src/Reactor/Print.hpp - SwiftShader - Git at Google

 // Copyright 2019 The SwiftShader Authors. All Rights Reserved.
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //    http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.

 #ifndef rr_Print_hpp
 #define rr_Print_hpp

 #ifdef ENABLE_RR_PRINT

 #	include "Reactor.hpp"

 #	include <string>
 #	include <vector>

 namespace rr {

 // PrintValue holds the printf format and value(s) for a single argument
 // to Print(). A single argument can be expanded into multiple printf
 // values - for example a Float4 will expand to "%f %f %f %f" and four
 // scalar values.
 // The PrintValue constructor accepts the following:
 //   * Reactor LValues, RValues, Pointers.
 //   * Standard Plain-Old-Value types (int, float, bool, etc)
 //   * Custom types that specialize the PrintValue::Ty template struct.
 //   * Static arrays in the form T[N] where T can be any of the above.
 class PrintValue
 {
 public:
 	// Ty is a template that can be specialized for printing type T.
 	// Each specialization must expose:
 	//  * A 'static std::string fmt(const T& v)' method that provides the
 	//    printf format specifier.
 	//  * A 'static std::vector<rr::Value*> val(const T& v)' method that
 	//    returns all the printf format values.
 	template<typename T>
 	struct Ty
 	{
 		// static std::string fmt(const T& v);
 		// static std::vector<rr::Value*> val(const T& v);
 	};

 	// returns the printf values for all the values in the given array.
 	template<typename T>
 	static std::vector<Value *> val(const T *list, int count)
 	{
 		std::vector<Value *> values;
 		values.reserve(count);
 		for(int i = 0; i < count; i++)
 		{
 			auto v = val(list[i]);
 			values.insert(values.end(), v.begin(), v.end());
 		}
 		return values;
 	}

 	// fmt returns the comma-delimited list of printf format strings for
 	// every element in the provided list, all enclosed in square brackets.
 	template<typename T>
 	static std::string fmt(const T *list, int count)
 	{
 		std::string out = "[";
 		for(int i = 0; i < count; i++)
 		{
 			if(i > 0) { out += ", "; }
 			out += fmt(list[i]);
 		}
 		return out + "]";
 	}

 	static std::string addr(const void *ptr)
 	{
 		char buf[32];
 		snprintf(buf, sizeof(buf), "%p", ptr);
 		return buf;
 	}

 	const std::string format;
 	const std::vector<Value *> values;

 	// Constructs a PrintValue for the given value.
 	template<typename T>
 	PrintValue(const T &v)
 	    : format(fmt(v))
 	    , values(val(v))
 	{}

 	// Constructs a PrintValue for the given static array.
 	template<typename T, int N>
 	PrintValue(const T (&v)[N])
 	    : format(fmt(&v[0], N))
 	    , values(val(&v[0], N))
 	{}

 	// Constructs a PrintValue for the given array starting at arr of length
 	// len.
 	template<typename T>
 	PrintValue(const T *arr, int len)
 	    : format(fmt(arr, len))
 	    , values(val(arr, len))
 	{}

 	// PrintValue constructors for plain-old-data values.
 	PrintValue(bool v)
 	    : format(v ? "true" : "false")
 	{}
 	PrintValue(int8_t v)
 	    : format(std::to_string(v))
 	{}
 	PrintValue(uint8_t v)
 	    : format(std::to_string(v))
 	{}
 	PrintValue(int16_t v)
 	    : format(std::to_string(v))
 	{}
 	PrintValue(uint16_t v)
 	    : format(std::to_string(v))
 	{}
 	PrintValue(int32_t v)
 	    : format(std::to_string(v))
 	{}
 	PrintValue(uint32_t v)
 	    : format(std::to_string(v))
 	{}
 	PrintValue(int64_t v)
 	    : format(std::to_string(v))
 	{}
 	PrintValue(uint64_t v)
 	    : format(std::to_string(v))
 	{}
 	PrintValue(float v)
 	    : format(std::to_string(v))
 	{}
 	PrintValue(double v)
 	    : format(std::to_string(v))
 	{}
 	PrintValue(const char *v)
 	    : format(v)
 	{}

