gcc/testsuite/jit.dg/test-quadratic.cc - gcc - Git at Google

 /* Test of C++ API.  */
 #include <stdlib.h>
 #include <stdio.h>

 #include "libgccjit++.h"

 #include <sstream>

 #include "harness.h"

 struct quadratic
 {
   double a;
   double b;
   double c;
   double discriminant;
 };

 /* As per test-quadratic.c, let's try to inject the equivalent of:

      extern double sqrt (double);

      void
      calc_discriminant (struct quadratic *q)
      {
        // (b^2 - 4ac)
        q->discriminant = (q->b * q->b) - (4 * q->a * q->c);
      }

      int
      test_quadratic (double a, double b, double c, double *r1, double *r2)
      {
        struct quadratic q;
        q.a = a;
        q.b = b;
        q.c = c;
        calc_discriminant (&q);
        if (q.discriminant > 0)
 	 {
 	    double s = sqrt (q.discriminant);
 	    *r1 = (-b + s) / (2 * a);
 	    *r2 = (-b - s) / (2 * a);
 	    return 2;
 	 }
        else if (q.discriminant == 0)
 	 {
 	    *r1 = -b / (2 * a);
 	    return 1;
 	 }
 	 else return 0;
      }

   However, we'll use the C++ bindings.
 */

 /****************************************************************************
  Test case
  ****************************************************************************/

 struct quadratic_test
 {
   gccjit::context ctxt;

   /* "double" and "(double *)".  */
   gccjit::type numeric_type;
   gccjit::type numeric_type_ptr;

   /* The value (double)0.  */
   gccjit::rvalue zero;

   gccjit::type int_type;
   gccjit::type void_type;

   /* "struct quadratic" */
   gccjit::type quadratic;
   gccjit::field a;
   gccjit::field b;
   gccjit::field c;
   gccjit::field discriminant;

   /* "(struct quadratic *)" */
   gccjit::type quadratic_ptr;

   gccjit::function calc_discriminant;

   gccjit::function sqrt;

 };

 static void
 make_types (quadratic_test &testcase)
 {
   testcase.numeric_type = testcase.ctxt.get_type (GCC_JIT_TYPE_DOUBLE);
   testcase.numeric_type_ptr = testcase.numeric_type.get_pointer ();
   testcase.zero = testcase.ctxt.zero (testcase.numeric_type);

   testcase.int_type = testcase.ctxt.get_int_type <int> ();
   testcase.void_type = testcase.ctxt.get_type (GCC_JIT_TYPE_VOID);

   testcase.a = testcase.ctxt.new_field (testcase.numeric_type, "a");
   testcase.b = testcase.ctxt.new_field (testcase.numeric_type, "b");
   testcase.c = testcase.ctxt.new_field (testcase.numeric_type, "c");
   testcase.discriminant =
     testcase.ctxt.new_field (testcase.numeric_type, "discriminant");
   CHECK_STRING_VALUE (testcase.discriminant.get_debug_string ().c_str (),
                       "discriminant");
   std::vector<gccjit::field> fields (4);
   fields[0] = testcase.a;
   fields[1] = testcase.b;
   fields[2] = testcase.c;
   fields[3] = testcase.discriminant;
   testcase.quadratic =
     testcase.ctxt.new_struct_type (
       "quadratic",
       fields);
   testcase.quadratic_ptr = testcase.quadratic.get_pointer ();
 }

 static void
 make_sqrt (quadratic_test &testcase)
 {
   std::vector<gccjit::param> params (1);
   params[0] =
     testcase.ctxt.new_param (testcase.numeric_type, "x");
   testcase.sqrt =
     testcase.ctxt.new_function (GCC_JIT_FUNCTION_IMPORTED,
 				testcase.numeric_type,
 				"sqrt",
 				params,
 				0);
 }

