mirror/guile
mirror/guile
1
Fork 0
mirror of https://git.savannah.gnu.org/git/guile.git synced 2025-04-30 03:40:34 +02:00
Code Activity
guile/libguile/stacks.c
Andy Wingo 53e28ed9b2 static opcodes; refactor program/objcode division; use new assembly pipeline 
* gdbinit: Untested attempts to get the stack fondling macros to deal
  with the new program representation.

* libguile/frames.c (scm_vm_frame_arguments, scm_vm_frame_source)
  (scm_vm_frame_local_ref, scm_vm_frame_local_set_x): SCM_PROGRAM_DATA is
  a struct scm_objcode*.

* libguile/instructions.h:
* libguile/instructions.c: Hide the instruction table and the struct
  scm_instruction structure; all access to instructions now goes through
  procedures. This is because instructions are no longer in a packed
  array indexed by opcode. Also, declare a mask that all instructions
  should fit in.

* libguile/objcodes.h:
* libguile/objcodes.c: Rewrite so that object code directly maps its
  arity and length from its bytecode. This makes it unnecessary to keep
  this information in programs, allowing programs to be simple conses
  between the code (objcodes) and data (the object table and the closure
  variables).

* libguile/programs.c (scm_make_program): Rework so that make-program
  takes objcode, an object table, and externals as arguments. It's much
  clearer this way, and we avoid malloc().

* libguile/stacks.c (is_vm_bootstrap_frame): Update for program/objcode
  changes.

* libguile/vm-engine.c (vm_run): Initialize the jump table on the first
  run, with the opcodes declared in the instruction sources, and with bad
  instructions raising an error instead of wandering off into the
  Unknown.

* libguile/vm-engine.h (FETCH_LENGTH): Always represent lengths as 3
  bytes. The old code was too error-prone.
  (NEXT_JUMP): Mask the instruction with SCM_VM_INSTRUCTION_MASK.
  (NEW_FRAME): Update for program/objcode changes.

* libguile/vm-expand.h (VM_DEFINE_FUNCTION, VM_DEFINE_INSTRUCTION)
  (VM_DEFINE_LOADER): Update so that we explicitly specify opcodes, so
  that we have a stable bytecode API.

* libguile/vm-i-loader.c: Update license to LGPLv2+. Explicitly declare
  opcodes.
  (load-integer): Use an int instead of a long as the accumulator; still
  need to revisit this code at some point, I think.
  (load-program): Simplify, thankfully!! Just creates the objcode slice
  and rolls with it.

* libguile/vm-i-scheme.c: Number the opcodes explicitly.

* libguile/vm-i-system.c: Update license to LGPLv2+. Explicitly declare
  opcodes.
  (make-closure): Update for new program API.

* libguile/vm.c (vm_make_boot_program): Update for new program/objcode
  API. Still a bit ugly.
  (scm_load_compiled_with_vm): Update for new program/objcode API.

* module/language/assembly.scm (byte-length): Fix byte-length calculation
  for loaders, and load-program.
  (code-pack, code-unpack): Start to move things from (system vm conv)
  here.
  (object->code, code->object): More things from conv.scm.

* module/language/glil.scm (<glil-program>): Add a new field,
  closure-level.
  (make-glil-program, compute-closure-level): Calculate the "closure
  level" when making a glil program. This is the maximum depth of
  external binding refs in this closure.
  (unparse-glil): Fix label serialization.

* module/language/glil/compile-assembly.scm (make-meta): Prepend #f for
  the meta's object table, though maybe in the future we can avoid
  creating assembly in the first place.
  (assoc-ref-or-acons, object-index-and-alist): GRRR! Caught again by the
  different sets of arguments to assoc and assoc-ref!
  (glil->assembly): Attempt to make the <glil-program> case more
  readable, and fix the bugs. Sorry I don't know how to comment this
  change any more than this.
  (glil->assembly): For <glil-module> serialize the whole key, not just
  the name.
  (dump-object): subprogram-code is already a list. Serialize integers as
  strings, not u8vectors. Fix the order of lists and vectors.

* module/language/glil/spec.scm (glil): Switch orders, so we prefer glil
  -> assembly -> objcode. Actually glil->objcode doesn't work any more,
  needs to be removed I think.