 	template<typename T>
 	PrintValue(T *v)
 	    : format(addr(v))
 	{}

 	// vals is a helper to build composite value lists.
 	// vals returns the full, sequential list of printf argument values used
 	// to print all the provided variadic values.
 	// vals() is intended to be used by implementations of
 	// PrintValue::Ty<>::vals() to help declare aggregate types.
 	// For example, if you were declaring a PrintValue::Ty<> specialization
 	// for a custom Mat4x4 matrix formed from four Vector4 values, you'd
 	// write:
 	//
 	// namespace rr
 	// {
 	//		template <> struct PrintValue::Ty<Mat4x4>
 	//		{
 	//			static std::string fmt(const Mat4x4& v)
 	//			{
 	//				return	"[a: <%f, %f, %f, %f>,"
 	//				        " b: <%f, %f, %f, %f>,"
 	//				        " c: <%f, %f, %f, %f>,"
 	//				        " d: <%f, %f, %f, %f>]";
 	//			}
 	//			static std::vector<rr::Value*> val(const Mat4x4& v)
 	//			{
 	//				return PrintValue::vals(v.a, v.b, v.c, v.d);
 	//			}
 	//		};
 	//	}
 	template<typename... ARGS>
 	static std::vector<Value *> vals(ARGS... v)
 	{
 		std::vector<std::vector<Value *>> lists = { val(v)... };
 		std::vector<Value *> joined;
 		for(const auto &list : lists)
 		{
 			joined.insert(joined.end(), list.begin(), list.end());
 		}
 		return joined;
 	}

 	// returns the printf format specifier for the given type via the
 	// PrintValue::Ty<T> specialization.
 	template<typename T>
 	static std::string fmt(const T &v)
 	{
 		return Ty<T>::fmt(v);
 	}

 	// returns the printf value for the given type with a
 	// PrintValue::Ty<T> specialization.
 	template<typename T>
 	static std::vector<Value *> val(const T &v)
 	{
 		return Ty<T>::val(v);
 	}
 };

 // PrintValue::Ty<T> specializations for basic types.
 template<>
 struct PrintValue::Ty<const char *>
 {
 	static std::string fmt(const char *v) { return "%s"; }
 	static std::vector<Value *> val(const char *v);
 };
 template<>
 struct PrintValue::Ty<std::string>
 {
 	static std::string fmt(const std::string &v) { return PrintValue::Ty<const char *>::fmt(v.c_str()); }
 	static std::vector<Value *> val(const std::string &v) { return PrintValue::Ty<const char *>::val(v.c_str()); }
 };

 // PrintValue::Ty<T> specializations for standard Reactor types.
 template<>
 struct PrintValue::Ty<Bool>
 {
 	static std::string fmt(const RValue<Bool> &v) { return "%s"; }
 	static std::vector<Value *> val(const RValue<Bool> &v);
 };
 template<>
 struct PrintValue::Ty<Byte>
 {
 	static std::string fmt(const RValue<Byte> &v) { return "%d"; }
 	static std::vector<Value *> val(const RValue<Byte> &v);
 };
 template<>
 struct PrintValue::Ty<Byte4>
 {
 	static std::string fmt(const RValue<Byte4> &v) { return "[%d, %d, %d, %d]"; }
 	static std::vector<Value *> val(const RValue<Byte4> &v);
 };
 template<>
 struct PrintValue::Ty<Int>
 {
 	static std::string fmt(const RValue<Int> &v) { return "%d"; }
 	static std::vector<Value *> val(const RValue<Int> &v);
 };
 template<>
 struct PrintValue::Ty<Int2>
 {
 	static std::string fmt(const RValue<Int2> &v) { return "[%d, %d]"; }
 	static std::vector<Value *> val(const RValue<Int2> &v);
 };
 template<>
 struct PrintValue::Ty<Int4>
 {
 	static std::string fmt(const RValue<Int4> &v) { return "[%d, %d, %d, %d]"; }
 	static std::vector<Value *> val(const RValue<Int4> &v);
 };
 template<>
 struct PrintValue::Ty<UInt>
 {
 	static std::string fmt(const RValue<UInt> &v) { return "%u"; }
 	static std::vector<Value *> val(const RValue<UInt> &v);
 };
 template<>
 struct PrintValue::Ty<UInt2>
 {
 	static std::string fmt(const RValue<UInt2> &v) { return "[%u, %u]"; }
 	static std::vector<Value *> val(const RValue<UInt2> &v);
 };
 template<>
 struct PrintValue::Ty<UInt4>
 {
 	static std::string fmt(const RValue<UInt4> &v) { return "[%u, %u, %u, %u]"; }
 	static std::vector<Value *> val(const RValue<UInt4> &v);
 };
 template<>
 struct PrintValue::Ty<Short>
 {
 	static std::string fmt(const RValue<Short> &v) { return "%d"; }
 	static std::vector<Value *> val(const RValue<Short> &v);
 };
 template<>
 struct PrintValue::Ty<Short4>
 {
 	static std::string fmt(const RValue<Short4> &v) { return "[%d, %d, %d, %d]"; }
 	static std::vector<Value *> val(const RValue<Short4> &v);
 };
 template<>
 struct PrintValue::Ty<UShort>
 {
 	static std::string fmt(const RValue<UShort> &v) { return "%u"; }
 	static std::vector<Value *> val(const RValue<UShort> &v);
 };
 template<>
 struct PrintValue::Ty<UShort4>
 {
 	static std::string fmt(const RValue<UShort4> &v) { return "[%u, %u, %u, %u]"; }
 	static std::vector<Value *> val(const RValue<UShort4> &v);
 };
 template<>
 struct PrintValue::Ty<Float>
 {
 	static std::string fmt(const RValue<Float> &v) { return "%f"; }
 	static std::vector<Value *> val(const RValue<Float> &v);
 };
 template<>
 struct PrintValue::Ty<Float4>
 {
 	static std::string fmt(const RValue<Float4> &v) { return "[%f, %f, %f, %f]"; }
 	static std::vector<Value *> val(const RValue<Float4> &v);
 };
 template<>
 struct PrintValue::Ty<Long>
 {
 	static std::string fmt(const RValue<Long> &v) { return "%lld"; }
 	static std::vector<Value *> val(const RValue<Long> &v) { return { v.value() }; }
 };
 template<typename T>
 struct PrintValue::Ty<Pointer<T>>
 {
 	static std::string fmt(const RValue<Pointer<T>> &v) { return "%p"; }
 	static std::vector<Value *> val(const RValue<Pointer<T>> &v) { return { v.value() }; }
 };
 template<typename T>
 struct PrintValue::Ty<Reference<T>>
 {
 	static std::string fmt(const Reference<T> &v) { return PrintValue::Ty<T>::fmt(v); }
 	static std::vector<Value *> val(const Reference<T> &v) { return PrintValue::Ty<T>::val(v); }
 };
 template<typename T>
 struct PrintValue::Ty<RValue<T>>
 {
 	static std::string fmt(const RValue<T> &v) { return PrintValue::Ty<T>::fmt(v); }
 	static std::vector<Value *> val(const RValue<T> &v) { return PrintValue::Ty<T>::val(v); }
 };

