CAMLprim value netsys_set_color(value objv, value colv)
{
    int col;
    col = Int_val(colv);
    Hd_val(objv) = Whitehd_hd(Hd_val(objv)) | (col << 8);
    return Val_unit;
}
int netsys_init_value_1(struct htab *t,
			struct nqueue *q,
			char *dest,
			char *dest_end,
			value orig,  
			int enable_bigarrays, 
			int enable_customs,
			int enable_atoms,
			int simulation,
			void *target_addr,
			struct named_custom_ops *target_custom_ops,
			int color,
			intnat *start_offset,
			intnat *bytelen
			)
{
    void *orig_addr;
    void *work_addr;
    value work;
    int   work_tag;
    char *work_header;
    size_t work_bytes;
    size_t work_words;
    void *copy_addr;
    value copy;
    char *copy_header;
    header_t copy_header1;
    int   copy_tag;
    size_t copy_words;
    void *fixup_addr;
    char *dest_cur;
    char *dest_ptr;
    int code, i;
    intnat addr_delta;
    struct named_custom_ops *ops_ptr;
    void *int32_target_ops;
    void *int64_target_ops;
    void *nativeint_target_ops;
    void *bigarray_target_ops;

    copy = 0;

    dest_cur = dest;
    addr_delta = ((char *) target_addr) - dest;

    if (dest_cur >= dest_end && !simulation) return (-4);   /* out of space */

    if (!Is_block(orig)) return (-2);

    orig_addr = (void *) orig;
    code = netsys_queue_add(q, orig_addr);
    if (code != 0) return code;

    /* initialize *_target_ops */
    bigarray_target_ops = NULL;
    int32_target_ops = NULL;
    int64_target_ops = NULL;
    nativeint_target_ops = NULL;
    ops_ptr = target_custom_ops;
    while (ops_ptr != NULL) {
	if (strcmp(ops_ptr->name, "_bigarray") == 0)
	    bigarray_target_ops = ops_ptr->ops;
	else if (strcmp(ops_ptr->name, "_i") == 0)
	    int32_target_ops = ops_ptr->ops;
	else if (strcmp(ops_ptr->name, "_j") == 0)
	    int64_target_ops = ops_ptr->ops;
	else if (strcmp(ops_ptr->name, "_n") == 0)
	    nativeint_target_ops = ops_ptr->ops;
	ops_ptr = ops_ptr->next;
    };

    /* First pass: Iterate over the addresses found in q. Ignore
       addresses already seen in the past (which are in t). For
       new addresses, make a copy, and add these copies to t.
    */

    /* fprintf(stderr, "first pass, orig_addr=%lx simulation=%d addr_delta=%lx\n",
       (unsigned long) orig_addr, simulation, addr_delta);
    */

    code = netsys_queue_take(q, &work_addr);
    while (code != (-3)) {
	if (code != 0) return code;

	/* fprintf(stderr, "work_addr=%lx\n", (unsigned long) work_addr); */

	code = netsys_htab_lookup(t, work_addr, &copy_addr);
	if (code != 0) return code;

	if (copy_addr == NULL) {
	    /* The address is unknown, so copy the value */

	    /* Body of first pass */
	    work = (value) work_addr;
	    work_tag = Tag_val(work);
	    work_header = Hp_val(work);
	    
	    if (work_tag < No_scan_tag) {
		/* It is a scanned value (with subvalues) */
		
		switch(work_tag) {
		case Object_tag:
		case Closure_tag:
		case Lazy_tag:
		case Forward_tag:
		    return (-2);   /* unsupported */
		}

		work_words = Wosize_hp(work_header);
		if (work_words == 0) {
		    if (!enable_atoms) return (-2);
		    if (enable_atoms == 1) goto next;
		};
		
