// Copyright 2009 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. #include "runtime.h" #include "type.h" #include "malloc.h" static int32 debug = 0; static void makeslice(SliceType*, int32, int32, Slice*); void ·slicecopy(Slice to, Slice fm, uintptr width, int32 ret); // see also unsafe·NewArray // makeslice(typ *Type, len, cap int64) (ary []any); void ·makeslice(SliceType *t, int64 len, int64 cap, Slice ret) { if(len < 0 || (int32)len != len) panicstring("makeslice: len out of range"); if(cap < len || (int32)cap != cap || cap > ((uintptr)-1) / t->elem->size) panicstring("makeslice: cap out of range"); makeslice(t, len, cap, &ret); if(debug) { printf("makeslice(%S, %D, %D); ret=", *t->string, len, cap); ·printslice(ret); } } static void makeslice(SliceType *t, int32 len, int32 cap, Slice *ret) { uintptr size; size = cap*t->elem->size; ret->len = len; ret->cap = cap; if((t->elem->kind&KindNoPointers)) ret->array = mallocgc(size, RefNoPointers, 1, 1); else ret->array = mal(size); } static void appendslice(SliceType*, Slice, Slice, Slice*); // append(type *Type, n int, old []T, ...,) []T #pragma textflag 7 void ·append(SliceType *t, int32 n, Slice old, ...) { Slice sl; Slice *ret; sl.len = n; sl.array = (byte*)(&old+1); ret = (Slice*)(sl.array + ((t->elem->size*n+sizeof(uintptr)-1) & ~(sizeof(uintptr)-1))); appendslice(t, old, sl, ret); } // appendslice(type *Type, x, y, []T) []T void ·appendslice(SliceType *t, Slice x, Slice y, Slice ret) { appendslice(t, x, y, &ret); } static void appendslice(SliceType *t, Slice x, Slice y, Slice *ret) { Slice newx; int32 m; uintptr w; if(x.len+y.len < x.len) throw("append: slice overflow"); w = t->elem->size; if(x.len+y.len > x.cap) { m = x.cap; if(m == 0) m = y.len; else { do { if(x.len < 1024) m += m; else m += m/4; } while(m < x.len+y.len); } makeslice(t, x.len, m, &newx); memmove(newx.array, x.array, x.len*w); x = newx; } memmove(x.array+x.len*w, y.array, y.len*w); x.len += y.len; *ret = x; } // sliceslice(old []any, lb uint64, hb uint64, width uint64) (ary []any); void ·sliceslice(Slice old, uint64 lb, uint64 hb, uint64 width, Slice ret) { if(hb > old.cap || lb > hb) { if(debug) { prints("runtime.sliceslice: old="); ·printslice(old); prints("; lb="); ·printint(lb); prints("; hb="); ·printint(hb); prints("; width="); ·printint(width); prints("\n"); prints("oldarray: nel="); ·printint(old.len); prints("; cap="); ·printint(old.cap); prints("\n"); } ·panicslice(); } // new array is inside old array ret.len = hb - lb; ret.cap = old.cap - lb; ret.array = old.array + lb*width; FLUSH(&ret); if(debug) { prints("runtime.sliceslice: old="); ·printslice(old); prints("; lb="); ·printint(lb); prints("; hb="); ·printint(hb); prints("; width="); ·printint(width); prints("; ret="); ·printslice(ret); prints("\n"); } } // sliceslice1(old []any, lb uint64, width uint64) (ary []any); void ·sliceslice1(Slice old, uint64 lb, uint64 width, Slice ret) { if(lb > old.len) { if(debug) { prints("runtime.sliceslice: old="); ·printslice(old); prints("; lb="); ·printint(lb); prints("; width="); ·printint(width); prints("\n"); prints("oldarray: nel="); ·printint(old.len); prints("; cap="); ·printint(old.cap); prints("\n"); } ·panicslice(); } // new array is inside old array ret.len = old.len - lb; ret.cap = old.cap - lb; ret.array = old.array + lb*width; FLUSH(&ret); if(debug) { prints("runtime.sliceslice: old="); ·printslice(old); prints("; lb="); ·printint(lb); prints("; width="); ·printint(width); prints("; ret="); ·printslice(ret); prints("\n"); } } // slicearray(old *any, nel uint64, lb uint64, hb uint64, width uint64) (ary []any); void ·slicearray(byte* old, uint64 nel, uint64 lb, uint64 hb, uint64 width, Slice ret) { if(nel > 0 && old == nil) { // crash if old == nil. // could give a better message // but this is consistent with all the in-line checks // that the compiler inserts for other uses. *old = 0; } if(hb > nel || lb > hb) { if(debug) { prints("runtime.slicearray: old="); ·printpointer(old); prints("; nel="); ·printint(nel); prints("; lb="); ·printint(lb); prints("; hb="); ·printint(hb); prints("; width="); ·printint(width); prints("\n"); } ·panicslice(); } // new array is inside old array ret.len = hb-lb; ret.cap = nel-lb; ret.array = old + lb*width; FLUSH(&ret); if(debug) { prints("runtime.slicearray: old="); ·printpointer(old); prints("; nel="); ·printint(nel); prints("; lb="); ·printint(lb); prints("; hb="); ·printint(hb); prints("; width="); ·printint(width); prints("; ret="); ·printslice(ret); prints("\n"); } } // slicecopy(to any, fr any, wid uint32) int void ·slicecopy(Slice to, Slice fm, uintptr width, int32 ret) { if(fm.len == 0 || to.len == 0 || width == 0) { ret = 0; goto out; } ret = fm.len; if(to.len < ret) ret = to.len; if(ret == 1 && width == 1) { // common case worth about 2x to do here *to.array = *fm.array; // known to be a byte pointer } else { memmove(to.array, fm.array, ret*width); } out: FLUSH(&ret); if(debug) { prints("main·copy: to="); ·printslice(to); prints("; fm="); ·printslice(fm); prints("; width="); ·printint(width); prints("; ret="); ·printint(ret); prints("\n"); } } void ·slicestringcopy(Slice to, String fm, int32 ret) { if(fm.len == 0 || to.len == 0) { ret = 0; goto out; } ret = fm.len; if(to.len < ret) ret = to.len; memmove(to.array, fm.str, ret); out: FLUSH(&ret); } void ·printslice(Slice a) { prints("["); ·printint(a.len); prints("/"); ·printint(a.cap); prints("]"); ·printpointer(a.array); }