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package compiler.lib.template_framework;
import java.util.function.BiFunction;
import java.util.function.Function;
import java.util.function.Supplier;
import java.util.List;
import compiler.lib.compile_framework.CompileFramework;
import compiler.lib.ir_framework.TestFramework;
/**
* The Template Framework allows the generation of code with Templates. The goal is that these Templates are
* easy to write, and allow regression tests to cover a larger scope, and to make template based fuzzing easy
* to extend.
*
*
* Motivation: We want to make it easy to generate variants of tests. Often, we would like to
* have a set of tests, corresponding to a set of types, a set of operators, a set of constants, etc. Writing all
* the tests by hand is cumbersome or even impossible. When generating such tests with scripts, it would be
* preferable if the code generation happens automatically, and the generator script was checked into the code
* base. Code generation can go beyond simple regression tests, and one might want to generate random code from
* a list of possible templates, to fuzz individual Java features and compiler optimizations.
*
*
* The Template Framework provides a facility to generate code with Templates. A Template is essentially a list
* of tokens that are concatenated (i.e. rendered) to a {@link String}. The Templates can have "holes", which are
* filled (replaced) by different values at each Template instantiation. For example, these "holes" can
* be filled with different types, operators or constants. Templates can also be nested, allowing a modular
* use of Templates.
*
*
* Once we rendered the source code to a {@link String}, we can compile it with the {@link CompileFramework}.
*
*
* Example:
* The following snippets are from the example test {@code TestAdvanced.java}.
* First, we define a template that generates a {@code @Test} method for a given type, operator and
* constant generator. We define two constants {@code con1} and {@code con2}, and then use a multiline
* string with hashtags {@code #} (i.e. "holes") that are then replaced by the template arguments and the
* {@link #let} definitions.
*
*
* {@snippet lang=java :
* var testTemplate = Template.make("typeName", "operator", "generator", (String typeName, String operator, MyGenerator generator) -> body(
* let("con1", generator.next()),
* let("con2", generator.next()),
* """
* // #typeName #operator #con1 #con2
* public static #typeName $GOLD = $test();
*
* @Test
* public static #typeName $test() {
* return (#typeName)(#con1 #operator #con2);
* }
*
* @Check(test = "$test")
* public static void $check(#typeName result) {
* Verify.checkEQ(result, $GOLD);
* }
* """
* ));
* }
*
*
* To get an executable test, we define a {@link Template} that produces a class body with a main method. The Template
* takes a list of types, and calls the {@code testTemplate} defined above for each type and operator. We use
* the {@link TestFramework} to call our {@code @Test} methods.
*
*
* {@snippet lang=java :
* var classTemplate = Template.make("types", (List types) -> body(
* let("classpath", comp.getEscapedClassPathOfCompiledClasses()),
* """
* package p.xyz;
*
* import compiler.lib.ir_framework.*;
* import compiler.lib.verify.*;
*
* public class InnerTest {
* public static void main() {
* // Set the classpath, so that the TestFramework test VM knows where
* // the CompileFramework put the class files of the compiled source code.
* TestFramework framework = new TestFramework(InnerTest.class);
* framework.addFlags("-classpath", "#classpath");
* framework.start();
* }
*
* """,
* // Call the testTemplate for each type and operator, generating a
* // list of lists of TemplateToken:
* types.stream().map((Type type) ->
* type.operators().stream().map((String operator) ->
* testTemplate.asToken(type.name(), operator, type.generator())).toList()
* ).toList(),
* """
* }
* """
* ));
* }
*
*
* Finally, we generate the list of types, and pass it to the class template:
*
*
* {@snippet lang=java :
* List types = List.of(
* new Type("byte", GEN_BYTE::next, List.of("+", "-", "*", "&", "|", "^")),
* new Type("char", GEN_CHAR::next, List.of("+", "-", "*", "&", "|", "^")),
* new Type("short", GEN_SHORT::next, List.of("+", "-", "*", "&", "|", "^")),
* new Type("int", GEN_INT::next, List.of("+", "-", "*", "&", "|", "^")),
* new Type("long", GEN_LONG::next, List.of("+", "-", "*", "&", "|", "^")),
* new Type("float", GEN_FLOAT::next, List.of("+", "-", "*", "/")),
* new Type("double", GEN_DOUBLE::next, List.of("+", "-", "*", "/"))
* );
*
* // Use the template with one argument, and render it to a String.
