third_party/subzero/src/IceThreading.h - SwiftShader - Git at Google

 //===- subzero/src/IceThreading.h - Threading functions ---------*- C++ -*-===//
 //
 //                        The Subzero Code Generator
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 ///
 /// \file
 /// \brief Declares threading-related functions.
 ///
 //===----------------------------------------------------------------------===//

 #ifndef SUBZERO_SRC_ICETHREADING_H
 #define SUBZERO_SRC_ICETHREADING_H

 #include "IceDefs.h"

 #include <condition_variable>
 #include <memory>
 #include <mutex>
 #include <utility>

 namespace Ice {

 /// BoundedProducerConsumerQueue is a work queue that allows multiple producers
 /// and multiple consumers. A producer adds entries using blockingPush(), and
 /// may block if the queue is "full". A producer uses notifyEnd() to indicate
 /// that no more entries will be added. A consumer removes an item using
 /// blockingPop(), which will return nullptr if notifyEnd() has been called and
 /// the queue is empty (it never returns nullptr if the queue contained any
 /// items).
 ///
 /// The MaxSize ctor arg controls the maximum size the queue can grow to
 /// (subject to a hard limit of MaxStaticSize-1). The Sequential arg indicates
 /// purely sequential execution in which the single thread should never wait().
 ///
 /// Two condition variables are used in the implementation. GrewOrEnded signals
 /// a waiting worker that a producer has changed the state of the queue. Shrunk
 /// signals a blocked producer that a consumer has changed the state of the
 /// queue.
 ///
 /// The methods begin with Sequential-specific code to be most clear. The lock
 /// and condition variables are not used in the Sequential case.
 ///
 /// Internally, the queue is implemented as a circular array of size
 /// MaxStaticSize, where the queue boundaries are denoted by the Front and Back
 /// fields. Front==Back indicates an empty queue.
 template <typename T, size_t MaxStaticSize = 128>
 class BoundedProducerConsumerQueue {
   BoundedProducerConsumerQueue() = delete;
   BoundedProducerConsumerQueue(const BoundedProducerConsumerQueue &) = delete;
   BoundedProducerConsumerQueue &
   operator=(const BoundedProducerConsumerQueue &) = delete;

 public:
   BoundedProducerConsumerQueue(bool Sequential, size_t MaxSize = MaxStaticSize)
       : MaxSize(std::min(MaxSize, MaxStaticSize)), Sequential(Sequential) {}
   void blockingPush(std::unique_ptr<T> Item) {
     {
       std::unique_lock<GlobalLockType> L(Lock);
       // If the work queue is already "full", wait for a consumer to grab an
       // element and shrink the queue.
       Shrunk.wait(L, [this] { return size() < MaxSize || Sequential; });
       push(std::move(Item));
     }
     GrewOrEnded.notify_one();
   }
   std::unique_ptr<T> blockingPop(size_t NotifyWhenDownToSize = MaxStaticSize) {
     std::unique_ptr<T> Item;
     bool ShouldNotifyProducer = false;
     {
       std::unique_lock<GlobalLockType> L(Lock);
       GrewOrEnded.wait(L, [this] { return IsEnded || !empty() || Sequential; });
       if (!empty()) {
         Item = pop();
         ShouldNotifyProducer = (size() < NotifyWhenDownToSize) && !IsEnded;
       }
     }
     if (ShouldNotifyProducer)
       Shrunk.notify_one();
     return Item;
   }
   void notifyEnd() {
     {
       std::lock_guard<GlobalLockType> L(Lock);
       IsEnded = true;
     }
     GrewOrEnded.notify_all();
   }

 private:
   const static size_t MaxStaticSizeMask = MaxStaticSize - 1;
   static_assert(!(MaxStaticSize & (MaxStaticSize - 1)),
                 "MaxStaticSize must be a power of 2");

   ICE_CACHELINE_BOUNDARY;
   /// WorkItems and Lock are read/written by all.
   std::unique_ptr<T> WorkItems[MaxStaticSize];
   ICE_CACHELINE_BOUNDARY;
   /// Lock guards access to WorkItems, Front, Back, and IsEnded.
   GlobalLockType Lock;