		/* Do the copy. */

		work_bytes = Bhsize_hp(work_header);
		copy_header = dest_cur;
		dest_cur += work_bytes;
		if (dest_cur > dest_end && !simulation) return (-4);
		
		if (simulation) 
		    copy_addr = work_addr;
		else {
		    memcpy(copy_header, work_header, work_bytes);
		    copy = Val_hp(copy_header);
		    copy_addr = (void *) copy;
		    Hd_val(copy) = Whitehd_hd(Hd_val(copy)) | color;
		}

		/* Add the association (work_addr -> copy_addr) to t: */

		code = netsys_htab_add(t, work_addr, copy_addr);
		if (code < 0) return code;

		/* Add the sub values of work_addr to q: */

		for (i=0; i < work_words; ++i) {
		    value field = Field(work, i);
		    if (Is_block (field)) {
			code = netsys_queue_add(q, (void *) field);
			if (code != 0) return code;
		    }
		}
	    }
	    else {
		/* It an opaque value */
		int do_copy = 0;
		int do_bigarray = 0;
		void *target_ops = NULL;
		char caml_id = ' ';  /* only b, i, j, n */
		/* Check for bigarrays and other custom blocks */
		switch (work_tag) {
		case Abstract_tag:
		    return(-2);
		case String_tag:
		    do_copy = 1; break;
		case Double_tag:
		    do_copy = 1; break;
		case Double_array_tag:
		    do_copy = 1; break;
		case Custom_tag: 
		    {
			struct custom_operations *custom_ops;
			char *id;

			custom_ops = Custom_ops_val(work);
			id = custom_ops->identifier;
			if (id[0] == '_') {
			    switch (id[1]) {
			    case 'b':
				if (!enable_bigarrays) return (-2);
				if (strcmp(id, "_bigarray") == 0) {
				    caml_id = 'b';
				    break;
				}
			    case 'i': /* int32 */
			    case 'j': /* int64 */
			    case 'n': /* nativeint */
				if (!enable_customs) return (-2);
				if (id[2] == 0) {
				    caml_id = id[1];
				    break;
				}
			    default:
				return (-2);
			    }
			}
			else
			    return (-2);
		    }
		}; /* switch */

		switch (caml_id) {  /* look closer at some cases */
		case 'b': {
		    target_ops = bigarray_target_ops;
		    do_copy = 1;
		    do_bigarray = 1;
		    break;
		}
		case 'i':
		    target_ops = int32_target_ops; do_copy = 1; break;
		case 'j':
		    target_ops = int64_target_ops; do_copy = 1; break;
		case 'n':
		    target_ops = nativeint_target_ops; do_copy = 1; break;
		};

		if (do_copy) {  
		    /* Copy the value */
		    work_bytes = Bhsize_hp(work_header);
		    copy_header = dest_cur;
		    dest_cur += work_bytes;

		    if (simulation)
			copy_addr = work_addr;
		    else {
			if (dest_cur > dest_end) return (-4);
			memcpy(copy_header, work_header, work_bytes);
			copy = Val_hp(copy_header);
			copy_addr = (void *) copy;
			Hd_val(copy) = Whitehd_hd(Hd_val(copy)) | color;
			if (target_ops != NULL)
			    Custom_ops_val(copy) = target_ops;
		    }
		    
		    code = netsys_htab_add(t, work_addr, copy_addr);
		    if (code < 0) return code;
		}

		if (do_bigarray) {
		    /* postprocessing for copying bigarrays */
		    struct caml_ba_array *b_work, *b_copy;
		    void * data_copy;
		    char * data_header;
		    header_t data_header1;
		    size_t size = 1;
		    size_t size_aligned;
		    size_t size_words;
		    b_work = Bigarray_val(work);
		    b_copy = Bigarray_val(copy);
		    for (i = 0; i < b_work->num_dims; i++) {
			size = size * b_work->dim[i];
		    };
		    size = 
			size * 
			caml_ba_element_size[b_work->flags & BIGARRAY_KIND_MASK];

		    size_aligned = size;
		    if (size%sizeof(void *) != 0)
			size_aligned += sizeof(void *) - (size%sizeof(void *));
		    size_words = Wsize_bsize(size_aligned);

		    /* If we put the copy of the bigarray into our own
		       dest buffer, also generate an abstract header,
		       so it can be skipped when iterating over it.