* return classTemplate.render(types);
* }
*
*
* Details:
*
* A {@link Template} can have zero or more arguments. A template can be created with {@code make} methods like
* {@link Template#make(String, Function)}. For each number of arguments there is an implementation
* (e.g. {@link Template.TwoArgs} for two arguments). This allows the use of generics for the
* {@link Template} argument types which enables type checking of the {@link Template} arguments.
* It is currently only allowed to use up to three arguments.
*
*
* A {@link Template} can be rendered to a {@link String} (e.g. {@link Template.ZeroArgs#render()}).
* Alternatively, we can generate a {@link Token} (more specifically, a {@link TemplateToken}) with {@code asToken()}
* (e.g. {@link Template.ZeroArgs#asToken()}), and use the {@link Token} inside another {@link Template#body}.
*
*
* Ideally, we would have used string templates to inject these Template
* arguments into the strings. But since string templates are not (yet) available, the Templates provide
* hashtag replacements in the {@link String}s: the Template argument names are captured, and
* the argument values automatically replace any {@code "#name"} in the {@link String}s. See the different overloads
* of {@link #make} for examples. Additional hashtag replacements can be defined with {@link #let}.
*
*
* When using nested Templates, there can be collisions with identifiers (e.g. variable names and method names).
* For this, Templates provide dollar replacements, which automatically rename any
* {@code "$name"} in the {@link String} with a {@code "name_ID"}, where the {@code "ID"} is unique for every use of
* a Template. The dollar replacement can also be captured with {@link #$}, and passed to nested
* Templates, which allows sharing of these identifier names between Templates.
*
*
* The dollar and hashtag names must have at least one character. The first character must be a letter
* or underscore (i.e. {@code a-zA-Z_}), the other characters can also be digits (i.e. {@code a-zA-Z0-9_}).
* One can use them with or without curly braces, e.g. {@code #name}, {@code #{name}}, {@code $name}, or
* {@code #{name}}.
*
*
* A {@link TemplateToken} cannot just be used in {@link Template#body}, but it can also be
* {@link Hook#insert}ed to where a {@link Hook} was {@link Hook#anchor}ed earlier (in some outer scope of the code).
* For example, while generating code in a method, one can reach out to the scope of the class, and insert a
* new field, or define a utility method.
*
*
* A {@link TemplateBinding} allows the recursive use of Templates. With the indirection of such a binding,
* a Template can reference itself.
*
*
* The writer of recursive {@link Template}s must ensure that this recursion terminates. To unify the
* approach across {@link Template}s, we introduce the concept of {@link #fuel}. Templates are rendered starting
* with a limited amount of {@link #fuel} (default: 100, see {@link #DEFAULT_FUEL}), which is decreased at each
* Template nesting by a certain amount (default: 10, see {@link #DEFAULT_FUEL_COST}). The default fuel for a
* template can be changed when we {@code render()} it (e.g. {@link ZeroArgs#render(float)}) and the default
* fuel cost with {@link #setFuelCost}) when defining the {@link #body(Object...)}. Recursive templates are
* supposed to terminate once the {@link #fuel} is depleted (i.e. reaches zero).
*
*
* Code generation can involve keeping track of fields and variables, as well as the scopes in which they
* are available, and if they are mutable or immutable. We model fields and variables with {@link DataName}s,
* which we can add to the current scope with {@link #addDataName}. We can access the {@link DataName}s with
* {@link #dataNames}. We can filter for {@link DataName}s of specific {@link DataName.Type}s, and then
* we can call {@link DataName.FilteredSet#count}, {@link DataName.FilteredSet#sample},
* {@link DataName.FilteredSet#toList}, etc. There are many use-cases for this mechanism, especially
* facilitating communication between the code of outer and inner {@link Template}s. Especially for fuzzing,
* it may be useful to be able to add fields and variables, and sample them randomly, to create a random data
* flow graph.
