factor/vm/code_heap.cpp

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#include "master.hpp"
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namespace factor
{
code_heap::code_heap(cell size)
{
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if(size > ((u64)1 << (sizeof(cell) * 8 - 6))) fatal_error("Heap too large",size);
seg = new segment(align_page(size),true,false);
if(!seg) fatal_error("Out of memory in code_heap constructor",size);
cell start = seg->start + getpagesize() + seh_area_size;
allocator = new free_list_allocator<code_block>(seg->end - start,start);
/* See os-windows-x86.64.cpp for seh_area usage */
safepoint_page = (void *)seg->start;
seh_area = (char *)seg->start + getpagesize();
}
code_heap::~code_heap()
{
delete allocator;
allocator = NULL;
delete seg;
seg = NULL;
}
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void code_heap::write_barrier(code_block *compiled)
{
points_to_nursery.insert(compiled);
points_to_aging.insert(compiled);
}
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void code_heap::clear_remembered_set()
{
points_to_nursery.clear();
points_to_aging.clear();
}
bool code_heap::uninitialized_p(code_block *compiled)
{
return uninitialized_blocks.count(compiled) > 0;
}
bool code_heap::marked_p(code_block *compiled)
{
return allocator->state.marked_p(compiled);
}
void code_heap::set_marked_p(code_block *compiled)
{
allocator->state.set_marked_p(compiled);
}
void code_heap::clear_mark_bits()
{
allocator->state.clear_mark_bits();
}
void code_heap::free(code_block *compiled)
{
assert(!uninitialized_p(compiled));
points_to_nursery.erase(compiled);
points_to_aging.erase(compiled);
allocator->free(compiled);
}
void code_heap::flush_icache()
{
factor::flush_icache(seg->start,seg->size);
}
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/* Allocate a code heap during startup */
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void factor_vm::init_code_heap(cell size)
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{
code = new code_heap(size);
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}
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bool factor_vm::in_code_heap_p(cell ptr)
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{
return (ptr >= code->seg->start && ptr <= code->seg->end);
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}
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struct word_updater {
factor_vm *parent;
bool reset_inline_caches;
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word_updater(factor_vm *parent_, bool reset_inline_caches_) :
parent(parent_), reset_inline_caches(reset_inline_caches_) {}
void operator()(code_block *compiled, cell size)
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{
parent->update_word_references(compiled,reset_inline_caches);
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}
};
/* Update pointers to words referenced from all code blocks.
Only needed after redefining an existing word.
If generic words were redefined, inline caches need to be reset. */
void factor_vm::update_code_heap_words(bool reset_inline_caches)
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{
word_updater updater(this,reset_inline_caches);
each_code_block(updater);
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}
/* Fix up new words only.
Fast path for compilation units that only define new words. */
void factor_vm::initialize_code_blocks()
{
std::map<code_block *, cell>::const_iterator iter = code->uninitialized_blocks.begin();
std::map<code_block *, cell>::const_iterator end = code->uninitialized_blocks.end();
for(; iter != end; iter++)
initialize_code_block(iter->first,iter->second);
code->uninitialized_blocks.clear();
}
void factor_vm::primitive_modify_code_heap()
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{
bool reset_inline_caches = to_boolean(ctx->pop());
bool update_existing_words = to_boolean(ctx->pop());
data_root<array> alist(ctx->pop(),this);
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cell count = array_capacity(alist.untagged());
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if(count == 0)
return;
for(cell i = 0; i < count; i++)
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{
data_root<array> pair(array_nth(alist.untagged(),i),this);
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data_root<word> word(array_nth(pair.untagged(),0),this);
data_root<object> data(array_nth(pair.untagged(),1),this);
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switch(data.type())
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{
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case QUOTATION_TYPE:
jit_compile_word(word.value(),data.value(),false);
break;
case ARRAY_TYPE:
{
array *compiled_data = data.as<array>().untagged();
cell parameters = array_nth(compiled_data,0);
cell literals = array_nth(compiled_data,1);
cell relocation = array_nth(compiled_data,2);
cell labels = array_nth(compiled_data,3);
cell code = array_nth(compiled_data,4);
code_block *compiled = add_code_block(
code_block_optimized,
code,
labels,
word.value(),
relocation,
parameters,
literals);
word->code = compiled;
}
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break;
default:
critical_error("Expected a quotation or an array",data.value());
break;
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}
update_word_entry_point(word.untagged());
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}
if(update_existing_words)
update_code_heap_words(reset_inline_caches);
else
initialize_code_blocks();
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}
code_heap_room factor_vm::code_room()
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{
code_heap_room room;
room.size = code->allocator->size;
room.occupied_space = code->allocator->occupied_space();
room.total_free = code->allocator->free_space();
room.contiguous_free = code->allocator->largest_free_block();
room.free_block_count = code->allocator->free_block_count();
return room;
}
void factor_vm::primitive_code_room()
{
code_heap_room room = code_room();
ctx->push(tag<byte_array>(byte_array_from_value(&room)));
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}
struct stack_trace_stripper {
explicit stack_trace_stripper() {}
void operator()(code_block *compiled, cell size)
{
compiled->owner = false_object;
}
};
void factor_vm::primitive_strip_stack_traces()
{
stack_trace_stripper stripper;
each_code_block(stripper);
}
struct code_block_accumulator {
std::vector<cell> objects;
void operator()(code_block *compiled, cell size)
{
objects.push_back(compiled->owner);
objects.push_back(compiled->parameters);
objects.push_back(compiled->relocation);
objects.push_back(tag_fixnum(compiled->type()));
objects.push_back(tag_fixnum(compiled->size()));
/* Note: the entry point is always a multiple of the heap
alignment (16 bytes). We cannot allocate while iterating
through the code heap, so it is not possible to call
from_unsigned_cell() here. It is OK, however, to add it as
if it were a fixnum, and have library code shift it to the
left by 4. */
cell entry_point = (cell)compiled->entry_point();
assert((entry_point & (data_alignment - 1)) == 0);
assert((entry_point & TAG_MASK) == FIXNUM_TYPE);
objects.push_back(entry_point);
}
};
cell factor_vm::code_blocks()
{
code_block_accumulator accum;
each_code_block(accum);
return std_vector_to_array(accum.objects);
}
void factor_vm::primitive_code_blocks()
{
ctx->push(code_blocks());
}
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}