 // VPrintf emits a call to printf() using vals[0] as the format string,
 // and vals[1..n] as the args.
 void VPrintf(const std::vector<Value *> &vals);

 // Printv emits a call to printf() using the function, file and line,
 // message and optional values.
 // See Printv below.
 void Printv(const char *function, const char *file, int line, const char *msg, std::initializer_list<PrintValue> vals);

 // Printv emits a call to printf() using the provided message and optional
 // values.
 // Printf replaces any bracketed indices in the message with string
 // representations of the corresponding value in vals.
 // For example:
 //   Printv("{0} and {1}", "red", "green");
 // Would print the string:
 //   "red and green"
 // Arguments can be indexed in any order.
 // Invalid indices are not substituted.
 inline void Printv(const char *msg, std::initializer_list<PrintValue> vals)
 {
 	Printv(nullptr, nullptr, 0, msg, vals);
 }

 // Print is a wrapper over Printv that wraps the variadic arguments into an
 // initializer_list before calling Printv.
 template<typename... ARGS>
 void Print(const char *msg, const ARGS &...vals)
 {
 	Printv(msg, { vals... });
 }

 // Print is a wrapper over Printv that wraps the variadic arguments into an
 // initializer_list before calling Printv.
 template<typename... ARGS>
 void Print(const char *function, const char *file, int line, const char *msg, const ARGS &...vals)
 {
 	Printv(function, file, line, msg, { vals... });
 }

 // RR_LOG is a macro that calls Print(), automatically populating the
 // function, file and line parameters and appending a newline to the string.
 //
 // RR_LOG() is intended to be used for debugging JIT compiled code, and is
 // not intended for production use.
 #	if defined(_WIN32)
 #		define RR_LOG(msg, ...) Print(__FUNCSIG__, __FILE__, static_cast<int>(__LINE__), msg "\n", ##__VA_ARGS__)
 #	else
 #		define RR_LOG(msg, ...) Print(__PRETTY_FUNCTION__, __FILE__, static_cast<int>(__LINE__), msg "\n", ##__VA_ARGS__)
 #	endif