* module/language/objcode/spec.scm (objcode->value):
  s/objcode->program/make-program/.

* module/language/scheme/inline.scm: Add acons inline.

* module/system/vm/conv.scm (make-byte-decoder): Skip the first 8 bytes,
  they are header. Handle subprograms properly. Still needs help though.
  (decode-length): Lengths are always 3 bytes now.

* module/system/vm/disasm.scm: Superficial changes to keep things
  working. I'd like to fix this better in the future.

* module/system/vm/frame.scm (bootstrap-frame?): Fixes for
  program-bytecode.

* module/system/vm/program.scm: Export make-program. It's program-objcode
  now, no more program-bytecode.

* module/system/vm/vm.scm (vm-load): Use make-program.

* test-suite/tests/asm-to-bytecode.test: New test, very minimal.

* module/system/vm/objcode.scm: Export word-size, byte-order, and
  write-objcode.
2009-01-29 21:12:00 +01:00

832 lines
25 KiB
C
Raw Blame History

This file contains invisible Unicode characters

This file contains invisible Unicode characters that are indistinguishable to humans but may be processed differently by a computer. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

/* Representation of stack frame debug information
* Copyright (C) 1996,1997,2000,2001, 2006, 2007, 2008 Free Software Foundation
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
*/
#ifdef HAVE_CONFIG_H
# include <config.h>
#endif
#include "libguile/_scm.h"
#include "libguile/eval.h"
#include "libguile/debug.h"
#include "libguile/continuations.h"
#include "libguile/struct.h"
#include "libguile/macros.h"
#include "libguile/procprop.h"
#include "libguile/modules.h"
#include "libguile/root.h"
#include "libguile/strings.h"
#include "libguile/vm.h" /* to capture vm stacks */
#include "libguile/frames.h" /* vm frames */
#include "libguile/instructions.h" /* scm_op_halt */
#include "libguile/validate.h"
#include "libguile/stacks.h"
#include "libguile/private-options.h"
/* {Frames and stacks}
*
* The debugging evaluator creates debug frames on the stack. These
* are linked from the innermost frame and outwards. The last frame
* created can always be accessed as SCM_LAST_DEBUG_FRAME.
* Continuations contain a pointer to the innermost debug frame on the
* continuation stack.
*
* Each debug frame contains a set of flags and information about one
* or more stack frames. The case of multiple frames occurs due to
* tail recursion. The maximal number of stack frames which can be
* recorded in one debug frame can be set dynamically with the debug
* option FRAMES.
*
* Stack frame information is of two types: eval information (the
* expression being evaluated and its environment) and apply
* information (the procedure being applied and its arguments). A
* stack frame normally corresponds to an eval/apply pair, but macros
* and special forms (which are implemented as macros in Guile) only
* have eval information and apply calls leads to apply only frames.
*
* Since we want to record the total stack information and later
* manipulate this data at the scheme level in the debugger, we need
* to transform it into a new representation. In the following code
* section you'll find the functions implementing this data type.
*
* Representation:
*
