ComVisible to false makes the types in this assembly not visible
// to COM componenets. If you need to access a type in this assembly from
// COM, set the ComVisible attribute to true on that type.
[assembly: ComVisible(false)]
// The following GUID is for the ID of the typelib if this project is exposed to COM
[assembly: Guid("8e6bded0-27ba-4d6b-a785-988958ca4b10")]
// Version information for an assembly consists of the following four values:
//
// Major Version
// Minor Version
// Build Number
// Revision
//
// You can specify all the values or you can default the Revision and Build Numbers
// by using the '*' as shown below:
[assembly: AssemblyVersion("1.0.0.0")]
[assembly: AssemblyFileVersion("1.0.0.0")]

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csmic.dll
Desktop

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<?xml version="1.0" encoding="utf-8"?>
<Project DefaultTargets="Build" xmlns="http://schemas.microsoft.com/developer/msbuild/2003" ToolsVersion="4.0">
<PropertyGroup>
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assemblies to include from solution and project documentation
sources -->
<Configuration Condition=" '$(Configuration)' == '' ">Debug</Configuration>
<Platform Condition=" '$(Platform)' == '' ">AnyCPU</Platform>
<SchemaVersion>2.0</SchemaVersion>
<ProjectGuid>{b60970b9-771a-4ebb-9978-89f55163888f}</ProjectGuid>
<SHFBSchemaVersion>1.9.5.0</SHFBSchemaVersion>
<!-- AssemblyName, Name, and RootNamespace are not used by SHFB but Visual
Studio adds them anyway -->
<AssemblyName>HelpFile</AssemblyName>
<RootNamespace>HelpFile</RootNamespace>
<Name>HelpFile</Name>
<!-- SHFB properties -->
<OutputPath>.\Help\</OutputPath>
<HtmlHelpName>csmic_help</HtmlHelpName>
<Language>en-US</Language>
<HelpFileFormat>HtmlHelp1, Website</HelpFileFormat>
<IndentHtml>False</IndentHtml>
<FrameworkVersion>.NET Framework 4.0</FrameworkVersion>
<KeepLogFile>True</KeepLogFile>
<DisableCodeBlockComponent>False</DisableCodeBlockComponent>
<CppCommentsFixup>False</CppCommentsFixup>
<CleanIntermediates>True</CleanIntermediates>
<SyntaxFilters>Standard</SyntaxFilters>
<SdkLinkTarget>Blank</SdkLinkTarget>
<RootNamespaceTitle>csmic</RootNamespaceTitle>
<RootNamespaceContainer>True</RootNamespaceContainer>
<PresentationStyle>VS2010</PresentationStyle>
<Preliminary>False</Preliminary>
<NamingMethod>Guid</NamingMethod>
<HelpTitle>CS-MIC - C Sharp Math Input Control</HelpTitle>
<FooterText>Please visit the &amp;lt%3ba href=&amp;quot%3bhttp://cs-mic.com&amp;quot%3b&amp;gt%3bofficial site&amp;lt%3b/a&amp;gt%3b for more information.</FooterText>
<FeedbackEMailLinkText>Please feel free to provide feedback!</FeedbackEMailLinkText>
<FeedbackEMailAddress>jordan%40jordanwages.com</FeedbackEMailAddress>
<CopyrightText>Copyright 2012</CopyrightText>
<ContentPlacement>AboveNamespaces</ContentPlacement>
<WebsiteSdkLinkType>Msdn</WebsiteSdkLinkType>
<HtmlSdkLinkType>Msdn</HtmlSdkLinkType>
<IncludeFavorites>True</IncludeFavorites>
<BinaryTOC>True</BinaryTOC>
<ProjectSummary>CS-MIC is a .NET library written in C# designed to give developers easy access to expression parsing. For many developers, there is no need to involve complicated settings and formats. With few exposed methods and objects, CS-MIC makes basic expression solving as simple as possible with as little logic required from developers as possible. In fact, one can pull a value with only one line of code.</ProjectSummary>
<VisibleItems>Attributes, ExplicitInterfaceImplementations, InheritedMembers, InheritedFrameworkMembers, Internals, Protected, SealedProtected</VisibleItems>
<DocumentationSources>
<DocumentationSource sourceFile="..\csmic\bin\Release\csmic.dll" />
<DocumentationSource sourceFile="..\csmic\bin\Release\csmic.xml" />
</DocumentationSources>
<ApiFilter />
<ComponentConfigurations />
<HelpAttributes />
<NamespaceSummaries />
<PlugInConfigurations />
<BuildLogFile />
<HtmlHelp1xCompilerPath />
<HtmlHelp2xCompilerPath />
<SandcastlePath />
<WorkingPath />
<SccProjectName>SAK</SccProjectName>
<SccProvider>SAK</SccProvider>
<SccAuxPath>SAK</SccAuxPath>
<SccLocalPath>SAK</SccLocalPath>
</PropertyGroup>
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order for Visual Studio to perform the build. The others are optional
common platform types that may appear. -->
<PropertyGroup Condition=" '$(Configuration)|$(Platform)' == 'Debug|AnyCPU' ">
</PropertyGroup>
<PropertyGroup Condition=" '$(Configuration)|$(Platform)' == 'Release|AnyCPU' ">
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<PropertyGroup Condition=" '$(Configuration)|$(Platform)' == 'Debug|x86' ">
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<PropertyGroup Condition=" '$(Configuration)|$(Platform)' == 'Release|x86' ">
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<PropertyGroup Condition=" '$(Configuration)|$(Platform)' == 'Debug|x64' ">
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<PropertyGroup Condition=" '$(Configuration)|$(Platform)' == 'Debug|Win32' ">
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<PropertyGroup Condition=" '$(Configuration)|$(Platform)' == 'Release|Win32' ">
</PropertyGroup>
<!-- Import the SHFB build targets -->
<Import Project="$(SHFBROOT)\SandcastleHelpFileBuilder.targets" />
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54
CS-MIC/csmic/csmic.sln Normal file
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Microsoft Visual Studio Solution File, Format Version 12.00
# Visual Studio 2012
Project("{FAE04EC0-301F-11D3-BF4B-00C04F79EFBC}") = "csmic", "csmic\csmic.csproj", "{7BBA4BA2-E885-4D89-8710-F1A609616B7D}"
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Global
GlobalSection(TeamFoundationVersionControl) = preSolution
SccNumberOfProjects = 4
SccEnterpriseProvider = {4CA58AB2-18FA-4F8D-95D4-32DDF27D184C}
SccTeamFoundationServer = https://tfs.codeplex.com/tfs/tfs35
SccLocalPath0 = .
SccProjectUniqueName1 = csmic\\csmic.csproj
SccProjectName1 = csmic
SccLocalPath1 = csmic
SccProjectUniqueName2 = CSMICTests\\CSMICTests.csproj
SccProjectName2 = CSMICTests
SccLocalPath2 = CSMICTests
SccProjectUniqueName3 = HelpFile\\HelpFile.shfbproj
SccProjectName3 = HelpFile
SccLocalPath3 = HelpFile
EndGlobalSection
GlobalSection(TestCaseManagementSettings) = postSolution
CategoryFile = csmic8.vsmdi
EndGlobalSection
GlobalSection(SolutionConfigurationPlatforms) = preSolution
Debug|Any CPU = Debug|Any CPU
Release|Any CPU = Release|Any CPU
EndGlobalSection
GlobalSection(ProjectConfigurationPlatforms) = postSolution
{7BBA4BA2-E885-4D89-8710-F1A609616B7D}.Debug|Any CPU.ActiveCfg = Debug|Any CPU
{7BBA4BA2-E885-4D89-8710-F1A609616B7D}.Debug|Any CPU.Build.0 = Debug|Any CPU
{7BBA4BA2-E885-4D89-8710-F1A609616B7D}.Release|Any CPU.ActiveCfg = Release|Any CPU
{7BBA4BA2-E885-4D89-8710-F1A609616B7D}.Release|Any CPU.Build.0 = Release|Any CPU
{C03AD9DF-630F-4C88-A9D4-8B4B450CCB54}.Debug|Any CPU.ActiveCfg = Debug|Any CPU
{C03AD9DF-630F-4C88-A9D4-8B4B450CCB54}.Debug|Any CPU.Build.0 = Debug|Any CPU
{C03AD9DF-630F-4C88-A9D4-8B4B450CCB54}.Release|Any CPU.ActiveCfg = Release|Any CPU
{C03AD9DF-630F-4C88-A9D4-8B4B450CCB54}.Release|Any CPU.Build.0 = Release|Any CPU
{B60970B9-771A-4EBB-9978-89F55163888F}.Debug|Any CPU.ActiveCfg = Debug|Any CPU
{B60970B9-771A-4EBB-9978-89F55163888F}.Debug|Any CPU.Build.0 = Debug|Any CPU
{B60970B9-771A-4EBB-9978-89F55163888F}.Release|Any CPU.ActiveCfg = Release|Any CPU
{B60970B9-771A-4EBB-9978-89F55163888F}.Release|Any CPU.Build.0 = Release|Any CPU
EndGlobalSection
GlobalSection(SolutionProperties) = preSolution
HideSolutionNode = FALSE
EndGlobalSection
GlobalSection(SubversionScc) = preSolution
Svn-Managed = True
Manager = AnkhSVN - Subversion Support for Visual Studio
EndGlobalSection
EndGlobal

10
CS-MIC/csmic/csmic.vssscc Normal file
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@ -0,0 +1,10 @@
""
{
"FILE_VERSION" = "9237"
"ENLISTMENT_CHOICE" = "NEVER"
"PROJECT_FILE_RELATIVE_PATH" = ""
"NUMBER_OF_EXCLUDED_FILES" = "0"
"ORIGINAL_PROJECT_FILE_PATH" = ""
"NUMBER_OF_NESTED_PROJECTS" = "0"
"SOURCE_CONTROL_SETTINGS_PROVIDER" = "PROJECT"
}

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@ -0,0 +1,24 @@
using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;
namespace csmic
{
/// <summary> Coded function factory. </summary>
/// <remarks>
/// This class generates new coded functions dynamically.
/// </remarks>
public static class CodedFunctionFactory
{
/// <summary> Creates a new ICodedFunction interface object that implements the dynamic method described. </summary>
/// <param name="functionName"> Name of the function. </param>
/// <param name="numExpectedArguments"> Number of expected arguments. </param>
/// <param name="methodBody"> The method body. </param>
/// <returns> An ICodedFunction interface object. </returns>
public static ICodedFunction Create(string functionName, int numExpectedArguments, Func<decimal[], decimal> methodBody)
{
return new GenericCodedFunction(functionName, numExpectedArguments, methodBody);
}
}
}

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using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;
namespace csmic.CodedFunctions
{
/// <summary>
/// A coded implementation of the absolute value function.
/// </summary>
class CF_Abs : ICodedFunction
{
#region ICodedFunction Members
/// <summary>
/// Expects 1 argument.
/// </summary>
public int NumExpectedArguments
{
get { return 1; }
}
/// <summary>
/// The name of the function.
/// </summary>
public string FunctionName
{
get { return "abs"; }
}
/// <summary>
/// Executes a code block.
/// </summary>
/// <param name="args">The arguments used in the code block.</param>
/// <returns>The absolute value of the argument.</returns>
public decimal Execute(params decimal[] args)
{
decimal output = 0;
if (args.Length == this.NumExpectedArguments)
{
decimal input = args[0];
output = Math.Abs(input);
}
return output;
}
#endregion
}
}

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using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;
namespace csmic.CodedFunctions
{
/// <summary>
/// A coded implementation of the cosine function.
/// </summary>
class CF_Cos : ICodedFunction
{
#region ICodedFunction Members
/// <summary>
/// Expects 1 argument.
/// </summary>
public int NumExpectedArguments
{
get { return 1; }
}
/// <summary>
/// The name of the function.
/// </summary>
public string FunctionName
{
get { return "cos"; }
}
/// <summary>
/// Executes a code block.
/// </summary>
/// <param name="args">The arguments used in the code block.</param>
/// <returns>The cosine of the argument.</returns>
public decimal Execute(params decimal[] args)
{
decimal output = 0;
if (args.Length == this.NumExpectedArguments)
{
decimal input = args[0];
output = (decimal)Math.Cos((double)input);
}
return output;
}
#endregion
}
}

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using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;
namespace csmic.CodedFunctions
{
/// <summary>
/// A coded implementation of the exponential function based on the constant e.
/// </summary>
class CF_Exp : ICodedFunction
{
#region ICodedFunction Members
/// <summary>
/// Expects 1 argument.
/// </summary>
public int NumExpectedArguments
{
get { return 1; }
}
/// <summary>
/// The name of the function.
/// </summary>
public string FunctionName
{
get { return "exp"; }
}
/// <summary>
/// Executes a code block.
/// </summary>
/// <param name="args">The arguments used in the code block.</param>
/// <returns>The constant e raised to the power of the argument.</returns>
public decimal Execute(params decimal[] args)
{
decimal output = 0;
if (args.Length == this.NumExpectedArguments)
{
decimal input = args[0];
output = (decimal)Math.Exp((double)input);
}
return output;
}
#endregion
}
}

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using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;
namespace csmic.CodedFunctions
{
/// <summary>
/// A coded implementation of the log function.
/// </summary>
class CF_Log : ICodedFunction
{
#region ICodedFunction Members
/// <summary>
/// Expects 2 arguments.
/// </summary>
public int NumExpectedArguments
{
get { return 2; }
}
/// <summary>
/// The name of the function.
/// </summary>
public string FunctionName
{
get { return "log"; }
}
/// <summary>
/// Executes a code block.
/// </summary>
/// <param name="args">The arguments used in the code block.</param>
/// <returns>The log of the first argument to the base of the second argument.</returns>
public decimal Execute(params decimal[] args)
{
decimal output = 0;
if (args.Length == this.NumExpectedArguments)
{
decimal input = args[0];
decimal logBase = args[1];
try
{
output = (decimal)Math.Log((double)input, (double)logBase);
}
catch
{
output = decimal.MinValue;
}
}
return output;
}
#endregion
}
}

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using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;
namespace csmic.CodedFunctions
{
/// <summary>
/// A coded implementation of a precision function.
/// </summary>
class CF_Precision : ICodedFunction
{
#region ICodedFunction Members
/// <summary>
/// Expects 2 arguments.
/// </summary>
public int NumExpectedArguments
{
get { return 2; }
}
/// <summary>
/// The name of the function.
/// </summary>
public string FunctionName
{
get { return "precision"; }
}
/// <summary>
/// Executes a code block.
/// </summary>
/// <param name="args">The arguments used in the code block.</param>
/// <returns>The first argument to the precision of the argument.</returns>
public decimal Execute(params decimal[] args)
{
decimal output = 0;
if (args.Length == this.NumExpectedArguments)
{
decimal input = args[0];
decimal precision = args[1];
output = (decimal)Math.Round(input, (int)precision);
}
return output;
}
#endregion
}
}

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using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;
namespace csmic.CodedFunctions
{
/// <summary>
/// A coded implementation of a rounded function.
/// </summary>
class CF_Round : ICodedFunction
{
#region ICodedFunction Members
/// <summary>
/// Expects 1 argument.
/// </summary>
public int NumExpectedArguments
{
get { return 1; }
}
/// <summary>
/// The name of the function.
/// </summary>
public string FunctionName
{
get { return "round"; }
}
/// <summary>
/// Executes a code block.
/// </summary>
/// <param name="args">The arguments used in the code block.</param>
/// <returns>The rounded argument.</returns>
public decimal Execute(params decimal[] args)
{
decimal output = 0;
if (args.Length == this.NumExpectedArguments)
{
decimal input = args[0];
output = Math.Round(input);
}
return output;
}
#endregion
}
}

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using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;
namespace csmic.CodedFunctions
{
/// <summary>
/// A coded implementation of the sine function.
/// </summary>
class CF_Sin : ICodedFunction
{
#region ICodedFunction Members
/// <summary>
/// Expects 1 argument.
/// </summary>
public int NumExpectedArguments
{
get { return 1; }
}
/// <summary>
/// The name of the function.
/// </summary>
public string FunctionName
{
get { return "sin"; }
}
/// <summary>
/// Executes a code block.
/// </summary>
/// <param name="args">The arguments used in the code block.</param>
/// <returns>The sine of the argument.</returns>
public decimal Execute(params decimal[] args)
{
decimal output = 0;
if (args.Length == this.NumExpectedArguments)
{
decimal input = args[0];
output = (decimal)Math.Sin((double)input);
}
return output;
}
#endregion
}
}

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using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;
namespace csmic.CodedFunctions
{
/// <summary>
/// A coded implementation of the squre root function.
/// </summary>
class CF_Sqrt : ICodedFunction
{
#region ICodedFunction Members
/// <summary>
/// Expects 1 argument.
/// </summary>
public int NumExpectedArguments
{
get { return 1; }
}
/// <summary>
/// The name of the function.
/// </summary>
public string FunctionName
{
get { return "sqrt"; }
}
/// <summary>
/// Executes a code block.
/// </summary>
/// <param name="args">The arguments used in the code block.</param>
/// <returns>The square root of the argument.</returns>
public decimal Execute(params decimal[] args)
{
decimal output = 0;
if (args.Length == this.NumExpectedArguments)
{
decimal input = args[0];
output = (decimal)Math.Sqrt((double)input);
}
return output;
}
#endregion
}
}

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using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;
namespace csmic.CodedFunctions
{
/// <summary>
/// A coded implementation of the tangent function.
/// </summary>
class CF_Tan : ICodedFunction
{
#region ICodedFunction Members
/// <summary>
/// Expects 1 argument.
/// </summary>
public int NumExpectedArguments
{
get { return 1; }
}
/// <summary>
/// The name of the function.
/// </summary>
public string FunctionName
{
get { return "tan"; }
}
/// <summary>
/// Executes a code block.
/// </summary>
/// <param name="args">The arguments used in the code block.</param>
/// <returns>The tangent of the argument.</returns>
public decimal Execute(params decimal[] args)
{
decimal output = 0;
if (args.Length == this.NumExpectedArguments)
{
decimal input = args[0];
output = (decimal)Math.Tan((double)input);
}
return output;
}
#endregion
}
}

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using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;
namespace csmic.ComputableEngine
{
/// <summary> Computable class. </summary>
public sealed class Computable
{
#region Members
/// <summary> The expression to be built.</summary>
private string expression;
/// <summary> The interpreter to act as a base.</summary>
private InputInterpreter interpreter;
#region Constants
/// <summary> The add symbol.</summary>
private const string ADD = "+";
/// <summary> The substract symbol.</summary>
private const string SUBSTRACT = "-";
/// <summary> The divide symbol.</summary>
private const string DIVIDE = "/";
/// <summary> The multiply symbol.</summary>
private const string MULTIPLY = "*";
/// <summary> The modifier symbol.</summary>
private const string MOD = "%";
/// <summary> The power symbol.</summary>
private const string POWER = "^";
#endregion
#endregion
#region Properties
/// <summary> Gets the expression. </summary>
/// <value> The expression. </value>
internal string Expression
{
get
{
return this.expression;
}
}
#endregion
#region Constructor
/// <summary> Creates a Computable instance. </summary>
/// <param name="expression"> The expression. </param>
/// <param name="interpreter"> The interpreter. </param>
internal Computable(string expression, InputInterpreter interpreter)
{
this.expression = expression;
this.interpreter = interpreter;
}
#endregion
#region Methods
/// <summary> Resolves the computable as an input interpreter having calculated the input. </summary>
/// <returns> The computable as an input interpreter. </returns>
public InputInterpreter Resolve()
{
this.interpreter.Interpret(this.Expression);
return this.interpreter;
}
/// <summary> Resolve the computer to a type <typeparamref name="T"/>. </summary>
/// <typeparam name="T"> Generic type parameter. </typeparam>
/// <param name="selector"> The selector function. </param>
/// <returns> . </returns>
public T ResolveTo<T>(Func<InputInterpreter, T> selector)
{
return selector(this.Resolve());
}
/// <summary> Form the operation given the operation constant and an argument. </summary>
/// <param name="operation"> The operation constant. </param>
/// <param name="argument"> The argument. </param>
/// <returns> A string with the given operation appended. </returns>
private string FormOperation(string operation, object argument)
{
return string.Format("({0} {1} {2})", this.Expression, operation, argument);
}
/// <summary> Form the function <paramref name="name"/> with the current expression as the first argument, followed by <paramref name="arguments"/>. </summary>
/// <param name="name"> The name of the function. </param>
/// <param name="arguments"> The arguments. </param>
/// <returns> . </returns>
private string FormFunction(string name, object[] arguments)
{
return string.Format("{0}({1})", name, string.Join(",", this.Expression, arguments));
}
/// <summary> Adds addend. </summary>
/// <param name="addend"> The decimal to add. </param>
/// <returns> A computable class after the addition. </returns>
public Computable Add(decimal addend)
{
this.expression = FormOperation(ADD, addend);
return this;
}
/// <summary> Subtracts the subtrahend. </summary>
/// <param name="subtrahend"> The subtrahend. </param>
/// <returns> A computable class after the subtraction. </returns>
public Computable Subtract(decimal subtrahend)
{
this.expression = FormOperation(SUBSTRACT, subtrahend);
return this;
}
/// <summary> Multiplies the multiplicand. </summary>
/// <param name="multiplicand"> The multiplicand. </param>
/// <returns> A computable class after the mulitplication. </returns>
public Computable Multiply(decimal multiplicand)
{
this.expression = FormOperation(MULTIPLY, multiplicand);
return this;
}
/// <summary> Divides the divisor. </summary>
/// <param name="divisor"> The divisor. </param>
/// <returns> A computable class after the divison. </returns>
public Computable Divide(decimal divisor)
{
this.expression = FormOperation(DIVIDE, divisor);
return this;
}
/// <summary> Mods using a given divisor. </summary>
/// <param name="divisor"> The divisor. </param>
/// <returns> A computable class after the mod. </returns>
public Computable Mod(decimal divisor)
{
this.expression = FormOperation(MOD, divisor);
return this;
}
/// <summary> Raises to power of the given integer value. </summary>
/// <param name="power"> The power. </param>
/// <returns> A computable class after the power operation. </returns>
public Computable RaiseToPower(int power)
{
this.expression = FormOperation(POWER, power);
return this;
}
/// <summary> Applies the function <paramref name="name"/> with the current expression as the first argument, followed by <paramref name="arguments"/>. </summary>
/// <param name="name"> The name of the function. </param>
/// <param name="arguments"> The arguments. </param>
/// <returns> A computable class after the function is applied. </returns>
public Computable ApplyFunction(string name, object[] arguments)
{
this.expression = FormFunction(name, arguments);
return this;
}
/// <summary> Executes a command for all items in a collection. </summary>
/// <typeparam name="T"> Generic type parameter. </typeparam>
/// <param name="items"> The items of type <typeparamref name="T"/>. </param>
/// <param name="action"> The action belonging to type <see cref="Computable"/>. </param>
/// <returns> . </returns>
public Computable ForAll<T>(ICollection<T> items, Func<Computable, Func<T, Computable>> action)
{
foreach (T item in items)
{
action(this)(item);
}
return this;
}
#endregion
}
}