 // Macro magic to perform variadic dispatch.
 // See: https://renenyffenegger.ch/notes/development/languages/C-C-plus-plus/preprocessor/macros/__VA_ARGS__/count-arguments
 // Note, this doesn't attempt to use the ##__VA_ARGS__ trick to handle 0
 #	define RR_MSVC_EXPAND_BUG(X) X  // Helper macro to force expanding __VA_ARGS__ to satisfy MSVC compiler.
 #	define RR_GET_NTH_ARG(_1, _2, _3, _4, _5, _6, _7, _8, _9, _10, _11, _12, _13, _14, _15, _16, N, ...) N
 #	define RR_COUNT_ARGUMENTS(...) RR_MSVC_EXPAND_BUG(RR_GET_NTH_ARG(__VA_ARGS__, 16, 15, 14, 13, 12, 11, 10, 9, 8, 7, 6, 5, 4, 3, 2, 1, 0))
 static_assert(1 == RR_COUNT_ARGUMENTS(a), "RR_COUNT_ARGUMENTS broken");  // Sanity checks.
 static_assert(2 == RR_COUNT_ARGUMENTS(a, b), "RR_COUNT_ARGUMENTS broken");
 static_assert(3 == RR_COUNT_ARGUMENTS(a, b, c), "RR_COUNT_ARGUMENTS broken");

 // RR_WATCH_FMT(...) resolves to a string literal that lists all the
 // arguments by name. This string can be passed to LOG() to print each of
 // the arguments with their name and value.
 //
 // RR_WATCH_FMT(...) uses the RR_COUNT_ARGUMENTS helper macro to delegate to a
 // corresponding RR_WATCH_FMT_n specialization macro below.
 #	define RR_WATCH_CONCAT(a, b) a##b
 #	define RR_WATCH_CONCAT2(a, b) RR_WATCH_CONCAT(a, b)
 #	define RR_WATCH_FMT(...) RR_MSVC_EXPAND_BUG(RR_WATCH_CONCAT2(RR_WATCH_FMT_, RR_COUNT_ARGUMENTS(__VA_ARGS__))(__VA_ARGS__))
 #	define RR_WATCH_FMT_1(_1) "\n  " #    _1 ": {0}"
 #	define RR_WATCH_FMT_2(_1, _2) \
 		RR_WATCH_FMT_1(_1)         \
 		"\n  " #_2 ": {1}"
 #	define RR_WATCH_FMT_3(_1, _2, _3) \
 		RR_WATCH_FMT_2(_1, _2)         \
 		"\n  " #_3 ": {2}"
 #	define RR_WATCH_FMT_4(_1, _2, _3, _4) \
 		RR_WATCH_FMT_3(_1, _2, _3)         \
 		"\n  " #_4 ": {3}"
 #	define RR_WATCH_FMT_5(_1, _2, _3, _4, _5) \
 		RR_WATCH_FMT_4(_1, _2, _3, _4)         \
 		"\n  " #_5 ": {4}"
 #	define RR_WATCH_FMT_6(_1, _2, _3, _4, _5, _6) \
 		RR_WATCH_FMT_5(_1, _2, _3, _4, _5)         \
 		"\n  " #_6 ": {5}"
 #	define RR_WATCH_FMT_7(_1, _2, _3, _4, _5, _6, _7) \
 		RR_WATCH_FMT_6(_1, _2, _3, _4, _5, _6)         \
 		"\n  " #_7 ": {6}"
 #	define RR_WATCH_FMT_8(_1, _2, _3, _4, _5, _6, _7, _8) \
 		RR_WATCH_FMT_7(_1, _2, _3, _4, _5, _6, _7)         \
 		"\n  " #_8 ": {7}"
 #	define RR_WATCH_FMT_9(_1, _2, _3, _4, _5, _6, _7, _8, _9) \
 		RR_WATCH_FMT_8(_1, _2, _3, _4, _5, _6, _7, _8)         \
 		"\n  " #_9 ": {8}"
 #	define RR_WATCH_FMT_10(_1, _2, _3, _4, _5, _6, _7, _8, _9, _10) \
 		RR_WATCH_FMT_9(_1, _2, _3, _4, _5, _6, _7, _8, _9)           \
 		"\n  " #_10 ": {9}"
 #	define RR_WATCH_FMT_11(_1, _2, _3, _4, _5, _6, _7, _8, _9, _10, _11) \
 		RR_WATCH_FMT_10(_1, _2, _3, _4, _5, _6, _7, _8, _9, _10)          \
 		"\n  " #_11 ": {10}"
 #	define RR_WATCH_FMT_12(_1, _2, _3, _4, _5, _6, _7, _8, _9, _10, _11, _12) \
 		RR_WATCH_FMT_11(_1, _2, _3, _4, _5, _6, _7, _8, _9, _10, _11)          \
 		"\n  " #_12 ": {11}"

 // RR_WATCH() is a helper that prints the name and value of all the supplied
 // arguments.
 // For example, if you had the Int and bool variables 'foo' and 'bar' that
 // you want to print, you can simply write:
 //    RR_WATCH(foo, bar)
 // When this JIT compiled code is executed, it will print the string
 // "foo: 1, bar: true" to stdout.
 //
 // RR_WATCH() is intended to be used for debugging JIT compiled code, and
 // is not intended for production use.
 #	define RR_WATCH(...) RR_LOG(RR_WATCH_FMT(__VA_ARGS__), __VA_ARGS__)

 }  // namespace rr

 #	define RR_PRINT_ONLY(x) x
 #else
 #	define RR_PRINT_ONLY(x)
 #endif  // ENABLE_RR_PRINT

 #endif  // rr_Print_hpp
	// Copyright 2019 The SwiftShader Authors. All Rights Reserved.
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// http://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.