   ICE_CACHELINE_BOUNDARY;
   /// GrewOrEnded is written by the producers and read by the consumers. It is
   /// notified (by the producer) when something is added to the queue, in case
   /// consumers are waiting for a non-empty queue.
   std::condition_variable GrewOrEnded;
   /// Back is the index into WorkItems[] of where the next element will be
   /// pushed. (More precisely, Back&MaxStaticSize is the index.) It is written
   /// by the producers, and read by all via size() and empty().
   size_t Back = 0;

   ICE_CACHELINE_BOUNDARY;
   /// Shrunk is notified (by the consumer) when something is removed from the
   /// queue, in case a producer is waiting for the queue to drop below maximum
   /// capacity. It is written by the consumers and read by the producers.
   std::condition_variable Shrunk;
   /// Front is the index into WorkItems[] of the oldest element, i.e. the next
   /// to be popped. (More precisely Front&MaxStaticSize is the index.) It is
   /// written by the consumers, and read by all via size() and empty().
   size_t Front = 0;

   ICE_CACHELINE_BOUNDARY;

   /// MaxSize and Sequential are read by all and written by none.
   const size_t MaxSize;
   const bool Sequential;
   /// IsEnded is read by the consumers, and only written once by the producer.
   bool IsEnded = false;

   /// The lock must be held when the following methods are called.
   bool empty() const { return Front == Back; }
   size_t size() const { return Back - Front; }
   void push(std::unique_ptr<T> Item) {
     WorkItems[Back++ & MaxStaticSizeMask] = std::move(Item);
     assert(size() <= MaxStaticSize);
   }
   std::unique_ptr<T> pop() {
     assert(!empty());
     return std::move(WorkItems[Front++ & MaxStaticSizeMask]);
   }
 };

 /// EmitterWorkItem is a simple wrapper around a pointer that represents a work
 /// item to be emitted, i.e. a function or a set of global declarations and
 /// initializers, and it includes a sequence number so that work items can be
 /// emitted in a particular order for deterministic output. It acts like an
 /// interface class, but instead of making the classes of interest inherit from
 /// EmitterWorkItem, it wraps pointers to these classes. Some space is wasted
 /// compared to storing the pointers in a union, but not too much due to the
 /// work granularity.
 class EmitterWorkItem {
   EmitterWorkItem() = delete;
   EmitterWorkItem(const EmitterWorkItem &) = delete;
   EmitterWorkItem &operator=(const EmitterWorkItem &) = delete;

 public:
   /// ItemKind can be one of the following:
   ///
   /// WI_Nop: No actual work. This is a placeholder to maintain sequence numbers
   /// in case there is a translation error.
   ///
   /// WI_GlobalInits: A list of global declarations and initializers.
   ///
   /// WI_Asm: A function that has already had emitIAS() called on it. The work
   /// is transferred via the Assembler buffer, and the originating Cfg has been
   /// deleted (to recover lots of memory).
   ///
   /// WI_Cfg: A Cfg that has not yet had emit() or emitIAS() called on it. This
   /// is only used as a debugging configuration when we want to emit "readable"
   /// assembly code, possibly annotated with liveness and other information only
   /// available in the Cfg and not in the Assembler buffer.
   enum ItemKind { WI_Nop, WI_GlobalInits, WI_Asm, WI_Cfg };
   /// Constructor for a WI_Nop work item.
   explicit EmitterWorkItem(uint32_t Seq);
   /// Constructor for a WI_GlobalInits work item.
   EmitterWorkItem(uint32_t Seq, std::unique_ptr<VariableDeclarationList> D);
   /// Constructor for a WI_Asm work item.
   EmitterWorkItem(uint32_t Seq, std::unique_ptr<Assembler> A);
   /// Constructor for a WI_Cfg work item.
   EmitterWorkItem(uint32_t Seq, std::unique_ptr<Cfg> F);
   uint32_t getSequenceNumber() const { return Sequence; }
   ItemKind getKind() const { return Kind; }
   void setGlobalInits(std::unique_ptr<VariableDeclarationList> GloblInits);
   std::unique_ptr<VariableDeclarationList> getGlobalInits();
   std::unique_ptr<Assembler> getAsm();
   std::unique_ptr<Cfg> getCfg();

 private:
   const uint32_t Sequence;
   const ItemKind Kind;
   std::unique_ptr<VariableDeclarationList> GlobalInits;
   std::unique_ptr<Assembler> Function;
   std::unique_ptr<Cfg> RawFunc;
 };

