tools/checker/README - LeafOS-Project/android_art - Gitiles

 Checker is a testing tool which compiles a given test file and compares the
 state of the control-flow graph before and after each optimization pass
 against a set of statements specified alongside the tests.

 Tests are written in Java or Smali, turned into DEX and compiled with the
 Optimizing compiler. "Check lines" are statements formatted as comments of the
 source file. They begin with prefix "/// CHECK" or "## CHECK", respectively,
 followed by a pattern that the engine attempts to match in the compiler output.

 Statements are tested in groups which correspond to the individual compiler
 passes. Each group of check lines therefore must start with a 'CHECK-START'
 header which specifies the output group it should be tested against. The group
 name must exactly match one of the groups recognized in the output (they can
 be listed with the '--list-passes' command-line flag).

 Matching of check lines is carried out in the order of appearance in the
 source file. There are five types of check lines. Branching instructions are
 also supported and documented later in this file.
  - CHECK:      Must match an output line which appears in the output group
                later than lines matched against any preceding checks. Output
                lines must therefore match the check lines in the same order.
                These are referred to as "in-order" checks in the code.
  - CHECK-DAG:  Must match an output line which appears in the output group
                later than lines matched against any preceding in-order checks.
                In other words, the order of output lines does not matter
                between consecutive DAG checks.
  - CHECK-NOT:  Must not match any output line which appears in the output group
                later than lines matched against any preceding checks and
                earlier than lines matched against any subsequent checks.
                Surrounding non-negative checks (or boundaries of the group)
                therefore create a scope within which the statement is verified.
  - CHECK-NEXT: Must match the output line which comes right after the line which
                matched the previous check. Can only be used after a CHECK or
                another CHECK-NEXT.
  - CHECK-EVAL: Specifies a Python expression which must evaluate to 'True'.

 Check-line patterns are treated as plain text rather than regular expressions
 but are whitespace agnostic.

 Actual regex patterns can be inserted enclosed in '{{' and '}}' brackets. If
 curly brackets need to be used inside the body of the regex, they need to be
 enclosed in round brackets. For example, the pattern '{{foo{2}}}' will parse
 the invalid regex 'foo{2', but '{{(fo{2})}}' will match 'foo'.

 Regex patterns can be named and referenced later. A new variable is defined
 with '<<name:regex>>' and can be referenced with '<<name>>'. Variables are
 only valid within the scope of the defining group. Within a group they cannot
 be redefined or used undefined.

 Example:
   The following statements can be placed in a Java source file:

   /// CHECK-START: int MyClass.MyMethod() constant_folding (after)
   /// CHECK:         <<ID:i\d+>>  IntConstant {{11|22}}
   /// CHECK:                      Return [<<ID>>]

   The engine will attempt to match the check lines against the output of the
   group named on the first line. Together they verify that the CFG after
   constant folding returns an integer constant with value either 11 or 22.


 Of the language constructs above, 'CHECK-EVAL' lines support only referencing of
 variables. Any other surrounding text will be passed to Python's `eval` as is.

 Example:
   /// CHECK-START: int MyClass.MyMethod() liveness (after)
   /// CHECK:         InstructionA liveness:<<VarA:\d+>>
   /// CHECK:         InstructionB liveness:<<VarB:\d+>>
   /// CHECK-EVAL:    <<VarA>> != <<VarB>>


 A group of check lines can be made architecture-specific by inserting '-<arch>'
 after the 'CHECK-START' keyword. The previous example can be updated to run for
 arm64 only with:

 Example:
   /// CHECK-START-ARM64: int MyClass.MyMethod() constant_folding (after)
   /// CHECK:         <<ID:i\d+>>  IntConstant {{11|22}}
   /// CHECK:                      Return [<<ID>>]

 For convenience, several architectures can be specified as set after the
 'CHECK-START' keyword. Any listed architecture will match in that case,
 thereby avoiding to repeat the check lines if some, but not all architectures
 match. An example line looks like:

   /// CHECK-START-{X86_64,ARM,ARM64}: int MyClass.MyMethod() constant_folding (after)


 Branching is possible thanks to the following statements:
  - CHECK-IF:
  - CHECK-ELIF:
  - CHECK-ELSE:
  - CHECK-FI:

 CHECK-IF and CHECK-ELIF take a Python expression as input that will be evaluated by `eval`.

 A possible use case of branching is to check whether the generated code exploits the instruction
 architecture features enabled at compile time. For that purpose, you can call the custom made
 function isaHasFeature("feature_name").