		       We use here a special representation, so we can
		       encode any length in this header (with a normal
		       Ocaml header we are limited by Max_wosize, e.g.
		       16M on 32 bit systems). The special representation
		       is an Abstract_tag with zero length, followed
		       by the real length (in words)
		    */
		    
		    if (enable_bigarrays == 2) {
			data_header = dest_cur;
			dest_cur += 2*sizeof(void *);
			data_copy = dest_cur;
			dest_cur += size_aligned;
		    } else if (!simulation) {
			data_header = NULL;
			data_copy = stat_alloc(size_aligned);
		    };

		    if (!simulation) {
			if (dest_cur > dest_end) return (-4);

			/* Initialize header: */
			
			if (data_header != NULL) {
			    data_header1 = Abstract_tag;
			    memcpy(data_header, 
				   (char *) &data_header1,
				   sizeof(header_t));
			    memcpy(data_header + sizeof(header_t),
				   (size_t *) &size_words,
				   sizeof(size_t));
			};

			/* Copy bigarray: */
			
			memcpy(data_copy, b_work->data, size);
			b_copy->data = data_copy;
			b_copy->proxy = NULL;

			/* If the copy is in our own buffer, it is
			   now externally managed.
			*/
			b_copy->flags = 
			    (b_copy->flags & ~CAML_BA_MANAGED_MASK) |
			    (enable_bigarrays == 2 ? 
			     CAML_BA_EXTERNAL :
			     CAML_BA_MANAGED);
		    }
		}

	    } /* if (work_tag < No_scan_tag) */
	} /* if (copy_addr == NULL) */

	/* Switch to next address in q: */
    next:
	code = netsys_queue_take(q, &work_addr);
    } /* while */
    
    /* Second pass. The copied blocks still have fields pointing to the
       original blocks. We fix that now by iterating once over the copied
       memory block.
    */

    if (!simulation) {
	/* fprintf(stderr, "second pass\n"); */
	dest_ptr = dest;
	while (dest_ptr < dest_cur) {
	    copy_header1 = *((header_t *) dest_ptr);
	    copy_tag = Tag_hd(copy_header1);
	    copy_words = Wosize_hd(copy_header1);
	    copy = (value) (dest_ptr + sizeof(void *));
	    
	    if (copy_tag < No_scan_tag) {
		for (i=0; i < copy_words; ++i) {
		    value field = Field(copy, i);
		    if (Is_block (field)) {
			/* It is a pointer. Try to fix it up. */
			code = netsys_htab_lookup(t, (void *) field,
						  &fixup_addr);
			if (code != 0) return code;

			if (fixup_addr != NULL)
			    Field(copy,i) = 
				(value) (((char *) fixup_addr) + addr_delta);
		    }
		}
	    }
	    else if (copy_tag == Abstract_tag && copy_words == 0) {
		/* our special representation for skipping data regions */
		copy_words = ((size_t *) dest_ptr)[1] + 1;
	    };
	    
	    dest_ptr += (copy_words + 1) * sizeof(void *);
	}
    }	

    /* hey, fine. Return result */
    *start_offset = sizeof(void *);
    *bytelen = dest_cur - dest;