 } // end of namespace Ice

 #endif // SUBZERO_SRC_ICETHREADING_H
	//===- subzero/src/IceThreading.h - Threading functions ---------- C++ --===//
	//
	// The Subzero Code Generator
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	///
	/// \file
	/// \brief Declares threading-related functions.
	///
	//===----------------------------------------------------------------------===//

	#ifndef SUBZERO_SRC_ICETHREADING_H
	#define SUBZERO_SRC_ICETHREADING_H

	#include "IceDefs.h"

	#include <condition_variable>
	#include <memory>
	#include <mutex>
	#include <utility>

	namespace Ice {

	/// BoundedProducerConsumerQueue is a work queue that allows multiple producers
	/// and multiple consumers. A producer adds entries using blockingPush(), and
	/// may block if the queue is "full". A producer uses notifyEnd() to indicate
	/// that no more entries will be added. A consumer removes an item using
	/// blockingPop(), which will return nullptr if notifyEnd() has been called and
	/// the queue is empty (it never returns nullptr if the queue contained any
	/// items).
	///
	/// The MaxSize ctor arg controls the maximum size the queue can grow to
	/// (subject to a hard limit of MaxStaticSize-1). The Sequential arg indicates
	/// purely sequential execution in which the single thread should never wait().
	///
	/// Two condition variables are used in the implementation. GrewOrEnded signals
	/// a waiting worker that a producer has changed the state of the queue. Shrunk
	/// signals a blocked producer that a consumer has changed the state of the
	/// queue.
	///
	/// The methods begin with Sequential-specific code to be most clear. The lock
	/// and condition variables are not used in the Sequential case.
	///
	/// Internally, the queue is implemented as a circular array of size
	/// MaxStaticSize, where the queue boundaries are denoted by the Front and Back
	/// fields. Front==Back indicates an empty queue.
	template <typename T, size_t MaxStaticSize = 128>
	class BoundedProducerConsumerQueue {
	BoundedProducerConsumerQueue() = delete;
	BoundedProducerConsumerQueue(const BoundedProducerConsumerQueue &) = delete;
	BoundedProducerConsumerQueue &
	operator=(const BoundedProducerConsumerQueue &) = delete;

	public:
	BoundedProducerConsumerQueue(bool Sequential, size_t MaxSize = MaxStaticSize)
	: MaxSize(std::min(MaxSize, MaxStaticSize)), Sequential(Sequential) {}
	void blockingPush(std::unique_ptr<T> Item) {
	{
	std::unique_lock<GlobalLockType> L(Lock);
	// If the work queue is already "full", wait for a consumer to grab an
	// element and shrink the queue.
	Shrunk.wait(L, [this] { return size() < MaxSize \|\| Sequential; });
	push(std::move(Item));
	}
	GrewOrEnded.notify_one();
	}
	std::unique_ptr<T> blockingPop(size_t NotifyWhenDownToSize = MaxStaticSize) {
	std::unique_ptr<T> Item;
	bool ShouldNotifyProducer = false;
	{
	std::unique_lock<GlobalLockType> L(Lock);
	GrewOrEnded.wait(L, [this] { return IsEnded \|\| !empty() \|\| Sequential; });
	if (!empty()) {
	Item = pop();
	ShouldNotifyProducer = (size() < NotifyWhenDownToSize) && !IsEnded;
	}
	}
	if (ShouldNotifyProducer)
	Shrunk.notify_one();
	return Item;
	}
	void notifyEnd() {
	{
	std::lock_guard<GlobalLockType> L(Lock);
	IsEnded = true;
	}
	GrewOrEnded.notify_all();
	}

	private:
	const static size_t MaxStaticSizeMask = MaxStaticSize - 1;
	static_assert(!(MaxStaticSize & (MaxStaticSize - 1)),
	"MaxStaticSize must be a power of 2");

	ICE_CACHELINE_BOUNDARY;
	/// WorkItems and Lock are read/written by all.
	std::unique_ptr<T> WorkItems[MaxStaticSize];
	ICE_CACHELINE_BOUNDARY;
	/// Lock guards access to WorkItems, Front, Back, and IsEnded.
	GlobalLockType Lock;