 static void
 make_calc_discriminant (quadratic_test &testcase)
 {
   /* Build "calc_discriminant".  */
   gccjit::param param_q =
     testcase.ctxt.new_param (testcase.quadratic_ptr, "q");
   std::vector <gccjit::param> params (1);
   params[0] = param_q;
   testcase.calc_discriminant =
     testcase.ctxt.new_function (GCC_JIT_FUNCTION_EXPORTED,
 				testcase.void_type,
 				"calc_discriminant",
 				params,
 				0);
   gccjit::block block = testcase.calc_discriminant.new_block ();
   block.add_comment ("(b^2 - 4ac)");

   gccjit::rvalue q_a = param_q.dereference_field (testcase.a);
   gccjit::rvalue q_b = param_q.dereference_field (testcase.b);
   gccjit::rvalue q_c = param_q.dereference_field (testcase.c);

   block.add_assignment (
     /* q->discriminant =...  */
     param_q.dereference_field (testcase.discriminant),
     /* (q->b * q->b) - (4 * q->a * q->c) */
     testcase.ctxt.new_minus (
       testcase.numeric_type,

       /* (q->b * q->b) */
       testcase.ctxt.new_mult (
 	testcase.numeric_type,
 	q_b, q_b),

       /* (4 * (q->a * q->c)) */
       testcase.ctxt.new_mult (
 	testcase.numeric_type,
 	/* 4.0 */
 	testcase.ctxt.new_rvalue (
 	  testcase.numeric_type,
 	  4),
 	/* (q->a * q->c) */
 	testcase.ctxt.new_mult (
 	  testcase.numeric_type,
 	  q_a, q_c)))); /* end of add_assignment call.	*/
   block.end_with_return ();
 }

 static void
 make_test_quadratic (quadratic_test &testcase)
 {
   gccjit::param a = testcase.ctxt.new_param (testcase.numeric_type, "a");
   gccjit::param b = testcase.ctxt.new_param (testcase.numeric_type, "b");
   gccjit::param c = testcase.ctxt.new_param (testcase.numeric_type, "c");
   gccjit::param r1 =
     testcase.ctxt.new_param (testcase.numeric_type_ptr, "r1");
   gccjit::param r2 =
     testcase.ctxt.new_param (testcase.numeric_type_ptr, "r2");

   std::vector<gccjit::param> params (5);
   params[0] = a;
   params[1] = b;
   params[2] = c;
   params[3] = r1;
   params[4] = r2;

   gccjit::function test_quadratic =
     testcase.ctxt.new_function (GCC_JIT_FUNCTION_EXPORTED,
 				testcase.int_type,
 				"test_quadratic",
 				params,
 				0);

   /* struct quadratic q; */
   gccjit::lvalue q = test_quadratic.new_local (testcase.quadratic, "q");

   gccjit::block initial = test_quadratic.new_block ("initial");
   gccjit::block on_positive_discriminant
     = test_quadratic.new_block ("positive_discriminant");
   gccjit::block on_nonpositive_discriminant
     = test_quadratic.new_block ("nonpositive_discriminant");
   gccjit::block on_zero_discriminant
     = test_quadratic.new_block ("zero_discriminant");
   gccjit::block on_negative_discriminant
     = test_quadratic.new_block ("negative_discriminant");

   CHECK_STRING_VALUE (on_zero_discriminant.get_debug_string ().c_str (),
                       "zero_discriminant");

   /* q.a = a; */
   initial.add_assignment (q.access_field (testcase.a), a);
   /* q.b = b; */
   initial.add_assignment (q.access_field (testcase.b), b);
   /* q.c = c; */
   initial.add_assignment (q.access_field (testcase.c), c);
   /* calc_discriminant (&q); */
   gccjit::rvalue address_of_q = q.get_address ();
   initial.add_call (testcase.calc_discriminant, address_of_q);

   initial.add_comment ("if (q.discriminant > 0)");
   initial.end_with_conditional (
     testcase.ctxt.new_gt (
       q.access_field (testcase.discriminant),
       testcase.zero),
     on_positive_discriminant,
     on_nonpositive_discriminant);

