/** * Base fiber module provides OS-indepedent part of lightweight threads aka fibers. * * Copyright: Copyright Sean Kelly 2005 - 2012. * License: Distributed under the * $(LINK2 http://www.boost.org/LICENSE_1_0.txt, Boost Software License 1.0). * (See accompanying file LICENSE) * Authors: Sean Kelly, Walter Bright, Alex Rønne Petersen, Martin Nowak * Source: $(DRUNTIMESRC core/thread/fiber/base.d) */ /* NOTE: This file has been patched from the original DMD distribution to * work with the GDC compiler. */ module core.thread.fiber.base; package: version (GNU) import gcc.config; import core.thread.fiber; import core.thread.threadbase; import core.thread.threadgroup; import core.thread.types; import core.thread.context; import core.memory : pageSize; package { import core.atomic : atomicStore, cas, MemoryOrder; import core.exception : onOutOfMemoryError; import core.stdc.stdlib : abort; extern (C) void fiber_entryPoint() nothrow { FiberBase obj = FiberBase.getThis(); assert( obj ); assert( ThreadBase.getThis().m_curr is obj.m_ctxt ); atomicStore!(MemoryOrder.raw)(*cast(shared)&ThreadBase.getThis().m_lock, false); obj.m_ctxt.tstack = obj.m_ctxt.bstack; obj.m_state = FiberBase.State.EXEC; try { obj.run(); } catch ( Throwable t ) { obj.m_unhandled = t; } static if ( __traits( compiles, ucontext_t ) ) obj.m_ucur = &obj.m_utxt; obj.m_state = Fiber.State.TERM; obj.switchOut(); } } /////////////////////////////////////////////////////////////////////////////// // Fiber /////////////////////////////////////////////////////////////////////////////// /* * Documentation of Fiber internals: * * The main routines to implement when porting Fibers to new architectures are * fiber_switchContext and initStack. Some version constants have to be defined * for the new platform as well, search for "Fiber Platform Detection and Memory Allocation". * * Fibers are based on a concept called 'Context'. A Context describes the execution * state of a Fiber or main thread which is fully described by the stack, some * registers and a return address at which the Fiber/Thread should continue executing. * Please note that not only each Fiber has a Context, but each thread also has got a * Context which describes the threads stack and state. If you call Fiber fib; fib.call * the first time in a thread you switch from Threads Context into the Fibers Context. * If you call fib.yield in that Fiber you switch out of the Fibers context and back * into the Thread Context. (However, this is not always the case. You can call a Fiber * from within another Fiber, then you switch Contexts between the Fibers and the Thread * Context is not involved) * * In all current implementations the registers and the return address are actually * saved on a Contexts stack. * * The fiber_switchContext routine has got two parameters: * void** a: This is the _location_ where we have to store the current stack pointer, * the stack pointer of the currently executing Context (Fiber or Thread). * void* b: This is the pointer to the stack of the Context which we want to switch into. * Note that we get the same pointer here as the one we stored into the void** a * in a previous call to fiber_switchContext. * * In the simplest case, a fiber_switchContext rountine looks like this: * fiber_switchContext: * push {return Address} * push {registers} * copy {stack pointer} into {location pointed to by a} * //We have now switch to the stack of a different Context! * copy {b} into {stack pointer} * pop {registers} * pop {return Address} * jump to {return Address} * * The GC uses the value returned in parameter a to scan the Fibers stack. It scans from * the stack base to that value. As the GC dislikes false pointers we can actually optimize * this a little: By storing registers which can not contain references to memory managed * by the GC outside of the region marked by the stack base pointer and the stack pointer * saved in fiber_switchContext we can prevent the GC from scanning them. * Such registers are usually floating point registers and the return address. In order to * implement this, we return a modified stack pointer from fiber_switchContext. However, * we have to remember that when we restore the registers from the stack! * * --------------------------- <= Stack Base * | Frame | <= Many other stack frames * | Frame | * |-------------------------| <= The last stack frame. This one is created by fiber_switchContext * | registers with pointers | * | | <= Stack pointer. GC stops scanning here * | return address | * |floating point registers | * --------------------------- <= Real Stack End * * fiber_switchContext: * push {registers with pointers} * copy {stack pointer} into {location pointed to by a} * push {return Address} * push {Floating point registers} * //We have now switch to the stack of a different Context! * copy {b} into {stack pointer} * //We now have to adjust the stack pointer to point to 'Real Stack End' so we can pop * //the FP registers * //+ or - depends on if your stack grows downwards or upwards * {stack pointer} = {stack pointer} +- ({FPRegisters}.sizeof + {return address}.sizeof} * pop {Floating point registers} * pop {return Address} * pop {registers with pointers} * jump to {return Address} * * So the question now is which registers need to be saved? This depends on the specific * architecture ABI of course, but here are some general guidelines: * - If a register is callee-save (if the callee modifies the register it must saved and * restored by the callee) it needs to be saved/restored in switchContext * - If a register is caller-save it needn't be saved/restored. (Calling fiber_switchContext * is a function call and the compiler therefore already must save these registers before * calling fiber_switchContext) * - Argument registers used for passing parameters to functions needn't be saved/restored * - The return register needn't be saved/restored (fiber_switchContext hasn't got a return type) * - All scratch registers needn't be saved/restored * - The link register usually needn't be saved/restored (but sometimes it must be cleared - * see below for details) * - The frame pointer register - if it exists - is usually callee-save * - All current implementations do not save control registers * * What happens on the first switch into a Fiber? We never saved a state for this fiber before, * but the initial state is prepared in the initStack routine. (This routine will also be called * when a Fiber is being resetted). initStack must produce exactly the same stack layout as the * part of fiber_switchContext which saves the registers. Pay special attention to set the stack * pointer correctly if you use the GC optimization mentioned before. the return Address saved in * initStack must be the address of fiber_entrypoint. * * There's now a small but important difference between the first context switch into a fiber and * further context switches. On the first switch, Fiber.call is used and the returnAddress in * fiber_switchContext will point to fiber_entrypoint. The important thing here is that this jump * is a _function call_, we call fiber_entrypoint by jumping before it's function prologue. On later * calls, the user used yield() in a function, and therefore the return address points into a user * function, after the yield call. So here the jump in fiber_switchContext is a _function return_, * not a function call! * * The most important result of this is that on entering a function, i.e. fiber_entrypoint, we * would have to provide a return address / set the link register once fiber_entrypoint * returns. Now fiber_entrypoint does never return and therefore the actual value of the return * address / link register is never read/used and therefore doesn't matter. When fiber_switchContext * performs a _function return_ the value in the link register doesn't matter either. * However, the link register will still be saved to the stack in fiber_entrypoint and some * exception handling / stack unwinding code might read it from this stack location and crash. * The exact solution depends on your architecture, but see the ARM implementation for a way * to deal with this issue. * * The ARM implementation is meant to be used as a kind of documented example implementation. * Look there for a concrete example. * * FIXME: fiber_entrypoint might benefit from a @noreturn attribute, but D doesn't have one. */ /** * This class provides a cooperative concurrency mechanism integrated with the * threading and garbage collection functionality. Calling a fiber may be * considered a blocking operation that returns when the fiber yields (via * Fiber.yield()). Execution occurs within the context of the calling thread * so synchronization is not necessary to guarantee memory visibility so long * as the same thread calls the fiber each time. Please note that there is no * requirement that a fiber be bound to one specific thread. Rather, fibers * may be freely passed between threads so long as they are not currently * executing. Like threads, a new fiber thread may be created using either * derivation or composition, as in the following example. * * Warning: * Status registers are not saved by the current implementations. This means * floating point exception