	#ifndef rr_Print_hpp
	#define rr_Print_hpp

	#ifdef ENABLE_RR_PRINT

	# include "Reactor.hpp"

	# include <string>
	# include <vector>

	namespace rr {

	// PrintValue holds the printf format and value(s) for a single argument
	// to Print(). A single argument can be expanded into multiple printf
	// values - for example a Float4 will expand to "%f %f %f %f" and four
	// scalar values.
	// The PrintValue constructor accepts the following:
	// * Reactor LValues, RValues, Pointers.
	// * Standard Plain-Old-Value types (int, float, bool, etc)
	// * Custom types that specialize the PrintValue::Ty template struct.
	// * Static arrays in the form T[N] where T can be any of the above.
	class PrintValue
	{
	public:
	// Ty is a template that can be specialized for printing type T.
	// Each specialization must expose:
	// * A 'static std::string fmt(const T& v)' method that provides the
	// printf format specifier.
	// * A 'static std::vector<rr::Value*> val(const T& v)' method that
	// returns all the printf format values.
	template<typename T>
	struct Ty
	{
	// static std::string fmt(const T& v);
	// static std::vector<rr::Value*> val(const T& v);
	};

	// returns the printf values for all the values in the given array.
	template<typename T>
	static std::vector<Value > val(const T list, int count)
	{
	std::vector<Value *> values;
	values.reserve(count);
	for(int i = 0; i < count; i++)
	{
	auto v = val(list[i]);
	values.insert(values.end(), v.begin(), v.end());
	}
	return values;
	}

	// fmt returns the comma-delimited list of printf format strings for
	// every element in the provided list, all enclosed in square brackets.
	template<typename T>
	static std::string fmt(const T *list, int count)
	{
	std::string out = "[";
	for(int i = 0; i < count; i++)
	{
	if(i > 0) { out += ", "; }
	out += fmt(list[i]);
	}
	return out + "]";
	}

	static std::string addr(const void *ptr)
	{
	char buf[32];
	snprintf(buf, sizeof(buf), "%p", ptr);
	return buf;
	}

	const std::string format;
	const std::vector<Value *> values;

	// Constructs a PrintValue for the given value.
	template<typename T>
	PrintValue(const T &v)
	: format(fmt(v))
	, values(val(v))
	{}

	// Constructs a PrintValue for the given static array.
	template<typename T, int N>
	PrintValue(const T (&v)[N])
	: format(fmt(&v[0], N))
	, values(val(&v[0], N))
	{}

	// Constructs a PrintValue for the given array starting at arr of length
	// len.
	template<typename T>
	PrintValue(const T *arr, int len)
	: format(fmt(arr, len))
	, values(val(arr, len))
	{}

	// PrintValue constructors for plain-old-data values.
	PrintValue(bool v)
	: format(v ? "true" : "false")
	{}
	PrintValue(int8_t v)
	: format(std::to_string(v))
	{}
	PrintValue(uint8_t v)
	: format(std::to_string(v))
	{}
	PrintValue(int16_t v)
	: format(std::to_string(v))
	{}
	PrintValue(uint16_t v)
	: format(std::to_string(v))
	{}
	PrintValue(int32_t v)
	: format(std::to_string(v))
	{}
	PrintValue(uint32_t v)
	: format(std::to_string(v))
	{}
	PrintValue(int64_t v)
	: format(std::to_string(v))
	{}
	PrintValue(uint64_t v)
	: format(std::to_string(v))
	{}
	PrintValue(float v)
	: format(std::to_string(v))
	{}
	PrintValue(double v)
	: format(std::to_string(v))
	{}
	PrintValue(const char *v)
	: format(v)
	{}

