ParserLibrary 1.1.1
See the version list below for details.
dotnet add package ParserLibrary --version 1.1.1
NuGet\Install-Package ParserLibrary -Version 1.1.1
<PackageReference Include="ParserLibrary" Version="1.1.1" />
paket add ParserLibrary --version 1.1.1
#r "nuget: ParserLibrary, 1.1.1"
// Install ParserLibrary as a Cake Addin #addin nuget:?package=ParserLibrary&version=1.1.1 // Install ParserLibrary as a Cake Tool #tool nuget:?package=ParserLibrary&version=1.1.1
ParserLibrary
No Other Expression Parser, Ever
About / How it began
I wanted to write my "custom terminal" that used interactive commands with expressions. Other Expression builders used only numbers as basic entities which I did not want; this is something too common. I wanted some variables to represent musical notes/chords, or even vectors and matrices and some other to represent numbers. The only way, was to build an Expression builder that could allow custom types. Obviously, the default capability of handling numerical values was needed as a start.
The library is based on modern programming tools and can be highly customized. Its basic features are:
- Default support for double arithmetic (via
DefaultParser
), complex arithmetic (viaComplexParser
). - Logger customization (typically via the
appsettings.json
). - Full control of unary and binary operators via configuration files (typically
appsettings.json
). - Support for custom data types and/or combination of custom data types with standard data types (such as
int
,double
). - Support for custom functions with arbitrary number of arguments. Each argument may be a custom type.
The library is frequently updated, so please check again for a newer version and the most recent README after a while 😃.
The library is built with modern tools:
- .NET 6.0
- Use of .NET Generic Host (i.e Dependency Inversion/Injection principles, Logging, Configuration) (see NET Generic Host for more). All derived Parsers are typically singletons.
- Support for custom loggers (Serilog is implemented by default)
There are 2 main classes: the Tokenizer
and the Parser
. Both of them are base classes and adapt to the corresponding interfaces ITokenizer
and IParser
. Let's uncover all the potential by giving examples with incrementally added functionality.
Examples
DefaultParser
examples
//This is a simple expression, which uses variables and literals of type double, and the DefaultParser.
double result = (double)App.Evaluate( "-5.0+2*a", new() { { "a", 5.0 } });
Console.WriteLine(result); //5
//2 variables example (spaces are obviously ignored)
double result2 = (double)App.Evaluate("-a + 500 * b + 2^3", new() { { "a", 5 }, { "b", 1 } });
Console.WriteLine(result2); //503
The first example is the same with the example below: the second way uses explicitly the DefaultParser
, which can be later overriden in order to use a custom Parser.
//The example below uses explicitly the DefaultParser.
var app = App.GetParserApp<DefaultParser>();
var parser = app.Services.GetParser();
double result = (double)parser.Evaluate("-5.0+2*a", new() { { "a", 5.0 } });
Let's use some functions already defined in the DefaultParser
double result3 = (double)App.Evaluate("cosd(ph)^2+sind(ph)^2", new() { { "ph", 45 } });
Console.WriteLine(result3); // 1.0000000000000002
...and some constants used in the DefaultParser
Console.WriteLine(App.Evaluate("5+2*cos(pi)+3*ln(e)")); //will return 5 - 2 + 3 -> 6
DefaultParser
examples #2 (custom functions)
That was the boring stuff, let's start adding some custom functionality. Let's add a custom function add3
that takes 3 arguments. For this purpose, we create a new subclass of DefaultParser
. Note that we can add custom logging via dependency injection (some more examples will follow on this). For the moment, ignore the constructor. We assume that the add3
functions sums its 3 arguments with a specific weight.