* The stack is represented as a struct with an id slot and a tail
* array of scm_t_info_frame structs.
*
* A frame is represented as a pair where the car contains a stack and
* the cdr an inum. The inum is an index to the first SCM value of
* the scm_t_info_frame struct.
*
* Stacks
* Constructor
* make-stack
* Selectors
* stack-id
* stack-ref
* Inspector
* stack-length
*
* Frames
* Constructor
* last-stack-frame
* Selectors
* frame-number
* frame-source
* frame-procedure
* frame-arguments
* frame-previous
* frame-next
* Predicates
* frame-real?
* frame-procedure?
* frame-evaluating-args?
* frame-overflow? */
/* Some auxiliary functions for reading debug frames off the stack.
*/
/* Stacks often contain pointers to other items on the stack; for
example, each scm_t_debug_frame structure contains a pointer to the
next frame out. When we capture a continuation, we copy the stack
into the heap, and just leave all the pointers unchanged. This
makes it simple to restore the continuation --- just copy the stack
back! However, if we retrieve a pointer from the heap copy to
another item that was originally on the stack, we have to add an
offset to the pointer to discover the new referent.
If PTR is a pointer retrieved from a continuation, whose original
target was on the stack, and OFFSET is the appropriate offset from
the original stack to the continuation, then RELOC_MUMBLE (PTR,
OFFSET) is a pointer to the copy in the continuation of the
original referent, cast to an scm_debug_MUMBLE *. */
#define RELOC_INFO(ptr, offset) \
((scm_t_debug_info *) ((SCM_STACKITEM *) (ptr) + (offset)))
#define RELOC_FRAME(ptr, offset) \
((scm_t_debug_frame *) ((SCM_STACKITEM *) (ptr) + (offset)))
/* FIXME: factor this out somewhere? */
static int is_vm_bootstrap_frame (SCM f)
{
struct scm_objcode *bp = SCM_PROGRAM_DATA (scm_vm_frame_program (f));
return bp->base[bp->len-1] == scm_op_halt;
}
/* Count number of debug info frames on a stack, beginning with
* DFRAME. OFFSET is used for relocation of pointers when the stack
* is read from a continuation.
*/
static long
stack_depth (scm_t_debug_frame *dframe, scm_t_ptrdiff offset, SCM vmframe,
SCM *id)
{
long n;
for (n = 0;
dframe && !SCM_VOIDFRAMEP (*dframe);
dframe = RELOC_FRAME (dframe->prev, offset))
{
if (SCM_EVALFRAMEP (*dframe))
{
scm_t_debug_info *info = RELOC_INFO (dframe->info, offset);
scm_t_debug_info *vect = RELOC_INFO (dframe->vect, offset);
n += (info - vect) / 2 + 1;
/* Data in the apply part of an eval info frame comes from previous
stack frame if the scm_t_debug_info vector is overflowed. */
if ((((info - vect) & 1) == 0)
&& SCM_OVERFLOWP (*dframe)
&& !SCM_UNBNDP (info[1].a.proc))
++n;
}
else if (SCM_APPLYFRAMEP (*dframe))
{
scm_t_debug_info *vect = RELOC_INFO (dframe->vect, offset);
if (SCM_PROGRAM_P (vect[0].a.proc))
{
/* count vmframe back to previous bootstrap frame */
for (; scm_is_true (vmframe); vmframe = scm_c_vm_frame_prev (vmframe))
{
if (is_vm_bootstrap_frame (vmframe))
{ /* skip bootstrap frame, cut out of the vm backtrace */
vmframe = scm_c_vm_frame_prev (vmframe);
break;
}
else
++n;
}
}
++n; /* increment for apply frame in any case */
}
else
++n;
}
if (dframe && SCM_VOIDFRAMEP (*dframe))
*id = RELOC_INFO(dframe->vect, offset)[0].id;