status bits (overflow, divide by 0), rounding mode * and similar stuff is set per-thread, not per Fiber! * * Warning: * On ARM FPU registers are not saved if druntime was compiled as ARM_SoftFloat. * If such a build is used on a ARM_SoftFP system which actually has got a FPU * and other libraries are using the FPU registers (other code is compiled * as ARM_SoftFP) this can cause problems. Druntime must be compiled as * ARM_SoftFP in this case. * * Authors: Based on a design by Mikola Lysenko. */ class FiberBase { /** * Initializes a fiber object which is associated with a static * D function. * * Params: * fn = The fiber function. * sz = The stack size for this fiber. * guardPageSize = size of the guard page to trap fiber's stack * overflows. Beware that using this will increase * the number of mmaped regions on platforms using mmap * so an OS-imposed limit may be hit. * * In: * fn must not be null. */ this( void function() fn, size_t sz, size_t guardPageSize ) nothrow in { assert( fn ); } do { allocStack( sz, guardPageSize ); reset( fn ); } /** * Initializes a fiber object which is associated with a dynamic * D function. * * Params: * dg = The fiber function. * sz = The stack size for this fiber. * guardPageSize = size of the guard page to trap fiber's stack * overflows. Beware that using this will increase * the number of mmaped regions on platforms using mmap * so an OS-imposed limit may be hit. * * In: * dg must not be null. */ this( void delegate() dg, size_t sz, size_t guardPageSize ) nothrow { allocStack( sz, guardPageSize ); reset( cast(void delegate() const) dg ); } /** * Cleans up any remaining resources used by this object. */ ~this() nothrow @nogc { // NOTE: A live reference to this object will exist on its associated // stack from the first time its call() method has been called // until its execution completes with State.TERM. Thus, the only // times this dtor should be called are either if the fiber has // terminated (and therefore has no active stack) or if the user // explicitly deletes this object. The latter case is an error // but is not easily tested for, since State.HOLD may imply that // the fiber was just created but has never been run. There is // not a compelling case to create a State.INIT just to offer a // means of ensuring the user isn't violating this object's // contract, so for now this requirement will be enforced by // documentation only. freeStack(); } /////////////////////////////////////////////////////////////////////////// // General Actions /////////////////////////////////////////////////////////////////////////// /** * Transfers execution to this fiber object. The calling context will be * suspended until the fiber calls Fiber.yield() or until it terminates * via an unhandled exception. * * Params: * rethrow = Rethrow any unhandled exception which may have caused this * fiber to terminate. * * In: * This fiber must be in state HOLD. * * Throws: * Any exception not handled by the joined thread. * * Returns: * Any exception not handled by this fiber if rethrow = false, null * otherwise. */ // Not marked with any attributes, even though `nothrow @nogc` works // because it calls arbitrary user code. Most of the implementation // is already `@nogc nothrow`, but in order for `Fiber.call` to // propagate the attributes of the user's function, the Fiber // class needs to be templated. final Throwable call( Rethrow rethrow = Rethrow.yes ) { return rethrow ? call!(Rethrow.yes)() : call!(Rethrow.no); } /// ditto final Throwable call( Rethrow rethrow )() { callImpl(); if ( m_unhandled ) { Throwable t = m_unhandled; m_unhandled = null; static if ( rethrow ) throw t; else return t; } return null; } private void callImpl() nothrow @nogc in { assert( m_state == State.HOLD ); } do { FiberBase cur = getThis(); static if ( __traits( compiles, ucontext_t ) ) m_ucur = cur ? &cur.m_utxt : &Fiber.sm_utxt; setThis( this ); this.switchIn(); setThis( cur ); static if ( __traits( compiles, ucontext_t ) ) m_ucur = null; // NOTE: If the fiber has terminated then the stack pointers must be // reset. This ensures that the stack for this fiber is not // scanned if the fiber has terminated. This is necessary to // prevent any references lingering on the stack from delaying // the collection of otherwise dead objects. The most notable // being the current object, which is referenced at the top of // fiber_entryPoint. if ( m_state == State.TERM ) { m_ctxt.tstack = m_ctxt.bstack; } } /// Flag to control rethrow behavior of $(D $(LREF call)) enum Rethrow : bool { no, yes } /** * Resets this fiber so that it may be re-used, optionally