// Copyright 2016 The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. // gccgo-specific support for GC. package runtime import ( "runtime/internal/sys" "unsafe" ) // For gccgo, use go:linkname to export compiler-called functions. // //go:linkname gcWriteBarrier // gcRoot is a single GC root: a variable plus a ptrmask. //go:notinheap type gcRoot struct { decl unsafe.Pointer // Pointer to variable. size uintptr // Size of variable. ptrdata uintptr // Length of gcdata. gcdata *uint8 // Pointer mask. } // gcRootList is the set of GC roots for a package. // The next field is used to put this all into a linked list. // count gives the real length of the array. type gcRootList struct { next *gcRootList count int roots [1 << 26]gcRoot } // roots is the list of GC roots for the program. // The compiler keeps this variable itself off the list. var gcRoots *gcRootList // Slice containing pointers to all reachable gcRoot's sorted by // starting address (generated at init time from 'gcRoots'). // The compiler also keeps this variable itself off the list. // The storage backing this slice is allocated via persistentalloc(), the // idea being that we don't want to treat the slice itself as a global // variable, since it points to things that don't need to be scanned // themselves. var gcRootsIndex []*gcRoot // rootradixsort performs an in-place radix sort of the 'arr' rootptr slice. // Note: not a stable sort, however we expect it to be called only on slices // with no duplicate entries, so this should not matter. func rootradixsort(arr []*gcRoot, lo, hi int, bit uint) { // Partition the array into two bins based on the values at the // specified bit position: 0's bin (grown from the left) and and // 1's bin (grown from the right). We keep two boundary markers, // the 0's boundary "zbb" (which grows to the right) and the 1's // boundary "obb" (which grows to the left). At each step we // examine the bit for the right-of-ZBB element: if it is zero, we // leave it in place and move the ZBB to the right. If the bit is // not zero, then we swap the ZBB and OBB elements and move the // OBB to the left. When this is done, the two partitions are then // sorted using the next lower bit. // 0's bin boundary, initially set to before the first element zbb := lo - 1 // 1's bin boundary, set to just beyond the last element obb := hi + 1 // mask to pick up bit of interest bmask := uintptr(1) << bit for obb-zbb > 1 { zbbval := uintptr(arr[zbb+1].decl) & bmask if zbbval == 0 { // Move zbb one to the right zbb++ } else { // Move obb one to the left and swap arr[obb-1], arr[zbb+1] = arr[zbb+1], arr[obb-1] obb-- } } if bit != 0 { // NB: in most cases there is just a single partition to visit // so if we wanted to reduce stack space we could check for this // and insert a goto back up to the top. if zbb-lo > 0 { rootradixsort(arr, lo, zbb, bit-1) } if hi-obb > 0 { rootradixsort(arr, obb, hi, bit-1) } } } //go:nowritebarrier func createGcRootsIndex() { // Count roots nroots := 0 gcr := gcRoots for gcr != nil { nroots += gcr.count gcr = gcr.next } // Construct the gcRootsIndex slice. Use non-heap storage for the array // backing the slice. sp := (*notInHeapSlice)(unsafe.Pointer(&gcRootsIndex)) sp.array = (*notInHeap)(persistentalloc1(sys.PtrSize*uintptr(nroots), sys.PtrSize, &memstats.other_sys)) if sp.array == nil { throw("runtime: cannot allocate memory") } sp.len = nroots sp.cap = nroots // Populate the roots index slice gcr = gcRoots k := 0 for gcr != nil { for i := 0; i < gcr.count; i++ { gcRootsIndex[k] = &gcr.roots[i] k++ } gcr = gcr.next } // Sort it by starting address. rootradixsort(gcRootsIndex, 0, nroots-1, sys.PtrSize*8-1) } // registerGCRoots is called by compiler-generated code. //go:linkname registerGCRoots // registerGCRoots is called by init functions to register the GC // roots for a package. The init functions are run sequentially at // the start of the program, so no locking is needed. func registerGCRoots(r *gcRootList) { r.next = gcRoots gcRoots = r } // checkPreempt is called when the preempt field in the running G is true. // It preempts the goroutine if it is safe to do so. // If preemptscan is true, this scans the stack for the garbage collector // and carries on. func checkPreempt() { gp := getg() if !gp.preempt || gp != gp.m.curg || !canPreemptM(gp.m) { return } if gp.preemptStop { mcall(preemptPark) } // Act like goroutine called runtime.Gosched. mcall(gopreempt_m) } // gcWriteBarrier implements a write barrier. This is implemented in // assembly in the gc library, but there is no special advantage to // doing so with gccgo. //go:nosplit //go:nowritebarrier func gcWriteBarrier(dst *uintptr, src uintptr) { buf := &getg().m.p.ptr().wbBuf if !buf.putFast(src, *dst) { wbBufFlush(dst, src) } *dst = src }