llvm/test/TableGen/SetTheory.td - third_party/llvm-project - Git at Google

 // Test evaluation of set operations in dags.
 // RUN: llvm-tblgen -print-sets %s | FileCheck %s
 // XFAIL: vg_leak
 //
 // The -print-sets driver configures a primitive SetTheory instance that
 // understands these sets:

 class Set<dag d> {
   dag Elements = d;
 }

 // It prints all Set instances and their ordered set interpretation.

 // Define some elements.
 def a;
 def b;
 def c;
 def d;

 // The 'add' operator evaluates and concatenates its arguments.
 def add;
 def S0a : Set<(add)>;
 def S0b : Set<(add a)>;
 def S0c : Set<(add a, b)>;
 def S0d : Set<(add b, a)>;
 def S0e : Set<(add a, a)>;
 def S0f : Set<(add a, a, b, a, c, b, d, a)>;
 def S0g : Set<(add b, a, b)>;
 // CHECK: S0a = [ ]
 // CHECK: S0b = [ a ]
 // CHECK: S0c = [ a b ]
 // CHECK: S0d = [ b a ]
 // CHECK: S0e = [ a ]
 // CHECK: S0f = [ a b c d ]
 // CHECK: S0g = [ b a ]

 // Defs of Set class expand into their elements.
 // Mixed sets and elements are flattened.
 def S1a : Set<(add S0a)>;
 def S1b : Set<(add S0a, S0a)>;
 def S1c : Set<(add S0d, S0f)>;
 def S1d : Set<(add d, S0d, S0f)>;
 // CHECK: S1a = [ ]
 // CHECK: S1b = [ ]
 // CHECK: S1c = [ b a c d ]
 // CHECK: S1d = [ d b a c ]

 // The 'sub' operator returns the first argument with the following arguments
 // removed.
 def sub;
 def S2a : Set<(sub S1a, S1c)>;
 def S2b : Set<(sub S1c, S1d)>;
 def S2c : Set<(sub S1c, b)>;
 def S2d : Set<(sub S1c, S0c)>;
 def S2e : Set<(sub S1c, S2d)>;
 // CHECK: S2a = [ ]
 // CHECK: S2b = [ ]
 // CHECK: S2c = [ a c d ]
 // CHECK: S2d = [ c d ]
 // CHECK: S2e = [ b a ]

 // The 'and' operator intersects two sets. The result has the same order as the
 // first argument.
 def and;
 def S3a : Set<(and S2d, S2e)>;
 def S3b : Set<(and S2d, S1d)>;
 // CHECK: S3a = [ ]
 // CHECK: S3b = [ c d ]

 // The 'shl' operator removes the first N elements.
 def shl;
 def S4a : Set<(shl S0f, 0)>;
 def S4b : Set<(shl S0f, 1)>;
 def S4c : Set<(shl S0f, 3)>;
 def S4d : Set<(shl S0f, 4)>;
 def S4e : Set<(shl S0f, 5)>;
 // CHECK: S4a = [ a b c d ]
 // CHECK: S4b = [ b c d ]
 // CHECK: S4c = [ d ]
 // CHECK: S4d = [ ]
 // CHECK: S4e = [ ]

 // The 'trunc' operator truncates after the first N elements.
 def trunc;
 def S5a : Set<(trunc S0f, 0)>;
 def S5b : Set<(trunc S0f, 1)>;
 def S5c : Set<(trunc S0f, 3)>;
 def S5d : Set<(trunc S0f, 4)>;
 def S5e : Set<(trunc S0f, 5)>;
 // CHECK: S5a = [ ]
 // CHECK: S5b = [ a ]
 // CHECK: S5c = [ a b c ]
 // CHECK: S5d = [ a b c d ]
 // CHECK: S5e = [ a b c d ]