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using System;
using System.Collections.Generic;
using System.Collections.Concurrent;
using System.Linq;
using System.Text;
namespace csmic.Extensions
{
/// <summary> CS-MIC extension methods. </summary>
public static class CSMICExtension
{
#region String
/// <summary> A string extension method that interprets as input the string that calls it. </summary>
/// <param name="input"> The input to act on. </param>
/// <returns> The output from the interpretation of the string. </returns>
public static string Interpret(this string input)
{
InputInterpreter interpreter = new InputInterpreter();
interpreter.Interpret(input);
return interpreter.Output;
}
/// <summary> A string extension method that executes as macro operation. </summary>
/// <param name="script"> The script to act on. </param>
/// <returns> The final output of the script. </returns>
public static string RunAsMacro(this string script)
{
MacroBuilder macro = new MacroBuilder(script, new InputInterpreter());
return macro.FinalOutput;
}
#endregion
#region IEnumerable<string>
/// <summary>
/// A string extension method that interprets as input the string that calls it.
/// </summary>
/// <param name="collection"> The collection to act on. </param>
/// <returns> The output from the interpretation of the string. </returns>
public static IEnumerable<string> Interpret(this IEnumerable<string> collection)
{
List<string> computed = new List<string>();
InputInterpreter interpreter = new InputInterpreter();
foreach (string input in collection)
{
interpreter.Interpret(input);
computed.Add(interpreter.Output);
}
return computed;
}
/// <summary>
/// A string extension method that interprets as input the string that calls it.
/// </summary>
/// <param name="collection"> The collection to act on. </param>
/// <param name="action"> The action. </param>
/// <returns> The output from the interpretation of the string. </returns>
public static IEnumerable<string> Interpret(this IEnumerable<string> collection, Action<InputInterpreter> action)
{
List<string> computed = new List<string>();
InputInterpreter interpreter = new InputInterpreter();
foreach (string input in collection)
{
interpreter.Interpret(input);
computed.Add(interpreter.Output);
action(interpreter);
}
return computed;
}
/// <summary> Enumerates input in this collection, returning a selection on the interpreter. </summary>
/// <typeparam name="T"> Generic type parameter. </typeparam>
/// <param name="collection"> The collection to act on. </param>
/// <param name="selection"> The selection. </param>
/// <returns>
/// An enumerator that allows foreach to be used to process interpret&lt; t&gt; in this
/// collection.
/// </returns>
public static IEnumerable<T> Interpret<T>(this IEnumerable<string> collection, Func<InputInterpreter, T> selection)
{
List<T> computed = new List<T>();
InputInterpreter interpreter = new InputInterpreter();
foreach (string input in collection)
{
interpreter.Interpret(input);
computed.Add(selection(interpreter));
}
return computed;
}
/// <summary> A string extension method that executes as macro operation. </summary>
/// <param name="collection"> The collection to act on. </param>
/// <returns> The final output of the script. </returns>
public static MacroBuilder RunAsMacro(this IEnumerable<string> collection)
{
return new MacroBuilder(string.Join(Environment.NewLine, collection.ToArray()), new InputInterpreter());
}
#endregion
#region IEnumerable<string> In Parallel
/// <summary> Enumerates input in parallel in this collection. </summary>
/// <param name="collection"> The collection to act on. </param>
/// <returns>
/// An enumerator that allows foreach to be used to process interpret in parallel in this
/// collection.
/// </returns>
public static IEnumerable<InputInterpreter> InterpretInParallel(this IEnumerable<string> collection)
{
ConcurrentBag<InputInterpreter> bag = new ConcurrentBag<InputInterpreter>();
collection.AsParallel().ForAll(input =>
{
InputInterpreter interpreter = new InputInterpreter();
interpreter.Interpret(input);
bag.Add(interpreter);
});
return bag;
}
/// <summary> Enumerates input in parallel this collection, returning a selection on the interpreter. </summary>
/// <typeparam name="T"> Generic type parameter. </typeparam>
/// <param name="collection"> The collection to act on. </param>
/// <param name="selection"> The selection. </param>
/// <returns>
/// An enumerator that allows foreach to be used to process interpret in parallel&lt; t&gt; in
/// this collection.
/// </returns>
public static IEnumerable<T> InterpretInParallel<T>(this IEnumerable<string> collection, Func<InputInterpreter, T> selection)
{
ConcurrentBag<T> bag = new ConcurrentBag<T>();
collection.AsParallel().ForAll(input =>
{
InputInterpreter interpreter = new InputInterpreter();
interpreter.Interpret(input);
bag.Add(selection(interpreter));
});
return bag;
}
#endregion
#region ParallelQuery<string>
/// <summary>
/// A string extension method that interprets as input the strings that calls it in parallel.
/// </summary>
/// <param name="collection"> The collection to act on. </param>
/// <returns> The output from the interpretation of the string. </returns>
public static IEnumerable<InputInterpreter> Interpret(this ParallelQuery<string> collection)
{
ConcurrentBag<InputInterpreter> bag = new ConcurrentBag<InputInterpreter>();
collection.ForAll(input =>
{
InputInterpreter interpreter = new InputInterpreter();
interpreter.Interpret(input);
bag.Add(interpreter);
});
return bag;
}
#endregion
}
}

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using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;
namespace csmic
{
/// <summary>
/// A generically coded implementation of the ICodedFunction interface.
/// </summary>
internal class GenericCodedFunction : ICodedFunction
{
#region Members
/// <summary> Number of expected arguments. </summary>
private int numExpectedArguments;
/// <summary> Name of the function. </summary>
private string functionName;
/// <summary> The method body. </summary>
private Func<decimal[], decimal> methodBody;
#endregion
#region Constructor
/// <summary> Constructor. </summary>
/// <param name="functionName"> Name of the function. </param>
/// <param name="NumExpectedArguments"> Number of expected arguments. </param>
/// <param name="methodBody"> The method body. </param>
internal GenericCodedFunction(string functionName, int numExpectedArguments, Func<decimal[], decimal> methodBody)
{
this.functionName = functionName;
this.numExpectedArguments = numExpectedArguments;
this.methodBody = methodBody;
}
#endregion
#region ICodedFunction Members
/// <summary> Gets the number of expected arguments. </summary>
/// <value> The total number of expected arguments. </value>
public int NumExpectedArguments
{
get
{
return this.numExpectedArguments;
}
}
/// <summary> Gets the name of the function. </summary>
/// <value> The name of the function. </value>
public string FunctionName
{
get
{
return this.functionName;
}
}
/// <summary> Executes a code block that computes the value of the function. </summary>
/// <param name="args"> A variable-length parameters list containing arguments. </param>
/// <returns> The decimal value computed by the function. </returns>
public decimal Execute(params decimal[] args)
{
if (this.methodBody != null)
{
return this.methodBody(args);
}
throw new MissingMethodException(this.GetType().Name, this.functionName);
}
#endregion
}
}

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using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;
namespace csmic
{
/// <summary>
/// Implements a function that is coded in the .Net environment.
/// </summary>
/// <remarks>This interface is required to implement a method or function
/// that can be used by the CS-MIC inputInterpreter. It is worth noting that the
/// function's name will be the text that is used in the inputInterpreter as the
/// executable text.</remarks>
public interface ICodedFunction
{
#region Properties
/// <summary>
/// Gets the number of expected arguments.
/// </summary>
int NumExpectedArguments { get; }
/// <summary>
/// Gets the name of the function.
/// </summary>
/// <remarks>The input inputInterpreter will use this function name as
/// executable text, expecting an opening and closing parenthesis following
/// it.</remarks>
string FunctionName { get; }
#endregion
#region Methods
/// <summary>
/// Executes a code block that computes the value of the function.
/// </summary>
/// <param name="args">An array of arguments passed to the function.</param>
/// <returns>The decimal value computed by the function.</returns>
/// <remarks>Any code block is valid. Error handling must be done by the
/// developer, as the inputInterpreter cannot determine if there is an error.</remarks>
/// <example>
/// This example shows how to implement the sine function through the interface's
/// Execute() function.
/// <code>
/// public decimal Execute(params decimal[] args)
///{
/// //Set up an output variable.
/// decimal output = 0;
///
/// //Check to see if the number or arguments recieved
/// //is equal to the number of arguments expected.
/// if (args.Length == this.NumExpectedArguments)
/// {
/// //Grab the argument and set a local variable for clarity.
/// decimal input = args[0];
///
/// //Set the output as a sine of the input.
/// output = (decimal)Math.Sin((double)input);
/// }
///
/// //Return the output. The function will return the sine if the arguments
/// //matched what was expected, and will return 0 otherwise. Returning 0 on
/// //errors is the standard in CS-MIC.
/// return output;
///}
///</code>
///</example>
decimal Execute(params decimal[] args);
#endregion
}
}

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using System;
using System.Collections.Generic;
using System.Text;
using System.Linq;
using System.Text.RegularExpressions;
using System.IO;
using System.Threading;
using csmic.CodedFunctions;
using csmic.Interpreter;
using csmic.ComputableEngine;
using System.Runtime.Remoting.Messaging;
// namespace: csmic
//
// summary: .
namespace csmic
{
/// <summary>
/// An interpreter object that reads user input and evaluates the code.
/// </summary>
/// <remarks>The interpreter does not support exceptions by design. Instead, invalid
/// calculations, parameters, etc. will result in a result of zero.
/// <code>
/// InputInterpreter interpreter = new InputInterpreter();
/// interpreter.Interpret("1/0"); // The result will be 0, not an exception.
/// </code>
/// </remarks>
public class InputInterpreter
{
#region Members
/// <summary>
/// The output generated.
/// </summary>
private string output;
/// <summary>
/// The variables assigned.
/// </summary>
internal Dictionary<string, Variable> variables;
/// <summary>
/// The time for execution.
/// </summary>
private TimeSpan executionTime;
/// <summary>
/// The verbose message of the calculation.
/// </summary>
private string message;
/// <summary>
/// The list of coded functions that can be executed.
/// </summary>
private List<ICodedFunction> codedFunctions;
/// <summary>
/// The list of user defined functions that can be executed.
/// </summary>
private List<InterpretedFunction> interpretedFunctions;
/// <summary>
/// The private calculated value.
/// </summary>
private decimal calculatedValue;
#endregion
#region Constructor
/// <summary>
/// Creates a new InputInterpreter.
/// </summary>
public InputInterpreter()
{
this.output = string.Empty;
this.variables = new Dictionary<string, Variable>();
this.executionTime = new TimeSpan();
this.codedFunctions = new List<ICodedFunction>();
this.interpretedFunctions = new List<InterpretedFunction>();
LoadDefaultCodedFunctions();
}
/// <summary>
/// Creates a new InputInterpreter from an original.
/// </summary>
/// <param name="original">The orginal input interpreter to copy.</param>
public InputInterpreter(InputInterpreter original)
{
this.output = original.output;
this.variables = original.variables;
this.executionTime = original.executionTime;
this.codedFunctions = original.codedFunctions;
this.interpretedFunctions = original.interpretedFunctions;
}
#endregion
#region Properties
/// <summary>
/// Gets the message that represents the InputInterpreters output.
/// </summary>
public string Output
{
get
{
return this.output;
}
}
/// <summary>
/// Gets the verbose message that is generated with a calculation.
/// </summary>
public string Message
{
get
{
return this.message;
}
}
/// <summary>
/// Gets the value of the output as a decimal.
/// </summary>
public decimal Decimal
{
get
{
return this.calculatedValue;
}
}
/// <summary>
/// Gets the value of the output cast as an int.
/// </summary>
public int Int
{
get
{
return (int)decimal.Round(this.calculatedValue);
}
}
/// <summary>
/// Gets the value of the output cast as a float.
/// </summary>
public float Float
{
get
{
return (float)this.calculatedValue;
}
}
/// <summary>
/// Gets the value of the output cast as a double.
/// </summary>
public double Double
{
get
{
return (double)this.calculatedValue;
}
}
/// <summary>
/// Gets the value (cast as a long) converted to its binary equivalent.
/// </summary>
public string Binary
{
get
{
return Convert.ToString((long)this.calculatedValue, 2).PadLeft(64, '0');
}
}
/// <summary>
/// Gets the execution time of the last calculation.
/// </summary>
public TimeSpan LastExecutionTime
{
get
{
return this.executionTime;
}
}
/// <summary>
/// Gets or sets a list of coded functions that the interpreter supports.
/// </summary>
public List<ICodedFunction> CodedFunctions
{
get
{
return this.codedFunctions;
}
set
{
this.codedFunctions = value;
}
}
/// <summary>
/// Gets or sets a list of user generated interpreted functions that the interpreter supports.
/// </summary>
/// <value> The interpreted functions. </value>
public List<InterpretedFunction> InterpretedFunctions
{
get
{
return this.interpretedFunctions;
}
set
{
this.interpretedFunctions = value;
}
}
/// <summary> Gets the variables. </summary>
/// <value> The variables. </value>
public Dictionary<string, Variable> Variables
{
get
{
return this.variables;
}
set
{
this.variables = value;
}
}
#endregion
#region Public Methods
/// <summary>
/// Interprets and executes given input.
/// </summary>
/// <param name="input">The input to interpret and execute.</param>
public void Interpret(string input)
{
if (string.IsNullOrEmpty(input))
{
return;
}
DateTime timeStart = DateTime.Now;
this.message = string.Empty;
UTF8Encoding encoder = new UTF8Encoding();
Parser p = new Parser(new Scanner(new MemoryStream(encoder.GetBytes(input))));
p.Interpreter = this;
try
{
p.Parse();
this.calculatedValue = p.CalculatedValue;
if (p.errors.count > 0)
{
ProduceOutput(this.calculatedValue, p.errors.builder.ToString());
}
}
catch (Exception e)
{
this.calculatedValue = 0;
ProduceOutput(this.calculatedValue, e.Message);
}
DateTime timeEnd = DateTime.Now;
this.executionTime = timeEnd - timeStart;
}
/// <summary>
/// Computes an expression and returns the result as a decimal.
/// </summary>
/// <param name="expression">The expression to be calculated.</param>
/// <returns>The value that was computed.</returns>
public decimal ComputeExpression(string expression)
{
this.Interpret(expression);
return this.calculatedValue;
}
/// <summary>
/// Assigns a decimal value to a variable.
/// </summary>
/// <param name="name">The name of the variable.</param>
/// <param name="value">The value of the variable.</param>
/// <returns>True if the variable was set, false otherwise.</returns>
internal bool Assign(string name, decimal value)
{
Variable v = new Variable();
v.Type = VariableType.Decimal;
v.Value = value;
if (!this.variables.ContainsKey(name))
{
this.variables.Add(name, v);
}
else
{
this.variables[name] = v;
}
return true;
}
/// <summary>
/// Assigns a decimal value to a variable.
/// </summary>
/// <param name="name">The name of the variable.</param>
/// <param name="expression">The expression of the variable.</param>
/// <returns>True if the variable was set, false otherwise.</returns>
internal bool Assign(string name, string expression)
{
Variable v = new Variable();
v.Type = VariableType.Equation;
v.Value = expression;
if (!this.variables.ContainsKey(name))
{
this.variables.Add(name, v);
}
else
{
this.variables[name] = v;
}
return true;
}
/// <summary>
/// Assigns a decimal value to a variable.
/// </summary>
/// <param name="name">The name of the variable.</param>
/// <param name="values">The values of the variable.</param>
/// <returns>True if the variable was set, false otherwise.</returns>
internal bool Assign(string name, decimal[] values)
{
Variable v = new Variable();
v.Type = VariableType.Array;
v.Value = values;
if (!this.variables.ContainsKey(name))
{
this.variables.Add(name, v);
}
else
{
this.variables[name] = v;
}
return true;
}
/// <summary>
/// Executes a function stored in the interpreter.
/// </summary>
/// <param name="name">The name of the function to execute.</param>
/// <param name="args">The arguments to pass to the function.</param>
/// <returns>The value computed from the function execution.</returns>
internal decimal ExecuteFunction(string name, decimal[] args)
{
foreach (ICodedFunction codedFunction in this.codedFunctions)
{
if (codedFunction.FunctionName == name)
{
return codedFunction.Execute(args);
}
}
foreach (InterpretedFunction interpretedFunction in this.interpretedFunctions)
{
if (interpretedFunction.Name == name)
{
string answer = interpretedFunction.Compute(args);
decimal parsed = 0;
if (decimal.TryParse(answer, out parsed))
{
return parsed;
}
}
}
return 0;
}
#endregion
#region Private Methods
/// <summary>
/// Loads the default coded functions supported by the interpreter.
/// </summary>
private void LoadDefaultCodedFunctions()
{
this.codedFunctions.Add(new CF_Sin());
this.codedFunctions.Add(new CF_Cos());
this.codedFunctions.Add(new CF_Tan());
this.codedFunctions.Add(new CF_Round());
this.codedFunctions.Add(new CF_Sqrt());
this.codedFunctions.Add(new CF_Abs());
this.codedFunctions.Add(new CF_Exp());
this.codedFunctions.Add(new CF_Log());
this.codedFunctions.Add(new CF_Precision());
}
/// <summary>
/// Produces output given a single object.
/// </summary>
/// <param name="output">The object representing the output.</param>
internal void ProduceOutput(object output)
{
if (output is bool)
{
bool o = (bool)output;
if (o)
{
this.calculatedValue = 1;
}
else
{
this.calculatedValue = 0;
}
}
this.output = string.Format("{0}", output);
}
/// <summary>
/// Produces output given an object and a message.
/// </summary>
/// <param name="output">The object representing the output.</param>
/// <param name="message">The message to be displayed with the output.</param>
private void ProduceOutput(object output, string message)
{
if (!string.IsNullOrEmpty(message))
{
this.output = string.Format("{0}", output);
this.message = message;
}
else
{
ProduceOutput(output);
this.message = string.Empty;
}
}
#endregion
#region Asynchronous
/// <summary> Interpret an input asynchronously. </summary>
/// <param name="input"> The input to interpret and execute. </param>
/// <param name="callback"> The callback. </param>
public void InterpretAsync(string input, Action<InputInterpreter> callback)
{
InterpretAsyncDelegate del = new InterpretAsyncDelegate(InterpretAsyncThreadingWork);
del.BeginInvoke(input, (result) =>
{
AsyncResult returned = result as AsyncResult;
if (returned != null)
{
InterpretAsyncDelegate end = returned.AsyncDelegate as InterpretAsyncDelegate;
if (end != null)
{
InputInterpreter returnValue = end.EndInvoke(result);
callback(returnValue);
}
}
}, null);
}
/// <summary> Interpret asynchronous threading work. </summary>
/// <param name="input"> The input to interpret and execute. </param>
private InputInterpreter InterpretAsyncThreadingWork(string input)
{
Interpret(input);
return this;
}
/// <summary> Interpret asynchronous delegate. </summary>
/// <param name="input"> The input. </param>
/// <returns> . </returns>
private delegate InputInterpreter InterpretAsyncDelegate(string input);
#endregion
#region Computable
/// <summary> Converts this object to a computable. </summary>
/// <returns> This object as a Computable. </returns>
public Computable ToComputable()
{
return new Computable(this.Decimal.ToString(), this);
}
/// <summary> Treats the current object as a computable and performs an action in that context. </summary>
/// <param name="action"> The action to execute as a computable object. </param>
/// <returns> This object as a Computable, after the given action. </returns>
public Computable AsComputable(Func<Computable, Computable> action)
{
return action(this.ToComputable());
}
#endregion
}
}

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using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;
namespace csmic
{
/// <summary>
/// Represents a user defined function that can be executed by the interpreter.
/// </summary>
public class InterpretedFunction
{
#region Members
/// <summary>
/// The name of the function.
/// </summary>
private string name;
/// <summary>
/// The number of expected arguments.
/// </summary>
private int numExpectedArguments;
/// <summary>
/// The set of instructions to be passed to the internal inputInterpreter.
/// </summary>
private MacroOperation script;
/// <summary>
/// A set of arguments used in computation of the function.
/// </summary>
private InterpretedFunctionArgument[] arguments;
/// <summary>
/// The internal macro builder used for computation.
/// </summary>
private MacroBuilder macroFunction;
/// <summary>
/// The internal input inputInterpreter that macro builder will use for computation.
/// </summary>
private InputInterpreter interpreter;
#endregion
#region Constructor
/// <summary>
/// Creates a new interpreted function.
/// </summary>
/// <param name="name">The name of the fuction.</param>
/// <param name="script">The node to be used in computation.</param>
/// <param name="args">A set of argument names to be used in computation.</param>
internal InterpretedFunction(string name, MacroOperation script, params string[] args)
{
this.name = name;
this.script = script;
this.macroFunction = null;
this.arguments = new InterpretedFunctionArgument[args.Length];
this.interpreter = new InputInterpreter();
this.numExpectedArguments = args.Length;
for (int i = 0; i < args.Length; i++)
{
this.arguments[i] = new InterpretedFunctionArgument(args[i], 0);
}
}
#endregion
#region Properties
/// <summary>
/// Gets the name of the function.
/// </summary>
public string Name
{
get
{
return this.name;
}
}
/// <summary>
/// Gets the number of expected arguments for the function.
/// </summary>
public int NumExpectedArguments
{
get
{
return this.numExpectedArguments;
}
}
#endregion
#region Public Methods
/// <summary>
/// Computes the value of the function.
/// </summary>
/// <param name="args">The arguments used for computation.</param>
/// <returns>The decimal value computed by the function.</returns>
public string Compute(params decimal[] args)
{
if (args.Length != this.numExpectedArguments)
{
return "0";
}
if (args.Length == this.arguments.Length)
{
for (int i = 0; i < args.Length; i++)
{
this.arguments[i].Value = args[i];
}
}
foreach (InterpretedFunctionArgument argument in this.arguments)
{
this.interpreter.Interpret(string.Format("{0} :: {1}", argument.Name, argument.Value));
}
this.macroFunction = new MacroBuilder(this.script, this.interpreter);
return this.macroFunction.FinalOutput;
}
#endregion
/// <summary>
/// Because a function's internal pattern may be different, we must manually check to see if the function
/// names are the same.
/// </summary>
/// <param name="obj">The object to test.</param>
/// <returns>True if the functions are the same.</returns>
public override bool Equals(object obj)
{
InterpretedFunction fun = obj as InterpretedFunction;
if(fun != null)
{
return fun.name == this.name;
}
return false;
}
/// <summary> Serves as a hash function for a particular type. </summary>
/// <returns> A hash code for the current <see cref="T:System.Object" />. </returns>
public override int GetHashCode()
{
return this.script.GetHashCode() & this.name.GetHashCode();
}
}
}