private class SimpleFunctionParser : DefaultParser
{
public SimpleFunctionParser(ILogger<Parser> logger, ITokenizer tokenizer, IOptions<TokenizerOptions> options) : base(logger, tokenizer, options)
{
}
protected override object EvaluateFunction(Node<Token> functionNode, Dictionary<Node<Token>, object> nodeValueDictionary)
{
double[] a = GetDoubleFunctionArguments(count: 3, functionNode, nodeValueDictionary);
return functionNode.Text.ToLower() switch
{
"add3" => a[0] + 2 * a[1] + 3 * a[2],
//for all other functions use the base class stuff (DefaultParser)
_ => base.EvaluateFunction(functionNode, nodeValueDictionary)
};
}
}
Let's use our first customized Parser
:
var parser = App.GetCustomParser<SimpleFunctionParser>();
double result = (double)parser.Evaluate("8 + add3(5.0,g,3.0)", new() { { "g", 3 } }); // will return 8 + (5 + 2 * 3 + 3 * 3.0) i.e -> 28
ComplexParser
examples
Another ready to use Parser
is the ComplexParser
for complex arithmetic. In fact, the application of the Parser
for Complex
numbers is a first application of a custom data type (i.e. other that double
). Let's see an example (Complex
belongs to the System.Numerics
namespace):
using System.Numerics; //needed if we want to further use the result
...
var cparser = App.GetCustomParser<ComplexParser>();
//unless we override the i or j variables, both are considered to correspond to the imaginary unit
//NOTE: because i is used as a variable (internally), the syntax for the imaginary part should be 3*i, NOT 3i
Complex result = (Complex)cparser.Evaluate("(1+3*i)/(2-3*i)");
Console.WriteLine(result); // (-0.5384615384615385, 0.6923076923076924)
//another one with a variable (should give the same result)
Complex result2 = (Complex)cparser.Evaluate("(1+3*i)/b", new() { { "b", new Complex(2,-3)} });
Console.WriteLine(result2); //same result
//and something more "complex", using nested functions: note that the complex number is returned as a string in the form (real, imaginary)
Console.WriteLine(cparser.Evaluate("cos((1+i)/(8+i))")); //(0.9961783779071353, -0.014892390041785901)
Console.WriteLine(cparser.Evaluate("round(cos((1+i)/(8+i)),4)")); //(0.9962, -0.0149)
Custom Types examples
Let's assume that we have a class named Item
, which we want to interact with integer numbers and with other Item
objects:
public class Item
{
public string Name { get; set; }
public int Value { get; set; } = 0;
//we define a custom operator for the type to simplify the evaluateoperator example later
//this is not 100% needed, but it keeps the code in the CustomTypeParser simpler
public static Item operator +(int v1, Item v2) =>
new Item { Name = v2.Name , Value = v2.Value + v1 };
public static Item operator +(Item v2, int v1) =>
new Item { Name = v2.Name, Value = v2.Value + v1 };
public static Item operator +(Item v1, Item v2) =>
new Item { Name = $"{v1.Name} {v2.Name}", Value = v2.Value + v1.Value };
public override string ToString() => $"{Name} {Value}";
}
A custom parser that uses custom types derives from the Parser
class. Because the Parser
class does not assume any type in advance, we should override the EvaluateLiteral
function which is used to parse the integer numbers in the string. In the following example we define the +
operator, which can take an Item
object or an int
for its operands. We also define the add
function, which assumes that the first argument is an Item
and the second argument is an int
. In practice, the Function syntax is usually stricter regarding the type of the arguments, so it is easier to write its implementation:
public class CustomTypeParser : Parser
{
public CustomTypeParser(ILogger<Parser> logger, ITokenizer tokenizer, IOptions<TokenizerOptions> options) : base(logger, tokenizer, options)
{ }
//we assume that literals are integer numbers only
protected override object EvaluateLiteral(string s) => int.Parse(s);
protected override object EvaluateOperator(Node<Token> operatorNode, Dictionary<Node<Token>, object> nodeValueDictionary)
{
(object LeftOperand, object RightOperand) = operatorNode.GetBinaryArguments(nodeValueDictionary);
//we assume the + operator
if (operatorNode.Text == "+")
{
//we manage all combinations of Item/Item, Item/int, int/Item combinations here
if (LeftOperand is Item && RightOperand is Item)
return (Item)LeftOperand + (Item)RightOperand;
return LeftOperand is Item ? (Item)LeftOperand + (int)RightOperand : (int)LeftOperand + (Item)RightOperand;
}
return base.EvaluateOperator(operatorNode, nodeValueDictionary);
}
protected override object EvaluateFunction(Node<Token> functionNode, Dictionary<Node<Token>, object> nodeValueDictionary)
{
var a = functionNode.GetFunctionArguments(count: 2, nodeValueDictionary);
return functionNode.Text switch
{
"add" => (Item)a[0] + (int)a[1],
_ => base.EvaluateFunction(functionNode, nodeValueDictionary)
};
}
}
Now we can use the CustomTypeParser
for parsing our custom expression:
var parser = App.GetCustomParser<CustomTypeParser>();
Item result = (Item)parser.Evaluate("a + add(b,4) + 5",
new() {
{"a", new Item { Name="foo", Value = 3} },
{"b", new Item { Name="bar"} }
});
Console.WriteLine(result); // foo bar 12
more examples to follow soon...