*
*
* Similarly, we may want to model method and class names, and possibly other structural names. We model
* these names with {@link StructuralName}, which works analogously to {@link DataName}, except that they
* are not concerned about mutability.
*
*
* When working with {@link DataName}s and {@link StructuralName}s, it is important to be aware of the
* relevant scopes, as well as the execution order of the {@link Template} lambdas and the evaluation
* of the {@link Template#body} tokens. When a {@link Template} is rendered, its lambda is invoked. In the
* lambda, we generate the tokens, and create the {@link Template#body}. Once the lambda returns, the
* tokens are evaluated one by one. While evaluating the tokens, the {@link Renderer} might encounter a nested
* {@link TemplateToken}, which in turn triggers the evaluation of that nested {@link Template}, i.e.
* the evaluation of its lambda and later the evaluation of its tokens. It is important to keep in mind
* that the lambda is always executed first, and the tokens are evaluated afterwards. A method like
* {@code dataNames(MUTABLE).exactOf(type).count()} is a method that is executed during the evaluation
* of the lambda. But a method like {@link #addDataName} returns a token, and does not immediately add
* the {@link DataName}. This ensures that the {@link DataName} is only inserted when the tokens are
* evaluated, so that it is inserted at the exact scope where we would expect it.
*
*
* Let us look at the following example to better understand the execution order.
*
*
* {@snippet lang=java :
* var testTemplate = Template.make(() -> body(
* // The lambda has just been invoked.
* // We count the DataNames and assign the count to the hashtag replacement "c1".
* let("c1", dataNames(MUTABLE).exactOf(someType).count()),
* // We want to define a DataName "v1", and create a token for it.
* addDataName($("v1"), someType, MUTABLE),
* // We count the DataNames again, but the count does NOT change compared to "c1".
* // This is because the token for "v1" is only evaluated later.
* let("c2", dataNames(MUTABLE).exactOf(someType).count()),
* // Create a nested scope.
* METHOD_HOOK.anchor(
* // We want to define a DataName "v2", which is only valid inside this
* // nested scope.
* addDataName($("v2"), someType, MUTABLE),
* // The count is still not different to "c1".
* let("c3", dataNames(MUTABLE).exactOf(someType).count()),
* // We nest a Template. This creates a TemplateToken, which is later evaluated.
* // By the time the TemplateToken is evaluated, the tokens from above will
* // be already evaluated. Hence, "v1" and "v2" are added by then, and if the
* // "otherTemplate" were to count the DataNames, the count would be increased
* // by 2 compared to "c1".
* otherTemplate.asToken()
* ),
* // After closing the scope, "v2" is no longer available.
* // The count is still the same as "c1", since "v1" is still only a token.
* let("c4", dataNames(MUTABLE).exactOf(someType).count()),
* // We nest another Template. Again, this creates a TemplateToken, which is only
* // evaluated later. By that time, the token for "v1" is evaluated, and so the
* // nested Template would observe an increment in the count.
* anotherTemplate.asToken()
* // By this point, all methods are called, and the tokens generated.
* // The lambda returns the "body", which is all of the tokens that we just
* // generated. After returning from the lambda, the tokens will be evaluated
* // one by one.
* ));
* }
*
* More examples for these functionalities can be found in {@code TestTutorial.java}, {@code TestSimple.java},
* and {@code TestAdvanced.java}, which all produce compilable Java code. Additional examples can be found in
* the tests, such as {@code TestTemplate.java} and {@code TestFormat.java}, which do not necessarily generate
* valid Java code, but generate deterministic Strings which are easier to verify, and may also serve as a
* reference when learning about these functionalities.