   /* Block: "on_positive_discriminant" */
   /* double s = sqrt (q.discriminant); */
   gccjit::lvalue s = test_quadratic.new_local (testcase.numeric_type, "s");
   gccjit::rvalue discriminant_of_q = q.access_field (testcase.discriminant);
   on_positive_discriminant.add_assignment (
     s,
     testcase.ctxt.new_call (testcase.sqrt, discriminant_of_q));

   gccjit::rvalue minus_b =
     testcase.ctxt.new_minus (
       testcase.numeric_type,
       b);
   gccjit::rvalue two_a =
     testcase.ctxt.new_mult (
       testcase.numeric_type,
       testcase.ctxt.new_rvalue (testcase.numeric_type, 2),
       a);
   CHECK_STRING_VALUE (two_a.get_debug_string ().c_str (),
                       "(double)2 * a");

   on_positive_discriminant.add_comment ("*r1 = (-b + s) / (2 * a);");
   on_positive_discriminant.add_assignment (
     /* "*r1 = ..." */
     r1.dereference (),

     /* (-b + s) / (2 * a) */
     testcase.ctxt.new_divide (
       testcase.numeric_type,
       testcase.ctxt.new_plus (
 	testcase.numeric_type,
 	minus_b,
 	s),
       two_a));

   on_positive_discriminant.add_comment ("*r2 = (-b - s) / (2 * a)");
   on_positive_discriminant.add_assignment (
     /* "*r2 = ..." */
     r2.dereference (),

     /* (-b - s) / (2 * a) */
     testcase.ctxt.new_divide (
       testcase.numeric_type,
       testcase.ctxt.new_minus (
 	testcase.numeric_type,
 	minus_b,
 	s),
       two_a));

   /* "return 2;" */
   on_positive_discriminant.end_with_return (
     testcase.ctxt.new_rvalue (testcase.int_type, 2));

   /* Block: "on_nonpositive_discriminant" */
   on_nonpositive_discriminant.add_comment ("else if (q.discriminant == 0)");
   on_nonpositive_discriminant.end_with_conditional (
     testcase.ctxt.new_eq (
       q.access_field (testcase.discriminant),
       testcase.zero),
     on_zero_discriminant,
     on_negative_discriminant);

   /* Block: "on_zero_discriminant" */
   /* if (q.discriminant == 0) */
   on_zero_discriminant.add_comment ("*r1 = -b / (2 * a);");
   on_zero_discriminant.add_assignment (
     /* "*r1 = ..." */
     r1.dereference (),

     /* -b / (2 * a) */
     testcase.ctxt.new_divide (
       testcase.numeric_type,
       minus_b,
       two_a));

   /* "return 1;" */
   on_zero_discriminant.end_with_return (
     testcase.ctxt.one (testcase.int_type));

   /* Block: "on_negative_discriminant" */
   /* else return 0; */
   on_negative_discriminant.end_with_return (
     testcase.ctxt.zero (testcase.int_type));

   /* Verify that output stream operator << works.  */
   std::ostringstream os;
   os << "streamed output: " << address_of_q;
   CHECK_STRING_VALUE (os.str ().c_str (), "streamed output: &q");
 }

 void
 create_code (gcc_jit_context *ctxt, void *user_data)
 {
   struct quadratic_test testcase = {};
   testcase.ctxt = ctxt;
   make_types (testcase);
   make_sqrt (testcase);
   make_calc_discriminant (testcase);
   make_test_quadratic (testcase);
 }

 void
 verify_code (gcc_jit_context *ctxt, gcc_jit_result *result)
 {
   typedef int (*fn_type) (double a, double b, double c,
 			  double *r1, double *r2);

   CHECK_NON_NULL (result);

   fn_type test_quadratic =
     (fn_type)gcc_jit_result_get_code (result, "test_quadratic");
   CHECK_NON_NULL (test_quadratic);

   /* Verify that the code correctly solves quadratic equations.  */
   double r1, r2;

   /* This one has two solutions: */
   CHECK_VALUE (test_quadratic (1, 3, -4, &r1, &r2), 2);
   CHECK_VALUE (r1, 1);
   CHECK_VALUE (r2, -4);

   /* This one has one solution: */
   CHECK_VALUE (test_quadratic (4, 4, 1, &r1, &r2), 1);
   CHECK_VALUE (r1, -0.5);