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using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;
namespace csmic
{
/// <summary>
/// Represents an argument made in an interpreted function.
/// </summary>
public class InterpretedFunctionArgument
{
#region Members
/// <summary>
/// The name of the argument.
/// </summary>
private string name;
/// <summary>
/// The value of the argument.
/// </summary>
private decimal value;
#endregion
#region Constructors
/// <summary>
/// Creates a new interpreted function argument.
/// </summary>
public InterpretedFunctionArgument()
{
this.name = string.Empty;
this.value = 0;
}
/// <summary>
/// Creates a new interpreted function argument.
/// </summary>
/// <param name="name">The name of the argument in the interpreted function.</param>
/// <param name="value">The value of the argument to use in the interpreted function.</param>
public InterpretedFunctionArgument(string name, decimal value)
{
this.name = name;
this.value = value;
}
#endregion
#region Properties
/// <summary>
/// Gets or sets the name of the argument.
/// </summary>
public string Name
{
get
{
return this.name;
}
set
{
this.name = value;
}
}
/// <summary>
/// Gets or sets the value of the argument.
/// </summary>
public decimal Value
{
get
{
return this.value;
}
set
{
this.value = value;
}
}
#endregion
}
}

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using csmic;
using System.Text;
using System.Collections.Generic;
COMPILER CSMIC
/*
*
* Class Structures
*
*/
private decimal calcValue = 0;
private string stringValue = string.Empty;
public decimal CalculatedValue
{
get
{
return this.calcValue;
}
set
{
this.calcValue = value;
}
}
private InputInterpreter interpreter = null;
public InputInterpreter Interpreter
{
get
{
return this.interpreter;
}
set
{
this.interpreter = value;
}
}
bool IsFunctionCall()
{
scanner.ResetPeek();
Token next = scanner.Peek();
if (next.kind == _LPAREN && la.kind == _identifier)
return true;
return false;
}
bool IsCompare()
{
scanner.ResetPeek();
Token next = scanner.Peek();
if (next.kind == _COMPARER)
return true;
return false;
}
bool IsAssignment()
{
scanner.ResetPeek();
Token next = scanner.Peek();
if (next.val == "::" || next.val == ":=" || next.val == "->")
return true;
return false;
}
bool IsArrayCall()
{
scanner.ResetPeek();
Token next = scanner.Peek();
if(next.val == "[")
return true;
return false;
}
CHARACTERS
UpperLetter = 'A'..'Z'.
LowerLetter = 'a'..'z'.
letter = UpperLetter + LowerLetter.
digit = "0123456789" .
cr = '\r' .
lf = '\n' .
tab = '\t' .
PM = "+-" .
NoQuote = ANY - '\"' .
TOKENS
identifier = letter { letter | digit}.
sign = PM .
binary = ( '0' | '1' ) { '0' | '1' } ('B' | 'b') .
hex = "0x" ( digit | ('A' | 'B' | 'C' | 'D' | 'E' |'F') | ('a' | 'b' | 'c' | 'd' | 'e' |'f') ) { digit | ('A' | 'B' | 'C' | 'D' | 'E' |'F') | ('a' | 'b' | 'c' | 'd' | 'e' |'f') } .
number = digit { digit }['.' {digit}] [('E'|'e')['+'|'-'] digit {digit}] .
string = "\"" { NoQuote } "\"" .
LPAREN = '(' .
RPAREN = ')' .
COMPARER = "==" | "<" | ">" | "<=" | ">=" .
IGNORE cr + tab
/*
* Parser specification
*
*/
PRODUCTIONS
CSMIC (. decimal r = 0;
string s = string.Empty;
decimal[] a = new decimal[0];
bool success = true;
if(this.interpreter == null)
{
return;
}
.)
=
IF(IsCompare())
Comparison<out success> (. this.calcValue = (success == true) ? 1 : 0; this.interpreter.ProduceOutput(success); .)
|
IF(IsAssignment())
Assignment<out r> (. this.calcValue = r; .)
|
Expression<out r> (. this.calcValue = r; this.interpreter.ProduceOutput(r); .)
|
String<out s> (. this.stringValue = s; this.interpreter.ProduceOutput(s); .)
.
String<out string s>
=
string (. s = t.val; .)
.
Expression<out decimal r>
=
(. decimal r1; .)
Term<out r>
{
'+' Term<out r1> (. r += r1; .)
|
'-' Term<out r1> (. r -= r1; .)
}
.
Term<out decimal r> (. decimal r1; .)
=
Factor<out r>
{
'*'
Factor<out r1> (. r *= r1; .)
|
'/'
Factor<out r1> (. r /= r1; .)
|
'%' Term<out r1> (. r %= r1; .)
}
.
Factor<out decimal r> (. decimal r1; .)
=
Value<out r>
{
'^'
Expression<out r1> (. r = Convert.ToDecimal(Math.Pow(Convert.ToDouble(r), Convert.ToDouble(r1))); .)
}
.
Value<out decimal r> (. r = 0;
decimal r1 = 0;
string fn;
int sign = 1;.)
=
[
"+"
|
"-" (. sign = -1; .)
]
(
IF(IsFunctionCall())
Function<out r> (. r = sign * r; .)
|
IF(IsArrayCall())
ArrayCall<out r> (. r = sign * r; .)
|
identifier (. if(this.interpreter.variables.ContainsKey(t.val))
{
Variable v = this.interpreter.variables[t.val];
if(v.Type == VariableType.Equation)
{
InputInterpreter i = new InputInterpreter(this.interpreter);
i.Interpret(v.Value.ToString());
r = i.Decimal;
}
else if(v.Type == VariableType.Decimal)
{
r = Convert.ToDecimal(v.Value);
}
else
{
r = 0;
}
}
.)
|
number (. r = sign * Convert.ToDecimal (t.val); .)
|
hex (. string expression = t.val.Remove(0,2);
try
{
decimal value = Convert.ToDecimal(Convert.ToInt64(expression, 16));
r = sign * value;
}
catch
{
r = 0;
}
.)
|
binary (. string expression = t.val.Remove(t.val.Length - 1);
try
{
decimal value = Convert.ToDecimal(Convert.ToInt64(expression, 2));
r = sign * value;
}
catch
{
r = 0;
}
.)
|
'('
Expression<out r>
')' (. r = sign * r; .)
)
.
ArrayL<out decimal[] d>
=
'['
CommaList<out d>
']'
.
ArrayCall<out decimal r> (. string ident = string.Empty; r = 0; decimal pos = 0; .)
=
identifier (. ident = t.val; .)
'['
Expression<out pos> (. int i = 0;
try
{
i = Convert.ToInt32(pos);
if(this.interpreter.variables.ContainsKey(ident))
{
decimal[] values = this.interpreter.variables[ident].Value as decimal[];
if(values != null)
{
r = values[i];
}
}
}
catch
{
}
.)
']'
.
CommaList<out decimal[] d> (. List<decimal> list = new List<decimal>(); decimal r = 0; .)
=
Expression<out r> (. list.Add(r); d = list.ToArray(); .)
{
','
Expression<out r> (. list.Add(r); d = list.ToArray(); .)
}
.
Assignment<out decimal r> (.
string identifier = string.Empty;
string expression = string.Empty;
decimal[] d = new decimal[0];
r = 0;
.)
=
identifier (. identifier = t.val; .)
(
(
"::"
Expression<out r> (. this.interpreter.Assign(identifier, r); .)
(. this.interpreter.ProduceOutput(r); .)
)
|
(
":="
AnyExpression<out expression> (. this.interpreter.Assign(identifier, expression); .)
(. this.interpreter.ProduceOutput(expression); .)
)
|
(
"->"
ArrayL<out d> (. this.interpreter.Assign(identifier, d); r = 0; .)
(.
StringBuilder builder = new StringBuilder();
foreach(decimal dec in d)
{
builder.Append("," + dec.ToString());
}
builder.Remove(0,1);
this.interpreter.ProduceOutput(builder.ToString());
.)
)
)
.
Function<out decimal r> (.
string functionName = string.Empty;
decimal[] d = new decimal[0];
.)
=
identifier (. functionName = t.val; .)
'('
CommaList<out d>
')' (. r = this.interpreter.ExecuteFunction(functionName, d); .)
.
Comparison<out bool result> (.
decimal firstValue = 0;
decimal secondValue = 0;
string compareType = string.Empty;
.)
=
Expression<out firstValue>
COMPARER (. compareType = t.val; .)
Expression<out secondValue> (.
switch(compareType)
{
case "==":
result = (firstValue == secondValue);
break;
case ">":
result = (firstValue > secondValue);
break;
case "<":
result = (firstValue < secondValue);
break;
case ">=":
result = (firstValue >= secondValue);
break;
case "<=":
result = (firstValue <= secondValue);
break;
default:
result = false;
break;
}
.)
.
AnyExpression<out string value> (. value = string.Empty; StringBuilder builder = new StringBuilder(); .)
=
ANY (. builder.Append(t.val); .) { ANY (. builder.Append(t.val); .) } (. value = builder.ToString(); .)
.
END CSMIC.

View file

@ -0,0 +1,534 @@
using csmic;
using System.Text;
using System.Collections.Generic;
using System;
using System.CodeDom.Compiler;
namespace csmic.Interpreter {
[GeneratedCodeAttribute("Coco/R", "")]
public class Parser {
public const int _EOF = 0;
public const int _identifier = 1;
public const int _sign = 2;
public const int _binary = 3;
public const int _hex = 4;
public const int _number = 5;
public const int _string = 6;
public const int _LPAREN = 7;
public const int _RPAREN = 8;
public const int _COMPARER = 9;
public const int maxT = 22;
const bool T = true;
const bool x = false;
const int minErrDist = 2;
public Scanner scanner;
public Errors errors;
public Token t; // last recognized token
public Token la; // lookahead token
int errDist = minErrDist;
private decimal calcValue = 0;
private string stringValue = string.Empty;
public decimal CalculatedValue
{
get
{
return this.calcValue;
}
set
{
this.calcValue = value;
}
}
private InputInterpreter interpreter = null;
public InputInterpreter Interpreter
{
get
{
return this.interpreter;
}
set
{
this.interpreter = value;
}
}
bool IsFunctionCall()
{
scanner.ResetPeek();
Token next = scanner.Peek();
if (next.kind == _LPAREN && la.kind == _identifier)
return true;
return false;
}
bool IsCompare()
{
scanner.ResetPeek();
Token next = scanner.Peek();
if (next.kind == _COMPARER)
return true;
return false;
}
bool IsAssignment()
{
scanner.ResetPeek();
Token next = scanner.Peek();
if (next.val == "::" || next.val == ":=" || next.val == "->")
return true;
return false;
}
bool IsArrayCall()
{
scanner.ResetPeek();
Token next = scanner.Peek();
if(next.val == "[")
return true;
return false;
}
public Parser(Scanner scanner) {
this.scanner = scanner;
errors = new Errors();
}
void SynErr (int n) {
if (errDist >= minErrDist) errors.SynErr(la.line, la.col, n);
errDist = 0;
}
public void SemErr (string msg) {
if (errDist >= minErrDist) errors.SemErr(t.line, t.col, msg);
errDist = 0;
}
void Get () {
for (;;) {
t = la;
la = scanner.Scan();
if (la.kind <= maxT) { ++errDist; break; }
la = t;
}
}
void Expect (int n) {
if (la.kind==n) Get(); else { SynErr(n); }
}
bool StartOf (int s) {
return set[s, la.kind];
}
void ExpectWeak (int n, int follow) {
if (la.kind == n) Get();
else {
SynErr(n);
while (!StartOf(follow)) Get();
}
}
bool WeakSeparator(int n, int syFol, int repFol) {
int kind = la.kind;
if (kind == n) {Get(); return true;}
else if (StartOf(repFol)) {return false;}
else {
SynErr(n);
while (!(set[syFol, kind] || set[repFol, kind] || set[0, kind])) {
Get();
kind = la.kind;
}
return StartOf(syFol);
}
}
void CSMIC() {
decimal r = 0;
string s = string.Empty;
decimal[] a = new decimal[0];
bool success = true;
if(this.interpreter == null)
{
return;
}
if (IsCompare()) {
Comparison(out success);
this.calcValue = (success == true) ? 1 : 0; this.interpreter.ProduceOutput(success);
} else if (IsAssignment()) {
Assignment(out r);
this.calcValue = r;
} else if (StartOf(1)) {
Expression(out r);
this.calcValue = r; this.interpreter.ProduceOutput(r);
} else if (la.kind == 6) {
String(out s);
this.stringValue = s; this.interpreter.ProduceOutput(s);
} else SynErr(23);
}
void Comparison(out bool result) {
decimal firstValue = 0;
decimal secondValue = 0;
string compareType = string.Empty;
Expression(out firstValue);
Expect(9);
compareType = t.val;
Expression(out secondValue);
switch(compareType)
{
case "==":
result = (firstValue == secondValue);
break;
case ">":
result = (firstValue > secondValue);
break;
case "<":
result = (firstValue < secondValue);
break;
case ">=":
result = (firstValue >= secondValue);
break;
case "<=":
result = (firstValue <= secondValue);
break;
default:
result = false;
break;
}
}
void Assignment(out decimal r) {
string identifier = string.Empty;
string expression = string.Empty;
decimal[] d = new decimal[0];
r = 0;
Expect(1);
identifier = t.val;
if (la.kind == 19) {
Get();
Expression(out r);
this.interpreter.Assign(identifier, r);
this.interpreter.ProduceOutput(r);
} else if (la.kind == 20) {
Get();
AnyExpression(out expression);
this.interpreter.Assign(identifier, expression);
this.interpreter.ProduceOutput(expression);
} else if (la.kind == 21) {
Get();
ArrayL(out d);
this.interpreter.Assign(identifier, d); r = 0;
StringBuilder builder = new StringBuilder();
foreach(decimal dec in d)
{
builder.Append("," + dec.ToString());
}
builder.Remove(0,1);
this.interpreter.ProduceOutput(builder.ToString());
} else SynErr(24);
}
void Expression(out decimal r) {
decimal r1;
Term(out r);
while (la.kind == 10 || la.kind == 11) {
if (la.kind == 10) {
Get();
Term(out r1);
r += r1;
} else {
Get();
Term(out r1);
r -= r1;
}
}
}
void String(out string s) {
Expect(6);
s = t.val;
}
void Term(out decimal r) {
decimal r1;
Factor(out r);
while (la.kind == 12 || la.kind == 13 || la.kind == 14) {
if (la.kind == 12) {
Get();
Factor(out r1);
r *= r1;
} else if (la.kind == 13) {
Get();
Factor(out r1);
r /= r1;
} else {
Get();
Term(out r1);
r %= r1;
}
}
}
void Factor(out decimal r) {
decimal r1;
Value(out r);
while (la.kind == 15) {
Get();
Expression(out r1);
r = Convert.ToDecimal(Math.Pow(Convert.ToDouble(r), Convert.ToDouble(r1)));
}
}
void Value(out decimal r) {
r = 0;
decimal r1 = 0;
string fn;
int sign = 1;
if (la.kind == 10 || la.kind == 11) {
if (la.kind == 10) {
Get();
} else {
Get();
sign = -1;
}
}
if (IsFunctionCall()) {
Function(out r);
r = sign * r;
} else if (IsArrayCall()) {
ArrayCall(out r);
r = sign * r;
} else if (la.kind == 1) {
Get();
if(this.interpreter.variables.ContainsKey(t.val))
{
Variable v = this.interpreter.variables[t.val];
if(v.Type == VariableType.Equation)
{
InputInterpreter i = new InputInterpreter(this.interpreter);
i.Interpret(v.Value.ToString());
r = i.Decimal;
}
else if(v.Type == VariableType.Decimal)
{
r = Convert.ToDecimal(v.Value);
}
else
{
r = 0;
}
}
} else if (la.kind == 5) {
Get();
r = sign * Convert.ToDecimal (t.val);
} else if (la.kind == 4) {
Get();
string expression = t.val.Remove(0,2);
try
{
decimal value = Convert.ToDecimal(Convert.ToInt64(expression, 16));
r = sign * value;
}
catch
{
r = 0;
}
} else if (la.kind == 3) {
Get();
string expression = t.val.Remove(t.val.Length - 1);
try
{
decimal value = Convert.ToDecimal(Convert.ToInt64(expression, 2));
r = sign * value;
}
catch
{
r = 0;
}
} else if (la.kind == 7) {
Get();
Expression(out r);
Expect(8);
r = sign * r;
} else SynErr(25);
}
void Function(out decimal r) {
string functionName = string.Empty;
decimal[] d = new decimal[0];
Expect(1);
functionName = t.val;
Expect(7);
CommaList(out d);
Expect(8);
r = this.interpreter.ExecuteFunction(functionName, d);
}
void ArrayCall(out decimal r) {
string ident = string.Empty; r = 0; decimal pos = 0;
Expect(1);
ident = t.val;
Expect(16);
Expression(out pos);
int i = 0;
try
{
i = Convert.ToInt32(pos);
if(this.interpreter.variables.ContainsKey(ident))
{
decimal[] values = this.interpreter.variables[ident].Value as decimal[];
if(values != null)
{
r = values[i];
}
}
}
catch
{
}
Expect(17);
}
void ArrayL(out decimal[] d) {
Expect(16);
CommaList(out d);
Expect(17);
}
void CommaList(out decimal[] d) {
List<decimal> list = new List<decimal>(); decimal r = 0;
Expression(out r);
list.Add(r); d = list.ToArray();
while (la.kind == 18) {
Get();
Expression(out r);
list.Add(r); d = list.ToArray();
}
}
void AnyExpression(out string value) {
value = string.Empty; StringBuilder builder = new StringBuilder();
Get();
builder.Append(t.val);
while (StartOf(2)) {
Get();
builder.Append(t.val);
}
value = builder.ToString();
}
public void Parse() {
la = new Token();
la.val = "";
Get();
CSMIC();
Expect(0);
Expect(0);
}
static readonly bool[,] set = {
{T,x,x,x, x,x,x,x, x,x,x,x, x,x,x,x, x,x,x,x, x,x,x,x},
{x,T,x,T, T,T,x,T, x,x,T,T, x,x,x,x, x,x,x,x, x,x,x,x},
{x,T,T,T, T,T,T,T, T,T,T,T, T,T,T,T, T,T,T,T, T,T,T,x}
};
} // end Parser
public class Errors {
public int count = 0; // number of errors detected
public StringBuilder builder = new StringBuilder(); // error messages go to this stream
public string errMsgFormat = "-- position {0}: {1}"; // 0=line, 1=column, 2=text
public void SynErr (int line, int col, int n) {
string s;
switch (n) {
case 0: s = "EOF expected"; break;
case 1: s = "identifier expected"; break;
case 2: s = "sign expected"; break;
case 3: s = "binary expected"; break;
case 4: s = "hex expected"; break;
case 5: s = "number expected"; break;
case 6: s = "string expected"; break;
case 7: s = "LPAREN expected"; break;
case 8: s = "RPAREN expected"; break;
case 9: s = "COMPARER expected"; break;
case 10: s = "\"+\" expected"; break;
case 11: s = "\"-\" expected"; break;
case 12: s = "\"*\" expected"; break;
case 13: s = "\"/\" expected"; break;
case 14: s = "\"%\" expected"; break;
case 15: s = "\"^\" expected"; break;
case 16: s = "\"[\" expected"; break;
case 17: s = "\"]\" expected"; break;
case 18: s = "\",\" expected"; break;
case 19: s = "\"::\" expected"; break;
case 20: s = "\":=\" expected"; break;
case 21: s = "\"->\" expected"; break;
case 22: s = "??? expected"; break;
case 23: s = "invalid CSMIC"; break;
case 24: s = "invalid Assignment"; break;
case 25: s = "invalid Value"; break;
default: s = "error " + n; break;
}
builder.AppendFormat(errMsgFormat, col, s);
count++;
}
public void SemErr (int line, int col, string s) {
builder.AppendFormat(errMsgFormat, col, s);
count++;
}
public void SemErr (string s) {
builder.AppendLine(s);
count++;
}
public void Warning (int line, int col, string s) {
builder.AppendFormat(errMsgFormat, col, s);
}
public void Warning(string s) {
builder.AppendLine(s);
}
} // Errors
public class FatalError: Exception {
public FatalError(string m): base(m) {}
}
}

View file

@ -0,0 +1,160 @@
/*----------------------------------------------------------------------
Compiler Generator Coco/R,
Copyright (c) 1990, 2004 Hanspeter Moessenboeck, University of Linz
extended by M. Loeberbauer & A. Woess, Univ. of Linz
with improvements by Pat Terry, Rhodes University
This program is free software; you can redistribute it and/or modify it
under the terms of the GNU General Public License as published by the
Free Software Foundation; either version 2, or (at your option) any
later version.
This program is distributed in the hope that it will be useful, but
WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
for more details.
You should have received a copy of the GNU General Public License along
with this program; if not, write to the Free Software Foundation, Inc.,
59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
As an exception, it is allowed to write an extension of Coco/R that is
used as a plugin in non-free software.
If not otherwise stated, any source code generated by Coco/R (other than
Coco/R itself) does not fall under the GNU General Public License.
----------------------------------------------------------------------*/
-->begin
using System;
using System.CodeDom.Compiler;
-->namespace
[GeneratedCodeAttribute("Coco/R", "")]
public class Parser {
-->constants
const bool T = true;
const bool x = false;
const int minErrDist = 2;
public Scanner scanner;
public Errors errors;
public Token t; // last recognized token
public Token la; // lookahead token
int errDist = minErrDist;
-->declarations
public Parser(Scanner scanner) {
this.scanner = scanner;
errors = new Errors();
}
void SynErr (int n) {
if (errDist >= minErrDist) errors.SynErr(la.line, la.col, n);
errDist = 0;
}
public void SemErr (string msg) {
if (errDist >= minErrDist) errors.SemErr(t.line, t.col, msg);
errDist = 0;
}
void Get () {
for (;;) {
t = la;
la = scanner.Scan();
if (la.kind <= maxT) { ++errDist; break; }
-->pragmas
la = t;
}
}
void Expect (int n) {
if (la.kind==n) Get(); else { SynErr(n); }
}
bool StartOf (int s) {
return set[s, la.kind];
}
void ExpectWeak (int n, int follow) {
if (la.kind == n) Get();
else {
SynErr(n);
while (!StartOf(follow)) Get();
}
}
bool WeakSeparator(int n, int syFol, int repFol) {
int kind = la.kind;
if (kind == n) {Get(); return true;}
else if (StartOf(repFol)) {return false;}
else {
SynErr(n);
while (!(set[syFol, kind] || set[repFol, kind] || set[0, kind])) {
Get();
kind = la.kind;
}
return StartOf(syFol);
}
}
-->productions
public void Parse() {
la = new Token();
la.val = "";
Get();
-->parseRoot
Expect(0);
}
static readonly bool[,] set = {
-->initialization
};
} // end Parser
public class Errors {
public int count = 0; // number of errors detected
public StringBuilder builder = new StringBuilder(); // error messages go to this stream
public string errMsgFormat = "-- position {0}: {1}"; // 0=line, 1=column, 2=text
public void SynErr (int line, int col, int n) {
string s;
switch (n) {
-->errors
default: s = "error " + n; break;
}
builder.AppendFormat(errMsgFormat, col, s);
count++;
}
public void SemErr (int line, int col, string s) {
builder.AppendFormat(errMsgFormat, col, s);
count++;
}
public void SemErr (string s) {
builder.AppendLine(s);
count++;
}
public void Warning (int line, int col, string s) {
builder.AppendFormat(errMsgFormat, col, s);
}
public void Warning(string s) {
builder.AppendLine(s);
}
} // Errors
public class FatalError: Exception {
public FatalError(string m): base(m) {}
}