*/
public sealed interface Template permits Template.ZeroArgs,
Template.OneArg,
Template.TwoArgs,
Template.ThreeArgs {
/**
* A {@link Template} with no arguments.
*
* @param function The {@link Supplier} that creates the {@link TemplateBody}.
*/
record ZeroArgs(Supplier function) implements Template {
TemplateBody instantiate() {
return function.get();
}
/**
* Creates a {@link TemplateToken} which can be used as a {@link Token} inside
* a {@link Template} for nested code generation.
*
* @return The {@link TemplateToken} to use the {@link Template} inside another
* {@link Template}.
*/
public TemplateToken asToken() {
return new TemplateToken.ZeroArgs(this);
}
/**
* Renders the {@link Template} to a {@link String}.
*
* @return The {@link String}, resulting from rendering the {@link Template}.
*/
public String render() {
return new TemplateToken.ZeroArgs(this).render();
}
/**
* Renders the {@link Template} to a {@link String}.
*
* @param fuel The amount of fuel provided for recursive Template instantiations.
* @return The {@link String}, resulting from rendering the {@link Template}.
*/
public String render(float fuel) {
return new TemplateToken.ZeroArgs(this).render(fuel);
}
}
/**
* A {@link Template} with one argument.
*
* @param arg1Name The name of the (first) argument, used for hashtag replacements in the {@link Template}.
* @param The type of the (first) argument.
* @param function The {@link Function} that creates the {@link TemplateBody} given the template argument.
*/
record OneArg(String arg1Name, Function function) implements Template {
TemplateBody instantiate(T1 arg1) {
return function.apply(arg1);
}
/**
* Creates a {@link TemplateToken} which can be used as a {@link Token} inside
* a {@link Template} for nested code generation.
*
* @param arg1 The value for the (first) argument.
* @return The {@link TemplateToken} to use the {@link Template} inside another
* {@link Template}.
*/
public TemplateToken asToken(T1 arg1) {
return new TemplateToken.OneArg<>(this, arg1);
}
/**
* Renders the {@link Template} to a {@link String}.
*
* @param arg1 The value for the first argument.
* @return The {@link String}, resulting from rendering the {@link Template}.
*/
public String render(T1 arg1) {
return new TemplateToken.OneArg<>(this, arg1).render();
}
/**
* Renders the {@link Template} to a {@link String}.
*
* @param arg1 The value for the first argument.
* @param fuel The amount of fuel provided for recursive Template instantiations.
* @return The {@link String}, resulting from rendering the {@link Template}.
*/
public String render(float fuel, T1 arg1) {
return new TemplateToken.OneArg<>(this, arg1).render(fuel);
}
}
/**
* A {@link Template} with two arguments.
*
* @param arg1Name The name of the first argument, used for hashtag replacements in the {@link Template}.
* @param arg2Name The name of the second argument, used for hashtag replacements in the {@link Template}.
* @param The type of the first argument.
* @param The type of the second argument.
* @param function The {@link BiFunction} that creates the {@link TemplateBody} given the template arguments.
*/
record TwoArgs(String arg1Name, String arg2Name, BiFunction function) implements Template {
TemplateBody instantiate(T1 arg1, T2 arg2) {
return function.apply(arg1, arg2);
}
/**
* Creates a {@link TemplateToken} which can be used as a {@link Token} inside
* a {@link Template} for nested code generation.
*
* @param arg1 The value for the first argument.
* @param arg2 The value for the second argument.
* @return The {@link TemplateToken} to use the {@link Template} inside another
* {@link Template}.
*/
public TemplateToken asToken(T1 arg1, T2 arg2) {
return new TemplateToken.TwoArgs<>(this, arg1, arg2);
}
/**
* Renders the {@link Template} to a {@link String}.
*
* @param arg1 The value for the first argument.
* @param arg2 The value for the second argument.
* @return The {@link String}, resulting from rendering the {@link Template}.
*/
public String render(T1 arg1, T2 arg2) {
return new TemplateToken.TwoArgs<>(this, arg1, arg2).render();
}
/**
* Renders the {@link Template} to a {@link String}.