return n;
}
/* Read debug info from DFRAME into IFRAME.
*/
static void
read_frame (scm_t_debug_frame *dframe, scm_t_ptrdiff offset,
scm_t_info_frame *iframe)
{
scm_t_bits flags = SCM_UNPACK (SCM_INUM0); /* UGh. */
if (SCM_EVALFRAMEP (*dframe))
{
scm_t_debug_info *info = RELOC_INFO (dframe->info, offset);
scm_t_debug_info *vect = RELOC_INFO (dframe->vect, offset);
if ((info - vect) & 1)
{
/* Debug.vect ends with apply info. */
--info;
if (!SCM_UNBNDP (info[1].a.proc))
{
flags |= SCM_FRAMEF_PROC;
iframe->proc = info[1].a.proc;
iframe->args = info[1].a.args;
if (!SCM_ARGS_READY_P (*dframe))
flags |= SCM_FRAMEF_EVAL_ARGS;
}
}
iframe->source = scm_make_memoized (info[0].e.exp, info[0].e.env);
}
else
{
scm_t_debug_info *vect = RELOC_INFO (dframe->vect, offset);
flags |= SCM_FRAMEF_PROC;
iframe->proc = vect[0].a.proc;
iframe->args = vect[0].a.args;
}
iframe->flags = flags;
}
/* Look up the first body form of the apply closure. We'll use this
below to prevent it from being displayed.
*/
static SCM
get_applybody ()
{
SCM var = scm_sym2var (scm_sym_apply, SCM_BOOL_F, SCM_BOOL_F);
if (SCM_VARIABLEP (var) && SCM_CLOSUREP (SCM_VARIABLE_REF (var)))
return SCM_CAR (SCM_CLOSURE_BODY (SCM_VARIABLE_REF (var)));
else
return SCM_UNDEFINED;
}
#define NEXT_FRAME(iframe, n, quit) \
do { \
if (SCM_MEMOIZEDP (iframe->source) \
&& scm_is_eq (SCM_MEMOIZED_EXP (iframe->source), applybody)) \
{ \
iframe->source = SCM_BOOL_F; \
if (scm_is_false (iframe->proc)) \
{ \
--iframe; \
++n; \
} \
} \
++iframe; \
if (--n == 0) \
goto quit; \
} while (0)
/* Fill the scm_t_info_frame vector IFRAME with data from N stack frames
* starting with the first stack frame represented by debug frame
* DFRAME.
*/
static scm_t_bits
read_frames (scm_t_debug_frame *dframe, scm_t_ptrdiff offset,
SCM vmframe, long n, scm_t_info_frame *iframes)
{
scm_t_info_frame *iframe = iframes;
scm_t_debug_info *info, *vect;
static SCM applybody = SCM_UNDEFINED;
/* The value of applybody has to be setup after r4rs.scm has executed. */
if (SCM_UNBNDP (applybody))
applybody = get_applybody ();
for (;
dframe && !SCM_VOIDFRAMEP (*dframe) && n > 0;
dframe = RELOC_FRAME (dframe->prev, offset))
{
read_frame (dframe, offset, iframe);
if (SCM_EVALFRAMEP (*dframe))
{
/* If current frame is a macro during expansion, we should
skip the previously recorded macro transformer
application frame. */
if (SCM_MACROEXPP (*dframe) && iframe > iframes)
{
*(iframe - 1) = *iframe;
--iframe;
}
info = RELOC_INFO (dframe->info, offset);
vect = RELOC_INFO (dframe->vect, offset);
if ((info - vect) & 1)
--info;
/* Data in the apply part of an eval info frame comes from
previous stack frame if the scm_t_debug_info vector is
overflowed. */
else if (SCM_OVERFLOWP (*dframe)
&& !SCM_UNBNDP (info[1].a.proc))
{
NEXT_FRAME (iframe, n, quit);
iframe->flags = SCM_UNPACK(SCM_INUM0) | SCM_FRAMEF_PROC;
iframe->proc = info[1].a.proc;
iframe->args = info[1].a.args;
}
if (SCM_OVERFLOWP (*dframe))
iframe->flags |= SCM_FRAMEF_OVERFLOW;
info -= 2;
NEXT_FRAME (iframe, n, quit);
while (info >= vect)
{
if (!SCM_UNBNDP (info[1].a.proc))
{
iframe->flags = SCM_UNPACK(SCM_INUM0) | SCM_FRAMEF_PROC;
iframe->proc = info[1].a.proc;
iframe->args = info[1].a.args;
}
else