View file

@ -0,0 +1,491 @@
using System;
using System.IO;
using System.Collections;
using System.Collections.Generic;
using System.CodeDom.Compiler;
namespace csmic.Interpreter {
[GeneratedCodeAttribute("Coco/R", "")]
public class Token {
public int kind; // token kind
public int pos; // token position in bytes in the source text (starting at 0)
public int charPos; // token position in characters in the source text (starting at 0)
public int col; // token column (starting at 1)
public int line; // token line (starting at 1)
public string val; // token value
public Token next; // ML 2005-03-11 Tokens are kept in linked list
}
//-----------------------------------------------------------------------------------
// Buffer
//-----------------------------------------------------------------------------------
public class Buffer {
// This Buffer supports the following cases:
// 1) seekable stream (file)
// a) whole stream in buffer
// b) part of stream in buffer
// 2) non seekable stream (network, console)
public const int EOF = char.MaxValue + 1;
const int MIN_BUFFER_LENGTH = 1024; // 1KB
const int MAX_BUFFER_LENGTH = MIN_BUFFER_LENGTH * 64; // 64KB
byte[] buf; // input buffer
int bufStart; // position of first byte in buffer relative to input stream
int bufLen; // length of buffer
int fileLen; // length of input stream (may change if the stream is no file)
int bufPos; // current position in buffer
Stream stream; // input stream (seekable)
bool isUserStream; // was the stream opened by the user?
public Buffer (Stream s, bool isUserStream) {
stream = s; this.isUserStream = isUserStream;
if (stream.CanSeek) {
fileLen = (int) stream.Length;
bufLen = Math.Min(fileLen, MAX_BUFFER_LENGTH);
bufStart = Int32.MaxValue; // nothing in the buffer so far
} else {
fileLen = bufLen = bufStart = 0;
}
buf = new byte[(bufLen>0) ? bufLen : MIN_BUFFER_LENGTH];
if (fileLen > 0) Pos = 0; // setup buffer to position 0 (start)
else bufPos = 0; // index 0 is already after the file, thus Pos = 0 is invalid
if (bufLen == fileLen && stream.CanSeek) Close();
}
protected Buffer(Buffer b) { // called in UTF8Buffer constructor
buf = b.buf;
bufStart = b.bufStart;
bufLen = b.bufLen;
fileLen = b.fileLen;
bufPos = b.bufPos;
stream = b.stream;
// keep destructor from closing the stream
b.stream = null;
isUserStream = b.isUserStream;
}
~Buffer() { Close(); }
protected void Close() {
if (!isUserStream && stream != null) {
stream.Close();
stream = null;
}
}
public virtual int Read () {
if (bufPos < bufLen) {
return buf[bufPos++];
} else if (Pos < fileLen) {
Pos = Pos; // shift buffer start to Pos
return buf[bufPos++];
} else if (stream != null && !stream.CanSeek && ReadNextStreamChunk() > 0) {
return buf[bufPos++];
} else {
return EOF;
}
}
public int Peek () {
int curPos = Pos;
int ch = Read();
Pos = curPos;
return ch;
}
// beg .. begin, zero-based, inclusive, in byte
// end .. end, zero-based, exclusive, in byte
public string GetString (int beg, int end) {
int len = 0;
char[] buf = new char[end - beg];
int oldPos = Pos;
Pos = beg;
while (Pos < end) buf[len++] = (char) Read();
Pos = oldPos;
return new String(buf, 0, len);
}
public int Pos {
get { return bufPos + bufStart; }
set {
if (value >= fileLen && stream != null && !stream.CanSeek) {
// Wanted position is after buffer and the stream
// is not seek-able e.g. network or console,
// thus we have to read the stream manually till
// the wanted position is in sight.
while (value >= fileLen && ReadNextStreamChunk() > 0);
}
if (value < 0 || value > fileLen) {
throw new FatalError("buffer out of bounds access, position: " + value);
}
if (value >= bufStart && value < bufStart + bufLen) { // already in buffer
bufPos = value - bufStart;
} else if (stream != null) { // must be swapped in
stream.Seek(value, SeekOrigin.Begin);
bufLen = stream.Read(buf, 0, buf.Length);
bufStart = value; bufPos = 0;
} else {
// set the position to the end of the file, Pos will return fileLen.
bufPos = fileLen - bufStart;
}
}
}
// Read the next chunk of bytes from the stream, increases the buffer
// if needed and updates the fields fileLen and bufLen.
// Returns the number of bytes read.
private int ReadNextStreamChunk() {
int free = buf.Length - bufLen;
if (free == 0) {
// in the case of a growing input stream
// we can neither seek in the stream, nor can we
// foresee the maximum length, thus we must adapt
// the buffer size on demand.
byte[] newBuf = new byte[bufLen * 2];
Array.Copy(buf, newBuf, bufLen);
buf = newBuf;
free = bufLen;
}
int read = stream.Read(buf, bufLen, free);
if (read > 0) {
fileLen = bufLen = (bufLen + read);
return read;
}
// end of stream reached
return 0;
}
}
//-----------------------------------------------------------------------------------
// UTF8Buffer
//-----------------------------------------------------------------------------------
public class UTF8Buffer: Buffer {
public UTF8Buffer(Buffer b): base(b) {}
public override int Read() {
int ch;
do {
ch = base.Read();
// until we find a utf8 start (0xxxxxxx or 11xxxxxx)
} while ((ch >= 128) && ((ch & 0xC0) != 0xC0) && (ch != EOF));
if (ch < 128 || ch == EOF) {
// nothing to do, first 127 chars are the same in ascii and utf8
// 0xxxxxxx or end of file character
} else if ((ch & 0xF0) == 0xF0) {
// 11110xxx 10xxxxxx 10xxxxxx 10xxxxxx
int c1 = ch & 0x07; ch = base.Read();
int c2 = ch & 0x3F; ch = base.Read();
int c3 = ch & 0x3F; ch = base.Read();
int c4 = ch & 0x3F;
ch = (((((c1 << 6) | c2) << 6) | c3) << 6) | c4;
} else if ((ch & 0xE0) == 0xE0) {
// 1110xxxx 10xxxxxx 10xxxxxx
int c1 = ch & 0x0F; ch = base.Read();
int c2 = ch & 0x3F; ch = base.Read();
int c3 = ch & 0x3F;
ch = (((c1 << 6) | c2) << 6) | c3;
} else if ((ch & 0xC0) == 0xC0) {
// 110xxxxx 10xxxxxx
int c1 = ch & 0x1F; ch = base.Read();
int c2 = ch & 0x3F;
ch = (c1 << 6) | c2;
}
return ch;
}
}
//-----------------------------------------------------------------------------------
// Scanner
//-----------------------------------------------------------------------------------
public class Scanner {
const char EOL = '\n';
const int eofSym = 0; /* pdt */
const int maxT = 22;
const int noSym = 22;
public Buffer buffer; // scanner buffer
Token t; // current token
int ch; // current input character
int pos; // byte position of current character
int charPos; // position by unicode characters starting with 0
int col; // column number of current character
int line; // line number of current character
int oldEols; // EOLs that appeared in a comment;
static readonly Dictionary<int, int> start; // maps first token character to start state
Token tokens; // list of tokens already peeked (first token is a dummy)
Token pt; // current peek token
char[] tval = new char[128]; // text of current token
int tlen; // length of current token
static Scanner() {
start = new Dictionary<int, int>(128);
for (int i = 65; i <= 90; ++i) start[i] = 1;
for (int i = 97; i <= 122; ++i) start[i] = 1;
start[43] = 2;
for (int i = 50; i <= 57; ++i) start[i] = 6;
start[48] = 17;
start[49] = 18;
start[34] = 11;
start[40] = 13;
start[41] = 14;
start[61] = 15;
start[60] = 19;
start[62] = 20;
start[42] = 21;
start[47] = 22;
start[37] = 23;
start[94] = 24;
start[91] = 25;
start[93] = 26;
start[44] = 27;
start[58] = 31;
start[45] = 32;
start[Buffer.EOF] = -1;
}
public Scanner (string fileName) {
try {
Stream stream = new FileStream(fileName, FileMode.Open, FileAccess.Read, FileShare.Read);
buffer = new Buffer(stream, false);
Init();
} catch (IOException) {
throw new FatalError("Cannot open file " + fileName);
}
}
public Scanner (Stream s) {
buffer = new Buffer(s, true);
Init();
}
void Init() {
pos = -1; line = 1; col = 0; charPos = -1;
oldEols = 0;
NextCh();
if (ch == 0xEF) { // check optional byte order mark for UTF-8
NextCh(); int ch1 = ch;
NextCh(); int ch2 = ch;
if (ch1 != 0xBB || ch2 != 0xBF) {
throw new FatalError(String.Format("illegal byte order mark: EF {0,2:X} {1,2:X}", ch1, ch2));
}
buffer = new UTF8Buffer(buffer); col = 0; charPos = -1;
NextCh();
}
pt = tokens = new Token(); // first token is a dummy
}
void NextCh() {
if (oldEols > 0) { ch = EOL; oldEols--; }
else {
pos = buffer.Pos;
// buffer reads unicode chars, if UTF8 has been detected
ch = buffer.Read(); col++; charPos++;
// replace isolated '\r' by '\n' in order to make
// eol handling uniform across Windows, Unix and Mac
if (ch == '\r' && buffer.Peek() != '\n') ch = EOL;
if (ch == EOL) { line++; col = 0; }
}
}
void AddCh() {
if (tlen >= tval.Length) {
char[] newBuf = new char[2 * tval.Length];
Array.Copy(tval, 0, newBuf, 0, tval.Length);
tval = newBuf;
}
if (ch != Buffer.EOF) {
tval[tlen++] = (char) ch;
NextCh();
}
}
void CheckLiteral() {
switch (t.val) {
case "+": t.kind = 10; break;
case "-": t.kind = 11; break;
default: break;
}
}
Token NextToken() {
while (ch == ' ' ||
ch == 9 || ch == 13
) NextCh();
int recKind = noSym;
int recEnd = pos;
t = new Token();
t.pos = pos; t.col = col; t.line = line; t.charPos = charPos;
int state;
state = (int) start[ch];
tlen = 0; AddCh();
switch (state) {
case -1: { t.kind = eofSym; break; } // NextCh already done
case 0: {
if (recKind != noSym) {
tlen = recEnd - t.pos;
SetScannerBehindT();
}
t.kind = recKind; break;
} // NextCh already done
case 1:
recEnd = pos; recKind = 1;
if (ch >= '0' && ch <= '9' || ch >= 'A' && ch <= 'Z' || ch >= 'a' && ch <= 'z') {AddCh(); goto case 1;}
else {t.kind = 1; break;}
case 2:
{t.kind = 2; t.val = new String(tval, 0, tlen); CheckLiteral(); return t;}
case 3:
{t.kind = 3; break;}
case 4:
if (ch >= '0' && ch <= '9' || ch >= 'A' && ch <= 'F' || ch >= 'a' && ch <= 'f') {AddCh(); goto case 5;}
else {goto case 0;}
case 5:
recEnd = pos; recKind = 4;
if (ch >= '0' && ch <= '9' || ch >= 'A' && ch <= 'F' || ch >= 'a' && ch <= 'f') {AddCh(); goto case 5;}
else {t.kind = 4; break;}
case 6:
recEnd = pos; recKind = 5;
if (ch >= '0' && ch <= '9') {AddCh(); goto case 6;}
else if (ch == 'E' || ch == 'e') {AddCh(); goto case 7;}
else if (ch == '.') {AddCh(); goto case 10;}
else {t.kind = 5; break;}
case 7:
if (ch >= '0' && ch <= '9') {AddCh(); goto case 9;}
else if (ch == '+' || ch == '-') {AddCh(); goto case 8;}
else {goto case 0;}
case 8:
if (ch >= '0' && ch <= '9') {AddCh(); goto case 9;}
else {goto case 0;}
case 9:
recEnd = pos; recKind = 5;
if (ch >= '0' && ch <= '9') {AddCh(); goto case 9;}
else {t.kind = 5; break;}
case 10:
recEnd = pos; recKind = 5;
if (ch >= '0' && ch <= '9') {AddCh(); goto case 10;}
else if (ch == 'E' || ch == 'e') {AddCh(); goto case 7;}
else {t.kind = 5; break;}
case 11:
if (ch <= '!' || ch >= '#' && ch <= 65535) {AddCh(); goto case 11;}
else if (ch == '"') {AddCh(); goto case 12;}
else {goto case 0;}
case 12:
{t.kind = 6; break;}
case 13:
{t.kind = 7; break;}
case 14:
{t.kind = 8; break;}
case 15:
if (ch == '=') {AddCh(); goto case 16;}
else {goto case 0;}
case 16:
{t.kind = 9; break;}
case 17:
recEnd = pos; recKind = 5;
if (ch >= '2' && ch <= '9') {AddCh(); goto case 6;}
else if (ch == 'B' || ch == 'b') {AddCh(); goto case 3;}
else if (ch >= '0' && ch <= '1') {AddCh(); goto case 18;}
else if (ch == 'x') {AddCh(); goto case 4;}
else if (ch == 'E' || ch == 'e') {AddCh(); goto case 7;}
else if (ch == '.') {AddCh(); goto case 10;}
else {t.kind = 5; break;}
case 18:
recEnd = pos; recKind = 5;
if (ch >= '2' && ch <= '9') {AddCh(); goto case 6;}
else if (ch == 'B' || ch == 'b') {AddCh(); goto case 3;}
else if (ch >= '0' && ch <= '1') {AddCh(); goto case 18;}
else if (ch == 'E' || ch == 'e') {AddCh(); goto case 7;}
else if (ch == '.') {AddCh(); goto case 10;}
else {t.kind = 5; break;}
case 19:
recEnd = pos; recKind = 9;
if (ch == '=') {AddCh(); goto case 16;}
else {t.kind = 9; break;}
case 20:
recEnd = pos; recKind = 9;
if (ch == '=') {AddCh(); goto case 16;}
else {t.kind = 9; break;}
case 21:
{t.kind = 12; break;}
case 22:
{t.kind = 13; break;}
case 23:
{t.kind = 14; break;}
case 24:
{t.kind = 15; break;}
case 25:
{t.kind = 16; break;}
case 26:
{t.kind = 17; break;}
case 27:
{t.kind = 18; break;}
case 28:
{t.kind = 19; break;}
case 29:
{t.kind = 20; break;}
case 30:
{t.kind = 21; break;}
case 31:
if (ch == ':') {AddCh(); goto case 28;}
else if (ch == '=') {AddCh(); goto case 29;}
else {goto case 0;}
case 32:
recEnd = pos; recKind = 2;
if (ch == '>') {AddCh(); goto case 30;}
else {t.kind = 2; t.val = new String(tval, 0, tlen); CheckLiteral(); return t;}
}
t.val = new String(tval, 0, tlen);
return t;
}
private void SetScannerBehindT() {
buffer.Pos = t.pos;
NextCh();
line = t.line; col = t.col; charPos = t.charPos;
for (int i = 0; i < tlen; i++) NextCh();
}
// get the next token (possibly a token already seen during peeking)
public Token Scan () {
if (tokens.next == null) {
return NextToken();
} else {
pt = tokens = tokens.next;
return tokens;
}
}
// peek for the next token, ignore pragmas
public Token Peek () {
do {
if (pt.next == null) {
pt.next = NextToken();
}
pt = pt.next;
} while (pt.kind > maxT); // skip pragmas
return pt;
}
// make sure that peeking starts at the current scan position
public void ResetPeek () { pt = tokens; }
} // end Scanner
}

View file

@ -0,0 +1,383 @@
/*----------------------------------------------------------------------
Compiler Generator Coco/R,
Copyright (c) 1990, 2004 Hanspeter Moessenboeck, University of Linz
extended by M. Loeberbauer & A. Woess, Univ. of Linz
with improvements by Pat Terry, Rhodes University
This program is free software; you can redistribute it and/or modify it
under the terms of the GNU General Public License as published by the
Free Software Foundation; either version 2, or (at your option) any
later version.
This program is distributed in the hope that it will be useful, but
WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
for more details.
You should have received a copy of the GNU General Public License along
with this program; if not, write to the Free Software Foundation, Inc.,
59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
As an exception, it is allowed to write an extension of Coco/R that is
used as a plugin in non-free software.
If not otherwise stated, any source code generated by Coco/R (other than
Coco/R itself) does not fall under the GNU General Public License.
-----------------------------------------------------------------------*/
-->begin
using System;
using System.IO;
using System.Collections;
using System.Collections.Generic;
using System.CodeDom.Compiler;
-->namespace
[GeneratedCodeAttribute("Coco/R", "")]
public class Token {
public int kind; // token kind
public int pos; // token position in bytes in the source text (starting at 0)
public int charPos; // token position in characters in the source text (starting at 0)
public int col; // token column (starting at 1)
public int line; // token line (starting at 1)
public string val; // token value
public Token next; // ML 2005-03-11 Tokens are kept in linked list
}
//-----------------------------------------------------------------------------------
// Buffer
//-----------------------------------------------------------------------------------
public class Buffer {
// This Buffer supports the following cases:
// 1) seekable stream (file)
// a) whole stream in buffer
// b) part of stream in buffer
// 2) non seekable stream (network, console)
public const int EOF = char.MaxValue + 1;
const int MIN_BUFFER_LENGTH = 1024; // 1KB
const int MAX_BUFFER_LENGTH = MIN_BUFFER_LENGTH * 64; // 64KB
byte[] buf; // input buffer
int bufStart; // position of first byte in buffer relative to input stream
int bufLen; // length of buffer
int fileLen; // length of input stream (may change if the stream is no file)
int bufPos; // current position in buffer
Stream stream; // input stream (seekable)
bool isUserStream; // was the stream opened by the user?
public Buffer (Stream s, bool isUserStream) {
stream = s; this.isUserStream = isUserStream;
if (stream.CanSeek) {
fileLen = (int) stream.Length;
bufLen = Math.Min(fileLen, MAX_BUFFER_LENGTH);
bufStart = Int32.MaxValue; // nothing in the buffer so far
} else {
fileLen = bufLen = bufStart = 0;
}
buf = new byte[(bufLen>0) ? bufLen : MIN_BUFFER_LENGTH];
if (fileLen > 0) Pos = 0; // setup buffer to position 0 (start)
else bufPos = 0; // index 0 is already after the file, thus Pos = 0 is invalid
if (bufLen == fileLen && stream.CanSeek) Close();
}
protected Buffer(Buffer b) { // called in UTF8Buffer constructor
buf = b.buf;
bufStart = b.bufStart;
bufLen = b.bufLen;
fileLen = b.fileLen;
bufPos = b.bufPos;
stream = b.stream;
// keep destructor from closing the stream
b.stream = null;
isUserStream = b.isUserStream;
}
~Buffer() { Close(); }
protected void Close() {
if (!isUserStream && stream != null) {
stream.Close();
stream = null;
}
}
public virtual int Read () {
if (bufPos < bufLen) {
return buf[bufPos++];
} else if (Pos < fileLen) {
Pos = Pos; // shift buffer start to Pos
return buf[bufPos++];
} else if (stream != null && !stream.CanSeek && ReadNextStreamChunk() > 0) {
return buf[bufPos++];
} else {
return EOF;
}
}
public int Peek () {
int curPos = Pos;
int ch = Read();
Pos = curPos;
return ch;
}
// beg .. begin, zero-based, inclusive, in byte
// end .. end, zero-based, exclusive, in byte
public string GetString (int beg, int end) {
int len = 0;
char[] buf = new char[end - beg];
int oldPos = Pos;
Pos = beg;
while (Pos < end) buf[len++] = (char) Read();
Pos = oldPos;
return new String(buf, 0, len);
}
public int Pos {
get { return bufPos + bufStart; }
set {
if (value >= fileLen && stream != null && !stream.CanSeek) {
// Wanted position is after buffer and the stream
// is not seek-able e.g. network or console,
// thus we have to read the stream manually till
// the wanted position is in sight.
while (value >= fileLen && ReadNextStreamChunk() > 0);
}
if (value < 0 || value > fileLen) {
throw new FatalError("buffer out of bounds access, position: " + value);
}
if (value >= bufStart && value < bufStart + bufLen) { // already in buffer
bufPos = value - bufStart;
} else if (stream != null) { // must be swapped in
stream.Seek(value, SeekOrigin.Begin);
bufLen = stream.Read(buf, 0, buf.Length);
bufStart = value; bufPos = 0;
} else {
// set the position to the end of the file, Pos will return fileLen.
bufPos = fileLen - bufStart;
}
}
}
// Read the next chunk of bytes from the stream, increases the buffer
// if needed and updates the fields fileLen and bufLen.
// Returns the number of bytes read.
private int ReadNextStreamChunk() {
int free = buf.Length - bufLen;
if (free == 0) {
// in the case of a growing input stream
// we can neither seek in the stream, nor can we
// foresee the maximum length, thus we must adapt
// the buffer size on demand.
byte[] newBuf = new byte[bufLen * 2];
Array.Copy(buf, newBuf, bufLen);
buf = newBuf;
free = bufLen;
}
int read = stream.Read(buf, bufLen, free);
if (read > 0) {
fileLen = bufLen = (bufLen + read);
return read;
}
// end of stream reached
return 0;
}
}
//-----------------------------------------------------------------------------------
// UTF8Buffer
//-----------------------------------------------------------------------------------
public class UTF8Buffer: Buffer {
public UTF8Buffer(Buffer b): base(b) {}
public override int Read() {
int ch;
do {
ch = base.Read();
// until we find a utf8 start (0xxxxxxx or 11xxxxxx)
} while ((ch >= 128) && ((ch & 0xC0) != 0xC0) && (ch != EOF));
if (ch < 128 || ch == EOF) {
// nothing to do, first 127 chars are the same in ascii and utf8
// 0xxxxxxx or end of file character
} else if ((ch & 0xF0) == 0xF0) {
// 11110xxx 10xxxxxx 10xxxxxx 10xxxxxx
int c1 = ch & 0x07; ch = base.Read();
int c2 = ch & 0x3F; ch = base.Read();
int c3 = ch & 0x3F; ch = base.Read();
int c4 = ch & 0x3F;
ch = (((((c1 << 6) | c2) << 6) | c3) << 6) | c4;
} else if ((ch & 0xE0) == 0xE0) {
// 1110xxxx 10xxxxxx 10xxxxxx
int c1 = ch & 0x0F; ch = base.Read();
int c2 = ch & 0x3F; ch = base.Read();
int c3 = ch & 0x3F;
ch = (((c1 << 6) | c2) << 6) | c3;
} else if ((ch & 0xC0) == 0xC0) {
// 110xxxxx 10xxxxxx
int c1 = ch & 0x1F; ch = base.Read();
int c2 = ch & 0x3F;
ch = (c1 << 6) | c2;
}
return ch;
}
}
//-----------------------------------------------------------------------------------
// Scanner
//-----------------------------------------------------------------------------------
public class Scanner {
const char EOL = '\n';
const int eofSym = 0; /* pdt */
-->declarations
public Buffer buffer; // scanner buffer
Token t; // current token
int ch; // current input character
int pos; // byte position of current character
int charPos; // position by unicode characters starting with 0
int col; // column number of current character
int line; // line number of current character
int oldEols; // EOLs that appeared in a comment;
static readonly Dictionary<int, int> start; // maps first token character to start state
Token tokens; // list of tokens already peeked (first token is a dummy)
Token pt; // current peek token
char[] tval = new char[128]; // text of current token
int tlen; // length of current token
static Scanner() {
start = new Dictionary<int, int>(128);
-->initialization
}
public Scanner (string fileName) {
try {
Stream stream = new FileStream(fileName, FileMode.Open, FileAccess.Read, FileShare.Read);
buffer = new Buffer(stream, false);
Init();
} catch (IOException) {
throw new FatalError("Cannot open file " + fileName);
}
}
public Scanner (Stream s) {
buffer = new Buffer(s, true);
Init();
}
void Init() {
pos = -1; line = 1; col = 0; charPos = -1;
oldEols = 0;
NextCh();
if (ch == 0xEF) { // check optional byte order mark for UTF-8
NextCh(); int ch1 = ch;
NextCh(); int ch2 = ch;
if (ch1 != 0xBB || ch2 != 0xBF) {
throw new FatalError(String.Format("illegal byte order mark: EF {0,2:X} {1,2:X}", ch1, ch2));
}
buffer = new UTF8Buffer(buffer); col = 0; charPos = -1;
NextCh();
}
pt = tokens = new Token(); // first token is a dummy
}
void NextCh() {
if (oldEols > 0) { ch = EOL; oldEols--; }
else {
pos = buffer.Pos;
// buffer reads unicode chars, if UTF8 has been detected
ch = buffer.Read(); col++; charPos++;
// replace isolated '\r' by '\n' in order to make
// eol handling uniform across Windows, Unix and Mac
if (ch == '\r' && buffer.Peek() != '\n') ch = EOL;
if (ch == EOL) { line++; col = 0; }
}
-->casing1
}
void AddCh() {
if (tlen >= tval.Length) {
char[] newBuf = new char[2 * tval.Length];
Array.Copy(tval, 0, newBuf, 0, tval.Length);
tval = newBuf;
}
if (ch != Buffer.EOF) {
-->casing2
NextCh();
}
}
-->comments
void CheckLiteral() {
-->literals
}
Token NextToken() {
while (ch == ' ' ||
-->scan1
) NextCh();
-->scan2
int recKind = noSym;
int recEnd = pos;
t = new Token();
t.pos = pos; t.col = col; t.line = line; t.charPos = charPos;
int state;
state = (int) start[ch];
tlen = 0; AddCh();
switch (state) {
case -1: { t.kind = eofSym; break; } // NextCh already done
case 0: {
if (recKind != noSym) {
tlen = recEnd - t.pos;
SetScannerBehindT();
}
t.kind = recKind; break;
} // NextCh already done
-->scan3
}
t.val = new String(tval, 0, tlen);
return t;
}
private void SetScannerBehindT() {
buffer.Pos = t.pos;
NextCh();
line = t.line; col = t.col; charPos = t.charPos;
for (int i = 0; i < tlen; i++) NextCh();
}
// get the next token (possibly a token already seen during peeking)
public Token Scan () {
if (tokens.next == null) {
return NextToken();
} else {
pt = tokens = tokens.next;
return tokens;
}
}
// peek for the next token, ignore pragmas
public Token Peek () {
do {
if (pt.next == null) {
pt.next = NextToken();
}
pt = pt.next;
} while (pt.kind > maxT); // skip pragmas
return pt;
}
// make sure that peeking starts at the current scan position
public void ResetPeek () { pt = tokens; }
} // end Scanner