*
* @param arg1 The value for the first argument.
* @param arg2 The value for the second argument.
* @param fuel The amount of fuel provided for recursive Template instantiations.
* @return The {@link String}, resulting from rendering the {@link Template}.
*/
public String render(float fuel, T1 arg1, T2 arg2) {
return new TemplateToken.TwoArgs<>(this, arg1, arg2).render(fuel);
}
}
/**
* Interface for function with three arguments.
*
* @param Type of the first argument.
* @param Type of the second argument.
* @param Type of the third argument.
* @param Type of the return value.
*/
@FunctionalInterface
interface TriFunction {
/**
* Function definition for the three argument functions.
*
* @param t The first argument.
* @param u The second argument.
* @param v The third argument.
* @return Return value of the three argument function.
*/
R apply(T t, U u, V v);
}
/**
* A {@link Template} with three arguments.
*
* @param arg1Name The name of the first argument, used for hashtag replacements in the {@link Template}.
* @param arg2Name The name of the second argument, used for hashtag replacements in the {@link Template}.
* @param arg3Name The name of the third argument, used for hashtag replacements in the {@link Template}.
* @param The type of the first argument.
* @param The type of the second argument.
* @param The type of the third argument.
* @param function The function with three arguments that creates the {@link TemplateBody} given the template arguments.
*/
record ThreeArgs(String arg1Name, String arg2Name, String arg3Name, TriFunction function) implements Template {
TemplateBody instantiate(T1 arg1, T2 arg2, T3 arg3) {
return function.apply(arg1, arg2, arg3);
}
/**
* Creates a {@link TemplateToken} which can be used as a {@link Token} inside
* a {@link Template} for nested code generation.
*
* @param arg1 The value for the first argument.
* @param arg2 The value for the second argument.
* @param arg3 The value for the third argument.
* @return The {@link TemplateToken} to use the {@link Template} inside another
* {@link Template}.
*/
public TemplateToken asToken(T1 arg1, T2 arg2, T3 arg3) {
return new TemplateToken.ThreeArgs<>(this, arg1, arg2, arg3);
}
/**
* Renders the {@link Template} to a {@link String}.
*
* @param arg1 The value for the first argument.
* @param arg2 The value for the second argument.
* @param arg3 The value for the third argument.
* @return The {@link String}, resulting from rendering the {@link Template}.
*/
public String render(T1 arg1, T2 arg2, T3 arg3) {
return new TemplateToken.ThreeArgs<>(this, arg1, arg2, arg3).render();
}
/**
* Renders the {@link Template} to a {@link String}.
*
* @param arg1 The value for the first argument.
* @param arg2 The value for the second argument.
* @param arg3 The value for the third argument.
* @param fuel The amount of fuel provided for recursive Template instantiations.
* @return The {@link String}, resulting from rendering the {@link Template}.
*/
public String render(float fuel, T1 arg1, T2 arg2, T3 arg3) {
return new TemplateToken.ThreeArgs<>(this, arg1, arg2, arg3).render(fuel);
}
}
/**
* Creates a {@link Template} with no arguments.
* See {@link #body} for more details about how to construct a Template with {@link Token}s.
*
*
* Example:
* {@snippet lang=java :
* var template = Template.make(() -> body(
* """
* Multi-line string or other tokens.
* """
* ));
* }
*
* @param body The {@link TemplateBody} created by {@link Template#body}.
* @return A {@link Template} with zero arguments.
*/
static Template.ZeroArgs make(Supplier body) {
return new Template.ZeroArgs(body);
}
/**
* Creates a {@link Template} with one argument.
* See {@link #body} for more details about how to construct a Template with {@link Token}s.
* Good practice but not enforced but not enforced: {@code arg1Name} should match the lambda argument name.
*
*
* Here is an example with template argument {@code 'a'}, captured once as string name
* for use in hashtag replacements, and captured once as lambda argument with the corresponding type
* of the generic argument.