 Example:
   /// CHECK-START-ARM64: int other.TestByte.testDotProdComplex(byte[], byte[]) disassembly (after)
   /// CHECK:        VecDotProd
   /// CHECK-IF:     isaHasFeature("dotprod")
   ///               CHECK:        sdot
   /// CHECK-ELSE:
   ///               CHECK-NOT:    sdot
   /// CHECK-FI:

 Like CHECK-EVAL, CHECK-IF and CHECK-ELIF support only referencing of variables, defining new
 variables as part of the statement input is not allowed. Any other surrounding text will be passed
 to Python's `eval` as is. CHECK-ELSE and CHECK-FI must not have any input.

 Example:
   /// CHECK-START: int MyClass.MyMethod() constant_folding (after)
   /// CHECK:        {{i\d+}} IntConstant <<MyConst:(0|1|2)>>
   /// CHECK-IF:     <<MyConst>> == 0
   ///               CHECK-NEXT:            FooBar01
   /// CHECK-ELIF:   <<MyConst>> == 1
   ///               CHECK-NOT:             FooBar01
   /// CHECK-FI:

 Branch blocks can contain any statement, including CHECK-NEXT and CHECK-DAG.
 Notice the CHECK-NEXT statement within the IF branch. When a CHECK-NEXT is encountered,
 Checker expects that the previously executed statement was either a CHECK or a CHECK-NEXT.
 This condition is enforced at runtime, and an error is thrown if it's not respected.

 Statements inside branches can define new variables. If a new variable gets defined inside a branch
 (of any depth, since nested branching is allowed), that variable will become global within the scope
 of the defining group. In other words, it will be valid everywhere after its definition within the
 block defined by the CHECK-START statement. The absence of lexical scoping for Checker variables
 seems a bit inelegant at first, but is probably more practical.

 Example:
   /// CHECK-START: void MyClass.FooBar() liveness (after)
   /// CHECK-IF:     os.environ.get('ART_READ_BARRIER_TYPE') != 'TABLELOOKUP'
   ///               CHECK:                 <<MyID:i\d+>> IntConstant 3
   /// CHECK-ELSE:
   ///               CHECK:                 <<MyID:i\d+>> IntConstant 5
   /// CHECK-FI:
   /// CHECK-NEXT:   Return [<<MyID>>]

 Notice that the variable MyID remained valid outside the branch where it was defined.
 Furthermore, in this example, the definition of MyID depends on which branch gets selected at
 runtime. Attempting to re-define a variable or referencing an undefined variable is not allowed,
 Checker will throw a runtime error.
 The example above also shows how we can use environment variables to perform custom checks.

 It is possible to combine IF, (multiple) ELIF and ELSE statements together. Nested branching is
 also supported.
	Checker is a testing tool which compiles a given test file and compares the
	state of the control-flow graph before and after each optimization pass
	against a set of statements specified alongside the tests.

	Tests are written in Java or Smali, turned into DEX and compiled with the
	Optimizing compiler. "Check lines" are statements formatted as comments of the
	source file. They begin with prefix "/// CHECK" or "## CHECK", respectively,
	followed by a pattern that the engine attempts to match in the compiler output.

	Statements are tested in groups which correspond to the individual compiler
	passes. Each group of check lines therefore must start with a 'CHECK-START'
	header which specifies the output group it should be tested against. The group
	name must exactly match one of the groups recognized in the output (they can
	be listed with the '--list-passes' command-line flag).

	Matching of check lines is carried out in the order of appearance in the
	source file. There are five types of check lines. Branching instructions are
	also supported and documented later in this file.
	- CHECK: Must match an output line which appears in the output group
	later than lines matched against any preceding checks. Output
	lines must therefore match the check lines in the same order.
	These are referred to as "in-order" checks in the code.
	- CHECK-DAG: Must match an output line which appears in the output group
	later than lines matched against any preceding in-order checks.
	In other words, the order of output lines does not matter
	between consecutive DAG checks.
	- CHECK-NOT: Must not match any output line which appears in the output group
	later than lines matched against any preceding checks and
	earlier than lines matched against any subsequent checks.
	Surrounding non-negative checks (or boundaries of the group)
	therefore create a scope within which the statement is verified.
	- CHECK-NEXT: Must match the output line which comes right after the line which
	matched the previous check. Can only be used after a CHECK or
	another CHECK-NEXT.
	- CHECK-EVAL: Specifies a Python expression which must evaluate to 'True'.

	Check-line patterns are treated as plain text rather than regular expressions
	but are whitespace agnostic.

	Actual regex patterns can be inserted enclosed in '{{' and '}}' brackets. If
	curly brackets need to be used inside the body of the regex, they need to be
	enclosed in round brackets. For example, the pattern '{{foo{2}}}' will parse
	the invalid regex 'foo{2', but '{{(fo{2})}}' will match 'foo'.

	Regex patterns can be named and referenced later. A new variable is defined
	with '<<name:regex>>' and can be referenced with '<<name>>'. Variables are
	only valid within the scope of the defining group. Within a group they cannot
	be redefined or used undefined.

