gcc/libgo/runtime/msize.c
Ian Lance Taylor 75791bab05 runtime: use -fgo-c-header to build C header file
Use the new -fgo-c-header option to build a header file for the Go
    runtime code in libgo/go/runtime, and use the new header file in the C
    runtime code in libgo/runtime.  This will ensure that the Go code and C
    code share the same data structures as we convert the runtime from C to
    Go.
    
    The new file libgo/go/runtime/runtime2.go is copied from the Go 1.7
    release, and then edited to remove unnecessary data structures and
    modify others for use with libgo.
    
    The new file libgo/go/runtime/mcache.go is an initial version of the
    same files in the Go 1.7 release, and will be replaced by the Go 1.7
    file when we convert to the new memory allocator.
    
    The new file libgo/go/runtime/type.go describes the gccgo version of the
    reflection data structures, and replaces the Go 1.7 runtime file which
    describes the gc version of those structures.
    
    Using the new header file means changing a number of struct fields to
    use Go naming conventions (that is, no underscores) and to rename
    constants to have a leading underscore so that they are not exported
    from the Go package.  These names were updated in the C code.
    
    The C code was also changed to drop the thread-local variable m, as was
    done some time ago in the gc sources.  Now the m field is always
    accessed using g->m, where g is the single remaining thread-local
    variable.  This in turn required some adjustments to set g->m correctly
    in all cases.
    
    Also pass the new -fgo-compiling-runtime option when compiling the
    runtime package, although that option doesn't do anything yet.
    