	template<typename T>
	PrintValue(T *v)
	: format(addr(v))
	{}

	// vals is a helper to build composite value lists.
	// vals returns the full, sequential list of printf argument values used
	// to print all the provided variadic values.
	// vals() is intended to be used by implementations of
	// PrintValue::Ty<>::vals() to help declare aggregate types.
	// For example, if you were declaring a PrintValue::Ty<> specialization
	// for a custom Mat4x4 matrix formed from four Vector4 values, you'd
	// write:
	//
	// namespace rr
	// {
	// template <> struct PrintValue::Ty<Mat4x4>
	// {
	// static std::string fmt(const Mat4x4& v)
	// {
	// return "[a: <%f, %f, %f, %f>,"
	// " b: <%f, %f, %f, %f>,"
	// " c: <%f, %f, %f, %f>,"
	// " d: <%f, %f, %f, %f>]";
	// }
	// static std::vector<rr::Value*> val(const Mat4x4& v)
	// {
	// return PrintValue::vals(v.a, v.b, v.c, v.d);
	// }
	// };
	// }
	template<typename... ARGS>
	static std::vector<Value *> vals(ARGS... v)
	{
	std::vector<std::vector<Value *>> lists = { val(v)... };
	std::vector<Value *> joined;
	for(const auto &list : lists)
	{
	joined.insert(joined.end(), list.begin(), list.end());
	}
	return joined;
	}

	// returns the printf format specifier for the given type via the
	// PrintValue::Ty<T> specialization.
	template<typename T>
	static std::string fmt(const T &v)
	{
	return Ty<T>::fmt(v);
	}

	// returns the printf value for the given type with a
	// PrintValue::Ty<T> specialization.
	template<typename T>
	static std::vector<Value *> val(const T &v)
	{
	return Ty<T>::val(v);
	}
	};

	// PrintValue::Ty<T> specializations for basic types.
	template<>
	struct PrintValue::Ty<const char *>
	{
	static std::string fmt(const char *v) { return "%s"; }
	static std::vector<Value > val(const char v);
	};
	template<>
	struct PrintValue::Ty<std::string>
	{
	static std::string fmt(const std::string &v) { return PrintValue::Ty<const char *>::fmt(v.c_str()); }
	static std::vector<Value > val(const std::string &v) { return PrintValue::Ty<const char >::val(v.c_str()); }
	};

	// PrintValue::Ty<T> specializations for standard Reactor types.
	template<>
	struct PrintValue::Ty<Bool>
	{
	static std::string fmt(const RValue<Bool> &v) { return "%s"; }
	static std::vector<Value *> val(const RValue<Bool> &v);
	};
	template<>
	struct PrintValue::Ty<Byte>
	{
	static std::string fmt(const RValue<Byte> &v) { return "%d"; }
	static std::vector<Value *> val(const RValue<Byte> &v);
	};
	template<>
	struct PrintValue::Ty<Byte4>
	{
	static std::string fmt(const RValue<Byte4> &v) { return "[%d, %d, %d, %d]"; }
	static std::vector<Value *> val(const RValue<Byte4> &v);
	};
	template<>
	struct PrintValue::Ty<Int>
	{
	static std::string fmt(const RValue<Int> &v) { return "%d"; }
	static std::vector<Value *> val(const RValue<Int> &v);
	};
	template<>
	struct PrintValue::Ty<Int2>
	{
	static std::string fmt(const RValue<Int2> &v) { return "[%d, %d]"; }
	static std::vector<Value *> val(const RValue<Int2> &v);
	};
	template<>
	struct PrintValue::Ty<Int4>
	{
	static std::string fmt(const RValue<Int4> &v) { return "[%d, %d, %d, %d]"; }
	static std::vector<Value *> val(const RValue<Int4> &v);
	};
	template<>
	struct PrintValue::Ty<UInt>
	{
	static std::string fmt(const RValue<UInt> &v) { return "%u"; }
	static std::vector<Value *> val(const RValue<UInt> &v);
	};
	template<>
	struct PrintValue::Ty<UInt2>
	{
	static std::string fmt(const RValue<UInt2> &v) { return "[%u, %u]"; }
	static std::vector<Value *> val(const RValue<UInt2> &v);
	};
	template<>
	struct PrintValue::Ty<UInt4>
	{
	static std::string fmt(const RValue<UInt4> &v) { return "[%u, %u, %u, %u]"; }
	static std::vector<Value *> val(const RValue<UInt4> &v);
	};
	template<>
	struct PrintValue::Ty<Short>
	{
	static std::string fmt(const RValue<Short> &v) { return "%d"; }
	static std::vector<Value *> val(const RValue<Short> &v);
	};
	template<>
	struct PrintValue::Ty<Short4>
	{
	static std::string fmt(const RValue<Short4> &v) { return "[%d, %d, %d, %d]"; }
	static std::vector<Value *> val(const RValue<Short4> &v);
	};
	template<>
	struct PrintValue::Ty<UShort>
	{
	static std::string fmt(const RValue<UShort> &v) { return "%u"; }
	static std::vector<Value *> val(const RValue<UShort> &v);
	};
	template<>
	struct PrintValue::Ty<UShort4>
	{
	static std::string fmt(const RValue<UShort4> &v) { return "[%u, %u, %u, %u]"; }
	static std::vector<Value *> val(const RValue<UShort4> &v);
	};
	template<>
	struct PrintValue::Ty<Float>
	{
	static std::string fmt(const RValue<Float> &v) { return "%f"; }
	static std::vector<Value *> val(const RValue<Float> &v);
	};
	template<>
	struct PrintValue::Ty<Float4>
	{
	static std::string fmt(const RValue<Float4> &v) { return "[%f, %f, %f, %f]"; }
	static std::vector<Value *> val(const RValue<Float4> &v);
	};
	template<>
	struct PrintValue::Ty<Long>
	{
	static std::string fmt(const RValue<Long> &v) { return "%lld"; }
	static std::vector<Value *> val(const RValue<Long> &v) { return { v.value() }; }
	};
	template<typename T>
	struct PrintValue::Ty<Pointer<T>>
	{
	static std::string fmt(const RValue<Pointer<T>> &v) { return "%p"; }
	static std::vector<Value *> val(const RValue<Pointer<T>> &v) { return { v.value() }; }
	};
	template<typename T>
	struct PrintValue::Ty<Reference<T>>
	{
	static std::string fmt(const Reference<T> &v) { return PrintValue::Ty<T>::fmt(v); }
	static std::vector<Value *> val(const Reference<T> &v) { return PrintValue::Ty<T>::val(v); }
	};
	template<typename T>
	struct PrintValue::Ty<RValue<T>>
	{
	static std::string fmt(const RValue<T> &v) { return PrintValue::Ty<T>::fmt(v); }
	static std::vector<Value *> val(const RValue<T> &v) { return PrintValue::Ty<T>::val(v); }
	};