 // The 'rotl' operator rotates left, but also accepts a negative shift.
 def rotl;
 def S6a : Set<(rotl S0f, 0)>;
 def S6b : Set<(rotl S0f, 1)>;
 def S6c : Set<(rotl S0f, 3)>;
 def S6d : Set<(rotl S0f, 4)>;
 def S6e : Set<(rotl S0f, 5)>;
 def S6f : Set<(rotl S0f, -1)>;
 def S6g : Set<(rotl S0f, -4)>;
 def S6h : Set<(rotl S0f, -5)>;
 // CHECK: S6a = [ a b c d ]
 // CHECK: S6b = [ b c d a ]
 // CHECK: S6c = [ d a b c ]
 // CHECK: S6d = [ a b c d ]
 // CHECK: S6e = [ b c d a ]
 // CHECK: S6f = [ d a b c ]
 // CHECK: S6g = [ a b c d ]
 // CHECK: S6h = [ d a b c ]

 // The 'rotr' operator rotates right, but also accepts a negative shift.
 def rotr;
 def S7a : Set<(rotr S0f, 0)>;
 def S7b : Set<(rotr S0f, 1)>;
 def S7c : Set<(rotr S0f, 3)>;
 def S7d : Set<(rotr S0f, 4)>;
 def S7e : Set<(rotr S0f, 5)>;
 def S7f : Set<(rotr S0f, -1)>;
 def S7g : Set<(rotr S0f, -4)>;
 def S7h : Set<(rotr S0f, -5)>;
 // CHECK: S7a = [ a b c d ]
 // CHECK: S7b = [ d a b c ]
 // CHECK: S7c = [ b c d a ]
 // CHECK: S7d = [ a b c d ]
 // CHECK: S7e = [ d a b c ]
 // CHECK: S7f = [ b c d a ]
 // CHECK: S7g = [ a b c d ]
 // CHECK: S7h = [ b c d a ]

 // The 'decimate' operator picks every N'th element.
 def decimate;
 def e0;
 def e1;
 def e2;
 def e3;
 def e4;
 def e5;
 def e6;
 def e7;
 def e8;
 def e9;
 def E : Set<(add e0, e1, e2, e3, e4, e5, e6, e7, e8, e9)>;
 def S8a : Set<(decimate E, 3)>;
 def S8b : Set<(decimate E, 9)>;
 def S8c : Set<(decimate E, 10)>;
 def S8d : Set<(decimate (rotl E, 1), 2)>;
 def S8e : Set<(add (decimate E, 2), (decimate (rotl E, 1), 2))>;
 // CHECK: S8a = [ e0 e3 e6 e9 ]
 // CHECK: S8b = [ e0 e9 ]
 // CHECK: S8c = [ e0 ]
 // CHECK: S8d = [ e1 e3 e5 e7 e9 ]
 // CHECK: S8e = [ e0 e2 e4 e6 e8 e1 e3 e5 e7 e9 ]

 // The 'sequence' operator finds a sequence of records from their name.
 def sequence;
 def S9a : Set<(sequence "e%u", 3, 7)>;
 def S9b : Set<(sequence "e%u", 7, 3)>;
 def S9c : Set<(sequence "e%u", 0, 0)>;
 def S9d : Set<(sequence "S%ua", 7, 9)>;
 def S9e : Set<(sequence "e%u", 3, 6, 2)>;
 // CHECK: S9a = [ e3 e4 e5 e6 e7 ]
 // CHECK: S9b = [ e7 e6 e5 e4 e3 ]
 // CHECK: S9c = [ e0 ]
 // CHECK: S9d = [ a b c d e0 e3 e6 e9 e4 e5 e7 ]
 // CHECK: S9e = [ e3 e5 ]

 // The 'interleave' operator is almost the inverse of 'decimate'.
 def interleave;
 def T0a : Set<(interleave S9a, S9b)>;
 def T0b : Set<(interleave S8e, S8d)>;
 // CHECK: T0a = [ e3 e7 e4 e6 e5 ]
 // CHECK: T0b = [ e0 e1 e2 e3 e4 e5 e6 e7 e8 e9 ]
	// Test evaluation of set operations in dags.
	// RUN: llvm-tblgen -print-sets %s \| FileCheck %s
	// XFAIL: vg_leak
	//
	// The -print-sets driver configures a primitive SetTheory instance that
	// understands these sets:

	class Set<dag d> {
	dag Elements = d;
	}

	// It prints all Set instances and their ordered set interpretation.