iframe->flags = SCM_UNPACK (SCM_INUM0);
iframe->source = scm_make_memoized (info[0].e.exp,
info[0].e.env);
info -= 2;
NEXT_FRAME (iframe, n, quit);
}
}
else if (scm_is_eq (iframe->proc, scm_f_gsubr_apply))
/* Skip gsubr apply frames. */
continue;
else
{
if (SCM_PROGRAM_P (iframe->proc))
{
scm_t_info_frame saved = *iframe;
for (; scm_is_true (vmframe);
vmframe = scm_c_vm_frame_prev (vmframe))
{
if (is_vm_bootstrap_frame (vmframe))
{ /* skip bootstrap frame, back to interpreted frames */
vmframe = scm_c_vm_frame_prev (vmframe);
break;
}
else
{
/* Oh dear, oh dear, oh dear. */
iframe->flags = SCM_UNPACK (SCM_INUM0) | SCM_FRAMEF_PROC;
iframe->source = scm_vm_frame_source (vmframe);
iframe->proc = scm_vm_frame_program (vmframe);
iframe->args = scm_vm_frame_arguments (vmframe);
++iframe;
if (--n == 0)
goto quit;
}
}
*iframe = saved;
}
NEXT_FRAME (iframe, n, quit);
}
quit:
if (iframe > iframes)
(iframe - 1) -> flags |= SCM_FRAMEF_REAL;
}
return iframe - iframes; /* Number of frames actually read */
}
/* Narrow STACK by cutting away stackframes (mutatingly).
*
* Inner frames (most recent) are cut by advancing the frames pointer.
* Outer frames are cut by decreasing the recorded length.
*
* Cut maximally INNER inner frames and OUTER outer frames using
* the keys INNER_KEY and OUTER_KEY.
*
* Frames are cut away starting at the end points and moving towards
* the center of the stack. The key is normally compared to the
* operator in application frames. Frames up to and including the key
* are cut.
*
* If INNER_KEY is #t a different scheme is used for inner frames:
*
* Frames up to but excluding the first source frame originating from
* a user module are cut, except for possible application frames
* between the user frame and the last system frame previously
* encountered.
*/
static void
narrow_stack (SCM stack, long inner, SCM inner_key, long outer, SCM outer_key)
{
scm_t_stack *s = SCM_STACK (stack);
unsigned long int i;
long n = s->length;
/* Cut inner part. */
if (scm_is_eq (inner_key, SCM_BOOL_T))
{
/* Cut all frames up to user module code */
for (i = 0; inner; ++i, --inner)
{
SCM m = s->frames[i].source;
if (SCM_MEMOIZEDP (m)
&& !SCM_IMP (SCM_MEMOIZED_ENV (m))
&& scm_is_false (scm_system_module_env_p (SCM_MEMOIZED_ENV (m))))
{
/* Back up in order to include any non-source frames */
while (i > 0)
{
m = s->frames[i - 1].source;
if (SCM_MEMOIZEDP (m))
break;
m = s->frames[i - 1].proc;
if (scm_is_true (scm_procedure_p (m))
&& scm_is_true (scm_procedure_property
(m, scm_sym_system_procedure)))
break;
--i;
++inner;
}
break;
}
}
}
else
/* Use standard cutting procedure. */
{
for (i = 0; inner; --inner)
if (scm_is_eq (s->frames[i++].proc, inner_key))
break;
}
s->frames = &s->frames[i];
n -= i;
/* Cut outer part. */
for (; n && outer; --outer)
if (scm_is_eq (s->frames[--n].proc, outer_key))
break;
s->length = n;
}
/* Stacks
*/
SCM scm_stack_type;
SCM_DEFINE (scm_stack_p, "stack?", 1, 0, 0,
(SCM obj),
"Return @code{#t} if @var{obj} is a calling stack.")
#define FUNC_NAME s_scm_stack_p
{
return scm_from_bool(SCM_STACKP (obj));
}
#undef FUNC_NAME
SCM_DEFINE (scm_make_stack, "make-stack", 1, 0, 1,
(SCM obj, SCM args),
"Create a new stack. If @var{obj} is @code{#t}, the current\n"