* {@snippet lang=java :
* var template = Template.make("a", (Integer a) -> body(
* """
* Multi-line string or other tokens.
* We can use the hashtag replacement #a to directly insert the String value of a.
* """,
* "We can also use the captured parameter of a: " + a
* ));
* }
*
* @param body The {@link TemplateBody} created by {@link Template#body}.
* @param Type of the (first) argument.
* @param arg1Name The name of the (first) argument for hashtag replacement.
* @return A {@link Template} with one argument.
*/
static Template.OneArg make(String arg1Name, Function body) {
return new Template.OneArg<>(arg1Name, body);
}
/**
* Creates a {@link Template} with two arguments.
* See {@link #body} for more details about how to construct a Template with {@link Token}s.
* Good practice but not enforced: {@code arg1Name} and {@code arg2Name} should match the lambda argument names.
*
*
* Here is an example with template arguments {@code 'a'} and {@code 'b'}, captured once as string names
* for use in hashtag replacements, and captured once as lambda arguments with the corresponding types
* of the generic arguments.
* {@snippet lang=java :
* var template = Template.make("a", "b", (Integer a, String b) -> body(
* """
* Multi-line string or other tokens.
* We can use the hashtag replacement #a and #b to directly insert the String value of a and b.
* """,
* "We can also use the captured parameter of a and b: " + a + " and " + b
* ));
* }
*
* @param body The {@link TemplateBody} created by {@link Template#body}.
* @param Type of the first argument.
* @param arg1Name The name of the first argument for hashtag replacement.
* @param Type of the second argument.
* @param arg2Name The name of the second argument for hashtag replacement.
* @return A {@link Template} with two arguments.
*/
static Template.TwoArgs make(String arg1Name, String arg2Name, BiFunction body) {
return new Template.TwoArgs<>(arg1Name, arg2Name, body);
}
/**
* Creates a {@link Template} with three arguments.
* See {@link #body} for more details about how to construct a Template with {@link Token}s.
* Good practice but not enforced: {@code arg1Name}, {@code arg2Name}, and {@code arg3Name} should match the lambda argument names.
*
* @param body The {@link TemplateBody} created by {@link Template#body}.
* @param Type of the first argument.
* @param arg1Name The name of the first argument for hashtag replacement.
* @param Type of the second argument.
* @param arg2Name The name of the second argument for hashtag replacement.
* @param Type of the third argument.
* @param arg3Name The name of the third argument for hashtag replacement.
* @return A {@link Template} with three arguments.
*/
static Template.ThreeArgs make(String arg1Name, String arg2Name, String arg3Name, Template.TriFunction body) {
return new Template.ThreeArgs<>(arg1Name, arg2Name, arg3Name, body);
}
/**
* Creates a {@link TemplateBody} from a list of tokens, which can be {@link String}s,
* boxed primitive types (for example {@link Integer} or auto-boxed {@code int}), any {@link Token},
* or {@link List}s of any of these.
*
*
* {@snippet lang=java :
* var template = Template.make(() -> body(
* """
* Multi-line string
* """,
* "normal string ", Integer.valueOf(3), 3, Float.valueOf(1.5f), 1.5f,
* List.of("abc", "def"),
* nestedTemplate.asToken(42)
* ));
* }
*
* @param tokens A list of tokens, which can be {@link String}s, boxed primitive types
* (for example {@link Integer}), any {@link Token}, or {@link List}s
* of any of these.
* @return The {@link TemplateBody} which captures the list of validated {@link Token}s.
* @throws IllegalArgumentException if the list of tokens contains an unexpected object.
*/
static TemplateBody body(Object... tokens) {
return new TemplateBody(Token.parse(tokens));
}
/**
* Retrieves the dollar replacement of the {@code 'name'} for the
* current Template that is being instantiated. It returns the same
* dollar replacement as the string use {@code "$name"}.
*
*
* Here is an example where a Template creates a local variable {@code 'var'},
* with an implicit dollar replacement, and then captures that dollar replacement
* using {@link #$} for the use inside a nested template.