    /* fprintf(stderr, "return regularly\n");*/

    return 0;
}
Exemplo n.º 3
0
static void extern_rec(value v)
{
  struct code_fragment * cf;
  struct extern_item * sp;
  sp = extern_stack;

  while(1) {
  if (Is_long(v)) {
    intnat n = Long_val(v);
    if (n >= 0 && n < 0x40) {
      Write(PREFIX_SMALL_INT + n);
    } else if (n >= -(1 << 7) && n < (1 << 7)) {
      writecode8(CODE_INT8, n);
    } else if (n >= -(1 << 15) && n < (1 << 15)) {
      writecode16(CODE_INT16, n);
#ifdef ARCH_SIXTYFOUR
    } else if (n < -((intnat)1 << 31) || n >= ((intnat)1 << 31)) {
      writecode64(CODE_INT64, n);
#endif
    } else
      writecode32(CODE_INT32, n);
    goto next_item;
  }
  if (Is_in_value_area(v)) {
    header_t hd = Hd_val(v);
    tag_t tag = Tag_hd(hd);
    mlsize_t sz = Wosize_hd(hd);

    if (tag == Forward_tag) {
      value f = Forward_val (v);
      if (Is_block (f)
          && (!Is_in_value_area(f) || Tag_val (f) == Forward_tag
              || Tag_val (f) == Lazy_tag || Tag_val (f) == Double_tag)){
        /* Do not short-circuit the pointer. */
      }else{
        v = f;
        continue;
      }
    }
    /* Atoms are treated specially for two reasons: they are not allocated
       in the externed block, and they are automatically shared. */
    if (sz == 0) {
      if (tag < 16) {
        Write(PREFIX_SMALL_BLOCK + tag);
      } else {
        writecode32(CODE_BLOCK32, hd);
      }
      goto next_item;
    }
    /* Check if already seen */
    if (Color_hd(hd) == Caml_blue) {
      uintnat d = obj_counter - (uintnat) Field(v, 0);
      if (d < 0x100) {
        writecode8(CODE_SHARED8, d);
      } else if (d < 0x10000) {
        writecode16(CODE_SHARED16, d);
      } else {
        writecode32(CODE_SHARED32, d);
      }
      goto next_item;
    }