"evaluation stack is used for creating the stack frames,\n"
"otherwise the frames are taken from @var{obj} (which must be\n"
"either a debug object or a continuation).\n\n"
"@var{args} should be a list containing any combination of\n"
"integer, procedure and @code{#t} values.\n\n"
"These values specify various ways of cutting away uninteresting\n"
"stack frames from the top and bottom of the stack that\n"
"@code{make-stack} returns. They come in pairs like this:\n"
"@code{(@var{inner_cut_1} @var{outer_cut_1} @var{inner_cut_2}\n"
"@var{outer_cut_2} @dots{})}.\n\n"
"Each @var{inner_cut_N} can be @code{#t}, an integer, or a\n"
"procedure. @code{#t} means to cut away all frames up to but\n"
"excluding the first user module frame. An integer means to cut\n"
"away exactly that number of frames. A procedure means to cut\n"
"away all frames up to but excluding the application frame whose\n"
"procedure matches the specified one.\n\n"
"Each @var{outer_cut_N} can be an integer or a procedure. An\n"
"integer means to cut away that number of frames. A procedure\n"
"means to cut away frames down to but excluding the application\n"
"frame whose procedure matches the specified one.\n\n"
"If the @var{outer_cut_N} of the last pair is missing, it is\n"
"taken as 0.")
#define FUNC_NAME s_scm_make_stack
{
long n, size;
int maxp;
scm_t_debug_frame *dframe;
scm_t_info_frame *iframe;
SCM vmframe;
long offset = 0;
SCM stack, id;
SCM inner_cut, outer_cut;
/* Extract a pointer to the innermost frame of whatever object
scm_make_stack was given. */
if (scm_is_eq (obj, SCM_BOOL_T))
{
struct scm_vm *vp = SCM_VM_DATA (scm_the_vm ());
dframe = scm_i_last_debug_frame ();
vmframe = scm_c_make_vm_frame (scm_the_vm (), vp->fp, vp->sp, vp->ip, 0);
}
else if (SCM_DEBUGOBJP (obj))
{
dframe = SCM_DEBUGOBJ_FRAME (obj);
vmframe = SCM_BOOL_F;
}
else if (SCM_VM_FRAME_P (obj))
{
dframe = NULL;
vmframe = obj;
}
else if (SCM_CONTINUATIONP (obj))
{
scm_t_contregs *cont = SCM_CONTREGS (obj);
offset = cont->offset;
dframe = RELOC_FRAME (cont->dframe, offset);
if (!scm_is_null (cont->vm_conts))
{ SCM vm_cont;
struct scm_vm_cont *data;
vm_cont = scm_cdr (scm_car (cont->vm_conts));
data = SCM_VM_CONT_DATA (vm_cont);
vmframe = scm_c_make_vm_frame (vm_cont,
data->fp + data->reloc,
data->sp + data->reloc,
data->ip,
data->reloc);
} else
vmframe = SCM_BOOL_F;
}
else
{
SCM_WRONG_TYPE_ARG (SCM_ARG1, obj);
/* not reached */
}
/* Count number of frames. Also get stack id tag and check whether
there are more stackframes than we want to record
(SCM_BACKTRACE_MAXDEPTH). */
id = SCM_BOOL_F;
maxp = 0;
n = stack_depth (dframe, offset, vmframe, &id);
/* FIXME: redo maxp? */
size = n * SCM_FRAME_N_SLOTS;
/* Make the stack object. */
stack = scm_make_struct (scm_stack_type, scm_from_long (size), SCM_EOL);
SCM_STACK (stack) -> id = id;
iframe = &SCM_STACK (stack) -> tail[0];
SCM_STACK (stack) -> frames = iframe;
/* Translate the current chain of stack frames into debugging information. */
n = read_frames (dframe, offset, vmframe, n, iframe);
SCM_STACK (stack) -> length = n;
/* Narrow the stack according to the arguments given to scm_make_stack. */
SCM_VALIDATE_REST_ARGUMENT (args);
while (n > 0 && !scm_is_null (args))
{
inner_cut = SCM_CAR (args);