View file

@ -0,0 +1,337 @@
using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;
using System.IO;
using System.Threading;
using csmic.Scripting;
using System.Runtime.Remoting.Messaging;
namespace csmic
{
/// <summary>
/// A builder object that executes macro scripts.
/// </summary>
public class MacroBuilder
{
#region Members
/// <summary>
/// The input inputInterpreter.
/// </summary>
private InputInterpreter interpreter;
/// <summary> The script to run as a macro. </summary>
private string script;
/// <summary>
/// The output as a list of strings.
/// </summary>
private List<string> output;
/// <summary>
/// The time for execution.
/// </summary>
private TimeSpan executionTime;
/// <summary>
/// The root macro operation.
/// </summary>
private MacroOperation rootOperation;
#endregion
#region Constructor
/// <summary>
/// Creates a new builder object that executes a given macro script.
/// </summary>
/// <param name="script">A list of strings representing the macro.</param>
/// <param name="inputInterpreter">The InputInterpreter to be used.</param>
public MacroBuilder(string script, InputInterpreter inputInterpreter)
{
this.output = new List<string>();
this.executionTime = new TimeSpan();
this.script = script;
this.interpreter = inputInterpreter;
}
/// <summary>
/// Creates a new builder object that executes a given macro script.
/// </summary>
/// <param name="script">A list of strings representing the macro.</param>
/// <param name="inputInterpreter">The InputInterpreter to be used.</param>
internal MacroBuilder(MacroOperation script, InputInterpreter inputInterpreter)
{
this.output = new List<string>();
this.executionTime = new TimeSpan();
DateTime timeStart = DateTime.Now;
this.interpreter = inputInterpreter;
this.rootOperation = script;
ExecuteOperation(this.rootOperation);
DateTime timeEnd = DateTime.Now;
this.executionTime = timeEnd - timeStart;
}
#endregion
#region Properties
/// <summary>
/// Gets a list of strings representing the output.
/// </summary>
public List<string> Output
{
get
{
return this.output;
}
}
/// <summary>
/// Gets the execution time of the last script computation.
/// </summary>
public TimeSpan LastExecutionTime
{
get
{
return this.executionTime;
}
}
/// <summary>
/// Gets the decimal value last computed by the macrobuilder.
/// </summary>
public string FinalOutput
{
get
{
return this.interpreter.Output;
}
}
#endregion
#region Public Methods
/// <summary> Runs this macro. </summary>
public void Run()
{
DateTime timeStart = DateTime.Now;
ASCIIEncoding encoder = new ASCIIEncoding();
Parser p = new Parser(new Scanner(new MemoryStream(encoder.GetBytes(this.script))));
p.Parse();
this.rootOperation = p.Root;
ExecuteOperation(p.Root);
DateTime timeEnd = DateTime.Now;
this.executionTime = timeEnd - timeStart;
}
#endregion
#region Private Methods
private void ExecuteOperation(MacroOperation operation)
{
switch (operation.OperationType)
{
case OperationType.If:
if (operation.Input.Count == 1)
{
this.interpreter.Interpret(operation.Input[0]);
if (this.interpreter.Decimal == 1)
{
foreach (MacroOperation op in operation.Children)
{
ExecuteOperation(op);
}
}
}
break;
case OperationType.Else:
foreach (MacroOperation op in operation.Children)
{
ExecuteOperation(op);
}
break;
case OperationType.IfElse:
if (operation.Children.Count == 2 && operation.Children[0].Input.Count == 1)
{
MacroOperation ifOp = operation.Children[0];
MacroOperation elseOp = operation.Children[1];
this.interpreter.Interpret(ifOp.Input[0]);
if (this.interpreter.Decimal == 1)
{
foreach (MacroOperation op in ifOp.Children)
{
ExecuteOperation(op);
}
}
else
{
foreach (MacroOperation op in elseOp.Children)
{
ExecuteOperation(op);
}
}
}
break;
case OperationType.While:
if (operation.Input.Count == 1)
{
this.interpreter.Interpret(operation.Input[0]);
while (this.interpreter.Decimal == 1)
{
foreach (MacroOperation op in operation.Children)
{
ExecuteOperation(op);
}
this.interpreter.Interpret(operation.Input[0]);
}
}
break;
case OperationType.For:
if (operation.Input.Count == 3)
{
this.interpreter.Interpret(operation.Input[0]);
this.interpreter.Interpret(operation.Input[1]);
int loopCount = this.interpreter.Int;
while (this.interpreter.Int == 1)
{
foreach (MacroOperation op in operation.Children)
{
ExecuteOperation(op);
}
this.interpreter.Interpret(operation.Input[2]);
this.interpreter.Interpret(operation.Input[1]);
}
}
break;
case OperationType.FunctionDeclaration:
if (operation.Input.Count > 1)
{
string name = operation.Input[0];
operation.Input.RemoveAt(0);
StringBuilder builder = new StringBuilder();
operation.OperationType = OperationType.Unknown;
InterpretedFunction function = new InterpretedFunction(name, operation, operation.Input.ToArray());
if (this.interpreter.InterpretedFunctions.Contains(function))
{
this.interpreter.InterpretedFunctions[this.interpreter.InterpretedFunctions.IndexOf(function)] = function;
}
else
{
this.interpreter.InterpretedFunctions.Add(function);
}
}
break;
case OperationType.Echo:
if (operation.Children.Count == 1)
{
MacroOperation op = operation.Children[0];
if (op.OperationType == OperationType.Statement)
{
this.interpreter.Interpret(op.Input[0]);
this.output.Add(this.interpreter.Output);
}
}
break;
case OperationType.Say:
if (operation.Input.Count == 1)
{
this.output.Add(operation.Input[0]);
}
break;
case OperationType.Display:
StringBuilder sb = new StringBuilder();
foreach (MacroOperation op in operation.Children)
{
if (op.OperationType == OperationType.Statement)
{
if (op.Input.Count == 1)
{
this.interpreter.Interpret(op.Input[0]);
sb.Append(this.interpreter.Output);
}
}
else if (op.OperationType == OperationType.String)
{
if (op.Input.Count == 1)
{
sb.Append(op.Input[0]);
}
}
}
this.output.Add(sb.ToString());
break;
case OperationType.Statement:
if (operation.Input.Count == 1)
{
this.interpreter.Interpret(operation.Input[0]);
}
break;
case OperationType.String:
//Should not reach this state.
break;
case OperationType.Unknown:
if (operation.Children.Count > 0)
{
foreach (MacroOperation op in operation.Children)
{
ExecuteOperation(op);
}
}
break;
default:
//CRAP.
break;
}
}
#endregion
#region Asynchronous
/// <summary> Executes the asynchronous operation. </summary>
/// <param name="input"> The input. </param>
/// <param name="callback"> The callback. </param>
public void RunAsync(string input, Action<MacroBuilder> callback)
{
MacroAsyncDelegate del = new MacroAsyncDelegate(RunAsyncThreadingWork);
del.BeginInvoke(input, (result) =>
{
AsyncResult returned = result as AsyncResult;
if (returned != null)
{
MacroAsyncDelegate end = returned.AsyncDelegate as MacroAsyncDelegate;
if (end != null)
{
MacroBuilder returnValue = end.EndInvoke(result);
callback(returnValue);
}
}
}, null);
}
/// <summary> Executes the asynchronous threading work operation. </summary>
/// <param name="input"> The input. </param>
/// <returns> . </returns>
private MacroBuilder RunAsyncThreadingWork(string input)
{
Run();
return this;
}
/// <summary> Macro asynchronous delegate. </summary>
/// <param name="input"> The input. </param>
/// <returns> . </returns>
private delegate MacroBuilder MacroAsyncDelegate(string input);
#endregion
}
}

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using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;
namespace csmic
{
/// <summary>
/// Represents the operation types supported by a scripted macro.
/// </summary>
internal enum OperationType
{
/// <summary>
/// Represents a conditional block.
/// </summary>
If,
/// <summary>
/// Represents a conditional else block.
/// </summary>
Else,
/// <summary>
/// Represents a complete conditional block.
/// </summary>
IfElse,
/// <summary>
/// A while block.
/// </summary>
While,
/// <summary>
/// A for block.
/// </summary>
For,
/// <summary>
/// A function declaration.
/// </summary>
FunctionDeclaration,
/// <summary>
/// An echo statement.
/// </summary>
Echo,
/// <summary>
/// A say statement.
/// </summary>
Say,
/// <summary>
/// A display statement.
/// </summary>
Display,
/// <summary>
/// A statement to execute.
/// </summary>
Statement,
/// <summary>
/// A string to display.
/// </summary>
String,
/// <summary>
/// An unknown or malformed block.
/// </summary>
Unknown
}
/// <summary>
/// An operation object that executes a specified action.
/// </summary>
internal class MacroOperation
{
#region Members
/// <summary>
/// The type of operation represented by the operation.
/// </summary>
private OperationType operationType;
/// <summary>
/// The collection of children nodes that belong to the operation.
/// </summary>
private List<MacroOperation> children;
/// <summary>
/// A list of the necesary input to execute the operation.
/// </summary>
private List<string> input;
#endregion
#region Constructor
/// <summary>
/// Creates a new macro operation node.
/// </summary>
/// <param name="operationType">The type of operation the node represents.</param>
public MacroOperation(OperationType operationType)
{
this.operationType = operationType;
this.children = new List<MacroOperation>();
this.input = new List<string>();
}
#endregion
#region Properties
/// <summary>
/// Gets or sets the children nodes of the operation.
/// </summary>
public List<MacroOperation> Children
{
get
{
return this.children;
}
set
{
this.children = value;
}
}
/// <summary>
/// Gets or sets the input for the operation.
/// </summary>
public List<string> Input
{
get
{
return this.input;
}
set
{
this.input = value;
}
}
/// <summary>
/// Gets or sets the operation type for this operation.
/// </summary>
public OperationType OperationType
{
get
{
return this.operationType;
}
set
{
this.operationType = value;
}
}
#endregion
}
}

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@ -0,0 +1,36 @@
using System.Reflection;
using System.Runtime.CompilerServices;
using System.Runtime.InteropServices;
// General Information about an assembly is controlled through the following
// set of attributes. Change these attribute values to modify the information
// associated with an assembly.
[assembly: AssemblyTitle("csmic")]
[assembly: AssemblyDescription("A .NET component for easy access to parsing simple math and scripting.")]
[assembly: AssemblyConfiguration("")]
[assembly: AssemblyCompany("Jordan Wages")]
[assembly: AssemblyProduct("csmic")]
[assembly: AssemblyCopyright("Copyright © 2012")]
[assembly: AssemblyTrademark("")]
[assembly: AssemblyCulture("")]
// Setting ComVisible to false makes the types in this assembly not visible
// to COM components. If you need to access a type in this assembly from
// COM, set the ComVisible attribute to true on that type.
[assembly: ComVisible(false)]
// The following GUID is for the ID of the typelib if this project is exposed to COM
[assembly: Guid("e36b7d85-f0e6-4f24-ba03-ac53124dd97e")]
// Version information for an assembly consists of the following four values:
//
// Major Version
// Minor Version
// Build Number
// Revision
//
// You can specify all the values or you can default the Build and Revision Numbers
// by using the '*' as shown below:
// [assembly: AssemblyVersion("1.0.*")]
[assembly: AssemblyVersion("1.1.5.0")]
[assembly: AssemblyFileVersion("1.1.5.0")]