* {@snippet lang=java :
* var template = Template.make(() -> body(
* """
* int $var = 42;
* """,
* otherTemplate.asToken($("var"))
* ));
* }
*
* @param name The {@link String} name of the name.
* @return The dollar replacement for the {@code 'name'}.
*/
static String $(String name) {
return Renderer.getCurrent().$(name);
}
/**
* Define a hashtag replacement for {@code "#key"}, with a specific value.
*
*
* {@snippet lang=java :
* var template = Template.make("a", (Integer a) -> body(
* let("b", a * 5),
* """
* System.out.println("Use a and b with hashtag replacement: #a and #b");
* """
* ));
* }
*
* @param key Name for the hashtag replacement.
* @param value The value that the hashtag is replaced with.
* @return A token that does nothing, so that the {@link #let} can easily be put in a list of tokens
* inside a {@link Template#body}.
* @throws RendererException if there is a duplicate hashtag {@code key}.
*/
static Token let(String key, Object value) {
Renderer.getCurrent().addHashtagReplacement(key, value);
return new NothingToken();
}
/**
* Define a hashtag replacement for {@code "#key"}, with a specific value, which is also captured
* by the provided {@code function} with type {@code }.
*
*
* {@snippet lang=java :
* var template = Template.make("a", (Integer a) -> let("b", a * 2, (Integer b) -> body(
* """
* System.out.println("Use a and b with hashtag replacement: #a and #b");
* """,
* "System.out.println(\"Use a and b as capture variables:\"" + a + " and " + b + ");\n"
* )));
* }
*
* @param key Name for the hashtag replacement.
* @param value The value that the hashtag is replaced with.
* @param The type of the value.
* @param function The function that is applied with the provided {@code value}.
* @return A {@link TemplateBody}.
* @throws RendererException if there is a duplicate hashtag {@code key}.
*/
static TemplateBody let(String key, T value, Function function) {
Renderer.getCurrent().addHashtagReplacement(key, value);
return function.apply(value);
}
/**
* Default amount of fuel for Template rendering. It guides the nesting depth of Templates. Can be changed when
* rendering a template with {@code render(fuel)} (e.g. {@link ZeroArgs#render(float)}).
*/
float DEFAULT_FUEL = 100.0f;
/**
* The default amount of fuel spent per Template. It is subtracted from the current {@link #fuel} at every
* nesting level, and once the {@link #fuel} reaches zero, the nesting is supposed to terminate. Can be changed
* with {@link #setFuelCost(float)} inside {@link #body(Object...)}.
*/
float DEFAULT_FUEL_COST = 10.0f;
/**
* The current remaining fuel for nested Templates. Every level of Template nesting
* subtracts a certain amount of fuel, and when it reaches zero, Templates are supposed to
* stop nesting, if possible. This is not a hard rule, but a guide, and a mechanism to ensure
* termination in recursive Template instantiations.
*
*
* Example of a recursive Template, which checks the remaining {@link #fuel} at every level,
* and terminates if it reaches zero. It also demonstrates the use of {@link TemplateBinding} for
* the recursive use of Templates. We {@link Template.OneArg#render} with {@code 30} total fuel,
* and spend {@code 5} fuel at each recursion level.
*
*
* {@snippet lang=java :
* var binding = new TemplateBinding>();
* var template = Template.make("depth", (Integer depth) -> body(
* setFuelCost(5.0f),
* let("fuel", fuel()),
* """
* System.out.println("Currently at depth #depth with fuel #fuel");
* """,
* (fuel() > 0) ? binding.get().asToken(depth + 1) :
* "// terminate\n"
* ));
* binding.bind(template);
* String code = template.render(30.0f, 0);
* }
*
* @return The amount of fuel left for nested Template use.
*/
static float fuel() {
return Renderer.getCurrent().fuel();
}
/**
* Changes the amount of fuel used for the current Template, where the default is
* {@link Template#DEFAULT_FUEL_COST}.