    /* Output the contents of the object */
    switch(tag) {
    case String_tag: {
      mlsize_t len = caml_string_length(v);
      if (len < 0x20) {
        Write(PREFIX_SMALL_STRING + len);
      } else if (len < 0x100) {
        writecode8(CODE_STRING8, len);
      } else {
        writecode32(CODE_STRING32, len);
      }
      writeblock(String_val(v), len);
      size_32 += 1 + (len + 4) / 4;
      size_64 += 1 + (len + 8) / 8;
      extern_record_location(v);
      break;
    }
    case Double_tag: {
      if (sizeof(double) != 8)
        extern_invalid_argument("output_value: non-standard floats");
      Write(CODE_DOUBLE_NATIVE);
      writeblock_float8((double *) v, 1);
      size_32 += 1 + 2;
      size_64 += 1 + 1;
      extern_record_location(v);
      break;
    }
    case Double_array_tag: {
      mlsize_t nfloats;
      if (sizeof(double) != 8)
        extern_invalid_argument("output_value: non-standard floats");
      nfloats = Wosize_val(v) / Double_wosize;
      if (nfloats < 0x100) {
        writecode8(CODE_DOUBLE_ARRAY8_NATIVE, nfloats);
      } else {
        writecode32(CODE_DOUBLE_ARRAY32_NATIVE, nfloats);
      }
      writeblock_float8((double *) v, nfloats);
      size_32 += 1 + nfloats * 2;
      size_64 += 1 + nfloats;
      extern_record_location(v);
      break;
    }
    case Abstract_tag:
      extern_invalid_argument("output_value: abstract value (Abstract)");
      break;
    case Infix_tag:
      writecode32(CODE_INFIXPOINTER, Infix_offset_hd(hd));
      extern_rec(v - Infix_offset_hd(hd));
      break;
    case Custom_tag: {
      uintnat sz_32, sz_64;
      char * ident = Custom_ops_val(v)->identifier;
      void (*serialize)(value v, uintnat * wsize_32,
                        uintnat * wsize_64)
        = Custom_ops_val(v)->serialize;
      if (serialize == NULL)
        extern_invalid_argument("output_value: abstract value (Custom)");
      Write(CODE_CUSTOM);
      writeblock(ident, strlen(ident) + 1);
      Custom_ops_val(v)->serialize(v, &sz_32, &sz_64);
      size_32 += 2 + ((sz_32 + 3) >> 2);  /* header + ops + data */
      size_64 += 2 + ((sz_64 + 7) >> 3);
      extern_record_location(v);
      break;
    }
    default: {
      value field0;
      if (tag < 16 && sz < 8) {
        Write(PREFIX_SMALL_BLOCK + tag + (sz << 4));
#ifdef ARCH_SIXTYFOUR
      } else if (hd >= ((uintnat)1 << 32)) {
        writecode64(CODE_BLOCK64, Whitehd_hd (hd));
#endif
      } else {
        writecode32(CODE_BLOCK32, Whitehd_hd (hd));
      }
      size_32 += 1 + sz;
      size_64 += 1 + sz;
      field0 = Field(v, 0);
      extern_record_location(v);
      /* Remember that we still have to serialize fields 1 ... sz - 1 */
      if (sz > 1) {
        sp++;
        if (sp >= extern_stack_limit) sp = extern_resize_stack(sp);
        sp->v = &Field(v,1);
        sp->count = sz-1;
      }
      /* Continue serialization with the first field */
      v = field0;
      continue;
    }
    }
  }
  else if ((cf = extern_find_code((char *) v)) != NULL) {
    if (!extern_closures)
      extern_invalid_argument("output_value: functional value");
    writecode32(CODE_CODEPOINTER, (char *) v - cf->code_start);
    writeblock((char *) cf->digest, 16);
  } else {
    extern_invalid_argument("output_value: abstract value (outside heap)");
  }
  next_item:
    /* Pop one more item to marshal, if any */
    if (sp == extern_stack) {
        /* We are done.   Cleanup the stack and leave the function */
        extern_free_stack();
        return;
    }
    v = *((sp->v)++);
    if (--(sp->count) == 0) sp--;
  }
Exemplo n.º 4
0
static void extern_rec(value v)
{
 tailcall:
  if (Is_long(v)) {
    intnat n = Long_val(v);
    if (n >= 0 && n < 0x40) {
      Write(PREFIX_SMALL_INT + n);
    } else if (n >= -(1 << 7) && n < (1 << 7)) {
      writecode8(CODE_INT8, n);
    } else if (n >= -(1 << 15) && n < (1 << 15)) {
      writecode16(CODE_INT16, n);
#ifdef ARCH_SIXTYFOUR
    } else if (n < -((intnat)1 << 31) || n >= ((intnat)1 << 31)) {
      writecode64(CODE_INT64, n);
#endif
    } else
      writecode32(CODE_INT32, n);
    return;
  }
  if (Is_in_value_area(v)) {
    header_t hd = Hd_val(v);
    tag_t tag = Tag_hd(hd);
    mlsize_t sz = Wosize_hd(hd);

    if (tag == Forward_tag) {
      value f = Forward_val (v);
      if (Is_block (f)
          && (!Is_in_value_area(f) || Tag_val (f) == Forward_tag
              || Tag_val (f) == Lazy_tag || Tag_val (f) == Double_tag)){
        /* Do not short-circuit the pointer. */
      }else{
        v = f;
        goto tailcall;
      }
    }
    /* Atoms are treated specially for two reasons: they are not allocated
       in the externed block, and they are automatically shared. */
    if (sz == 0) {
      if (tag < 16) {
        Write(PREFIX_SMALL_BLOCK + tag);
      } else {
        writecode32(CODE_BLOCK32, hd);
      }
      return;
    }
    /* Check if already seen */
    if (Color_hd(hd) == Caml_blue) {
      uintnat d = obj_counter - (uintnat) Field(v, 0);
      if (d < 0x100) {
        writecode8(CODE_SHARED8, d);
      } else if (d < 0x10000) {
        writecode16(CODE_SHARED16, d);
      } else {
        writecode32(CODE_SHARED32, d);
      }
      return;
    }