	// Define some elements.
	def a;
	def b;
	def c;
	def d;

	// The 'add' operator evaluates and concatenates its arguments.
	def add;
	def S0a : Set<(add)>;
	def S0b : Set<(add a)>;
	def S0c : Set<(add a, b)>;
	def S0d : Set<(add b, a)>;
	def S0e : Set<(add a, a)>;
	def S0f : Set<(add a, a, b, a, c, b, d, a)>;
	def S0g : Set<(add b, a, b)>;
	// CHECK: S0a = [ ]
	// CHECK: S0b = [ a ]
	// CHECK: S0c = [ a b ]
	// CHECK: S0d = [ b a ]
	// CHECK: S0e = [ a ]
	// CHECK: S0f = [ a b c d ]
	// CHECK: S0g = [ b a ]

	// Defs of Set class expand into their elements.
	// Mixed sets and elements are flattened.
	def S1a : Set<(add S0a)>;
	def S1b : Set<(add S0a, S0a)>;
	def S1c : Set<(add S0d, S0f)>;
	def S1d : Set<(add d, S0d, S0f)>;
	// CHECK: S1a = [ ]
	// CHECK: S1b = [ ]
	// CHECK: S1c = [ b a c d ]
	// CHECK: S1d = [ d b a c ]

	// The 'sub' operator returns the first argument with the following arguments
	// removed.
	def sub;
	def S2a : Set<(sub S1a, S1c)>;
	def S2b : Set<(sub S1c, S1d)>;
	def S2c : Set<(sub S1c, b)>;
	def S2d : Set<(sub S1c, S0c)>;
	def S2e : Set<(sub S1c, S2d)>;
	// CHECK: S2a = [ ]
	// CHECK: S2b = [ ]
	// CHECK: S2c = [ a c d ]
	// CHECK: S2d = [ c d ]
	// CHECK: S2e = [ b a ]

	// The 'and' operator intersects two sets. The result has the same order as the
	// first argument.
	def and;
	def S3a : Set<(and S2d, S2e)>;
	def S3b : Set<(and S2d, S1d)>;
	// CHECK: S3a = [ ]
	// CHECK: S3b = [ c d ]

	// The 'shl' operator removes the first N elements.
	def shl;
	def S4a : Set<(shl S0f, 0)>;
	def S4b : Set<(shl S0f, 1)>;
	def S4c : Set<(shl S0f, 3)>;
	def S4d : Set<(shl S0f, 4)>;
	def S4e : Set<(shl S0f, 5)>;
	// CHECK: S4a = [ a b c d ]
	// CHECK: S4b = [ b c d ]
	// CHECK: S4c = [ d ]
	// CHECK: S4d = [ ]
	// CHECK: S4e = [ ]

	// The 'trunc' operator truncates after the first N elements.
	def trunc;
	def S5a : Set<(trunc S0f, 0)>;
	def S5b : Set<(trunc S0f, 1)>;
	def S5c : Set<(trunc S0f, 3)>;
	def S5d : Set<(trunc S0f, 4)>;
	def S5e : Set<(trunc S0f, 5)>;
	// CHECK: S5a = [ ]
	// CHECK: S5b = [ a ]
	// CHECK: S5c = [ a b c ]
	// CHECK: S5d = [ a b c d ]
	// CHECK: S5e = [ a b c d ]