*
* @param fuelCost The amount of fuel used for the current Template.
* @return A token for convenient use in {@link Template#body}.
*/
static Token setFuelCost(float fuelCost) {
Renderer.getCurrent().setFuelCost(fuelCost);
return new NothingToken();
}
/**
* Add a {@link DataName} in the current scope, that is the innermost of either
* {@link Template#body} or {@link Hook#anchor}.
*
* @param name The name of the {@link DataName}, i.e. the {@link String} used in code.
* @param type The type of the {@link DataName}.
* @param mutability Indicates if the {@link DataName} is to be mutable or immutable,
* i.e. if we intend to use the {@link DataName} only for reading
* or if we also allow it to be mutated.
* @param weight The weight of the {@link DataName}, which correlates to the probability
* of this {@link DataName} being chosen when we sample.
* Must be a value from 1 to 1000.
* @return The token that performs the defining action.
*/
static Token addDataName(String name, DataName.Type type, DataName.Mutability mutability, int weight) {
if (mutability != DataName.Mutability.MUTABLE &&
mutability != DataName.Mutability.IMMUTABLE) {
throw new IllegalArgumentException("Unexpected mutability: " + mutability);
}
boolean mutable = mutability == DataName.Mutability.MUTABLE;
if (weight <= 0 || 1000 < weight) {
throw new IllegalArgumentException("Unexpected weight: " + weight);
}
return new AddNameToken(new DataName(name, type, mutable, weight));
}
/**
* Add a {@link DataName} in the current scope, that is the innermost of either
* {@link Template#body} or {@link Hook#anchor}, with a {@code weight} of 1.
*
* @param name The name of the {@link DataName}, i.e. the {@link String} used in code.
* @param type The type of the {@link DataName}.
* @param mutability Indicates if the {@link DataName} is to be mutable or immutable,
* i.e. if we intend to use the {@link DataName} only for reading
* or if we also allow it to be mutated.
* @return The token that performs the defining action.
*/
static Token addDataName(String name, DataName.Type type, DataName.Mutability mutability) {
return addDataName(name, type, mutability, 1);
}
/**
* Access the set of {@link DataName}s, for sampling, counting, etc.
*
* @param mutability Indicates if we only sample from mutable, immutable or either {@link DataName}s.
* @return A view on the {@link DataName}s, on which we can sample, count, etc.
*/
static DataName.FilteredSet dataNames(DataName.Mutability mutability) {
return new DataName.FilteredSet(mutability);
}
/**
* Add a {@link StructuralName} in the current scope, that is the innermost of either
* {@link Template#body} or {@link Hook#anchor}.
*
* @param name The name of the {@link StructuralName}, i.e. the {@link String} used in code.
* @param type The type of the {@link StructuralName}.
* @param weight The weight of the {@link StructuralName}, which correlates to the probability
* of this {@link StructuralName} being chosen when we sample.
* Must be a value from 1 to 1000.
* @return The token that performs the defining action.
*/
static Token addStructuralName(String name, StructuralName.Type type, int weight) {
if (weight <= 0 || 1000 < weight) {
throw new IllegalArgumentException("Unexpected weight: " + weight);
}
return new AddNameToken(new StructuralName(name, type, weight));
}
/**
* Add a {@link StructuralName} in the current scope, that is the innermost of either
* {@link Template#body} or {@link Hook#anchor}, with a {@code weight} of 1.
*
* @param name The name of the {@link StructuralName}, i.e. the {@link String} used in code.
* @param type The type of the {@link StructuralName}.
* @return The token that performs the defining action.
*/
static Token addStructuralName(String name, StructuralName.Type type) {
return addStructuralName(name, type, 1);
}
/**
* Access the set of {@link StructuralName}s, for sampling, counting, etc.
*
* @return A view on the {@link StructuralName}s, on which we can sample, count, etc.
*/
static StructuralName.FilteredSet structuralNames() {
return new StructuralName.FilteredSet();
}
}