Customizing ParserLibrary
appsettings.json
configuration file
The appsettings.json
configuration file is crucial, when the user wants to have precise control over the tokenizer and the logger as well.
The library is configured to use Serilog for debugging and informational purposes. The Serilog section (see Serilog configuration for more) typically can be configured to output to the Console and/or to an external file. In order to show less messages in the case below, we can use "Information"
instead of "Debug"
for the Console
output. The logger can be accessed via the _logger
field in every Parser
subclass, so we can output debug/informational/critical messages to the screen/to a file in a controlled manner. The _logger
field is of type ILogger
, so Serilog is not the only type of logger that can be used (although it is recommended).
The tokenizer options include the following properties:
caseSensitive
: if false, then the tokenizer/parser should be case insensitivetokenPatterns
: this includes the regular expression patterns or simple string characters for identifying any tokenidentifier
: regular expression to identify variable and function names as tokensliteral
: regular expresssion to identify all literal -typically numeric- valuesopenParenthesis
,closeParenthesis
,argumentSeparator
: the characters which correspond to the parenthesis pair and the argument separatorunary
: the unary array defines all unary operators. The priority of unary operator priority is in general higher than the binary operatorsoperators
: the operators array defines all binary operators. All binary operators are left-to-right by default except if specified otherwise (just like the exponent operator'^'
) Operators with higherpriority
have higher precedence for the calculations. The priority is overriden as always via the use of parentheses, which are identified as defined above.
{
"Serilog": {
"MinimumLevel": "Debug",
"WriteTo": [
{
"Name": "Console",
"Args": {
"restrictedToMinimumLevel": "Debug"
}
}
]
},
"tokenizer": {
"version": "1.0",
"caseSensitive": false,
"tokenPatterns": {
"identifier": "[A-Za-z_]\\w*",
"literal": "\\b(?:\\d+(?:\\.\\d*)?|\\.\\d+)\\b",
"openParenthesis": "(",
"closeParenthesis": ")",
"argumentSeparator": ",",
"unary": [
{
"name": "-",
"priority": 3,
"prefix": true
},
{
"name": "+",
"priority": 3,
"prefix": true
},
{
"name": "!",
"priority": 3,
"prefix": true
},
{
"name": "%",
"priority": 3,
"prefix": false
},
{
"name": "*",
"priority": 3,
"prefix": false
}
],
"operators": [
{
"name": ",",
"priority": 0
},
{
"name": "+",
"priority": 1
},
{
"name": "-",
"priority": 1
},
{
"name": "*",
"priority": 2
},
{
"name": "/",
"priority": 2
},
{
"name": "^",
"priority": 4,
"lefttoright": false
}
]
}
}
}
The appsettings.json
file should exist in the same folder with the executable, so be sure that the file is set to be copied to the output directory. For example, inside the project file, the following block should be included:
<ItemGroup>
<EmbeddedResource Include="appsettings.json">
<CopyToOutputDirectory>PreserveNewest</CopyToOutputDirectory>
</EmbeddedResource>
</ItemGroup>
Note that we are not bound to use the specific name for the configuration file. For example, we might want to keep the appsettings.json
file for the logger configuration, and have another file parsersettings.json
for the tokenizer (which should be also in the same directory with the executable). In order to define the parsersettings.json
file, we define it as an argument when retrieving the IHost
app instance, or immediately the IParser
parser instance via the following calls:
var app = App.GetParserApp<DefaultParser>("parsersettings.json");
var parser = app.Services.GetParser();
//or to immediately get the parser
var parser2 = App.GetCustomParser<DefaultParser>("parsersettings.json");
Note, that in both cases above, the appsettings.json
is also read (if found). The parsersettings.json
file has higher priority, in case there are some conflicting options.