with a * new function/delegate. This routine should only be called for * fibers that have terminated, as doing otherwise could result in * scope-dependent functionality that is not executed. * Stack-based classes, for example, may not be cleaned up * properly if a fiber is reset before it has terminated. * * In: * This fiber must be in state TERM or HOLD. */ final void reset() nothrow @nogc in { assert( m_state == State.TERM || m_state == State.HOLD ); } do { m_ctxt.tstack = m_ctxt.bstack; m_state = State.HOLD; initStack(); m_unhandled = null; } /// ditto final void reset( void function() fn ) nothrow @nogc { reset(); m_call = fn; } /// ditto final void reset( void delegate() dg ) nothrow @nogc { reset(); m_call = dg; } /////////////////////////////////////////////////////////////////////////// // General Properties /////////////////////////////////////////////////////////////////////////// /// A fiber may occupy one of three states: HOLD, EXEC, and TERM. enum State { /** The HOLD state applies to any fiber that is suspended and ready to be called. */ HOLD, /** The EXEC state will be set for any fiber that is currently executing. */ EXEC, /** The TERM state is set when a fiber terminates. Once a fiber terminates, it must be reset before it may be called again. */ TERM } /** * Gets the current state of this fiber. * * Returns: * The state of this fiber as an enumerated value. */ final @property State state() const @safe pure nothrow @nogc { return m_state; } /////////////////////////////////////////////////////////////////////////// // Actions on Calling Fiber /////////////////////////////////////////////////////////////////////////// /** * Forces a context switch to occur away from the calling fiber. */ static void yield() nothrow @nogc { FiberBase cur = getThis(); assert( cur, "Fiber.yield() called with no active fiber" ); assert( cur.m_state == State.EXEC ); static if ( __traits( compiles, ucontext_t ) ) cur.m_ucur = &cur.m_utxt; cur.m_state = State.HOLD; cur.switchOut(); cur.m_state = State.EXEC; } /** * Forces a context switch to occur away from the calling fiber and then * throws obj in the calling fiber. * * Params: * t = The object to throw. * * In: * t must not be null. */ static void yieldAndThrow( Throwable t ) nothrow @nogc in { assert( t ); } do { FiberBase cur = getThis(); assert( cur, "Fiber.yield() called with no active fiber" ); assert( cur.m_state == State.EXEC ); static if ( __traits( compiles, ucontext_t ) ) cur.m_ucur = &cur.m_utxt; cur.m_unhandled = t; cur.m_state = State.HOLD; cur.switchOut(); cur.m_state = State.EXEC; } /////////////////////////////////////////////////////////////////////////// // Fiber Accessors /////////////////////////////////////////////////////////////////////////// /** * Provides a reference to the calling fiber or null if no fiber is * currently active. * * Returns: * The fiber object representing the calling fiber or null if no fiber * is currently active within this thread. The result of deleting this object is undefined. */ static FiberBase getThis() @safe nothrow @nogc { version (GNU) pragma(inline, false); return sm_this; } private: // // Fiber entry point. Invokes the function or delegate passed on // construction (if any). // final void run() { m_call(); } // // Standard fiber data // Callable m_call; bool m_isRunning; Throwable m_unhandled; State m_state; protected: /////////////////////////////////////////////////////////////////////////// // Stack Management /////////////////////////////////////////////////////////////////////////// // // Allocate a new stack for this fiber. // abstract void allocStack( size_t sz, size_t guardPageSize ) nothrow; // // Free this fiber's stack. // abstract void freeStack() nothrow @nogc; // // Initialize the allocated stack. // Look above the definition of 'class Fiber' for some information about the implementation of this routine // abstract void initStack() nothrow @nogc; StackContext* m_ctxt; size_t m_size; void* m_pmem; static if ( __traits( compiles, ucontext_t ) ) { // NOTE: The static ucontext instance is used to represent the context // of the executing thread. static ucontext_t sm_utxt = void; ucontext_t m_utxt = void; package ucontext_t* m_ucur = null; } else static if (GNU_Enable_CET) { // When libphobos was built with --enable-cet, these fields need to // always be present in the Fiber class layout. import core.sys.posix.ucontext; static ucontext_t sm_utxt = void; ucontext_t m_utxt = void; package ucontext_t* m_ucur = null; } private: /////////////////////////////////////////////////////////////////////////// // Storage of Active Fiber /////////////////////////////////////////////////////////////////////////// // // Sets a thread-local reference to the current fiber object. // static void setThis( FiberBase f ) nothrow @nogc { sm_this = f; } static FiberBase sm_this; private: /////////////////////////////////////////////////////////////////////////// // Context Switching /////////////////////////////////////////////////////////////////////////// // // Switches into the stack held by this fiber. // final void switchIn() nothrow @nogc { ThreadBase tobj = ThreadBase.getThis(); void** oldp = &tobj.m_curr.tstack; void* newp = m_ctxt.tstack; // NOTE: The order of operations here is very important. The current // stack top must be stored before m_lock is set, and pushContext // must not be called until after m_lock is set. This process // is intended to prevent a race condition with the suspend // mechanism used for garbage collection. If it is not followed, // a badly timed collection could cause the GC to scan from the // bottom of one stack to the top of another, or to miss scanning // a stack that still contains valid data. The old stack pointer // oldp will be set again before the context switch to guarantee // that it points to exactly the correct stack location so the // successive pop operations will succeed. *oldp = getStackTop(); atomicStore!(MemoryOrder.raw)(*cast(shared)&tobj.m_lock, true); tobj.pushContext( m_ctxt ); fiber_switchContext( oldp, newp ); // NOTE: As above, these operations must be performed in a strict order // to prevent Bad Things from happening. tobj.popContext(); atomicStore!(MemoryOrder.raw)(*cast(shared)&tobj.m_lock, false); tobj.m_curr.tstack = tobj.m_curr.bstack; } // // Switches out of the current stack and into the enclosing stack. // final void switchOut() nothrow @nogc { ThreadBase tobj = ThreadBase.getThis(); void** oldp = &m_ctxt.tstack; void* newp = tobj.m_curr.within.tstack; // NOTE: The order of operations here is very important. The current // stack top must be stored before m_lock is set, and pushContext // must not be called until after m_lock is set. This process // is intended to prevent a race condition with the suspend // mechanism used for garbage collection. If it is not followed, // a badly timed collection could cause the GC to scan from the // bottom of one stack to the top of another, or to miss scanning // a stack that still contains valid data. The old stack pointer // oldp will be set again before the context switch to guarantee // that it points to exactly the correct stack location so the // successive pop operations will succeed. *oldp = getStackTop(); atomicStore!(MemoryOrder.raw)(*cast(shared)&tobj.m_lock, true); fiber_switchContext( oldp, newp ); // NOTE: As above, these operations must be performed in a strict order // to prevent Bad Things from happening. // NOTE: If use of this fiber is multiplexed across threads, the thread // executing here may be different from the one above, so get the // current thread handle before unlocking, etc. tobj = ThreadBase.getThis(); atomicStore!(MemoryOrder.raw)(*cast(shared)&tobj.m_lock, false); tobj.m_curr.tstack = tobj.m_curr.bstack; } } /// unittest { int counter; class DerivedFiber : Fiber { this() { super( &run ); } private : void run() { counter += 2; } } void fiberFunc() { counter += 4; Fiber.yield(); counter += 8; } // create instances of each type Fiber derived = new DerivedFiber(); Fiber composed = new Fiber( &fiberFunc ); assert( counter == 0 ); derived.call(); assert( counter == 2, "Derived fiber increment." ); composed.call(); assert( counter == 6, "First composed fiber increment." ); counter += 16; assert( counter == 22, "Calling context increment." ); composed.call(); assert( counter == 30, "Second composed fiber increment." ); // since each fiber has run to completion, each should have state TERM assert( derived.state == Fiber.State.TERM ); assert( composed.state == Fiber.State.TERM ); } version (unittest) { import core.thread.fiber: Fiber; } version (CoreUnittest) { class TestFiber : Fiber { this() { super(&run); } void run() { foreach (i; 0 .. 1000) { sum += i; Fiber.yield(); } } enum expSum = 1000 * 999 / 2; size_t sum; } void runTen() { TestFiber[10] fibs; foreach (ref fib; fibs) fib = new TestFiber(); bool cont; do { cont = false; foreach (fib; fibs) { if (fib.state == Fiber.State.HOLD) { fib.call(); cont |= fib.state != Fiber.State.TERM; } } } while (cont); foreach (fib; fibs) { assert(fib.sum == TestFiber.expSum); } } } // Single thread running separate fibers unittest { runTen(); } // Multiple threads running separate fibers unittest { auto group = new ThreadGroup(); foreach (_; 0 .. 