compiler-rt/test/profile/instrprof-merging.cpp - llvm-project - Git at Google

 // 1) Compile shared code into different object files and into an executable.

 // RUN: %clangxx_profgen -std=c++14 -fcoverage-mapping %s -c -o %t.v1.o \
 // RUN:                  -D_VERSION_1
 // RUN: %clangxx_profgen -std=c++14 -fcoverage-mapping %s -c -o %t.v2.o \
 // RUN:                  -D_VERSION_2
 // RUN: %clangxx_profgen -std=c++14 -fcoverage-mapping %t.v1.o %t.v2.o \
 // RUN:                  -o %t.exe

 // 2) Collect profile data.

 // RUN: env LLVM_PROFILE_FILE=%t.profraw %run %t.exe
 // RUN: llvm-profdata merge %t.profraw -o %t.profdata

 // 3) Generate coverage reports from the different object files and the exe.

 // RUN: llvm-cov show %t.v1.o -instr-profile=%t.profdata | FileCheck %s -check-prefixes=V1,V1-ONLY
 // RUN: llvm-cov show %t.v2.o -instr-profile=%t.profdata | FileCheck %s -check-prefixes=V2,V2-ONLY
 // RUN: llvm-cov show %t.v1.o -object %t.v2.o -instr-profile=%t.profdata | FileCheck %s -check-prefixes=V1,V2
 // RUN: llvm-cov show %t.exe -instr-profile=%t.profdata | FileCheck %s -check-prefixes=V1,V2

 // 4) Verify that coverage reporting on the aggregate coverage mapping shows
 //    hits for all code. (We used to arbitrarily pick a mapping from one binary
 //    and prefer it over others.) When only limited coverage information is
 //    available (just from one binary), don't try to guess any region counts.

 struct A {
   A() {}    // V1: [[@LINE]]{{ *}}|{{ *}}1
             // V1-ONLY: [[@LINE+1]]{{ *}}|{{ *}}|
   A(int) {} // V2-ONLY: [[@LINE-2]]{{ *}}|{{ *}}|
             // V2: [[@LINE-1]]{{ *}}|{{ *}}1
 };

 #ifdef _VERSION_1

 void foo();

 void bar() {
   A x;      // V1: [[@LINE]]{{ *}}|{{ *}}1
 }

 int main() {
   foo();    // V1: [[@LINE]]{{ *}}|{{ *}}1
   bar();
   return 0;
 }

 #endif // _VERSION_1

 #ifdef _VERSION_2

 void foo() {
   A x{0};   // V2: [[@LINE]]{{ *}}|{{ *}}1
 }

 #endif // _VERSION_2
	// 1) Compile shared code into different object files and into an executable.

	// RUN: %clangxx_profgen -std=c++14 -fcoverage-mapping %s -c -o %t.v1.o \
	// RUN: -D_VERSION_1
	// RUN: %clangxx_profgen -std=c++14 -fcoverage-mapping %s -c -o %t.v2.o \
	// RUN: -D_VERSION_2
	// RUN: %clangxx_profgen -std=c++14 -fcoverage-mapping %t.v1.o %t.v2.o \
	// RUN: -o %t.exe

	// 2) Collect profile data.

	// RUN: env LLVM_PROFILE_FILE=%t.profraw %run %t.exe
	// RUN: llvm-profdata merge %t.profraw -o %t.profdata

	// 3) Generate coverage reports from the different object files and the exe.

	// RUN: llvm-cov show %t.v1.o -instr-profile=%t.profdata \| FileCheck %s -check-prefixes=V1,V1-ONLY
	// RUN: llvm-cov show %t.v2.o -instr-profile=%t.profdata \| FileCheck %s -check-prefixes=V2,V2-ONLY
	// RUN: llvm-cov show %t.v1.o -object %t.v2.o -instr-profile=%t.profdata \| FileCheck %s -check-prefixes=V1,V2
	// RUN: llvm-cov show %t.exe -instr-profile=%t.profdata \| FileCheck %s -check-prefixes=V1,V2

	// 4) Verify that coverage reporting on the aggregate coverage mapping shows
	// hits for all code. (We used to arbitrarily pick a mapping from one binary
	// and prefer it over others.) When only limited coverage information is
	// available (just from one binary), don't try to guess any region counts.

	struct A {
	A() {} // V1: [[@LINE]]{{ }}\|{{ }}1
	// V1-ONLY: [[@LINE+1]]{{ }}\|{{ }}\|
	A(int) {} // V2-ONLY: [[@LINE-2]]{{ }}\|{{ }}\|
	// V2: [[@LINE-1]]{{ }}\|{{ }}1
	};

	#ifdef _VERSION_1

	void foo();

	void bar() {
	A x; // V1: [[@LINE]]{{ }}\|{{ }}1
	}

	int main() {
	foo(); // V1: [[@LINE]]{{ }}\|{{ }}1
	bar();
	return 0;
	}

	#endif // _VERSION_1

	#ifdef _VERSION_2

	void foo() {
	A x{0}; // V2: [[@LINE]]{{ }}\|{{ }}1
	}

	#endif // _VERSION_2