An example of using the internal fields _options
of type TokenizerOptions
and _logger
of type ILogger
can be shown below, by modifying the CustomTypeParser
slightly modifying the example above:
...
protected override object EvaluateOperator(Node<Token> operatorNode, Dictionary<Node<Token>, object> nodeValueDictionary)
{
(object LeftOperand, object RightOperand) = operatorNode.GetBinaryArguments(nodeValueDictionary);
if (operatorNode.Text == "+")
{
//ADDED:
_logger.LogDebug("Adding with + operator {left} and {right}", LeftOperand, RightOperand);
if (LeftOperand is Item && RightOperand is Item)
return (Item)LeftOperand + (Item)RightOperand;
return LeftOperand is Item ? (Item)LeftOperand + (int)RightOperand : (int)LeftOperand + (Item)RightOperand;
}
return base.EvaluateOperator(operatorNode, nodeValueDictionary);
}
protected override object EvaluateFunction(Node<Token> functionNode, Dictionary<Node<Token>, object> nodeValueDictionary)
{
var a = functionNode.GetFunctionArguments(2, nodeValueDictionary);
//return functionNode.Text switch
//MODIFIED: use the CaseSensitive property from the options in the configuration files
return _options.CaseSensitive ? functionNode.Text : functionNode.Text.ToLower() switch
{
"add" => (Item)a[0] + (int)a[1],
_ => base.EvaluateFunction(functionNode, nodeValueDictionary)
};
}
If you want to extend your own IHostBuilder
then this is easily feasible via the AddParserLibrary
extension method. This includes the ITokenizer
, the IParser
and the TokenizerOptions
. Examples of using the extension methods are given below:
using Microsoft.Extensions.DependencyInjection;
using Microsoft.Extensions.Options;
using ParserLibrary;
...
IHostBuilder builder = Host.CreateDefaultBuilder()
...
.ConfigureServices((context, services) =>
{
services
//NOTE: TParser should be one of the derived parsers such as DefaultParser
.AddParserLibrary<TParser>(context) //extension method.
...
;
})
...
var app = builder.Build();
...
var parser1 = app.Services.GetService<IParser>();
//or
var parser2 = app.Services.GetParser(); //extension method
//sample calls if we want to retrieve instances of Tokenizer and TokenizerOptions outside a subclassed Parser
var tokenizer1 = app.Services.GetService<ITokenizer>();
//or
var tokenizer2 = app.Services.GetTokenizer(); //extension method
var tokenizerOptions = app.Services.GetService<IOptions<TokenizerOptions>>().Value;
Parsers
Every Parser
subclass adapts to the IParser
interface and typically every Parser
derives from the Parser
base class.
All derived Parsers use parenthesis pairs ((
, )
) by default to override the operators priority. The priority of the operators is internally defined in the DefaultParser
. A custom Parser
can override the default operator priority and use other than the common operators using an external appsettings.json
file, which will be analyzed in later examples.