	// The 'rotl' operator rotates left, but also accepts a negative shift.
	def rotl;
	def S6a : Set<(rotl S0f, 0)>;
	def S6b : Set<(rotl S0f, 1)>;
	def S6c : Set<(rotl S0f, 3)>;
	def S6d : Set<(rotl S0f, 4)>;
	def S6e : Set<(rotl S0f, 5)>;
	def S6f : Set<(rotl S0f, -1)>;
	def S6g : Set<(rotl S0f, -4)>;
	def S6h : Set<(rotl S0f, -5)>;
	// CHECK: S6a = [ a b c d ]
	// CHECK: S6b = [ b c d a ]
	// CHECK: S6c = [ d a b c ]
	// CHECK: S6d = [ a b c d ]
	// CHECK: S6e = [ b c d a ]
	// CHECK: S6f = [ d a b c ]
	// CHECK: S6g = [ a b c d ]
	// CHECK: S6h = [ d a b c ]

	// The 'rotr' operator rotates right, but also accepts a negative shift.
	def rotr;
	def S7a : Set<(rotr S0f, 0)>;
	def S7b : Set<(rotr S0f, 1)>;
	def S7c : Set<(rotr S0f, 3)>;
	def S7d : Set<(rotr S0f, 4)>;
	def S7e : Set<(rotr S0f, 5)>;
	def S7f : Set<(rotr S0f, -1)>;
	def S7g : Set<(rotr S0f, -4)>;
	def S7h : Set<(rotr S0f, -5)>;
	// CHECK: S7a = [ a b c d ]
	// CHECK: S7b = [ d a b c ]
	// CHECK: S7c = [ b c d a ]
	// CHECK: S7d = [ a b c d ]
	// CHECK: S7e = [ d a b c ]
	// CHECK: S7f = [ b c d a ]
	// CHECK: S7g = [ a b c d ]
	// CHECK: S7h = [ b c d a ]

	// The 'decimate' operator picks every N'th element.
	def decimate;
	def e0;
	def e1;
	def e2;
	def e3;
	def e4;
	def e5;
	def e6;
	def e7;
	def e8;
	def e9;
	def E : Set<(add e0, e1, e2, e3, e4, e5, e6, e7, e8, e9)>;
	def S8a : Set<(decimate E, 3)>;
	def S8b : Set<(decimate E, 9)>;
	def S8c : Set<(decimate E, 10)>;
	def S8d : Set<(decimate (rotl E, 1), 2)>;
	def S8e : Set<(add (decimate E, 2), (decimate (rotl E, 1), 2))>;
	// CHECK: S8a = [ e0 e3 e6 e9 ]
	// CHECK: S8b = [ e0 e9 ]
	// CHECK: S8c = [ e0 ]
	// CHECK: S8d = [ e1 e3 e5 e7 e9 ]
	// CHECK: S8e = [ e0 e2 e4 e6 e8 e1 e3 e5 e7 e9 ]

	// The 'sequence' operator finds a sequence of records from their name.
	def sequence;
	def S9a : Set<(sequence "e%u", 3, 7)>;
	def S9b : Set<(sequence "e%u", 7, 3)>;
	def S9c : Set<(sequence "e%u", 0, 0)>;
	def S9d : Set<(sequence "S%ua", 7, 9)>;
	def S9e : Set<(sequence "e%u", 3, 6, 2)>;
	// CHECK: S9a = [ e3 e4 e5 e6 e7 ]
	// CHECK: S9b = [ e7 e6 e5 e4 e3 ]
	// CHECK: S9c = [ e0 ]
	// CHECK: S9d = [ a b c d e0 e3 e6 e9 e4 e5 e7 ]
	// CHECK: S9e = [ e3 e5 ]

	// The 'interleave' operator is almost the inverse of 'decimate'.
	def interleave;
	def T0a : Set<(interleave S9a, S9b)>;
	def T0b : Set<(interleave S8e, S8d)>;
	// CHECK: T0a = [ e3 e7 e4 e6 e5 ]
	// CHECK: T0b = [ e0 e1 e2 e3 e4 e5 e6 e7 e8 e9 ]