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using csmic;
using System.Text;
using System.Collections.Generic;
using System;
using System.CodeDom.Compiler;
namespace csmic.Scripting {
[GeneratedCodeAttribute("Coco/R", "")]
public class Parser {
public const int _EOF = 0;
public const int _identifier = 1;
public const int _sign = 2;
public const int _binary = 3;
public const int _hex = 4;
public const int _number = 5;
public const int _newline = 6;
public const int _string = 7;
public const int _LPAREN = 8;
public const int _RPAREN = 9;
public const int _COMPARER = 10;
public const int maxT = 34;
const bool T = true;
const bool x = false;
const int minErrDist = 2;
public Scanner scanner;
public Errors errors;
public Token t; // last recognized token
public Token la; // lookahead token
int errDist = minErrDist;
private MacroOperation root = new MacroOperation(OperationType.Unknown);
internal MacroOperation Root
{
get
{
return this.root;
}
set
{
this.root = value;
}
}
bool IsFunctionCall()
{
scanner.ResetPeek();
Token next = scanner.Peek();
if (next.kind == _LPAREN && la.kind == _identifier)
return true;
return false;
}
bool IsCompare()
{
scanner.ResetPeek();
Token next = scanner.Peek();
if (next.kind == _COMPARER)
return true;
return false;
}
bool IsAssignment()
{
scanner.ResetPeek();
Token next = scanner.Peek();
if (next.val == "::" || next.val == ":=" || next.val == "->")
return true;
return false;
}
bool IsArrayCall()
{
scanner.ResetPeek();
Token next = scanner.Peek();
if(next.val == "[")
return true;
return false;
}
public Parser(Scanner scanner) {
this.scanner = scanner;
errors = new Errors();
}
void SynErr (int n) {
if (errDist >= minErrDist) errors.SynErr(la.line, la.col, n);
errDist = 0;
}
public void SemErr (string msg) {
if (errDist >= minErrDist) errors.SemErr(t.line, t.col, msg);
errDist = 0;
}
void Get () {
for (;;) {
t = la;
la = scanner.Scan();
if (la.kind <= maxT) { ++errDist; break; }
la = t;
}
}
void Expect (int n) {
if (la.kind==n) Get(); else { SynErr(n); }
}
bool StartOf (int s) {
return set[s, la.kind];
}
void ExpectWeak (int n, int follow) {
if (la.kind == n) Get();
else {
SynErr(n);
while (!StartOf(follow)) Get();
}
}
bool WeakSeparator(int n, int syFol, int repFol) {
int kind = la.kind;
if (kind == n) {Get(); return true;}
else if (StartOf(repFol)) {return false;}
else {
SynErr(n);
while (!(set[syFol, kind] || set[repFol, kind] || set[0, kind])) {
Get();
kind = la.kind;
}
return StartOf(syFol);
}
}
void SCRIPT() {
string statement = string.Empty;
while (StartOf(1)) {
switch (la.kind) {
case 1: case 3: case 4: case 5: case 8: case 22: case 23: {
Statement(out statement);
MacroOperation operation = new MacroOperation(OperationType.Statement);
operation.Input.Add(statement);
this.root.Children.Add(operation);
break;
}
case 11: {
IfBlock(ref this.root);
break;
}
case 15: {
WhileBlock(ref this.root);
break;
}
case 18: {
FunctionDeclaration(ref this.root);
break;
}
case 19: {
EchoStatement(ref this.root);
break;
}
case 20: {
SayStatement(ref this.root);
break;
}
case 21: {
DisplayStatement(ref this.root);
break;
}
case 16: {
ForBlock(ref this.root);
break;
}
}
}
}
void Statement(out string value) {
value = string.Empty;
StringBuilder builder = new StringBuilder();
if (IsAssignment()) {
Assignment(ref builder);
value = builder.ToString();
} else if (StartOf(2)) {
Expression(ref builder);
value = builder.ToString();
} else SynErr(35);
}
void IfBlock(ref MacroOperation parent) {
MacroOperation ifBlock = new MacroOperation(OperationType.If);
MacroOperation elseBlock = new MacroOperation(OperationType.Else);
string ifStatement = string.Empty;
string statement = string.Empty;
StringBuilder builder = new StringBuilder();
bool hasElse = false;
Expect(11);
Expect(8);
Comparison(ref builder);
ifStatement = builder.ToString(); ifBlock.Input.Add(ifStatement);
Expect(9);
Expect(12);
while (StartOf(3)) {
switch (la.kind) {
case 1: case 3: case 4: case 5: case 8: case 22: case 23: {
Statement(out statement);
MacroOperation operation = new MacroOperation(OperationType.Statement);
operation.Input.Add(statement);
ifBlock.Children.Add(operation);
break;
}
case 11: {
IfBlock(ref ifBlock);
break;
}
case 15: {
WhileBlock(ref ifBlock);
break;
}
case 19: {
EchoStatement(ref ifBlock);
break;
}
case 20: {
SayStatement(ref ifBlock);
break;
}
case 21: {
DisplayStatement(ref ifBlock);
break;
}
case 16: {
ForBlock(ref ifBlock);
break;
}
}
}
Expect(13);
if (la.kind == 14) {
Get();
hasElse = true;
Expect(12);
while (StartOf(3)) {
switch (la.kind) {
case 1: case 3: case 4: case 5: case 8: case 22: case 23: {
Statement(out statement);
MacroOperation operation = new MacroOperation(OperationType.Statement);
operation.Input.Add(statement);
elseBlock.Children.Add(operation);
break;
}
case 11: {
IfBlock(ref elseBlock);
break;
}
case 15: {
WhileBlock(ref elseBlock);
break;
}
case 19: {
EchoStatement(ref elseBlock);
break;
}
case 20: {
SayStatement(ref elseBlock);
break;
}
case 21: {
DisplayStatement(ref elseBlock);
break;
}
case 16: {
ForBlock(ref elseBlock);
break;
}
}
}
Expect(13);
}
if(hasElse)
{
MacroOperation ifelse = new MacroOperation(OperationType.IfElse);
ifelse.Children.Add(ifBlock);
ifelse.Children.Add(elseBlock);
parent.Children.Add(ifelse);
}
else
{
parent.Children.Add(ifBlock);
}
}
void WhileBlock(ref MacroOperation parent) {
StringBuilder builder = new StringBuilder();
MacroOperation whileBlock = new MacroOperation(OperationType.While);
string statement = string.Empty;
Expect(15);
Expect(8);
Comparison(ref builder);
whileBlock.Input.Add(builder.ToString());
Expect(9);
Expect(12);
while (StartOf(3)) {
switch (la.kind) {
case 1: case 3: case 4: case 5: case 8: case 22: case 23: {
Statement(out statement);
MacroOperation operation = new MacroOperation(OperationType.Statement);
operation.Input.Add(statement);
whileBlock.Children.Add(operation);
break;
}
case 11: {
IfBlock(ref whileBlock);
break;
}
case 15: {
WhileBlock(ref whileBlock);
break;
}
case 19: {
EchoStatement(ref whileBlock);
break;
}
case 20: {
SayStatement(ref whileBlock);
break;
}
case 21: {
DisplayStatement(ref whileBlock);
break;
}
case 16: {
ForBlock(ref whileBlock);
break;
}
}
}
Expect(13);
parent.Children.Add(whileBlock);
}
void FunctionDeclaration(ref MacroOperation parent) {
StringBuilder builder = new StringBuilder();
string statement = string.Empty;
MacroOperation func = new MacroOperation(OperationType.FunctionDeclaration);
Expect(18);
Expect(8);
CommaList(ref builder);
string[] args = builder.ToString().Split(','); func.Input.AddRange(args);
Expect(9);
Expect(12);
while (StartOf(3)) {
switch (la.kind) {
case 1: case 3: case 4: case 5: case 8: case 22: case 23: {
Statement(out statement);
MacroOperation operation = new MacroOperation(OperationType.Statement);
operation.Input.Add(statement);
func.Children.Add(operation);
break;
}
case 11: {
IfBlock(ref func);
break;
}
case 15: {
WhileBlock(ref func);
break;
}
case 19: {
EchoStatement(ref func);
break;
}
case 20: {
SayStatement(ref func);
break;
}
case 21: {
DisplayStatement(ref func);
break;
}
case 16: {
ForBlock(ref func);
break;
}
}
}
Expect(13);
parent.Children.Add(func);
}
void EchoStatement(ref MacroOperation parent) {
StringBuilder builder = new StringBuilder();
MacroOperation echoStatement = new MacroOperation(OperationType.Echo);
string statement = string.Empty;
Expect(19);
Statement(out statement);
MacroOperation operation = new MacroOperation(OperationType.Statement);
operation.Input.Add(statement);
echoStatement.Children.Add(operation);
parent.Children.Add(echoStatement);
}
void SayStatement(ref MacroOperation parent) {
StringBuilder builder = new StringBuilder();
MacroOperation sayStatement = new MacroOperation(OperationType.Say);
string statement = string.Empty;
Expect(20);
Expect(7);
statement = t.val.Replace("\"", "");
sayStatement.Input.Add(statement);
parent.Children.Add(sayStatement);
}
void DisplayStatement(ref MacroOperation parent) {
StringBuilder builder = new StringBuilder();
MacroOperation displayStatement = new MacroOperation(OperationType.Display);
string statement = string.Empty;
Expect(21);
if (StartOf(2)) {
Statement(out statement);
MacroOperation operation = new MacroOperation(OperationType.Statement);
operation.Input.Add(statement);
displayStatement.Children.Add(operation);
} else if (la.kind == 7) {
Get();
statement = t.val.Replace("\"", "");
MacroOperation operation = new MacroOperation(OperationType.String);
operation.Input.Add(statement);
displayStatement.Children.Add(operation);
} else SynErr(36);
while (la.kind == 17) {
Get();
if (StartOf(2)) {
Statement(out statement);
MacroOperation operation = new MacroOperation(OperationType.Statement);
operation.Input.Add(statement);
displayStatement.Children.Add(operation);
} else if (la.kind == 7) {
Get();
statement = t.val.Replace("\"", "");
MacroOperation operation = new MacroOperation(OperationType.String);
operation.Input.Add(statement);
displayStatement.Children.Add(operation);
} else SynErr(37);
}
parent.Children.Add(displayStatement);
}
void ForBlock(ref MacroOperation parent) {
StringBuilder builder = new StringBuilder();
string statement = string.Empty;
string statement2 = string.Empty;
MacroOperation forBlock = new MacroOperation(OperationType.For);
Expect(16);
Expect(8);
Statement(out statement);
Expect(17);
Comparison(ref builder);
Expect(17);
Statement(out statement2);
forBlock.Input.Add(statement); forBlock.Input.Add(builder.ToString()); forBlock.Input.Add(statement2);
Expect(9);
Expect(12);
while (StartOf(3)) {
switch (la.kind) {
case 1: case 3: case 4: case 5: case 8: case 22: case 23: {
Statement(out statement);
MacroOperation operation = new MacroOperation(OperationType.Statement);
operation.Input.Add(statement);
forBlock.Children.Add(operation);
break;
}
case 11: {
IfBlock(ref forBlock);
break;
}
case 15: {
WhileBlock(ref forBlock);
break;
}
case 19: {
EchoStatement(ref forBlock);
break;
}
case 20: {
SayStatement(ref forBlock);
break;
}
case 21: {
DisplayStatement(ref forBlock);
break;
}
case 16: {
ForBlock(ref forBlock);
break;
}
}
}
Expect(13);
parent.Children.Add(forBlock);
}
void Comparison(ref StringBuilder result) {
Expression(ref result);
Expect(10);
result.Append(t.val);
Expression(ref result);
}
void CommaList(ref StringBuilder builder) {
Expression(ref builder);
while (la.kind == 17) {
Get();
builder.Append(t.val);
Expression(ref builder);
}
}
void Assignment(ref StringBuilder builder) {
Expect(1);
builder.Append(t.val);
if (la.kind == 30) {
Get();
builder.Append(t.val);
Expression(ref builder);
} else if (la.kind == 31) {
Get();
builder.Append(t.val); string value = string.Empty;
AnyExpression(out value);
builder.Append(value);
Expect(6);
} else if (la.kind == 32) {
Get();
builder.Append(t.val);
ArrayL(ref builder);
} else SynErr(38);
}
void Expression(ref StringBuilder builder) {
Term(ref builder);
while (la.kind == 22 || la.kind == 23 || la.kind == 24) {
if (la.kind == 22) {
Get();
builder.Append(t.val);
Term(ref builder);
} else if (la.kind == 23) {
Get();
builder.Append(t.val);
Term(ref builder);
} else {
Get();
builder.Append(t.val);
Term(ref builder);
}
}
}
void Term(ref StringBuilder builder) {
Factor(ref builder);
while (la.kind == 25 || la.kind == 26) {
if (la.kind == 25) {
Get();
builder.Append(t.val);
Factor(ref builder);
} else {
Get();
builder.Append(t.val);
Factor(ref builder);
}
}
}
void Factor(ref StringBuilder builder) {
Value(ref builder);
while (la.kind == 27) {
Get();
builder.Append(t.val);
Value(ref builder);
}
}
void Value(ref StringBuilder builder) {
if (la.kind == 22 || la.kind == 23) {
if (la.kind == 22) {
Get();
builder.Append(t.val);
} else {
Get();
builder.Append(t.val);
}
}
if (IsFunctionCall()) {
Function(ref builder);
} else if (IsArrayCall()) {
ArrayCall(ref builder);
} else if (la.kind == 1) {
Get();
builder.Append(t.val);
} else if (la.kind == 5) {
Get();
builder.Append(t.val);
} else if (la.kind == 4) {
Get();
builder.Append(t.val);
} else if (la.kind == 3) {
Get();
builder.Append(t.val);
} else if (la.kind == 8) {
Get();
builder.Append(t.val);
Expression(ref builder);
Expect(9);
builder.Append(t.val);
} else SynErr(39);
}
void Function(ref StringBuilder builder) {
Expect(1);
builder.Append(t.val);
Expect(8);
builder.Append(t.val);
CommaList(ref builder);
Expect(9);
builder.Append(t.val);
}
void ArrayCall(ref StringBuilder builder) {
Expect(1);
builder.Append(t.val);
Expect(28);
builder.Append(t.val);
Expression(ref builder);
Expect(29);
builder.Append(t.val);
}
void ArrayL(ref StringBuilder builder) {
Expect(28);
builder.Append(t.val);
CommaList(ref builder);
Expect(29);
builder.Append(t.val);
}
void AnyExpression(out string value) {
value = string.Empty; StringBuilder builder = new StringBuilder();
Get();
builder.Append(t.val);
while (StartOf(4)) {
Get();
builder.Append(t.val);
}
Expect(33);
value = builder.ToString();
}
public void Parse() {
la = new Token();
la.val = "";
Get();
SCRIPT();
Expect(0);
Expect(0);
}
static readonly bool[,] set = {
{T,x,x,x, x,x,x,x, x,x,x,x, x,x,x,x, x,x,x,x, x,x,x,x, x,x,x,x, x,x,x,x, x,x,x,x},
{x,T,x,T, T,T,x,x, T,x,x,T, x,x,x,T, T,x,T,T, T,T,T,T, x,x,x,x, x,x,x,x, x,x,x,x},
{x,T,x,T, T,T,x,x, T,x,x,x, x,x,x,x, x,x,x,x, x,x,T,T, x,x,x,x, x,x,x,x, x,x,x,x},
{x,T,x,T, T,T,x,x, T,x,x,T, x,x,x,T, T,x,x,T, T,T,T,T, x,x,x,x, x,x,x,x, x,x,x,x},
{x,T,T,T, T,T,T,T, T,T,T,T, T,T,T,T, T,T,T,T, T,T,T,T, T,T,T,T, T,T,T,T, T,x,T,x}
};
} // end Parser
public class Errors {
public int count = 0; // number of errors detected
public System.IO.TextWriter errorStream = Console.Out; // error messages go to this stream
public string errMsgFormat = "-- line {0} col {1}: {2}"; // 0=line, 1=column, 2=text
public void SynErr (int line, int col, int n) {
string s;
switch (n) {
case 0: s = "EOF expected"; break;
case 1: s = "identifier expected"; break;
case 2: s = "sign expected"; break;
case 3: s = "binary expected"; break;
case 4: s = "hex expected"; break;
case 5: s = "number expected"; break;
case 6: s = "newline expected"; break;
case 7: s = "string expected"; break;
case 8: s = "LPAREN expected"; break;
case 9: s = "RPAREN expected"; break;
case 10: s = "COMPARER expected"; break;
case 11: s = "\"if\" expected"; break;
case 12: s = "\"{\" expected"; break;
case 13: s = "\"}\" expected"; break;
case 14: s = "\"else\" expected"; break;
case 15: s = "\"while\" expected"; break;
case 16: s = "\"for\" expected"; break;
case 17: s = "\",\" expected"; break;
case 18: s = "\"function\" expected"; break;
case 19: s = "\"echo:\" expected"; break;
case 20: s = "\"say:\" expected"; break;
case 21: s = "\"display:\" expected"; break;
case 22: s = "\"+\" expected"; break;
case 23: s = "\"-\" expected"; break;
case 24: s = "\"%\" expected"; break;
case 25: s = "\"*\" expected"; break;
case 26: s = "\"/\" expected"; break;
case 27: s = "\"^\" expected"; break;
case 28: s = "\"[\" expected"; break;
case 29: s = "\"]\" expected"; break;
case 30: s = "\"::\" expected"; break;
case 31: s = "\":=\" expected"; break;
case 32: s = "\"->\" expected"; break;
case 33: s = "\"\\n\" expected"; break;
case 34: s = "??? expected"; break;
case 35: s = "invalid Statement"; break;
case 36: s = "invalid DisplayStatement"; break;
case 37: s = "invalid DisplayStatement"; break;
case 38: s = "invalid Assignment"; break;
case 39: s = "invalid Value"; break;
default: s = "error " + n; break;
}
errorStream.WriteLine(errMsgFormat, line, col, s);
count++;
}
public void SemErr (int line, int col, string s) {
errorStream.WriteLine(errMsgFormat, line, col, s);
count++;
}
public void SemErr (string s) {
errorStream.WriteLine(s);
count++;
}
public void Warning (int line, int col, string s) {
errorStream.WriteLine(errMsgFormat, line, col, s);
}
public void Warning(string s) {
errorStream.WriteLine(s);
}
} // Errors
public class FatalError: Exception {
public FatalError(string m): base(m) {}
}
}

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@ -0,0 +1,160 @@
/*----------------------------------------------------------------------
Compiler Generator Coco/R,
Copyright (c) 1990, 2004 Hanspeter Moessenboeck, University of Linz
extended by M. Loeberbauer & A. Woess, Univ. of Linz
with improvements by Pat Terry, Rhodes University
This program is free software; you can redistribute it and/or modify it
under the terms of the GNU General Public License as published by the
Free Software Foundation; either version 2, or (at your option) any
later version.
This program is distributed in the hope that it will be useful, but
WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
for more details.
You should have received a copy of the GNU General Public License along
with this program; if not, write to the Free Software Foundation, Inc.,
59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
As an exception, it is allowed to write an extension of Coco/R that is
used as a plugin in non-free software.
If not otherwise stated, any source code generated by Coco/R (other than
Coco/R itself) does not fall under the GNU General Public License.
----------------------------------------------------------------------*/
-->begin
using System;
using System.CodeDom.Compiler;
-->namespace
[GeneratedCodeAttribute("Coco/R", "")]
public class Parser {
-->constants
const bool T = true;
const bool x = false;
const int minErrDist = 2;
public Scanner scanner;
public Errors errors;
public Token t; // last recognized token
public Token la; // lookahead token
int errDist = minErrDist;
-->declarations
public Parser(Scanner scanner) {
this.scanner = scanner;
errors = new Errors();
}
void SynErr (int n) {
if (errDist >= minErrDist) errors.SynErr(la.line, la.col, n);
errDist = 0;
}
public void SemErr (string msg) {
if (errDist >= minErrDist) errors.SemErr(t.line, t.col, msg);
errDist = 0;
}
void Get () {
for (;;) {
t = la;
la = scanner.Scan();
if (la.kind <= maxT) { ++errDist; break; }
-->pragmas
la = t;
}
}
void Expect (int n) {
if (la.kind==n) Get(); else { SynErr(n); }
}
bool StartOf (int s) {
return set[s, la.kind];
}
void ExpectWeak (int n, int follow) {
if (la.kind == n) Get();
else {
SynErr(n);
while (!StartOf(follow)) Get();
}
}
bool WeakSeparator(int n, int syFol, int repFol) {
int kind = la.kind;
if (kind == n) {Get(); return true;}
else if (StartOf(repFol)) {return false;}
else {
SynErr(n);
while (!(set[syFol, kind] || set[repFol, kind] || set[0, kind])) {
Get();
kind = la.kind;
}
return StartOf(syFol);
}
}
-->productions
public void Parse() {
la = new Token();
la.val = "";
Get();
-->parseRoot
Expect(0);
}
static readonly bool[,] set = {
-->initialization
};
} // end Parser
public class Errors {
public int count = 0; // number of errors detected
public System.IO.TextWriter errorStream = Console.Out; // error messages go to this stream
public string errMsgFormat = "-- line {0} col {1}: {2}"; // 0=line, 1=column, 2=text
public void SynErr (int line, int col, int n) {
string s;
switch (n) {
-->errors
default: s = "error " + n; break;
}
errorStream.WriteLine(errMsgFormat, line, col, s);
count++;
}
public void SemErr (int line, int col, string s) {
errorStream.WriteLine(errMsgFormat, line, col, s);
count++;
}
public void SemErr (string s) {
errorStream.WriteLine(s);
count++;
}
public void Warning (int line, int col, string s) {
errorStream.WriteLine(errMsgFormat, line, col, s);
}
public void Warning(string s) {
errorStream.WriteLine(s);
}
} // Errors
public class FatalError: Exception {
public FatalError(string m): base(m) {}
}