	ICE_CACHELINE_BOUNDARY;
	/// GrewOrEnded is written by the producers and read by the consumers. It is
	/// notified (by the producer) when something is added to the queue, in case
	/// consumers are waiting for a non-empty queue.
	std::condition_variable GrewOrEnded;
	/// Back is the index into WorkItems[] of where the next element will be
	/// pushed. (More precisely, Back&MaxStaticSize is the index.) It is written
	/// by the producers, and read by all via size() and empty().
	size_t Back = 0;

	ICE_CACHELINE_BOUNDARY;
	/// Shrunk is notified (by the consumer) when something is removed from the
	/// queue, in case a producer is waiting for the queue to drop below maximum
	/// capacity. It is written by the consumers and read by the producers.
	std::condition_variable Shrunk;
	/// Front is the index into WorkItems[] of the oldest element, i.e. the next
	/// to be popped. (More precisely Front&MaxStaticSize is the index.) It is
	/// written by the consumers, and read by all via size() and empty().
	size_t Front = 0;

	ICE_CACHELINE_BOUNDARY;

	/// MaxSize and Sequential are read by all and written by none.
	const size_t MaxSize;
	const bool Sequential;
	/// IsEnded is read by the consumers, and only written once by the producer.
	bool IsEnded = false;

	/// The lock must be held when the following methods are called.
	bool empty() const { return Front == Back; }
	size_t size() const { return Back - Front; }
	void push(std::unique_ptr<T> Item) {
	WorkItems[Back++ & MaxStaticSizeMask] = std::move(Item);
	assert(size() <= MaxStaticSize);
	}
	std::unique_ptr<T> pop() {
	assert(!empty());
	return std::move(WorkItems[Front++ & MaxStaticSizeMask]);
	}
	};

	/// EmitterWorkItem is a simple wrapper around a pointer that represents a work
	/// item to be emitted, i.e. a function or a set of global declarations and
	/// initializers, and it includes a sequence number so that work items can be
	/// emitted in a particular order for deterministic output. It acts like an
	/// interface class, but instead of making the classes of interest inherit from
	/// EmitterWorkItem, it wraps pointers to these classes. Some space is wasted
	/// compared to storing the pointers in a union, but not too much due to the
	/// work granularity.
	class EmitterWorkItem {
	EmitterWorkItem() = delete;
	EmitterWorkItem(const EmitterWorkItem &) = delete;
	EmitterWorkItem &operator=(const EmitterWorkItem &) = delete;

	public:
	/// ItemKind can be one of the following:
	///
	/// WI_Nop: No actual work. This is a placeholder to maintain sequence numbers
	/// in case there is a translation error.
	///
	/// WI_GlobalInits: A list of global declarations and initializers.
	///
	/// WI_Asm: A function that has already had emitIAS() called on it. The work
	/// is transferred via the Assembler buffer, and the originating Cfg has been
	/// deleted (to recover lots of memory).
	///
	/// WI_Cfg: A Cfg that has not yet had emit() or emitIAS() called on it. This
	/// is only used as a debugging configuration when we want to emit "readable"
	/// assembly code, possibly annotated with liveness and other information only
	/// available in the Cfg and not in the Assembler buffer.
	enum ItemKind { WI_Nop, WI_GlobalInits, WI_Asm, WI_Cfg };
	/// Constructor for a WI_Nop work item.
	explicit EmitterWorkItem(uint32_t Seq);
	/// Constructor for a WI_GlobalInits work item.
	EmitterWorkItem(uint32_t Seq, std::unique_ptr<VariableDeclarationList> D);
	/// Constructor for a WI_Asm work item.
	EmitterWorkItem(uint32_t Seq, std::unique_ptr<Assembler> A);
	/// Constructor for a WI_Cfg work item.
	EmitterWorkItem(uint32_t Seq, std::unique_ptr<Cfg> F);
	uint32_t getSequenceNumber() const { return Sequence; }
	ItemKind getKind() const { return Kind; }
	void setGlobalInits(std::unique_ptr<VariableDeclarationList> GloblInits);
	std::unique_ptr<VariableDeclarationList> getGlobalInits();
	std::unique_ptr<Assembler> getAsm();
	std::unique_ptr<Cfg> getCfg();

	private:
	const uint32_t Sequence;
	const ItemKind Kind;
	std::unique_ptr<VariableDeclarationList> GlobalInits;
	std::unique_ptr<Assembler> Function;
	std::unique_ptr<Cfg> RawFunc;
	};

	} // end of namespace Ice

	#endif // SUBZERO_SRC_ICETHREADING_H