   /* This one has no real solutions: */
   CHECK_VALUE (test_quadratic (4, 1, 1, &r1, &r2), 0);
 }
	/* Test of C++ API. */
	#include <stdlib.h>
	#include <stdio.h>

	#include "libgccjit++.h"

	#include <sstream>

	#include "harness.h"

	struct quadratic
	{
	double a;
	double b;
	double c;
	double discriminant;
	};

	/* As per test-quadratic.c, let's try to inject the equivalent of:

	extern double sqrt (double);

	void
	calc_discriminant (struct quadratic *q)
	{
	// (b^2 - 4ac)
	q->discriminant = (q->b * q->b) - (4 * q->a * q->c);
	}

	int
	test_quadratic (double a, double b, double c, double r1, double r2)
	{
	struct quadratic q;
	q.a = a;
	q.b = b;
	q.c = c;
	calc_discriminant (&q);
	if (q.discriminant > 0)
	{
	double s = sqrt (q.discriminant);
	r1 = (-b + s) / (2 a);
	r2 = (-b - s) / (2 a);
	return 2;
	}
	else if (q.discriminant == 0)
	{
	r1 = -b / (2 a);
	return 1;
	}
	else return 0;
	}

	However, we'll use the C++ bindings.
	*/

	/****************************************************************************
	Test case
	****************************************************************************/

	struct quadratic_test
	{
	gccjit::context ctxt;

	/* "double" and "(double )". /
	gccjit::type numeric_type;
	gccjit::type numeric_type_ptr;

	/* The value (double)0. */
	gccjit::rvalue zero;

	gccjit::type int_type;
	gccjit::type void_type;

	/* "struct quadratic" */
	gccjit::type quadratic;
	gccjit::field a;
	gccjit::field b;
	gccjit::field c;
	gccjit::field discriminant;

	/* "(struct quadratic )" /
	gccjit::type quadratic_ptr;

	gccjit::function calc_discriminant;

	gccjit::function sqrt;

	};

	static void
	make_types (quadratic_test &testcase)
	{
	testcase.numeric_type = testcase.ctxt.get_type (GCC_JIT_TYPE_DOUBLE);
	testcase.numeric_type_ptr = testcase.numeric_type.get_pointer ();
	testcase.zero = testcase.ctxt.zero (testcase.numeric_type);

	testcase.int_type = testcase.ctxt.get_int_type <int> ();
	testcase.void_type = testcase.ctxt.get_type (GCC_JIT_TYPE_VOID);

	testcase.a = testcase.ctxt.new_field (testcase.numeric_type, "a");
	testcase.b = testcase.ctxt.new_field (testcase.numeric_type, "b");
	testcase.c = testcase.ctxt.new_field (testcase.numeric_type, "c");
	testcase.discriminant =
	testcase.ctxt.new_field (testcase.numeric_type, "discriminant");
	CHECK_STRING_VALUE (testcase.discriminant.get_debug_string ().c_str (),
	"discriminant");
	std::vector<gccjit::field> fields (4);
	fields[0] = testcase.a;
	fields[1] = testcase.b;
	fields[2] = testcase.c;
	fields[3] = testcase.discriminant;
	testcase.quadratic =
	testcase.ctxt.new_struct_type (
	"quadratic",
	fields);
	testcase.quadratic_ptr = testcase.quadratic.get_pointer ();
	}

	static void
	make_sqrt (quadratic_test &testcase)
	{
	std::vector<gccjit::param> params (1);
	params[0] =
	testcase.ctxt.new_param (testcase.numeric_type, "x");
	testcase.sqrt =
	testcase.ctxt.new_function (GCC_JIT_FUNCTION_IMPORTED,
	testcase.numeric_type,
	"sqrt",
	params,
	0);
	}