DefaultParser
The DefaultParser
class for the moment accepts the followig operators:
+
: plus sign (unary) and plus (binary)-
: negative sign (unary) and minus (binary)*
: multiplication/
: division^
: power
and the following functions:
abs(x)
: Absolute valueacos(x)
: Inverse cosine (in radians)acosd(x)
: Inverse cosine (in degrees)acosh(x)
: Inverse hyperbolic cosineasin(x)
: Inverse sine (in radians)asind(x)
: Inverse sine (in degrees)asinh(x)
: Inverse hyperbolic sineatan(x)
: Inverse tangent (in radians)atand(x)
: Inverse tangent (in degrees)atan2(y,x)
: Inverse tangent (in radians)atan2d(y,x)
: Inverse tangent (in degrees)atanh(x)
: Inverse hyperbolic tangentcbrt(x)
: Cube rootcos(x)
: Cosine (x in radians)cosd(x)
: Cosine (x in degrees)cosh(x)
: Hyperbolic cosineexp(x)
: Exponential function (e^x)log(x)
/ln(x)
: Natural logarithmlog10(x)
: Base 10 logarithmlog2(x)
: Base 2 logarithmlogn(x,n)
: Base n logarithmmax(x,y)
: Maximummin(x,y)
: Minimumpow(x,y)
: Power function (x^y)round(x,y)
: Round to y decimal digitssin(x)
: Sine (x in radians)sind(x)
: Sine (x in degrees)sinh(x)
: Hyperbolic sinesqr(x)
/sqrt(x)
: Square roottan(x)
: Tangent (x in radians)tand(x)
: Tangent (x in degrees)tanh(x)
: Hyperbolic tangent
The following constants are also defined unless the same names are overriden by the variables
dictionary argument when calling the Evaluate
function:
ComplexParser
The ComplexParser
class for the moment accepts the followig operators:
+
: plus sign (unary) and plus (binary)-
: negative sign (unary) and minus (binary)*
: multiplication/
: division^
: power
and the following functions:
abs(z)
: Absolute valueacos(z)
: Inverse cosine (in radians)acosd(z)
: Inverse cosine (in degrees)asin(z)
: Inverse sine (in radians)asind(z)
: Inverse sine (in degrees)atan(z)
: Inverse tangent (in radians)atand(z)
: Inverse tangent (in degrees)cos(z)
: Cosine (z in radians)cosd(z)
: Cosine (z in degrees)cosh(z)
: Hyperbolic cosineexp(z)
: Exponential function (e^z)log(z)
/ln(z)
: Natural logarithmlog10(z)
: Base 10 logarithmlog2(z)
: Base 2 logarithmlogn(z,n)
: Base n logarithmpow(z,y)
: Power function (z^y)round(z,y)
: Round to y decimal digitssin(z)
: Sine (z in radians)sind(z)
: Sine (z in degrees)sinh(z)
: Hyperbolic sinesqr(z)
/sqrt(z)
: Square roottan(z)
: Tangent (z in radians)tand(z)
: Tangent (z in degrees)tanh(z)
: Hyperbolic tangent
The following constants are also defined unless the same names are overriden by the variables
dictionary argument when calling the Evaluate
function:
i
,j
: the imaginary unit (see imaginary unit)pi
: the number π (see π)e
: the Euler's number (see e)
more documentation to follow soon...
Product | Versions Compatible and additional computed target framework versions. |
---|---|
.NET | net6.0 is compatible. net6.0-android was computed. net6.0-ios was computed. net6.0-maccatalyst was computed. net6.0-macos was computed. net6.0-tvos was computed. net6.0-windows was computed. net7.0 was computed. net7.0-android was computed. net7.0-ios was computed. net7.0-maccatalyst was computed. net7.0-macos was computed. net7.0-tvos was computed. net7.0-windows was computed. net8.0 was computed. net8.0-android was computed. net8.0-browser was computed. net8.0-ios was computed. net8.0-maccatalyst was computed. net8.0-macos was computed. net8.0-tvos was computed. net8.0-windows was computed. |
-
net6.0
- Microsoft.Extensions.Hosting (>= 6.0.1)
- Microsoft.Extensions.Hosting.Abstractions (>= 6.0.0)
- Serilog.AspNetCore (>= 5.0.0)
NuGet packages
This package is not used by any NuGet packages.
GitHub repositories
This package is not used by any popular GitHub repositories.
Version | Downloads | Last updated | |
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1.4.12 | 124 | 3/1/2024 | |
1.4.11 | 169 | 6/26/2023 | |
1.4.10 | 127 | 6/26/2023 | |
1.4.9 | 126 | 6/25/2023 | |
1.4.8 | 131 | 6/23/2023 | |
1.4.7 | 119 | 6/19/2023 | |
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1.3.3 | 384 | 7/25/2022 | |
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