    Reviewed-on: https://go-review.googlesource.com/28051

From-SVN: r239872
2016-08-30 21:07:47 +00:00

176 lines
5.9 KiB
C

// 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.
// Malloc small size classes.
//
// See malloc.h for overview.
//
// The size classes are chosen so that rounding an allocation
// request up to the next size class wastes at most 12.5% (1.125x).
//
// Each size class has its own page count that gets allocated
// and chopped up when new objects of the size class are needed.
// That page count is chosen so that chopping up the run of
// pages into objects of the given size wastes at most 12.5% (1.125x)
// of the memory. It is not necessary that the cutoff here be
// the same as above.
//
// The two sources of waste multiply, so the worst possible case
// for the above constraints would be that allocations of some
// size might have a 26.6% (1.266x) overhead.
// In practice, only one of the wastes comes into play for a
// given size (sizes < 512 waste mainly on the round-up,
// sizes > 512 waste mainly on the page chopping).
//
// TODO(rsc): Compute max waste for any given size.
#include "runtime.h"
#include "arch.h"
#include "malloc.h"
int32 runtime_class_to_size[_NumSizeClasses];
int32 runtime_class_to_allocnpages[_NumSizeClasses];
// The SizeToClass lookup is implemented using two arrays,
// one mapping sizes <= 1024 to their class and one mapping
// sizes >= 1024 and <= MaxSmallSize to their class.
// All objects are 8-aligned, so the first array is indexed by
// the size divided by 8 (rounded up). Objects >= 1024 bytes
// are 128-aligned, so the second array is indexed by the
// size divided by 128 (rounded up). The arrays are filled in
// by InitSizes.
int8 runtime_size_to_class8[1024/8 + 1];
int8 runtime_size_to_class128[(MaxSmallSize-1024)/128 + 1];
int32
runtime_SizeToClass(int32 size)
{
if(size > MaxSmallSize)
runtime_throw("SizeToClass - invalid size");
if(size > 1024-8)
return runtime_size_to_class128[(size-1024+127) >> 7];
return runtime_size_to_class8[(size+7)>>3];
}
void
runtime_InitSizes(void)
{
int32 align, sizeclass, size, nextsize, n;
uint32 i;
uintptr allocsize, npages;
// Initialize the runtime_class_to_size table (and choose class sizes in the process).
runtime_class_to_size[0] = 0;
sizeclass = 1; // 0 means no class
align = 8;
for(size = align; size <= MaxSmallSize; size += align) {
if((size&(size-1)) == 0) { // bump alignment once in a while
if(size >= 2048)
align = 256;
else if(size >= 128)
align = size / 8;
else if(size >= 16)
align = 16; // required for x86 SSE instructions, if we want to use them
}
if((align&(align-1)) != 0)
runtime_throw("InitSizes - bug");
// Make the allocnpages big enough that
// the leftover is less than 1/8 of the total,
// so wasted space is at most 12.5%.
allocsize = PageSize;
while(allocsize%size > allocsize/8)
allocsize += PageSize;
npages = allocsize >> PageShift;
// If the previous sizeclass chose the same
// allocation size and fit the same number of
// objects into the page, we might as well
// use just this size instead of having two
// different sizes.
if(sizeclass > 1 &&
(int32)npages == runtime_class_to_allocnpages[sizeclass-1] &&
allocsize/size == allocsize/runtime_class_to_size[sizeclass-1]) {
runtime_class_to_size[sizeclass-1] = size;
continue;
}
runtime_class_to_allocnpages[sizeclass] = npages;
runtime_class_to_size[sizeclass] = size;
sizeclass++;
}
if(sizeclass != _NumSizeClasses) {
runtime_printf("sizeclass=%d _NumSizeClasses=%d\n", sizeclass, _NumSizeClasses);
runtime_throw("InitSizes - bad _NumSizeClasses");
}
// Initialize the size_to_class tables.
nextsize = 0;
for (sizeclass = 1; sizeclass < _NumSizeClasses; sizeclass++) {
for(; nextsize < 1024 && nextsize <= runtime_class_to_size[sizeclass]; nextsize+=8)
runtime_size_to_class8[nextsize/8] = sizeclass;
if(nextsize >= 1024)
for(; nextsize <= runtime_class_to_size[sizeclass]; nextsize += 128)
runtime_size_to_class128[(nextsize-1024)/128] = sizeclass;
}
// Double-check SizeToClass.
if(0) {
for(n=0; n < MaxSmallSize; n++) {
sizeclass = runtime_SizeToClass(n);
if(sizeclass < 1 || sizeclass >= _NumSizeClasses || runtime_class_to_size[sizeclass] < n) {
runtime_printf("size=%d sizeclass=%d runtime_class_to_size=%d\n", n, sizeclass, runtime_class_to_size[sizeclass]);
runtime_printf("incorrect SizeToClass");
goto dump;
}
if(sizeclass > 1 && runtime_class_to_size[sizeclass-1] >= n) {
runtime_printf("size=%d sizeclass=%d runtime_class_to_size=%d\n", n, sizeclass, runtime_class_to_size[sizeclass]);
runtime_printf("SizeToClass too big");
goto dump;
}
}
}
// Copy out for statistics table.
for(i=0; i<nelem(runtime_class_to_size); i++)
mstats.by_size[i].size = runtime_class_to_size[i];
return;
dump:
if(1){
runtime_printf("NumSizeClasses=%d\n", _NumSizeClasses);
runtime_printf("runtime_class_to_size:");
for(sizeclass=0; sizeclass<_NumSizeClasses; sizeclass++)
runtime_printf(" %d", runtime_class_to_size[sizeclass]);
runtime_printf("\n\n");
runtime_printf("size_to_class8:");
for(i=0; i<nelem(runtime_size_to_class8); i++)
runtime_printf(" %d=>%d(%d)\n", i*8, runtime_size_to_class8[i],
runtime_class_to_size[runtime_size_to_class8[i]]);
runtime_printf("\n");
runtime_printf("size_to_class128:");
for(i=0; i<nelem(runtime_size_to_class128); i++)
runtime_printf(" %d=>%d(%d)\n", i*128, runtime_size_to_class128[i],
runtime_class_to_size[runtime_size_to_class128[i]]);
runtime_printf("\n");
}
runtime_throw("InitSizes failed");
}
// Returns size of the memory block that mallocgc will allocate if you ask for the size.
uintptr
runtime_roundupsize(uintptr size)
{
if(size < MaxSmallSize) {
if(size <= 1024-8)
return runtime_class_to_size[runtime_size_to_class8[(size+7)>>3]];
else
return runtime_class_to_size[runtime_size_to_class128[(size-1024+127) >> 7]];
}
if(size + PageSize < size)
return size;
return ROUND(size, PageSize);
}