factor/vm/entry_points.cpp

#include "master.hpp"

namespace factor {

void factor_vm::c_to_factor(cell quot) {
  // First time this is called, wrap the c-to-factor sub-primitive inside
  // of a callback stub, which saves and restores non-volatile registers
  // per platform ABI conventions, so that the Factor compiler can treat
  // all registers as volatile
  if (!c_to_factor_func) {
    tagged<word> c_to_factor_word(special_objects[C_TO_FACTOR_WORD]);
    code_block* c_to_factor_block = callbacks->add(c_to_factor_word.value(), 0);
    cell func = c_to_factor_block->entry_point();
    CODE_TO_FUNCTION_POINTER_CALLBACK(this, func);
    c_to_factor_func = (c_to_factor_func_type) func;
  }
  c_to_factor_func(quot);
}

void factor_vm::unwind_native_frames(cell quot, cell to) {
  tagged<word> entry_point_word(special_objects[UNWIND_NATIVE_FRAMES_WORD]);
  cell func = entry_point_word->entry_point;
  CODE_TO_FUNCTION_POINTER(func);
  ((unwind_native_frames_func_type) func)(quot, to);
}

cell factor_vm::get_fpu_state() {
  tagged<word> entry_point_word(special_objects[GET_FPU_STATE_WORD]);
  cell func = entry_point_word->entry_point;
  CODE_TO_FUNCTION_POINTER(func);
  return ((get_fpu_state_func_type) func)();
}

void factor_vm::set_fpu_state(cell state) {
  tagged<word> entry_point_word(special_objects[SET_FPU_STATE_WORD]);
  cell func = entry_point_word->entry_point;
  CODE_TO_FUNCTION_POINTER(func);
  ((set_fpu_state_func_type) func)(state);
}

}
vm: move c_to_factor, lazy_jit_compile_impl, throw_impl, set_callstack assembly routines into non-optimizing compiler for x86-64 2010-01-05 21:47:36 -05:00			`#include "master.hpp"`

VM: Refactor entry_points to Factor style 2013-05-11 21:58:23 -04:00			`namespace factor {`
vm: move c_to_factor, lazy_jit_compile_impl, throw_impl, set_callstack assembly routines into non-optimizing compiler for x86-64 2010-01-05 21:47:36 -05:00
VM: Refactor entry_points to Factor style 2013-05-11 21:58:23 -04:00			`void factor_vm::c_to_factor(cell quot) {`
vm: replace block comments /**/ with line comments // 2016-08-21 10:26:04 -04:00			`// First time this is called, wrap the c-to-factor sub-primitive inside`
			`// of a callback stub, which saves and restores non-volatile registers`
			`// per platform ABI conventions, so that the Factor compiler can treat`
			`// all registers as volatile`
VM: Refactor entry_points to Factor style 2013-05-11 21:58:23 -04:00			`if (!c_to_factor_func) {`
			`tagged<word> c_to_factor_word(special_objects[C_TO_FACTOR_WORD]);`
			`code_block* c_to_factor_block = callbacks->add(c_to_factor_word.value(), 0);`
VM: change the definition of entry_point in word and quotation from void* to cell this gets rid of lots of redundant casts from void* to cell 2015-01-07 05:51:19 -05:00			`cell func = c_to_factor_block->entry_point();`
VM: Refactor entry_points to Factor style 2013-05-11 21:58:23 -04:00			`CODE_TO_FUNCTION_POINTER_CALLBACK(this, func);`
			`c_to_factor_func = (c_to_factor_func_type) func;`
			`}`
			`c_to_factor_func(quot);`
vm: move c_to_factor, lazy_jit_compile_impl, throw_impl, set_callstack assembly routines into non-optimizing compiler for x86-64 2010-01-05 21:47:36 -05:00			`}`

VM: change type of callstack_top and callstack_bottom from void* to cell cell and void* is always the same size, but now you can remove lots of redundant type casts from void* to cell. 2015-01-05 06:59:54 -05:00			`void factor_vm::unwind_native_frames(cell quot, cell to) {`
VM: Refactor entry_points to Factor style 2013-05-11 21:58:23 -04:00			`tagged<word> entry_point_word(special_objects[UNWIND_NATIVE_FRAMES_WORD]);`
VM: change the definition of entry_point in word and quotation from void* to cell this gets rid of lots of redundant casts from void* to cell 2015-01-07 05:51:19 -05:00			`cell func = entry_point_word->entry_point;`
VM: Refactor entry_points to Factor style 2013-05-11 21:58:23 -04:00			`CODE_TO_FUNCTION_POINTER(func);`
			`((unwind_native_frames_func_type) func)(quot, to);`
Update x86-32 for assembly entry point changes 2010-01-05 23:55:20 -05:00			`}`

VM: Refactor entry_points to Factor style 2013-05-11 21:58:23 -04:00			`cell factor_vm::get_fpu_state() {`
			`tagged<word> entry_point_word(special_objects[GET_FPU_STATE_WORD]);`
VM: change the definition of entry_point in word and quotation from void* to cell this gets rid of lots of redundant casts from void* to cell 2015-01-07 05:51:19 -05:00			`cell func = entry_point_word->entry_point;`
VM: Refactor entry_points to Factor style 2013-05-11 21:58:23 -04:00			`CODE_TO_FUNCTION_POINTER(func);`
			`return ((get_fpu_state_func_type) func)();`
Fix three problems discovered by running math.floats.env tests in a loop: - Crash if allocating error triggers a GC from a signal/SEH handler - Crash if GC runs with floating point traps enabled on Windows - Floating point traps didn't prettyprint properly 2010-09-01 23:46:39 -04:00			`}`

VM: Refactor entry_points to Factor style 2013-05-11 21:58:23 -04:00			`void factor_vm::set_fpu_state(cell state) {`
			`tagged<word> entry_point_word(special_objects[SET_FPU_STATE_WORD]);`
VM: change the definition of entry_point in word and quotation from void* to cell this gets rid of lots of redundant casts from void* to cell 2015-01-07 05:51:19 -05:00			`cell func = entry_point_word->entry_point;`
VM: Refactor entry_points to Factor style 2013-05-11 21:58:23 -04:00			`CODE_TO_FUNCTION_POINTER(func);`
			`((set_fpu_state_func_type) func)(state);`
Fix three problems discovered by running math.floats.env tests in a loop: - Crash if allocating error triggers a GC from a signal/SEH handler - Crash if GC runs with floating point traps enabled on Windows - Floating point traps didn't prettyprint properly 2010-09-01 23:46:39 -04:00			`}`

vm: move c_to_factor, lazy_jit_compile_impl, throw_impl, set_callstack assembly routines into non-optimizing compiler for x86-64 2010-01-05 21:47:36 -05:00			`}`