#include "master.hpp" namespace factor { callback_heap::callback_heap(cell size, factor_vm* parent) { seg = new segment(size, true); if (!seg) fatal_error("Out of memory in callback_heap constructor", size); allocator = new free_list_allocator(size, seg->start); this->parent = parent; } callback_heap::~callback_heap() { delete allocator; allocator = NULL; delete seg; seg = NULL; } void factor_vm::init_callbacks(cell size) { callbacks = new callback_heap(size, this); } bool callback_heap::setup_seh_p() { #if defined(WINDOWS) && defined(FACTOR_X86) return true; #else return false; #endif } bool callback_heap::return_takes_param_p() { #if defined(FACTOR_X86) || defined(FACTOR_AMD64) return true; #else return false; #endif } instruction_operand callback_heap::callback_operand(code_block* stub, cell index) { tagged code_template(parent->special_objects[CALLBACK_STUB]); tagged relocation_template( array_nth(code_template.untagged(), 0)); relocation_entry entry(relocation_template->data()[index]); return instruction_operand(entry, stub, 0); } void callback_heap::store_callback_operand(code_block* stub, cell index) { parent->store_external_address(callback_operand(stub, index)); } void callback_heap::store_callback_operand(code_block* stub, cell index, cell value) { callback_operand(stub, index).store_value(value); } void callback_heap::update(code_block* stub) { store_callback_operand(stub, setup_seh_p() ? 2 : 1, (cell)callback_entry_point(stub)); stub->flush_icache(); } code_block* callback_heap::add(cell owner, cell return_rewind) { tagged code_template(parent->special_objects[CALLBACK_STUB]); tagged insns(array_nth(code_template.untagged(), 1)); cell size = array_capacity(insns.untagged()); cell bump = align(size + sizeof(code_block), data_alignment); code_block* stub = allocator->allot(bump); if (!stub) { parent->general_error(ERROR_CALLBACK_SPACE_OVERFLOW, false_object, false_object); } stub->header = bump & ~7; stub->owner = owner; stub->parameters = false_object; stub->relocation = false_object; memcpy(stub->entry_point(), insns->data(), size); /* Store VM pointer */ store_callback_operand(stub, 0, (cell)parent); cell index; if (setup_seh_p()) { store_callback_operand(stub, 1); index = 1; } else index = 0; /* Store VM pointer */ store_callback_operand(stub, index + 2, (cell) parent); /* On x86, the RET instruction takes an argument which depends on the callback's calling convention */ if (return_takes_param_p()) store_callback_operand(stub, index + 3, return_rewind); update(stub); return stub; } struct callback_updater { callback_heap* callbacks; explicit callback_updater(callback_heap* callbacks) : callbacks(callbacks) {} void operator()(code_block* stub, cell size) { callbacks->update(stub); } }; void callback_heap::update() { callback_updater updater(this); allocator->iterate(updater); } /* Allocates memory */ void factor_vm::primitive_callback() { cell return_rewind = to_cell(ctx->pop()); tagged w(ctx->pop()); w.untag_check(this); void* func = callbacks->add(w.value(), return_rewind)->entry_point(); CODE_TO_FUNCTION_POINTER_CALLBACK(this, func); ctx->push(allot_alien(func)); } void factor_vm::primitive_free_callback() { void* entry_point = alien_offset(ctx->pop()); code_block* stub = (code_block*)entry_point - 1; callbacks->allocator->free(stub); } /* Allocates memory */ void factor_vm::primitive_callback_room() { allocator_room room = callbacks->allocator->as_allocator_room(); ctx->push(tag(byte_array_from_value(&room))); } }