	// VPrintf emits a call to printf() using vals[0] as the format string,
	// and vals[1..n] as the args.
	void VPrintf(const std::vector<Value *> &vals);

	// Printv emits a call to printf() using the function, file and line,
	// message and optional values.
	// See Printv below.
	void Printv(const char function, const char file, int line, const char *msg, std::initializer_list<PrintValue> vals);

	// Printv emits a call to printf() using the provided message and optional
	// values.
	// Printf replaces any bracketed indices in the message with string
	// representations of the corresponding value in vals.
	// For example:
	// Printv("{0} and {1}", "red", "green");
	// Would print the string:
	// "red and green"
	// Arguments can be indexed in any order.
	// Invalid indices are not substituted.
	inline void Printv(const char *msg, std::initializer_list<PrintValue> vals)
	{
	Printv(nullptr, nullptr, 0, msg, vals);
	}

	// Print is a wrapper over Printv that wraps the variadic arguments into an
	// initializer_list before calling Printv.
	template<typename... ARGS>
	void Print(const char *msg, const ARGS &...vals)
	{
	Printv(msg, { vals... });
	}

	// Print is a wrapper over Printv that wraps the variadic arguments into an
	// initializer_list before calling Printv.
	template<typename... ARGS>
	void Print(const char function, const char file, int line, const char *msg, const ARGS &...vals)
	{
	Printv(function, file, line, msg, { vals... });
	}

	// RR_LOG is a macro that calls Print(), automatically populating the
	// function, file and line parameters and appending a newline to the string.
	//
	// RR_LOG() is intended to be used for debugging JIT compiled code, and is
	// not intended for production use.
	# if defined(_WIN32)
	# define RR_LOG(msg, ...) Print(__FUNCSIG__, __FILE__, static_cast<int>(__LINE__), msg "\n", ##__VA_ARGS__)
	# else
	# define RR_LOG(msg, ...) Print(__PRETTY_FUNCTION__, __FILE__, static_cast<int>(__LINE__), msg "\n", ##__VA_ARGS__)
	# endif

	// Macro magic to perform variadic dispatch.
	// See: https://renenyffenegger.ch/notes/development/languages/C-C-plus-plus/preprocessor/macros/__VA_ARGS__/count-arguments
	// Note, this doesn't attempt to use the ##__VA_ARGS__ trick to handle 0
	# define RR_MSVC_EXPAND_BUG(X) X // Helper macro to force expanding __VA_ARGS__ to satisfy MSVC compiler.
	# define RR_GET_NTH_ARG(_1, _2, _3, _4, _5, _6, _7, _8, _9, _10, _11, _12, _13, _14, _15, _16, N, ...) N
	# define RR_COUNT_ARGUMENTS(...) RR_MSVC_EXPAND_BUG(RR_GET_NTH_ARG(__VA_ARGS__, 16, 15, 14, 13, 12, 11, 10, 9, 8, 7, 6, 5, 4, 3, 2, 1, 0))
	static_assert(1 == RR_COUNT_ARGUMENTS(a), "RR_COUNT_ARGUMENTS broken"); // Sanity checks.
	static_assert(2 == RR_COUNT_ARGUMENTS(a, b), "RR_COUNT_ARGUMENTS broken");
	static_assert(3 == RR_COUNT_ARGUMENTS(a, b, c), "RR_COUNT_ARGUMENTS broken");