View file

@ -0,0 +1,637 @@
using System;
using System.IO;
using System.Collections;
using System.Collections.Generic;
using System.CodeDom.Compiler;
namespace csmic.Scripting {
[GeneratedCodeAttribute("Coco/R", "")]
public class Token {
public int kind; // token kind
public int pos; // token position in bytes in the source text (starting at 0)
public int charPos; // token position in characters in the source text (starting at 0)
public int col; // token column (starting at 1)
public int line; // token line (starting at 1)
public string val; // token value
public Token next; // ML 2005-03-11 Tokens are kept in linked list
}
//-----------------------------------------------------------------------------------
// Buffer
//-----------------------------------------------------------------------------------
public class Buffer {
// This Buffer supports the following cases:
// 1) seekable stream (file)
// a) whole stream in buffer
// b) part of stream in buffer
// 2) non seekable stream (network, console)
public const int EOF = char.MaxValue + 1;
const int MIN_BUFFER_LENGTH = 1024; // 1KB
const int MAX_BUFFER_LENGTH = MIN_BUFFER_LENGTH * 64; // 64KB
byte[] buf; // input buffer
int bufStart; // position of first byte in buffer relative to input stream
int bufLen; // length of buffer
int fileLen; // length of input stream (may change if the stream is no file)
int bufPos; // current position in buffer
Stream stream; // input stream (seekable)
bool isUserStream; // was the stream opened by the user?
public Buffer (Stream s, bool isUserStream) {
stream = s; this.isUserStream = isUserStream;
if (stream.CanSeek) {
fileLen = (int) stream.Length;
bufLen = Math.Min(fileLen, MAX_BUFFER_LENGTH);
bufStart = Int32.MaxValue; // nothing in the buffer so far
} else {
fileLen = bufLen = bufStart = 0;
}
buf = new byte[(bufLen>0) ? bufLen : MIN_BUFFER_LENGTH];
if (fileLen > 0) Pos = 0; // setup buffer to position 0 (start)
else bufPos = 0; // index 0 is already after the file, thus Pos = 0 is invalid
if (bufLen == fileLen && stream.CanSeek) Close();
}
protected Buffer(Buffer b) { // called in UTF8Buffer constructor
buf = b.buf;
bufStart = b.bufStart;
bufLen = b.bufLen;
fileLen = b.fileLen;
bufPos = b.bufPos;
stream = b.stream;
// keep destructor from closing the stream
b.stream = null;
isUserStream = b.isUserStream;
}
~Buffer() { Close(); }
protected void Close() {
if (!isUserStream && stream != null) {
stream.Close();
stream = null;
}
}
public virtual int Read () {
if (bufPos < bufLen) {
return buf[bufPos++];
} else if (Pos < fileLen) {
Pos = Pos; // shift buffer start to Pos
return buf[bufPos++];
} else if (stream != null && !stream.CanSeek && ReadNextStreamChunk() > 0) {
return buf[bufPos++];
} else {
return EOF;
}
}
public int Peek () {
int curPos = Pos;
int ch = Read();
Pos = curPos;
return ch;
}
// beg .. begin, zero-based, inclusive, in byte
// end .. end, zero-based, exclusive, in byte
public string GetString (int beg, int end) {
int len = 0;
char[] buf = new char[end - beg];
int oldPos = Pos;
Pos = beg;
while (Pos < end) buf[len++] = (char) Read();
Pos = oldPos;
return new String(buf, 0, len);
}
public int Pos {
get { return bufPos + bufStart; }
set {
if (value >= fileLen && stream != null && !stream.CanSeek) {
// Wanted position is after buffer and the stream
// is not seek-able e.g. network or console,
// thus we have to read the stream manually till
// the wanted position is in sight.
while (value >= fileLen && ReadNextStreamChunk() > 0);
}
if (value < 0 || value > fileLen) {
throw new FatalError("buffer out of bounds access, position: " + value);
}
if (value >= bufStart && value < bufStart + bufLen) { // already in buffer
bufPos = value - bufStart;
} else if (stream != null) { // must be swapped in
stream.Seek(value, SeekOrigin.Begin);
bufLen = stream.Read(buf, 0, buf.Length);
bufStart = value; bufPos = 0;
} else {
// set the position to the end of the file, Pos will return fileLen.
bufPos = fileLen - bufStart;
}
}
}
// Read the next chunk of bytes from the stream, increases the buffer
// if needed and updates the fields fileLen and bufLen.
// Returns the number of bytes read.
private int ReadNextStreamChunk() {
int free = buf.Length - bufLen;
if (free == 0) {
// in the case of a growing input stream
// we can neither seek in the stream, nor can we
// foresee the maximum length, thus we must adapt
// the buffer size on demand.
byte[] newBuf = new byte[bufLen * 2];
Array.Copy(buf, newBuf, bufLen);
buf = newBuf;
free = bufLen;
}
int read = stream.Read(buf, bufLen, free);
if (read > 0) {
fileLen = bufLen = (bufLen + read);
return read;
}
// end of stream reached
return 0;
}
}
//-----------------------------------------------------------------------------------
// UTF8Buffer
//-----------------------------------------------------------------------------------
public class UTF8Buffer: Buffer {
public UTF8Buffer(Buffer b): base(b) {}
public override int Read() {
int ch;
do {
ch = base.Read();
// until we find a utf8 start (0xxxxxxx or 11xxxxxx)
} while ((ch >= 128) && ((ch & 0xC0) != 0xC0) && (ch != EOF));
if (ch < 128 || ch == EOF) {
// nothing to do, first 127 chars are the same in ascii and utf8
// 0xxxxxxx or end of file character
} else if ((ch & 0xF0) == 0xF0) {
// 11110xxx 10xxxxxx 10xxxxxx 10xxxxxx
int c1 = ch & 0x07; ch = base.Read();
int c2 = ch & 0x3F; ch = base.Read();
int c3 = ch & 0x3F; ch = base.Read();
int c4 = ch & 0x3F;
ch = (((((c1 << 6) | c2) << 6) | c3) << 6) | c4;
} else if ((ch & 0xE0) == 0xE0) {
// 1110xxxx 10xxxxxx 10xxxxxx
int c1 = ch & 0x0F; ch = base.Read();
int c2 = ch & 0x3F; ch = base.Read();
int c3 = ch & 0x3F;
ch = (((c1 << 6) | c2) << 6) | c3;
} else if ((ch & 0xC0) == 0xC0) {
// 110xxxxx 10xxxxxx
int c1 = ch & 0x1F; ch = base.Read();
int c2 = ch & 0x3F;
ch = (c1 << 6) | c2;
}
return ch;
}
}
//-----------------------------------------------------------------------------------
// Scanner
//-----------------------------------------------------------------------------------
public class Scanner {
const char EOL = '\n';
const int eofSym = 0; /* pdt */
const int maxT = 34;
const int noSym = 34;
public Buffer buffer; // scanner buffer
Token t; // current token
int ch; // current input character
int pos; // byte position of current character
int charPos; // position by unicode characters starting with 0
int col; // column number of current character
int line; // line number of current character
int oldEols; // EOLs that appeared in a comment;
static readonly Dictionary<int, int> start; // maps first token character to start state
Token tokens; // list of tokens already peeked (first token is a dummy)
Token pt; // current peek token
char[] tval = new char[128]; // text of current token
int tlen; // length of current token
static Scanner() {
start = new Dictionary<int, int>(128);
for (int i = 65; i <= 90; ++i) start[i] = 1;
for (int i = 97; i <= 99; ++i) start[i] = 1;
for (int i = 102; i <= 114; ++i) start[i] = 1;
for (int i = 116; i <= 122; ++i) start[i] = 1;
start[43] = 2;
for (int i = 50; i <= 57; ++i) start[i] = 6;
for (int i = 10; i <= 10; ++i) start[i] = 12;
for (int i = 13; i <= 13; ++i) start[i] = 11;
start[48] = 19;
start[49] = 20;
start[34] = 13;
start[40] = 15;
start[41] = 16;
start[61] = 17;
start[60] = 21;
start[62] = 22;
start[123] = 23;
start[125] = 24;
start[44] = 25;
start[101] = 38;
start[115] = 39;
start[100] = 40;
start[37] = 29;
start[42] = 30;
start[47] = 31;
start[94] = 32;
start[91] = 33;
start[93] = 34;
start[58] = 41;
start[45] = 42;
start[Buffer.EOF] = -1;
}
public Scanner (string fileName) {
try {
Stream stream = new FileStream(fileName, FileMode.Open, FileAccess.Read, FileShare.Read);
buffer = new Buffer(stream, false);
Init();
} catch (IOException) {
throw new FatalError("Cannot open file " + fileName);
}
}
public Scanner (Stream s) {
buffer = new Buffer(s, true);
Init();
}
void Init() {
pos = -1; line = 1; col = 0; charPos = -1;
oldEols = 0;
NextCh();
if (ch == 0xEF) { // check optional byte order mark for UTF-8
NextCh(); int ch1 = ch;
NextCh(); int ch2 = ch;
if (ch1 != 0xBB || ch2 != 0xBF) {
throw new FatalError(String.Format("illegal byte order mark: EF {0,2:X} {1,2:X}", ch1, ch2));
}
buffer = new UTF8Buffer(buffer); col = 0; charPos = -1;
NextCh();
}
pt = tokens = new Token(); // first token is a dummy
}
void NextCh() {
if (oldEols > 0) { ch = EOL; oldEols--; }
else {
pos = buffer.Pos;
// buffer reads unicode chars, if UTF8 has been detected
ch = buffer.Read(); col++; charPos++;
// replace isolated '\r' by '\n' in order to make
// eol handling uniform across Windows, Unix and Mac
if (ch == '\r' && buffer.Peek() != '\n') ch = EOL;
if (ch == EOL) { line++; col = 0; }
}
}
void AddCh() {
if (tlen >= tval.Length) {
char[] newBuf = new char[2 * tval.Length];
Array.Copy(tval, 0, newBuf, 0, tval.Length);
tval = newBuf;
}
if (ch != Buffer.EOF) {
tval[tlen++] = (char) ch;
NextCh();
}
}
bool Comment0() {
int level = 1, pos0 = pos, line0 = line, col0 = col, charPos0 = charPos;
NextCh();
if (ch == '/') {
NextCh();
for(;;) {
if (ch == 10) {
level--;
if (level == 0) { oldEols = line - line0; NextCh(); return true; }
NextCh();
} else if (ch == Buffer.EOF) return false;
else NextCh();
}
} else {
buffer.Pos = pos0; NextCh(); line = line0; col = col0; charPos = charPos0;
}
return false;
}
bool Comment1() {
int level = 1, pos0 = pos, line0 = line, col0 = col, charPos0 = charPos;
NextCh();
if (ch == '*') {
NextCh();
for(;;) {
if (ch == '*') {
NextCh();
if (ch == '/') {
level--;
if (level == 0) { oldEols = line - line0; NextCh(); return true; }
NextCh();
}
} else if (ch == '/') {
NextCh();
if (ch == '*') {
level++; NextCh();
}
} else if (ch == Buffer.EOF) return false;
else NextCh();
}
} else {
buffer.Pos = pos0; NextCh(); line = line0; col = col0; charPos = charPos0;
}
return false;
}
void CheckLiteral() {
switch (t.val) {
case "if": t.kind = 11; break;
case "else": t.kind = 14; break;
case "while": t.kind = 15; break;
case "for": t.kind = 16; break;
case "function": t.kind = 18; break;
case "+": t.kind = 22; break;
case "-": t.kind = 23; break;
case "\n": t.kind = 33; break;
default: break;
}
}
Token NextToken() {
while (ch == ' ' ||
ch >= 9 && ch <= 10 || ch == 13
) NextCh();
if (ch == '/' && Comment0() ||ch == '/' && Comment1()) return NextToken();
int recKind = noSym;
int recEnd = pos;
t = new Token();
t.pos = pos; t.col = col; t.line = line; t.charPos = charPos;
int state;
state = (int) start[ch];
tlen = 0; AddCh();
switch (state) {
case -1: { t.kind = eofSym; break; } // NextCh already done
case 0: {
if (recKind != noSym) {
tlen = recEnd - t.pos;
SetScannerBehindT();
}
t.kind = recKind; break;
} // NextCh already done
case 1:
recEnd = pos; recKind = 1;
if (ch >= '0' && ch <= '9' || ch >= 'A' && ch <= 'Z' || ch >= 'a' && ch <= 'z') {AddCh(); goto case 1;}
else {t.kind = 1; t.val = new String(tval, 0, tlen); CheckLiteral(); return t;}
case 2:
{t.kind = 2; t.val = new String(tval, 0, tlen); CheckLiteral(); return t;}
case 3:
{t.kind = 3; break;}
case 4:
if (ch >= '0' && ch <= '9' || ch >= 'A' && ch <= 'F' || ch >= 'a' && ch <= 'f') {AddCh(); goto case 5;}
else {goto case 0;}
case 5:
recEnd = pos; recKind = 4;
if (ch >= '0' && ch <= '9' || ch >= 'A' && ch <= 'F' || ch >= 'a' && ch <= 'f') {AddCh(); goto case 5;}
else {t.kind = 4; break;}
case 6:
recEnd = pos; recKind = 5;
if (ch >= '0' && ch <= '9') {AddCh(); goto case 6;}
else if (ch == 'E' || ch == 'e') {AddCh(); goto case 7;}
else if (ch == '.') {AddCh(); goto case 10;}
else {t.kind = 5; break;}
case 7:
if (ch >= '0' && ch <= '9') {AddCh(); goto case 9;}
else if (ch == '+' || ch == '-') {AddCh(); goto case 8;}
else {goto case 0;}
case 8:
if (ch >= '0' && ch <= '9') {AddCh(); goto case 9;}
else {goto case 0;}
case 9:
recEnd = pos; recKind = 5;
if (ch >= '0' && ch <= '9') {AddCh(); goto case 9;}
else {t.kind = 5; break;}
case 10:
recEnd = pos; recKind = 5;
if (ch >= '0' && ch <= '9') {AddCh(); goto case 10;}
else if (ch == 'E' || ch == 'e') {AddCh(); goto case 7;}
else {t.kind = 5; break;}
case 11:
if (ch == 10) {AddCh(); goto case 12;}
else {goto case 0;}
case 12:
{t.kind = 6; t.val = new String(tval, 0, tlen); CheckLiteral(); return t;}
case 13:
if (ch <= '!' || ch >= '#' && ch <= 65535) {AddCh(); goto case 13;}
else if (ch == '"') {AddCh(); goto case 14;}
else {goto case 0;}
case 14:
{t.kind = 7; break;}
case 15:
{t.kind = 8; break;}
case 16:
{t.kind = 9; break;}
case 17:
if (ch == '=') {AddCh(); goto case 18;}
else {goto case 0;}
case 18:
{t.kind = 10; break;}
case 19:
recEnd = pos; recKind = 5;
if (ch >= '2' && ch <= '9') {AddCh(); goto case 6;}
else if (ch == 'B' || ch == 'b') {AddCh(); goto case 3;}
else if (ch >= '0' && ch <= '1') {AddCh(); goto case 20;}
else if (ch == 'x') {AddCh(); goto case 4;}
else if (ch == 'E' || ch == 'e') {AddCh(); goto case 7;}
else if (ch == '.') {AddCh(); goto case 10;}
else {t.kind = 5; break;}
case 20:
recEnd = pos; recKind = 5;
if (ch >= '2' && ch <= '9') {AddCh(); goto case 6;}
else if (ch == 'B' || ch == 'b') {AddCh(); goto case 3;}
else if (ch >= '0' && ch <= '1') {AddCh(); goto case 20;}
else if (ch == 'E' || ch == 'e') {AddCh(); goto case 7;}
else if (ch == '.') {AddCh(); goto case 10;}
else {t.kind = 5; break;}
case 21:
recEnd = pos; recKind = 10;
if (ch == '=') {AddCh(); goto case 18;}
else {t.kind = 10; break;}
case 22:
recEnd = pos; recKind = 10;
if (ch == '=') {AddCh(); goto case 18;}
else {t.kind = 10; break;}
case 23:
{t.kind = 12; break;}
case 24:
{t.kind = 13; break;}
case 25:
{t.kind = 17; break;}
case 26:
{t.kind = 19; break;}
case 27:
{t.kind = 20; break;}
case 28:
{t.kind = 21; break;}
case 29:
{t.kind = 24; break;}
case 30:
{t.kind = 25; break;}
case 31:
{t.kind = 26; break;}
case 32:
{t.kind = 27; break;}
case 33:
{t.kind = 28; break;}
case 34:
{t.kind = 29; break;}
case 35:
{t.kind = 30; break;}
case 36:
{t.kind = 31; break;}
case 37:
{t.kind = 32; break;}
case 38:
recEnd = pos; recKind = 1;
if (ch >= '0' && ch <= '9' || ch >= 'A' && ch <= 'Z' || ch >= 'a' && ch <= 'b' || ch >= 'd' && ch <= 'z') {AddCh(); goto case 1;}
else if (ch == 'c') {AddCh(); goto case 43;}
else {t.kind = 1; t.val = new String(tval, 0, tlen); CheckLiteral(); return t;}
case 39:
recEnd = pos; recKind = 1;
if (ch >= '0' && ch <= '9' || ch >= 'A' && ch <= 'Z' || ch >= 'b' && ch <= 'z') {AddCh(); goto case 1;}
else if (ch == 'a') {AddCh(); goto case 44;}
else {t.kind = 1; t.val = new String(tval, 0, tlen); CheckLiteral(); return t;}
case 40:
recEnd = pos; recKind = 1;
if (ch >= '0' && ch <= '9' || ch >= 'A' && ch <= 'Z' || ch >= 'a' && ch <= 'h' || ch >= 'j' && ch <= 'z') {AddCh(); goto case 1;}
else if (ch == 'i') {AddCh(); goto case 45;}
else {t.kind = 1; t.val = new String(tval, 0, tlen); CheckLiteral(); return t;}
case 41:
if (ch == ':') {AddCh(); goto case 35;}
else if (ch == '=') {AddCh(); goto case 36;}
else {goto case 0;}
case 42:
recEnd = pos; recKind = 2;
if (ch == '>') {AddCh(); goto case 37;}
else {t.kind = 2; t.val = new String(tval, 0, tlen); CheckLiteral(); return t;}
case 43:
recEnd = pos; recKind = 1;
if (ch >= '0' && ch <= '9' || ch >= 'A' && ch <= 'Z' || ch >= 'a' && ch <= 'g' || ch >= 'i' && ch <= 'z') {AddCh(); goto case 1;}
else if (ch == 'h') {AddCh(); goto case 46;}
else {t.kind = 1; t.val = new String(tval, 0, tlen); CheckLiteral(); return t;}
case 44:
recEnd = pos; recKind = 1;
if (ch >= '0' && ch <= '9' || ch >= 'A' && ch <= 'Z' || ch >= 'a' && ch <= 'x' || ch == 'z') {AddCh(); goto case 1;}
else if (ch == 'y') {AddCh(); goto case 47;}
else {t.kind = 1; t.val = new String(tval, 0, tlen); CheckLiteral(); return t;}
case 45:
recEnd = pos; recKind = 1;
if (ch >= '0' && ch <= '9' || ch >= 'A' && ch <= 'Z' || ch >= 'a' && ch <= 'r' || ch >= 't' && ch <= 'z') {AddCh(); goto case 1;}
else if (ch == 's') {AddCh(); goto case 48;}
else {t.kind = 1; t.val = new String(tval, 0, tlen); CheckLiteral(); return t;}
case 46:
recEnd = pos; recKind = 1;
if (ch >= '0' && ch <= '9' || ch >= 'A' && ch <= 'Z' || ch >= 'a' && ch <= 'n' || ch >= 'p' && ch <= 'z') {AddCh(); goto case 1;}
else if (ch == 'o') {AddCh(); goto case 49;}
else {t.kind = 1; t.val = new String(tval, 0, tlen); CheckLiteral(); return t;}
case 47:
recEnd = pos; recKind = 1;
if (ch >= '0' && ch <= '9' || ch >= 'A' && ch <= 'Z' || ch >= 'a' && ch <= 'z') {AddCh(); goto case 1;}
else if (ch == ':') {AddCh(); goto case 27;}
else {t.kind = 1; t.val = new String(tval, 0, tlen); CheckLiteral(); return t;}
case 48:
recEnd = pos; recKind = 1;
if (ch >= '0' && ch <= '9' || ch >= 'A' && ch <= 'Z' || ch >= 'a' && ch <= 'o' || ch >= 'q' && ch <= 'z') {AddCh(); goto case 1;}
else if (ch == 'p') {AddCh(); goto case 50;}
else {t.kind = 1; t.val = new String(tval, 0, tlen); CheckLiteral(); return t;}
case 49:
recEnd = pos; recKind = 1;
if (ch >= '0' && ch <= '9' || ch >= 'A' && ch <= 'Z' || ch >= 'a' && ch <= 'z') {AddCh(); goto case 1;}
else if (ch == ':') {AddCh(); goto case 26;}
else {t.kind = 1; t.val = new String(tval, 0, tlen); CheckLiteral(); return t;}
case 50:
recEnd = pos; recKind = 1;
if (ch >= '0' && ch <= '9' || ch >= 'A' && ch <= 'Z' || ch >= 'a' && ch <= 'k' || ch >= 'm' && ch <= 'z') {AddCh(); goto case 1;}
else if (ch == 'l') {AddCh(); goto case 51;}
else {t.kind = 1; t.val = new String(tval, 0, tlen); CheckLiteral(); return t;}
case 51:
recEnd = pos; recKind = 1;
if (ch >= '0' && ch <= '9' || ch >= 'A' && ch <= 'Z' || ch >= 'b' && ch <= 'z') {AddCh(); goto case 1;}
else if (ch == 'a') {AddCh(); goto case 52;}
else {t.kind = 1; t.val = new String(tval, 0, tlen); CheckLiteral(); return t;}
case 52:
recEnd = pos; recKind = 1;
if (ch >= '0' && ch <= '9' || ch >= 'A' && ch <= 'Z' || ch >= 'a' && ch <= 'x' || ch == 'z') {AddCh(); goto case 1;}
else if (ch == 'y') {AddCh(); goto case 53;}
else {t.kind = 1; t.val = new String(tval, 0, tlen); CheckLiteral(); return t;}
case 53:
recEnd = pos; recKind = 1;
if (ch >= '0' && ch <= '9' || ch >= 'A' && ch <= 'Z' || ch >= 'a' && ch <= 'z') {AddCh(); goto case 1;}
else if (ch == ':') {AddCh(); goto case 28;}
else {t.kind = 1; t.val = new String(tval, 0, tlen); CheckLiteral(); return t;}
}
t.val = new String(tval, 0, tlen);
return t;
}
private void SetScannerBehindT() {
buffer.Pos = t.pos;
NextCh();
line = t.line; col = t.col; charPos = t.charPos;
for (int i = 0; i < tlen; i++) NextCh();
}
// get the next token (possibly a token already seen during peeking)
public Token Scan () {
if (tokens.next == null) {
return NextToken();
} else {
pt = tokens = tokens.next;
return tokens;
}
}
// peek for the next token, ignore pragmas
public Token Peek () {
do {
if (pt.next == null) {
pt.next = NextToken();
}
pt = pt.next;
} while (pt.kind > maxT); // skip pragmas
return pt;
}
// make sure that peeking starts at the current scan position
public void ResetPeek () { pt = tokens; }
} // end Scanner
}

View file

@ -0,0 +1,383 @@
/*----------------------------------------------------------------------
Compiler Generator Coco/R,
Copyright (c) 1990, 2004 Hanspeter Moessenboeck, University of Linz
extended by M. Loeberbauer & A. Woess, Univ. of Linz
with improvements by Pat Terry, Rhodes University
This program is free software; you can redistribute it and/or modify it
under the terms of the GNU General Public License as published by the
Free Software Foundation; either version 2, or (at your option) any
later version.
This program is distributed in the hope that it will be useful, but
WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
for more details.
You should have received a copy of the GNU General Public License along
with this program; if not, write to the Free Software Foundation, Inc.,
59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
As an exception, it is allowed to write an extension of Coco/R that is
used as a plugin in non-free software.
If not otherwise stated, any source code generated by Coco/R (other than
Coco/R itself) does not fall under the GNU General Public License.
-----------------------------------------------------------------------*/
-->begin
using System;
using System.IO;
using System.Collections;
using System.Collections.Generic;
using System.CodeDom.Compiler;
-->namespace
[GeneratedCodeAttribute("Coco/R", "")]
public class Token {
public int kind; // token kind
public int pos; // token position in bytes in the source text (starting at 0)
public int charPos; // token position in characters in the source text (starting at 0)
public int col; // token column (starting at 1)
public int line; // token line (starting at 1)
public string val; // token value
public Token next; // ML 2005-03-11 Tokens are kept in linked list
}
//-----------------------------------------------------------------------------------
// Buffer
//-----------------------------------------------------------------------------------
public class Buffer {
// This Buffer supports the following cases:
// 1) seekable stream (file)
// a) whole stream in buffer
// b) part of stream in buffer
// 2) non seekable stream (network, console)
public const int EOF = char.MaxValue + 1;
const int MIN_BUFFER_LENGTH = 1024; // 1KB
const int MAX_BUFFER_LENGTH = MIN_BUFFER_LENGTH * 64; // 64KB
byte[] buf; // input buffer
int bufStart; // position of first byte in buffer relative to input stream
int bufLen; // length of buffer
int fileLen; // length of input stream (may change if the stream is no file)
int bufPos; // current position in buffer
Stream stream; // input stream (seekable)
bool isUserStream; // was the stream opened by the user?
public Buffer (Stream s, bool isUserStream) {
stream = s; this.isUserStream = isUserStream;
if (stream.CanSeek) {
fileLen = (int) stream.Length;
bufLen = Math.Min(fileLen, MAX_BUFFER_LENGTH);
bufStart = Int32.MaxValue; // nothing in the buffer so far
} else {
fileLen = bufLen = bufStart = 0;
}
buf = new byte[(bufLen>0) ? bufLen : MIN_BUFFER_LENGTH];
if (fileLen > 0) Pos = 0; // setup buffer to position 0 (start)
else bufPos = 0; // index 0 is already after the file, thus Pos = 0 is invalid
if (bufLen == fileLen && stream.CanSeek) Close();
}
protected Buffer(Buffer b) { // called in UTF8Buffer constructor
buf = b.buf;
bufStart = b.bufStart;
bufLen = b.bufLen;
fileLen = b.fileLen;
bufPos = b.bufPos;
stream = b.stream;
// keep destructor from closing the stream
b.stream = null;
isUserStream = b.isUserStream;
}
~Buffer() { Close(); }
protected void Close() {
if (!isUserStream && stream != null) {
stream.Close();
stream = null;
}
}
public virtual int Read () {
if (bufPos < bufLen) {
return buf[bufPos++];
} else if (Pos < fileLen) {
Pos = Pos; // shift buffer start to Pos
return buf[bufPos++];
} else if (stream != null && !stream.CanSeek && ReadNextStreamChunk() > 0) {
return buf[bufPos++];
} else {
return EOF;
}
}
public int Peek () {
int curPos = Pos;
int ch = Read();
Pos = curPos;
return ch;
}
// beg .. begin, zero-based, inclusive, in byte
// end .. end, zero-based, exclusive, in byte
public string GetString (int beg, int end) {
int len = 0;
char[] buf = new char[end - beg];
int oldPos = Pos;
Pos = beg;
while (Pos < end) buf[len++] = (char) Read();
Pos = oldPos;
return new String(buf, 0, len);
}
public int Pos {
get { return bufPos + bufStart; }
set {
if (value >= fileLen && stream != null && !stream.CanSeek) {
// Wanted position is after buffer and the stream
// is not seek-able e.g. network or console,
// thus we have to read the stream manually till
// the wanted position is in sight.
while (value >= fileLen && ReadNextStreamChunk() > 0);
}
if (value < 0 || value > fileLen) {
throw new FatalError("buffer out of bounds access, position: " + value);
}
if (value >= bufStart && value < bufStart + bufLen) { // already in buffer
bufPos = value - bufStart;
} else if (stream != null) { // must be swapped in
stream.Seek(value, SeekOrigin.Begin);
bufLen = stream.Read(buf, 0, buf.Length);
bufStart = value; bufPos = 0;
} else {
// set the position to the end of the file, Pos will return fileLen.
bufPos = fileLen - bufStart;
}
}
}
// Read the next chunk of bytes from the stream, increases the buffer
// if needed and updates the fields fileLen and bufLen.
// Returns the number of bytes read.
private int ReadNextStreamChunk() {
int free = buf.Length - bufLen;
if (free == 0) {
// in the case of a growing input stream
// we can neither seek in the stream, nor can we
// foresee the maximum length, thus we must adapt
// the buffer size on demand.
byte[] newBuf = new byte[bufLen * 2];
Array.Copy(buf, newBuf, bufLen);
buf = newBuf;
free = bufLen;
}
int read = stream.Read(buf, bufLen, free);
if (read > 0) {
fileLen = bufLen = (bufLen + read);
return read;
}
// end of stream reached
return 0;
}
}
//-----------------------------------------------------------------------------------
// UTF8Buffer
//-----------------------------------------------------------------------------------
public class UTF8Buffer: Buffer {
public UTF8Buffer(Buffer b): base(b) {}
public override int Read() {
int ch;
do {
ch = base.Read();
// until we find a utf8 start (0xxxxxxx or 11xxxxxx)
} while ((ch >= 128) && ((ch & 0xC0) != 0xC0) && (ch != EOF));
if (ch < 128 || ch == EOF) {
// nothing to do, first 127 chars are the same in ascii and utf8
// 0xxxxxxx or end of file character
} else if ((ch & 0xF0) == 0xF0) {
// 11110xxx 10xxxxxx 10xxxxxx 10xxxxxx
int c1 = ch & 0x07; ch = base.Read();
int c2 = ch & 0x3F; ch = base.Read();
int c3 = ch & 0x3F; ch = base.Read();
int c4 = ch & 0x3F;
ch = (((((c1 << 6) | c2) << 6) | c3) << 6) | c4;
} else if ((ch & 0xE0) == 0xE0) {
// 1110xxxx 10xxxxxx 10xxxxxx
int c1 = ch & 0x0F; ch = base.Read();
int c2 = ch & 0x3F; ch = base.Read();
int c3 = ch & 0x3F;
ch = (((c1 << 6) | c2) << 6) | c3;
} else if ((ch & 0xC0) == 0xC0) {
// 110xxxxx 10xxxxxx
int c1 = ch & 0x1F; ch = base.Read();
int c2 = ch & 0x3F;
ch = (c1 << 6) | c2;
}
return ch;
}
}
//-----------------------------------------------------------------------------------
// Scanner
//-----------------------------------------------------------------------------------
public class Scanner {
const char EOL = '\n';
const int eofSym = 0; /* pdt */
-->declarations
public Buffer buffer; // scanner buffer
Token t; // current token
int ch; // current input character
int pos; // byte position of current character
int charPos; // position by unicode characters starting with 0
int col; // column number of current character
int line; // line number of current character
int oldEols; // EOLs that appeared in a comment;
static readonly Dictionary<int, int> start; // maps first token character to start state
Token tokens; // list of tokens already peeked (first token is a dummy)
Token pt; // current peek token
char[] tval = new char[128]; // text of current token
int tlen; // length of current token
static Scanner() {
start = new Dictionary<int, int>(128);
-->initialization
}
public Scanner (string fileName) {
try {
Stream stream = new FileStream(fileName, FileMode.Open, FileAccess.Read, FileShare.Read);
buffer = new Buffer(stream, false);
Init();
} catch (IOException) {
throw new FatalError("Cannot open file " + fileName);
}
}
public Scanner (Stream s) {
buffer = new Buffer(s, true);
Init();
}
void Init() {
pos = -1; line = 1; col = 0; charPos = -1;
oldEols = 0;
NextCh();
if (ch == 0xEF) { // check optional byte order mark for UTF-8
NextCh(); int ch1 = ch;
NextCh(); int ch2 = ch;
if (ch1 != 0xBB || ch2 != 0xBF) {
throw new FatalError(String.Format("illegal byte order mark: EF {0,2:X} {1,2:X}", ch1, ch2));
}
buffer = new UTF8Buffer(buffer); col = 0; charPos = -1;
NextCh();
}
pt = tokens = new Token(); // first token is a dummy
}
void NextCh() {
if (oldEols > 0) { ch = EOL; oldEols--; }
else {
pos = buffer.Pos;
// buffer reads unicode chars, if UTF8 has been detected
ch = buffer.Read(); col++; charPos++;
// replace isolated '\r' by '\n' in order to make
// eol handling uniform across Windows, Unix and Mac
if (ch == '\r' && buffer.Peek() != '\n') ch = EOL;
if (ch == EOL) { line++; col = 0; }
}
-->casing1
}
void AddCh() {
if (tlen >= tval.Length) {
char[] newBuf = new char[2 * tval.Length];
Array.Copy(tval, 0, newBuf, 0, tval.Length);
tval = newBuf;
}
if (ch != Buffer.EOF) {
-->casing2
NextCh();
}
}
-->comments
void CheckLiteral() {
-->literals
}
Token NextToken() {
while (ch == ' ' ||
-->scan1
) NextCh();
-->scan2
int recKind = noSym;
int recEnd = pos;
t = new Token();
t.pos = pos; t.col = col; t.line = line; t.charPos = charPos;
int state;
state = (int) start[ch];
tlen = 0; AddCh();
switch (state) {
case -1: { t.kind = eofSym; break; } // NextCh already done
case 0: {
if (recKind != noSym) {
tlen = recEnd - t.pos;
SetScannerBehindT();
}
t.kind = recKind; break;
} // NextCh already done
-->scan3
}
t.val = new String(tval, 0, tlen);
return t;
}
private void SetScannerBehindT() {
buffer.Pos = t.pos;
NextCh();
line = t.line; col = t.col; charPos = t.charPos;
for (int i = 0; i < tlen; i++) NextCh();
}
// get the next token (possibly a token already seen during peeking)
public Token Scan () {
if (tokens.next == null) {
return NextToken();
} else {
pt = tokens = tokens.next;
return tokens;
}
}
// peek for the next token, ignore pragmas
public Token Peek () {
do {
if (pt.next == null) {
pt.next = NextToken();
}
pt = pt.next;
} while (pt.kind > maxT); // skip pragmas
return pt;
}
// make sure that peeking starts at the current scan position
public void ResetPeek () { pt = tokens; }
} // end Scanner