	static void
	make_calc_discriminant (quadratic_test &testcase)
	{
	/* Build "calc_discriminant". */
	gccjit::param param_q =
	testcase.ctxt.new_param (testcase.quadratic_ptr, "q");
	std::vector <gccjit::param> params (1);
	params[0] = param_q;
	testcase.calc_discriminant =
	testcase.ctxt.new_function (GCC_JIT_FUNCTION_EXPORTED,
	testcase.void_type,
	"calc_discriminant",
	params,
	0);
	gccjit::block block = testcase.calc_discriminant.new_block ();
	block.add_comment ("(b^2 - 4ac)");

	gccjit::rvalue q_a = param_q.dereference_field (testcase.a);
	gccjit::rvalue q_b = param_q.dereference_field (testcase.b);
	gccjit::rvalue q_c = param_q.dereference_field (testcase.c);

	block.add_assignment (
	/* q->discriminant =... */
	param_q.dereference_field (testcase.discriminant),
	/* (q->b * q->b) - (4 * q->a * q->c) */
	testcase.ctxt.new_minus (
	testcase.numeric_type,

	/* (q->b * q->b) */
	testcase.ctxt.new_mult (
	testcase.numeric_type,
	q_b, q_b),

	/* (4 * (q->a * q->c)) */
	testcase.ctxt.new_mult (
	testcase.numeric_type,
	/* 4.0 */
	testcase.ctxt.new_rvalue (
	testcase.numeric_type,
	4),
	/* (q->a * q->c) */
	testcase.ctxt.new_mult (
	testcase.numeric_type,
	q_a, q_c)))); /* end of add_assignment call. */
	block.end_with_return ();
	}

	static void
	make_test_quadratic (quadratic_test &testcase)
	{
	gccjit::param a = testcase.ctxt.new_param (testcase.numeric_type, "a");
	gccjit::param b = testcase.ctxt.new_param (testcase.numeric_type, "b");
	gccjit::param c = testcase.ctxt.new_param (testcase.numeric_type, "c");
	gccjit::param r1 =
	testcase.ctxt.new_param (testcase.numeric_type_ptr, "r1");
	gccjit::param r2 =
	testcase.ctxt.new_param (testcase.numeric_type_ptr, "r2");

	std::vector<gccjit::param> params (5);
	params[0] = a;
	params[1] = b;
	params[2] = c;
	params[3] = r1;
	params[4] = r2;

	gccjit::function test_quadratic =
	testcase.ctxt.new_function (GCC_JIT_FUNCTION_EXPORTED,
	testcase.int_type,
	"test_quadratic",
	params,
	0);

	/* struct quadratic q; */
	gccjit::lvalue q = test_quadratic.new_local (testcase.quadratic, "q");

	gccjit::block initial = test_quadratic.new_block ("initial");
	gccjit::block on_positive_discriminant
	= test_quadratic.new_block ("positive_discriminant");
	gccjit::block on_nonpositive_discriminant
	= test_quadratic.new_block ("nonpositive_discriminant");
	gccjit::block on_zero_discriminant
	= test_quadratic.new_block ("zero_discriminant");
	gccjit::block on_negative_discriminant
	= test_quadratic.new_block ("negative_discriminant");

	CHECK_STRING_VALUE (on_zero_discriminant.get_debug_string ().c_str (),
	"zero_discriminant");

	/* q.a = a; */
	initial.add_assignment (q.access_field (testcase.a), a);
	/* q.b = b; */
	initial.add_assignment (q.access_field (testcase.b), b);
	/* q.c = c; */
	initial.add_assignment (q.access_field (testcase.c), c);
	/* calc_discriminant (&q); */
	gccjit::rvalue address_of_q = q.get_address ();
	initial.add_call (testcase.calc_discriminant, address_of_q);

	initial.add_comment ("if (q.discriminant > 0)");
	initial.end_with_conditional (
	testcase.ctxt.new_gt (
	q.access_field (testcase.discriminant),
	testcase.zero),
	on_positive_discriminant,
	on_nonpositive_discriminant);