args = SCM_CDR (args);
if (scm_is_null (args))
{
outer_cut = SCM_INUM0;
}
else
{
outer_cut = SCM_CAR (args);
args = SCM_CDR (args);
}
narrow_stack (stack,
scm_is_integer (inner_cut) ? scm_to_int (inner_cut) : n,
scm_is_integer (inner_cut) ? 0 : inner_cut,
scm_is_integer (outer_cut) ? scm_to_int (outer_cut) : n,
scm_is_integer (outer_cut) ? 0 : outer_cut);
n = SCM_STACK (stack) -> length;
}
if (n > 0 && maxp)
iframe[n - 1].flags |= SCM_FRAMEF_OVERFLOW;
if (n > 0)
return stack;
else
return SCM_BOOL_F;
}
#undef FUNC_NAME
SCM_DEFINE (scm_stack_id, "stack-id", 1, 0, 0,
(SCM stack),
"Return the identifier given to @var{stack} by @code{start-stack}.")
#define FUNC_NAME s_scm_stack_id
{
scm_t_debug_frame *dframe;
long offset = 0;
if (scm_is_eq (stack, SCM_BOOL_T))
{
dframe = scm_i_last_debug_frame ();
}
else if (SCM_DEBUGOBJP (stack))
{
dframe = SCM_DEBUGOBJ_FRAME (stack);
}
else if (SCM_CONTINUATIONP (stack))
{
scm_t_contregs *cont = SCM_CONTREGS (stack);
offset = cont->offset;
dframe = RELOC_FRAME (cont->dframe, offset);
}
else if (SCM_STACKP (stack))
{
return SCM_STACK (stack) -> id;
}
else
{
SCM_WRONG_TYPE_ARG (1, stack);
}
while (dframe && !SCM_VOIDFRAMEP (*dframe))
dframe = RELOC_FRAME (dframe->prev, offset);
if (dframe && SCM_VOIDFRAMEP (*dframe))
return RELOC_INFO (dframe->vect, offset)[0].id;
return SCM_BOOL_F;
}
#undef FUNC_NAME
SCM_DEFINE (scm_stack_ref, "stack-ref", 2, 0, 0,
(SCM stack, SCM index),
"Return the @var{index}'th frame from @var{stack}.")
#define FUNC_NAME s_scm_stack_ref
{
unsigned long int c_index;
SCM_VALIDATE_STACK (1, stack);
c_index = scm_to_unsigned_integer (index, 0, SCM_STACK_LENGTH(stack)-1);
return scm_cons (stack, index);
}
#undef FUNC_NAME
SCM_DEFINE (scm_stack_length, "stack-length", 1, 0, 0,
(SCM stack),
"Return the length of @var{stack}.")
#define FUNC_NAME s_scm_stack_length
{
SCM_VALIDATE_STACK (1, stack);
return scm_from_int (SCM_STACK_LENGTH (stack));
}
#undef FUNC_NAME
/* Frames
*/
SCM_DEFINE (scm_frame_p, "frame?", 1, 0, 0,
(SCM obj),
"Return @code{#t} if @var{obj} is a stack frame.")
#define FUNC_NAME s_scm_frame_p
{
return scm_from_bool(SCM_FRAMEP (obj));
}
#undef FUNC_NAME
SCM_DEFINE (scm_last_stack_frame, "last-stack-frame", 1, 0, 0,
(SCM obj),
"Return the last (innermost) frame of @var{obj}, which must be\n"
"either a debug object or a continuation.")
#define FUNC_NAME s_scm_last_stack_frame
{
scm_t_debug_frame *dframe;
long offset = 0;
SCM stack;
if (SCM_DEBUGOBJP (obj))
{
dframe = SCM_DEBUGOBJ_FRAME (obj);
}
else if (SCM_CONTINUATIONP (obj))
{
scm_t_contregs *cont = SCM_CONTREGS (obj);
offset = cont->offset;
dframe = RELOC_FRAME (cont->dframe, offset);
}
else
{
SCM_WRONG_TYPE_ARG (1, obj);
/* not reached */
}
if (!dframe || SCM_VOIDFRAMEP (*dframe))
return SCM_BOOL_F;
stack = scm_make_struct (scm_stack_type, scm_from_int (SCM_FRAME_N_SLOTS),
SCM_EOL);
SCM_STACK (stack) -> length = 1;
SCM_STACK (stack) -> frames = &SCM_STACK (stack) -> tail[0];
read_frame (dframe, offset,
(scm_t_info_frame *) &SCM_STACK (stack) -> frames[0]);
return scm_cons (stack, SCM_INUM0);
}
#undef FUNC_NAME
SCM_DEFINE (scm_frame_number, "frame-number", 1, 0, 0,
(SCM frame),
"Return the frame number of @var{frame}.")
#define FUNC_NAME s_scm_frame_number
{