	Example:
	The following statements can be placed in a Java source file:

	/// CHECK-START: int MyClass.MyMethod() constant_folding (after)
	/// CHECK: <<ID:i\d+>> IntConstant {{11\|22}}
	/// CHECK: Return [<<ID>>]

	The engine will attempt to match the check lines against the output of the
	group named on the first line. Together they verify that the CFG after
	constant folding returns an integer constant with value either 11 or 22.


	Of the language constructs above, 'CHECK-EVAL' lines support only referencing of
	variables. Any other surrounding text will be passed to Python's `eval` as is.

	Example:
	/// CHECK-START: int MyClass.MyMethod() liveness (after)
	/// CHECK: InstructionA liveness:<<VarA:\d+>>
	/// CHECK: InstructionB liveness:<<VarB:\d+>>
	/// CHECK-EVAL: <<VarA>> != <<VarB>>


	A group of check lines can be made architecture-specific by inserting '-<arch>'
	after the 'CHECK-START' keyword. The previous example can be updated to run for
	arm64 only with:

	Example:
	/// CHECK-START-ARM64: int MyClass.MyMethod() constant_folding (after)
	/// CHECK: <<ID:i\d+>> IntConstant {{11\|22}}
	/// CHECK: Return [<<ID>>]

	For convenience, several architectures can be specified as set after the
	'CHECK-START' keyword. Any listed architecture will match in that case,
	thereby avoiding to repeat the check lines if some, but not all architectures
	match. An example line looks like:

	/// CHECK-START-{X86_64,ARM,ARM64}: int MyClass.MyMethod() constant_folding (after)


	Branching is possible thanks to the following statements:
	- CHECK-IF:
	- CHECK-ELIF:
	- CHECK-ELSE:
	- CHECK-FI:

	CHECK-IF and CHECK-ELIF take a Python expression as input that will be evaluated by `eval`.

	A possible use case of branching is to check whether the generated code exploits the instruction
	architecture features enabled at compile time. For that purpose, you can call the custom made
	function isaHasFeature("feature_name").

	Example:
	/// CHECK-START-ARM64: int other.TestByte.testDotProdComplex(byte[], byte[]) disassembly (after)
	/// CHECK: VecDotProd
	/// CHECK-IF: isaHasFeature("dotprod")
	/// CHECK: sdot
	/// CHECK-ELSE:
	/// CHECK-NOT: sdot
	/// CHECK-FI:

	Like CHECK-EVAL, CHECK-IF and CHECK-ELIF support only referencing of variables, defining new
	variables as part of the statement input is not allowed. Any other surrounding text will be passed
	to Python's `eval` as is. CHECK-ELSE and CHECK-FI must not have any input.

	Example:
	/// CHECK-START: int MyClass.MyMethod() constant_folding (after)
	/// CHECK: {{i\d+}} IntConstant <<MyConst:(0\|1\|2)>>
	/// CHECK-IF: <<MyConst>> == 0
	/// CHECK-NEXT: FooBar01
	/// CHECK-ELIF: <<MyConst>> == 1
	/// CHECK-NOT: FooBar01
	/// CHECK-FI:

	Branch blocks can contain any statement, including CHECK-NEXT and CHECK-DAG.
	Notice the CHECK-NEXT statement within the IF branch. When a CHECK-NEXT is encountered,
	Checker expects that the previously executed statement was either a CHECK or a CHECK-NEXT.
	This condition is enforced at runtime, and an error is thrown if it's not respected.

	Statements inside branches can define new variables. If a new variable gets defined inside a branch
	(of any depth, since nested branching is allowed), that variable will become global within the scope
	of the defining group. In other words, it will be valid everywhere after its definition within the
	block defined by the CHECK-START statement. The absence of lexical scoping for Checker variables
	seems a bit inelegant at first, but is probably more practical.

	Example:
	/// CHECK-START: void MyClass.FooBar() liveness (after)
	/// CHECK-IF: os.environ.get('ART_READ_BARRIER_TYPE') != 'TABLELOOKUP'
	/// CHECK: <<MyID:i\d+>> IntConstant 3
	/// CHECK-ELSE:
	/// CHECK: <<MyID:i\d+>> IntConstant 5
	/// CHECK-FI:
	/// CHECK-NEXT: Return [<<MyID>>]

	Notice that the variable MyID remained valid outside the branch where it was defined.
	Furthermore, in this example, the definition of MyID depends on which branch gets selected at
	runtime. Attempting to re-define a variable or referencing an undefined variable is not allowed,
	Checker will throw a runtime error.
	The example above also shows how we can use environment variables to perform custom checks.

	It is possible to combine IF, (multiple) ELIF and ELSE statements together. Nested branching is
	also supported.