	/* Block: "on_positive_discriminant" */
	/* double s = sqrt (q.discriminant); */
	gccjit::lvalue s = test_quadratic.new_local (testcase.numeric_type, "s");
	gccjit::rvalue discriminant_of_q = q.access_field (testcase.discriminant);
	on_positive_discriminant.add_assignment (
	s,
	testcase.ctxt.new_call (testcase.sqrt, discriminant_of_q));

	gccjit::rvalue minus_b =
	testcase.ctxt.new_minus (
	testcase.numeric_type,
	b);
	gccjit::rvalue two_a =
	testcase.ctxt.new_mult (
	testcase.numeric_type,
	testcase.ctxt.new_rvalue (testcase.numeric_type, 2),
	a);
	CHECK_STRING_VALUE (two_a.get_debug_string ().c_str (),
	"(double)2 * a");

	on_positive_discriminant.add_comment ("r1 = (-b + s) / (2 a);");
	on_positive_discriminant.add_assignment (
	/* "r1 = ..." /
	r1.dereference (),

	/* (-b + s) / (2 * a) */
	testcase.ctxt.new_divide (
	testcase.numeric_type,
	testcase.ctxt.new_plus (
	testcase.numeric_type,
	minus_b,
	s),
	two_a));

	on_positive_discriminant.add_comment ("r2 = (-b - s) / (2 a)");
	on_positive_discriminant.add_assignment (
	/* "r2 = ..." /
	r2.dereference (),

	/* (-b - s) / (2 * a) */
	testcase.ctxt.new_divide (
	testcase.numeric_type,
	testcase.ctxt.new_minus (
	testcase.numeric_type,
	minus_b,
	s),
	two_a));

	/* "return 2;" */
	on_positive_discriminant.end_with_return (
	testcase.ctxt.new_rvalue (testcase.int_type, 2));

	/* Block: "on_nonpositive_discriminant" */
	on_nonpositive_discriminant.add_comment ("else if (q.discriminant == 0)");
	on_nonpositive_discriminant.end_with_conditional (
	testcase.ctxt.new_eq (
	q.access_field (testcase.discriminant),
	testcase.zero),
	on_zero_discriminant,
	on_negative_discriminant);

	/* Block: "on_zero_discriminant" */
	/* if (q.discriminant == 0) */
	on_zero_discriminant.add_comment ("r1 = -b / (2 a);");
	on_zero_discriminant.add_assignment (
	/* "r1 = ..." /
	r1.dereference (),

	/* -b / (2 * a) */
	testcase.ctxt.new_divide (
	testcase.numeric_type,
	minus_b,
	two_a));

	/* "return 1;" */
	on_zero_discriminant.end_with_return (
	testcase.ctxt.one (testcase.int_type));

	/* Block: "on_negative_discriminant" */
	/* else return 0; */
	on_negative_discriminant.end_with_return (
	testcase.ctxt.zero (testcase.int_type));

	/* Verify that output stream operator << works. */
	std::ostringstream os;
	os << "streamed output: " << address_of_q;
	CHECK_STRING_VALUE (os.str ().c_str (), "streamed output: &q");
	}

	void
	create_code (gcc_jit_context ctxt, void user_data)
	{
	struct quadratic_test testcase = {};
	testcase.ctxt = ctxt;
	make_types (testcase);
	make_sqrt (testcase);
	make_calc_discriminant (testcase);
	make_test_quadratic (testcase);
	}

	void
	verify_code (gcc_jit_context ctxt, gcc_jit_result result)
	{
	typedef int (*fn_type) (double a, double b, double c,
	double r1, double r2);

	CHECK_NON_NULL (result);

	fn_type test_quadratic =
	(fn_type)gcc_jit_result_get_code (result, "test_quadratic");
	CHECK_NON_NULL (test_quadratic);

	/* Verify that the code correctly solves quadratic equations. */
	double r1, r2;

	/* This one has two solutions: */
	CHECK_VALUE (test_quadratic (1, 3, -4, &r1, &r2), 2);
	CHECK_VALUE (r1, 1);
	CHECK_VALUE (r2, -4);

	/* This one has one solution: */
	CHECK_VALUE (test_quadratic (4, 4, 1, &r1, &r2), 1);
	CHECK_VALUE (r1, -0.5);

	/* This one has no real solutions: */
	CHECK_VALUE (test_quadratic (4, 1, 1, &r1, &r2), 0);
	}