SCM_VALIDATE_FRAME (1, frame);
return scm_from_int (SCM_FRAME_NUMBER (frame));
}
#undef FUNC_NAME
SCM_DEFINE (scm_frame_source, "frame-source", 1, 0, 0,
(SCM frame),
"Return the source of @var{frame}.")
#define FUNC_NAME s_scm_frame_source
{
SCM_VALIDATE_FRAME (1, frame);
return SCM_FRAME_SOURCE (frame);
}
#undef FUNC_NAME
SCM_DEFINE (scm_frame_procedure, "frame-procedure", 1, 0, 0,
(SCM frame),
"Return the procedure for @var{frame}, or @code{#f} if no\n"
"procedure is associated with @var{frame}.")
#define FUNC_NAME s_scm_frame_procedure
{
SCM_VALIDATE_FRAME (1, frame);
return (SCM_FRAME_PROC_P (frame)
? SCM_FRAME_PROC (frame)
: SCM_BOOL_F);
}
#undef FUNC_NAME
SCM_DEFINE (scm_frame_arguments, "frame-arguments", 1, 0, 0,
(SCM frame),
"Return the arguments of @var{frame}.")
#define FUNC_NAME s_scm_frame_arguments
{
SCM_VALIDATE_FRAME (1, frame);
return SCM_FRAME_ARGS (frame);
}
#undef FUNC_NAME
SCM_DEFINE (scm_frame_previous, "frame-previous", 1, 0, 0,
(SCM frame),
"Return the previous frame of @var{frame}, or @code{#f} if\n"
"@var{frame} is the first frame in its stack.")
#define FUNC_NAME s_scm_frame_previous
{
unsigned long int n;
SCM_VALIDATE_FRAME (1, frame);
n = scm_to_ulong (SCM_CDR (frame)) + 1;
if (n >= SCM_STACK_LENGTH (SCM_CAR (frame)))
return SCM_BOOL_F;
else
return scm_cons (SCM_CAR (frame), scm_from_ulong (n));
}
#undef FUNC_NAME
SCM_DEFINE (scm_frame_next, "frame-next", 1, 0, 0,
(SCM frame),
"Return the next frame of @var{frame}, or @code{#f} if\n"
"@var{frame} is the last frame in its stack.")
#define FUNC_NAME s_scm_frame_next
{
unsigned long int n;
SCM_VALIDATE_FRAME (1, frame);
n = scm_to_ulong (SCM_CDR (frame));
if (n == 0)
return SCM_BOOL_F;
else
return scm_cons (SCM_CAR (frame), scm_from_ulong (n - 1));
}
#undef FUNC_NAME
SCM_DEFINE (scm_frame_real_p, "frame-real?", 1, 0, 0,
(SCM frame),
"Return @code{#t} if @var{frame} is a real frame.")
#define FUNC_NAME s_scm_frame_real_p
{
SCM_VALIDATE_FRAME (1, frame);
return scm_from_bool(SCM_FRAME_REAL_P (frame));
}
#undef FUNC_NAME
SCM_DEFINE (scm_frame_procedure_p, "frame-procedure?", 1, 0, 0,
(SCM frame),
"Return @code{#t} if a procedure is associated with @var{frame}.")
#define FUNC_NAME s_scm_frame_procedure_p
{
SCM_VALIDATE_FRAME (1, frame);
return scm_from_bool(SCM_FRAME_PROC_P (frame));
}
#undef FUNC_NAME
SCM_DEFINE (scm_frame_evaluating_args_p, "frame-evaluating-args?", 1, 0, 0,
(SCM frame),
"Return @code{#t} if @var{frame} contains evaluated arguments.")
#define FUNC_NAME s_scm_frame_evaluating_args_p
{
SCM_VALIDATE_FRAME (1, frame);
return scm_from_bool(SCM_FRAME_EVAL_ARGS_P (frame));
}
#undef FUNC_NAME
SCM_DEFINE (scm_frame_overflow_p, "frame-overflow?", 1, 0, 0,
(SCM frame),
"Return @code{#t} if @var{frame} is an overflow frame.")
#define FUNC_NAME s_scm_frame_overflow_p
{
SCM_VALIDATE_FRAME (1, frame);
return scm_from_bool(SCM_FRAME_OVERFLOW_P (frame));
}
#undef FUNC_NAME
void
scm_init_stacks ()
{
scm_stack_type =
scm_permanent_object
(scm_make_vtable (scm_from_locale_string (SCM_STACK_LAYOUT),
SCM_UNDEFINED));
scm_set_struct_vtable_name_x (scm_stack_type,
scm_from_locale_symbol ("stack"));
#include "libguile/stacks.x"
}
/*
Local Variables:
c-file-style: "gnu"
End:
*/
View git blame Copy permalink