View file

@ -0,0 +1,525 @@
using csmic;
using System.Text;
using System.Collections.Generic;
COMPILER SCRIPT
/*
*
* Class Structures
*
*/
private MacroOperation root = new MacroOperation(OperationType.Unknown);
internal MacroOperation Root
{
get
{
return this.root;
}
set
{
this.root = value;
}
}
bool IsFunctionCall()
{
scanner.ResetPeek();
Token next = scanner.Peek();
if (next.kind == _LPAREN && la.kind == _identifier)
return true;
return false;
}
bool IsCompare()
{
scanner.ResetPeek();
Token next = scanner.Peek();
if (next.kind == _COMPARER)
return true;
return false;
}
bool IsAssignment()
{
scanner.ResetPeek();
Token next = scanner.Peek();
if (next.val == "::" || next.val == ":=" || next.val == "->")
return true;
return false;
}
bool IsArrayCall()
{
scanner.ResetPeek();
Token next = scanner.Peek();
if(next.val == "[")
return true;
return false;
}
CHARACTERS
UpperLetter = 'A'..'Z'.
LowerLetter = 'a'..'z'.
letter = UpperLetter + LowerLetter.
NoQuote = ANY - '\"' .
digit = "0123456789" .
cr = '\r' .
lf = '\n' .
tab = '\t' .
PM = "+-" .
TOKENS
identifier = letter { letter | digit }.
sign = PM .
binary = ( '0' | '1' ) { '0' | '1' } ('B' | 'b') .
hex = "0x" ( digit | ('A' | 'B' | 'C' | 'D' | 'E' |'F') | ('a' | 'b' | 'c' | 'd' | 'e' |'f') ) { digit | ('A' | 'B' | 'C' | 'D' | 'E' |'F') | ('a' | 'b' | 'c' | 'd' | 'e' |'f') } .
number = digit { digit }['.' {digit}] [('E'|'e')['+'|'-'] digit {digit}] .
newline = [cr] lf .
string = "\"" { NoQuote } "\"" .
LPAREN = '(' .
RPAREN = ')' .
COMPARER = "==" | "<" | ">" | "<=" | ">=" .
COMMENTS FROM "/*" TO "*/" NESTED
COMMENTS FROM "//" TO lf
IGNORE cr + lf + tab
/*
* Parser specification
*
*/
PRODUCTIONS
SCRIPT (. string statement = string.Empty; .)
=
{
Statement<out statement> (.
MacroOperation operation = new MacroOperation(OperationType.Statement);
operation.Input.Add(statement);
this.root.Children.Add(operation);
.)
|
IfBlock<ref this.root>
|
WhileBlock<ref this.root>
|
FunctionDeclaration<ref this.root>
|
EchoStatement<ref this.root>
|
SayStatement<ref this.root>
|
DisplayStatement<ref this.root>
|
ForBlock<ref this.root>
}
.
IfBlock<ref MacroOperation parent> (.
MacroOperation ifBlock = new MacroOperation(OperationType.If);
MacroOperation elseBlock = new MacroOperation(OperationType.Else);
string ifStatement = string.Empty;
string statement = string.Empty;
StringBuilder builder = new StringBuilder();
bool hasElse = false;
.)
=
"if"
LPAREN
Comparison<ref builder> (. ifStatement = builder.ToString(); ifBlock.Input.Add(ifStatement); .)
RPAREN
'{'
{
Statement<out statement> (.
MacroOperation operation = new MacroOperation(OperationType.Statement);
operation.Input.Add(statement);
ifBlock.Children.Add(operation);
.)
|
IfBlock<ref ifBlock>
|
WhileBlock<ref ifBlock>
|
EchoStatement<ref ifBlock>
|
SayStatement<ref ifBlock>
|
DisplayStatement<ref ifBlock>
|
ForBlock<ref ifBlock>
}
'}'
[
"else" (. hasElse = true; .)
'{'
{
Statement<out statement> (.
MacroOperation operation = new MacroOperation(OperationType.Statement);
operation.Input.Add(statement);
elseBlock.Children.Add(operation);
.)
|
IfBlock<ref elseBlock>
|
WhileBlock<ref elseBlock>
|
EchoStatement<ref elseBlock>
|
SayStatement<ref elseBlock>
|
DisplayStatement<ref elseBlock>
|
ForBlock<ref elseBlock>
}
'}'
]
(.
if(hasElse)
{
MacroOperation ifelse = new MacroOperation(OperationType.IfElse);
ifelse.Children.Add(ifBlock);
ifelse.Children.Add(elseBlock);
parent.Children.Add(ifelse);
}
else
{
parent.Children.Add(ifBlock);
}
.)
.
WhileBlock<ref MacroOperation parent> (.
StringBuilder builder = new StringBuilder();
MacroOperation whileBlock = new MacroOperation(OperationType.While);
string statement = string.Empty;
.)
=
"while"
LPAREN
Comparison<ref builder> (. whileBlock.Input.Add(builder.ToString()); .)
RPAREN
'{'
{
Statement<out statement> (.
MacroOperation operation = new MacroOperation(OperationType.Statement);
operation.Input.Add(statement);
whileBlock.Children.Add(operation);
.)
|
IfBlock<ref whileBlock>
|
WhileBlock<ref whileBlock>
|
EchoStatement<ref whileBlock>
|
SayStatement<ref whileBlock>
|
DisplayStatement<ref whileBlock>
|
ForBlock<ref whileBlock>
}
'}'
(.
parent.Children.Add(whileBlock);
.)
.
ForBlock<ref MacroOperation parent> (.
StringBuilder builder = new StringBuilder();
string statement = string.Empty;
string statement2 = string.Empty;
MacroOperation forBlock = new MacroOperation(OperationType.For);
.)
=
"for"
LPAREN
Statement<out statement>
','
Comparison<ref builder>
','
Statement<out statement2> (. forBlock.Input.Add(statement); forBlock.Input.Add(builder.ToString()); forBlock.Input.Add(statement2); .)
RPAREN
'{'
{
Statement<out statement> (.
MacroOperation operation = new MacroOperation(OperationType.Statement);
operation.Input.Add(statement);
forBlock.Children.Add(operation);
.)
|
IfBlock<ref forBlock>
|
WhileBlock<ref forBlock>
|
EchoStatement<ref forBlock>
|
SayStatement<ref forBlock>
|
DisplayStatement<ref forBlock>
|
ForBlock<ref forBlock>
}
'}'
(.
parent.Children.Add(forBlock);
.)
.
FunctionDeclaration<ref MacroOperation parent> (.
StringBuilder builder = new StringBuilder();
string statement = string.Empty;
MacroOperation func = new MacroOperation(OperationType.FunctionDeclaration);
.)
=
"function"
LPAREN
CommaList<ref builder> (. string[] args = builder.ToString().Split(','); func.Input.AddRange(args); .)
RPAREN
'{'
{
Statement<out statement> (.
MacroOperation operation = new MacroOperation(OperationType.Statement);
operation.Input.Add(statement);
func.Children.Add(operation);
.)
|
IfBlock<ref func>
|
WhileBlock<ref func>
|
EchoStatement<ref func>
|
SayStatement<ref func>
|
DisplayStatement<ref func>
|
ForBlock<ref func>
}
'}'
(.
parent.Children.Add(func);
.)
.
EchoStatement<ref MacroOperation parent> (.
StringBuilder builder = new StringBuilder();
MacroOperation echoStatement = new MacroOperation(OperationType.Echo);
string statement = string.Empty;
.)
=
"echo:"
Statement<out statement> (.
MacroOperation operation = new MacroOperation(OperationType.Statement);
operation.Input.Add(statement);
echoStatement.Children.Add(operation);
parent.Children.Add(echoStatement);
.)
.
SayStatement<ref MacroOperation parent> (.
StringBuilder builder = new StringBuilder();
MacroOperation sayStatement = new MacroOperation(OperationType.Say);
string statement = string.Empty;
.)
=
"say:"
string (.
statement = t.val.Replace("\"", "");
sayStatement.Input.Add(statement);
parent.Children.Add(sayStatement);
.)
.
DisplayStatement<ref MacroOperation parent> (.
StringBuilder builder = new StringBuilder();
MacroOperation displayStatement = new MacroOperation(OperationType.Display);
string statement = string.Empty;
.)
=
"display:"
(
Statement<out statement> (.
MacroOperation operation = new MacroOperation(OperationType.Statement);
operation.Input.Add(statement);
displayStatement.Children.Add(operation);
.)
|
string (.
statement = t.val.Replace("\"", "");
MacroOperation operation = new MacroOperation(OperationType.String);
operation.Input.Add(statement);
displayStatement.Children.Add(operation);
.)
)
{
','
(
Statement<out statement> (.
MacroOperation operation = new MacroOperation(OperationType.Statement);
operation.Input.Add(statement);
displayStatement.Children.Add(operation);
.)
|
string (.
statement = t.val.Replace("\"", "");
MacroOperation operation = new MacroOperation(OperationType.String);
operation.Input.Add(statement);
displayStatement.Children.Add(operation);
.)
)
}
(.
parent.Children.Add(displayStatement);
.)
.
Statement<out string value> (.
value = string.Empty;
StringBuilder builder = new StringBuilder();
.)
=
IF(IsAssignment())
Assignment<ref builder> (. value = builder.ToString(); .)
|
Expression<ref builder> (. value = builder.ToString(); .)
.
Expression<ref StringBuilder builder>
=
Term<ref builder>
{
'+' (. builder.Append(t.val); .) Term<ref builder>
|
'-' (. builder.Append(t.val); .) Term<ref builder>
|
'%' (. builder.Append(t.val); .) Term<ref builder>
}
.
Term<ref StringBuilder builder>
=
Factor<ref builder>
{
'*' (. builder.Append(t.val); .)
Factor<ref builder>
|
'/' (. builder.Append(t.val); .)
Factor<ref builder>
}
.
Factor<ref StringBuilder builder>
=
Value<ref builder>
{
'^' (. builder.Append(t.val); .)
Value<ref builder>
}
.
Value<ref StringBuilder builder>
=
[
"+" (. builder.Append(t.val); .)
|
"-" (. builder.Append(t.val); .)
]
(
IF(IsFunctionCall())
Function<ref builder>
|
IF(IsArrayCall())
ArrayCall<ref builder>
|
identifier (. builder.Append(t.val); .)
|
number (. builder.Append(t.val); .)
|
hex (. builder.Append(t.val); .)
|
binary (. builder.Append(t.val); .)
|
'(' (. builder.Append(t.val); .)
Expression<ref builder>
')' (. builder.Append(t.val); .)
)
.
ArrayL<ref StringBuilder builder>
=
'[' (. builder.Append(t.val); .)
CommaList<ref builder>
']' (. builder.Append(t.val); .)
.
CommaList<ref StringBuilder builder>
=
Expression<ref builder>
{
',' (. builder.Append(t.val); .)
Expression<ref builder>
}
.
Assignment<ref StringBuilder builder>
=
identifier (. builder.Append(t.val); .)
(
(
"::" (. builder.Append(t.val); .)
Expression<ref builder>
)
|
(
":=" (. builder.Append(t.val); string value = string.Empty; .)
AnyExpression<out value> (. builder.Append(value); .)
newline
)
|
(
"->" (. builder.Append(t.val); .)
ArrayL<ref builder>
)
)
.
Function<ref StringBuilder builder>
=
identifier (. builder.Append(t.val); .)
'(' (. builder.Append(t.val); .)
CommaList<ref builder>
')' (. builder.Append(t.val); .)
.
ArrayCall<ref StringBuilder builder>
=
identifier (. builder.Append(t.val); .)
'[' (. builder.Append(t.val); .)
Expression<ref builder>
']' (. builder.Append(t.val); .)
.
Comparison<ref StringBuilder result>
=
Expression<ref result>
COMPARER (. result.Append(t.val); .)
Expression<ref result>
.
AnyExpression<out string value> (. value = string.Empty; StringBuilder builder = new StringBuilder(); .)
=
ANY (. builder.Append(t.val); .) { ANY (. builder.Append(t.val); .) } '\n' (. value = builder.ToString(); .)
.
END SCRIPT.

View file

@ -0,0 +1,100 @@
using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;
namespace csmic
{
/// <summary>
/// Represents the data types supported in a variable.
/// </summary>
public enum VariableType
{
/// <summary>
/// Decimal
/// </summary>
Decimal,
/// <summary>
/// Equation
/// </summary>
Equation,
/// <summary>
/// Array
/// </summary>
Array,
/// <summary>
/// Unknown
/// </summary>
Unknown,
/// <summary>
/// No type associated
/// </summary>
None
}
/// <summary>
/// An object that contains information about a variable.
/// </summary>
public class Variable
{
#region Members
/// <summary>
/// The type of variable.
/// </summary>
private VariableType type;
/// <summary>
/// The value of the variable.
/// </summary>
private object value;
#endregion
#region Constructor
/// <summary>
/// Creates an empty variable.
/// </summary>
public Variable()
{
this.type = VariableType.None;
this.value = null;
}
#endregion
#region Properties
/// <summary>
/// Gets or sets an object representing the variable's value.
/// </summary>
public object Value
{
get
{
return this.value;
}
set
{
this.value = value;
}
}
/// <summary>
/// Gets or sets the type of the variable.
/// </summary>
public VariableType Type
{
get
{
return this.type;
}
set
{
this.type = value;
}
}
#endregion
}
}

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@ -0,0 +1,136 @@
<?xml version="1.0" encoding="utf-8"?>
<Project ToolsVersion="4.0" DefaultTargets="Build" xmlns="http://schemas.microsoft.com/developer/msbuild/2003">
<PropertyGroup>
<Configuration Condition=" '$(Configuration)' == '' ">Debug</Configuration>
<Platform Condition=" '$(Platform)' == '' ">AnyCPU</Platform>
<ProductVersion>9.0.21022</ProductVersion>
<SchemaVersion>2.0</SchemaVersion>
<ProjectGuid>{7BBA4BA2-E885-4D89-8710-F1A609616B7D}</ProjectGuid>
<OutputType>Library</OutputType>
<AppDesignerFolder>Properties</AppDesignerFolder>
<RootNamespace>csmic</RootNamespace>
<AssemblyName>csmic</AssemblyName>
<TargetFrameworkVersion>v4.0</TargetFrameworkVersion>
<FileAlignment>512</FileAlignment>
<SignAssembly>true</SignAssembly>
<AssemblyOriginatorKeyFile>csmic_open.snk</AssemblyOriginatorKeyFile>
<FileUpgradeFlags>
</FileUpgradeFlags>
<OldToolsVersion>3.5</OldToolsVersion>
<UpgradeBackupLocation />
<PublishUrl>publish\</PublishUrl>
<Install>true</Install>
<InstallFrom>Disk</InstallFrom>
<UpdateEnabled>false</UpdateEnabled>
<UpdateMode>Foreground</UpdateMode>
<UpdateInterval>7</UpdateInterval>
<UpdateIntervalUnits>Days</UpdateIntervalUnits>
<UpdatePeriodically>false</UpdatePeriodically>
<UpdateRequired>false</UpdateRequired>
<MapFileExtensions>true</MapFileExtensions>
<ApplicationRevision>0</ApplicationRevision>
<ApplicationVersion>1.0.0.%2a</ApplicationVersion>
<IsWebBootstrapper>false</IsWebBootstrapper>
<UseApplicationTrust>false</UseApplicationTrust>
<BootstrapperEnabled>true</BootstrapperEnabled>
<TargetFrameworkProfile />
<SccProjectName>SAK</SccProjectName>
<SccLocalPath>SAK</SccLocalPath>
<SccAuxPath>SAK</SccAuxPath>
<SccProvider>SAK</SccProvider>
</PropertyGroup>
<PropertyGroup Condition=" '$(Configuration)|$(Platform)' == 'Debug|AnyCPU' ">
<DebugSymbols>true</DebugSymbols>
<DebugType>full</DebugType>
<Optimize>false</Optimize>
<OutputPath>bin\Debug\</OutputPath>
<DefineConstants>DEBUG;TRACE</DefineConstants>
<ErrorReport>prompt</ErrorReport>
<WarningLevel>4</WarningLevel>
<DocumentationFile>bin\Debug\csmic.XML</DocumentationFile>
<CodeAnalysisRuleSet>AllRules.ruleset</CodeAnalysisRuleSet>
</PropertyGroup>
<PropertyGroup Condition=" '$(Configuration)|$(Platform)' == 'Release|AnyCPU' ">
<DebugType>pdbonly</DebugType>
<Optimize>true</Optimize>
<OutputPath>bin\Release\</OutputPath>
<DefineConstants>
</DefineConstants>
<ErrorReport>prompt</ErrorReport>
<WarningLevel>4</WarningLevel>
<DocumentationFile>bin\Release\csmic.XML</DocumentationFile>
<CodeAnalysisRuleSet>AllRules.ruleset</CodeAnalysisRuleSet>
<RunCodeAnalysis>false</RunCodeAnalysis>
</PropertyGroup>
<ItemGroup>
<Reference Include="System" />
<Reference Include="System.Core">
<RequiredTargetFramework>3.5</RequiredTargetFramework>
</Reference>
</ItemGroup>
<ItemGroup>
<Compile Include="CodedFunctionFactory.cs" />
<Compile Include="CodedFunctions\CF_Abs.cs" />
<Compile Include="CodedFunctions\CF_Exp.cs" />
<Compile Include="CodedFunctions\CF_Log.cs" />
<Compile Include="CodedFunctions\CF_Precision.cs" />
<Compile Include="CodedFunctions\CF_Sqrt.cs" />
<Compile Include="CodedFunctions\CF_Cos.cs" />
<Compile Include="CodedFunctions\CF_Round.cs" />
<Compile Include="CodedFunctions\CF_Sin.cs" />
<Compile Include="CodedFunctions\CF_Tan.cs" />
<Compile Include="Computable\Computable.cs" />
<Compile Include="Extensions\CSMICExtension.cs" />
<Compile Include="GenericCodedFunction.cs" />
<Compile Include="ICodedFunction.cs" />
<Compile Include="InputInterpreter.cs" />
<Compile Include="InterpretedFunction.cs" />
<Compile Include="InterpretedFunctionArgument.cs" />
<Compile Include="MacroBuilder.cs" />
<Compile Include="MacroOperation.cs" />
<Compile Include="InterpreterParser\Parser.cs" />
<Compile Include="Properties\AssemblyInfo.cs" />
<Compile Include="InterpreterParser\Scanner.cs" />
<Compile Include="ScriptParser\Parser.cs" />
<Compile Include="ScriptParser\Scanner.cs" />
<Compile Include="Variable.cs" />
</ItemGroup>
<ItemGroup>
<None Include="csmic_open.snk" />
<None Include="InterpreterParser\Parser.frame" />
<None Include="InterpreterParser\Scanner.frame" />
<None Include="ScriptParser\Parser.frame" />
<None Include="ScriptParser\Scanner.frame" />
<None Include="ScriptParser\Scripting.atg" />
<None Include="InterpreterParser\CSMIC.atg" />
</ItemGroup>
<ItemGroup>
<BootstrapperPackage Include="Microsoft.Net.Client.3.5">
<Visible>False</Visible>
<ProductName>.NET Framework 3.5 SP1 Client Profile</ProductName>
<Install>false</Install>
</BootstrapperPackage>
<BootstrapperPackage Include="Microsoft.Net.Framework.3.5.SP1">
<Visible>False</Visible>
<ProductName>.NET Framework 3.5 SP1</ProductName>
<Install>true</Install>
</BootstrapperPackage>
<BootstrapperPackage Include="Microsoft.Windows.Installer.3.1">
<Visible>False</Visible>
<ProductName>Windows Installer 3.1</ProductName>
<Install>true</Install>
</BootstrapperPackage>
</ItemGroup>
<Import Project="$(MSBuildToolsPath)\Microsoft.CSharp.targets" />
<!-- To modify your build process, add your task inside one of the targets below and uncomment it.
Other similar extension points exist, see Microsoft.Common.targets.
<Target Name="BeforeBuild">
</Target>
<Target Name="AfterBuild">
</Target>
-->
<PropertyGroup>
<PreBuildEvent>"$(ProjectDir)\coco.exe" -namespace csmic.Interpreter -frames . "$(ProjectDir)\InterpreterParser\CSMIC.atg"
"$(ProjectDir)\coco.exe" -namespace csmic.Scripting -frames . "$(ProjectDir)\ScriptParser\Scripting.atg"</PreBuildEvent>
</PropertyGroup>
</Project>

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@ -0,0 +1,10 @@
""
{
"FILE_VERSION" = "9237"
"ENLISTMENT_CHOICE" = "NEVER"
"PROJECT_FILE_RELATIVE_PATH" = ""
"NUMBER_OF_EXCLUDED_FILES" = "0"
"ORIGINAL_PROJECT_FILE_PATH" = ""
"NUMBER_OF_NESTED_PROJECTS" = "0"
"SOURCE_CONTROL_SETTINGS_PROVIDER" = "PROVIDER"
}

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