	// RR_WATCH_FMT(...) resolves to a string literal that lists all the
	// arguments by name. This string can be passed to LOG() to print each of
	// the arguments with their name and value.
	//
	// RR_WATCH_FMT(...) uses the RR_COUNT_ARGUMENTS helper macro to delegate to a
	// corresponding RR_WATCH_FMT_n specialization macro below.
	# define RR_WATCH_CONCAT(a, b) a##b
	# define RR_WATCH_CONCAT2(a, b) RR_WATCH_CONCAT(a, b)
	# define RR_WATCH_FMT(...) RR_MSVC_EXPAND_BUG(RR_WATCH_CONCAT2(RR_WATCH_FMT_, RR_COUNT_ARGUMENTS(__VA_ARGS__))(__VA_ARGS__))
	# define RR_WATCH_FMT_1(_1) "\n " # _1 ": {0}"
	# define RR_WATCH_FMT_2(_1, _2) \
	RR_WATCH_FMT_1(_1) \
	"\n " #_2 ": {1}"
	# define RR_WATCH_FMT_3(_1, _2, _3) \
	RR_WATCH_FMT_2(_1, _2) \
	"\n " #_3 ": {2}"
	# define RR_WATCH_FMT_4(_1, _2, _3, _4) \
	RR_WATCH_FMT_3(_1, _2, _3) \
	"\n " #_4 ": {3}"
	# define RR_WATCH_FMT_5(_1, _2, _3, _4, _5) \
	RR_WATCH_FMT_4(_1, _2, _3, _4) \
	"\n " #_5 ": {4}"
	# define RR_WATCH_FMT_6(_1, _2, _3, _4, _5, _6) \
	RR_WATCH_FMT_5(_1, _2, _3, _4, _5) \
	"\n " #_6 ": {5}"
	# define RR_WATCH_FMT_7(_1, _2, _3, _4, _5, _6, _7) \
	RR_WATCH_FMT_6(_1, _2, _3, _4, _5, _6) \
	"\n " #_7 ": {6}"
	# define RR_WATCH_FMT_8(_1, _2, _3, _4, _5, _6, _7, _8) \
	RR_WATCH_FMT_7(_1, _2, _3, _4, _5, _6, _7) \
	"\n " #_8 ": {7}"
	# define RR_WATCH_FMT_9(_1, _2, _3, _4, _5, _6, _7, _8, _9) \
	RR_WATCH_FMT_8(_1, _2, _3, _4, _5, _6, _7, _8) \
	"\n " #_9 ": {8}"
	# define RR_WATCH_FMT_10(_1, _2, _3, _4, _5, _6, _7, _8, _9, _10) \
	RR_WATCH_FMT_9(_1, _2, _3, _4, _5, _6, _7, _8, _9) \
	"\n " #_10 ": {9}"
	# define RR_WATCH_FMT_11(_1, _2, _3, _4, _5, _6, _7, _8, _9, _10, _11) \
	RR_WATCH_FMT_10(_1, _2, _3, _4, _5, _6, _7, _8, _9, _10) \
	"\n " #_11 ": {10}"
	# define RR_WATCH_FMT_12(_1, _2, _3, _4, _5, _6, _7, _8, _9, _10, _11, _12) \
	RR_WATCH_FMT_11(_1, _2, _3, _4, _5, _6, _7, _8, _9, _10, _11) \
	"\n " #_12 ": {11}"

	// RR_WATCH() is a helper that prints the name and value of all the supplied
	// arguments.
	// For example, if you had the Int and bool variables 'foo' and 'bar' that
	// you want to print, you can simply write:
	// RR_WATCH(foo, bar)
	// When this JIT compiled code is executed, it will print the string
	// "foo: 1, bar: true" to stdout.
	//
	// RR_WATCH() is intended to be used for debugging JIT compiled code, and
	// is not intended for production use.
	# define RR_WATCH(...) RR_LOG(RR_WATCH_FMT(__VA_ARGS__), __VA_ARGS__)

	} // namespace rr

	# define RR_PRINT_ONLY(x) x
	#else
	# define RR_PRINT_ONLY(x)
	#endif // ENABLE_RR_PRINT

	#endif // rr_Print_hpp