4) { group.create(&runTen); } group.joinAll(); } // Multiple threads running shared fibers version (PPC) version = UnsafeFiberMigration; version (PPC64) version = UnsafeFiberMigration; version (OSX) { version (X86) version = UnsafeFiberMigration; version (X86_64) version = UnsafeFiberMigration; version (AArch64) version = UnsafeFiberMigration; } version (UnsafeFiberMigration) { // XBUG: core.thread fibers are supposed to be safe to migrate across // threads, however, there is a problem: GCC always assumes that the // address of thread-local variables don't change while on a given stack. // In consequence, migrating fibers between threads currently is an unsafe // thing to do, and will break on some targets (possibly PR26461). } else { version = FiberMigrationUnittest; } version (FiberMigrationUnittest) unittest { shared bool[10] locks; TestFiber[10] fibs; void runShared() { bool cont; do { cont = false; foreach (idx; 0 .. 10) { if (cas(&locks[idx], false, true)) { if (fibs[idx].state == Fiber.State.HOLD) { fibs[idx].call(); cont |= fibs[idx].state != Fiber.State.TERM; } locks[idx] = false; } else { cont = true; } } } while (cont); } foreach (ref fib; fibs) { fib = new TestFiber(); } auto group = new ThreadGroup(); foreach (_; 0 .. 4) { group.create(&runShared); } group.joinAll(); foreach (fib; fibs) { assert(fib.sum == TestFiber.expSum); } } // Test exception handling inside fibers. unittest { enum MSG = "Test message."; string caughtMsg; (new Fiber({ try { throw new Exception(MSG); } catch (Exception e) { caughtMsg = e.msg; } })).call(); assert(caughtMsg == MSG); } unittest { int x = 0; (new Fiber({ x++; })).call(); assert( x == 1 ); } nothrow unittest { new Fiber({}).call!(Fiber.Rethrow.no)(); } unittest { new Fiber({}).call(Fiber.Rethrow.yes); new Fiber({}).call(Fiber.Rethrow.no); } unittest { enum MSG = "Test message."; try { (new Fiber(function() { throw new Exception( MSG ); })).call(); assert( false, "Expected rethrown exception." ); } catch ( Throwable t ) { assert( t.msg == MSG ); } } // Test exception chaining when switching contexts in finally blocks. unittest { static void throwAndYield(string msg) { try { throw new Exception(msg); } finally { Fiber.yield(); } } static void fiber(string name) { try { try { throwAndYield(name ~ ".1"); } finally { throwAndYield(name ~ ".2"); } } catch (Exception e) { assert(e.msg == name ~ ".1"); assert(e.next); assert(e.next.msg == name ~ ".2"); assert(!e.next.next); } } auto first = new Fiber(() => fiber("first")); auto second = new Fiber(() => fiber("second")); first.call(); second.call(); first.call(); second.call(); first.call(); second.call(); assert(first.state == Fiber.State.TERM); assert(second.state == Fiber.State.TERM); } // Test Fiber resetting unittest { static string method; static void foo() { method = "foo"; } void bar() { method = "bar"; } static void expect(Fiber fib, string s) { assert(fib.state == Fiber.State.HOLD); fib.call(); assert(fib.state == Fiber.State.TERM); assert(method == s); method = null; } auto fib = new Fiber(&foo); expect(fib, "foo"); fib.reset(); expect(fib, "foo"); fib.reset(&foo); expect(fib, "foo"); fib.reset(&bar); expect(fib, "bar"); fib.reset(function void(){method = "function";}); expect(fib, "function"); fib.reset(delegate void(){method = "delegate";}); expect(fib, "delegate"); } // Test unsafe reset in hold state unittest { auto fib = new Fiber(function {ubyte[2048] buf = void; Fiber.yield();}, 4096); foreach (_; 0 .. 10) { fib.call(); assert(fib.state == Fiber.State.HOLD); fib.reset(); } } // stress testing GC stack scanning unittest { import core.memory; import core.thread.osthread : Thread; import core.time : dur; static void unreferencedThreadObject() { static void sleep() { Thread.sleep(dur!"msecs"(100)); } auto thread = new Thread(&sleep).start(); } unreferencedThreadObject(); GC.collect(); static class Foo { this(int value) { _value = value; } int bar() { return _value; } int _value; } static void collect() { auto foo = new Foo(2); assert(foo.bar() == 2); GC.collect(); Fiber.yield(); GC.collect(); assert(foo.bar() == 2); } auto fiber = new Fiber(&collect); fiber.call(); GC.collect(); fiber.call(); // thread reference auto foo = new Foo(2); void collect2() { assert(foo.bar() == 2); GC.collect(); Fiber.yield(); GC.collect(); assert(foo.bar() == 2); } fiber = new Fiber(&collect2); fiber.call(); GC.collect(); fiber.call(); static void recurse(size_t cnt) { --cnt; Fiber.yield(); if (cnt) { auto fib = new Fiber(() { recurse(cnt); }); fib.call(); GC.collect(); fib.call(); } } fiber = new Fiber(() { recurse(20); }); fiber.call(); }