    /* Output the contents of the object */
    switch(tag) {
    case String_tag: {
      mlsize_t len = caml_string_length(v);
      if (len < 0x20) {
        Write(PREFIX_SMALL_STRING + len);
      } else if (len < 0x100) {
        writecode8(CODE_STRING8, len);
      } else {
        writecode32(CODE_STRING32, len);
      }
      writeblock(String_val(v), len);
      size_32 += 1 + (len + 4) / 4;
      size_64 += 1 + (len + 8) / 8;
      extern_record_location(v);
      break;
    }
    case Double_tag: {
      if (sizeof(double) != 8)
        extern_invalid_argument("output_value: non-standard floats");
      Write(CODE_DOUBLE_NATIVE);
      writeblock_float8((double *) v, 1);
      size_32 += 1 + 2;
      size_64 += 1 + 1;
      extern_record_location(v);
      break;
    }
    case Double_array_tag: {
      mlsize_t nfloats;
      if (sizeof(double) != 8)
        extern_invalid_argument("output_value: non-standard floats");
      nfloats = Wosize_val(v) / Double_wosize;
      if (nfloats < 0x100) {
        writecode8(CODE_DOUBLE_ARRAY8_NATIVE, nfloats);
      } else {
        writecode32(CODE_DOUBLE_ARRAY32_NATIVE, nfloats);
      }
      writeblock_float8((double *) v, nfloats);
      size_32 += 1 + nfloats * 2;
      size_64 += 1 + nfloats;
      extern_record_location(v);
      break;
    }
    case Abstract_tag:
      extern_invalid_argument("output_value: abstract value (Abstract)");
      break;
    case Infix_tag:
      writecode32(CODE_INFIXPOINTER, Infix_offset_hd(hd));
      extern_rec(v - Infix_offset_hd(hd));
      break;
    case Custom_tag: {
      uintnat sz_32, sz_64;
      char * ident = Custom_ops_val(v)->identifier;
      void (*serialize)(value v, uintnat * wsize_32,
                        uintnat * wsize_64)
        = Custom_ops_val(v)->serialize;
      if (serialize == NULL)
        extern_invalid_argument("output_value: abstract value (Custom)");
      Write(CODE_CUSTOM);
      writeblock(ident, strlen(ident) + 1);
      Custom_ops_val(v)->serialize(v, &sz_32, &sz_64);
      size_32 += 2 + ((sz_32 + 3) >> 2);  /* header + ops + data */
      size_64 += 2 + ((sz_64 + 7) >> 3);
      extern_record_location(v);
      break;
    }
    default: {
      value field0;
      mlsize_t i;
      if (tag < 16 && sz < 8) {
        Write(PREFIX_SMALL_BLOCK + tag + (sz << 4));
#ifdef ARCH_SIXTYFOUR
      } else if (hd >= ((uintnat)1 << 32)) {
        writecode64(CODE_BLOCK64, Whitehd_hd (hd));
#endif
      } else {
        writecode32(CODE_BLOCK32, Whitehd_hd (hd));
      }
      size_32 += 1 + sz;
      size_64 += 1 + sz;
      field0 = Field(v, 0);
      extern_record_location(v);
      if (sz == 1) {
        v = field0;
      } else {
        extern_rec(field0);
        for (i = 1; i < sz - 1; i++) extern_rec(Field(v, i));
        v = Field(v, i);
      }
      goto tailcall;
    }
    }
  }
  else if ((char *) v >= caml_code_area_start &&
Exemplo n.º 5
0
static void extern_rec_r(CAML_R, value v)
{
  struct code_fragment * cf;
  struct extern_item * sp;
  sp = extern_stack;

  while(1) {
    //?????DUMP("QQQ 0x%lx, or %li ", v, v);
  if (Is_long(v)) {
    intnat n = Long_val(v);
    if (n >= 0 && n < 0x40) {
      Write(PREFIX_SMALL_INT + n);
    } else if (n >= -(1 << 7) && n < (1 << 7)) {
      writecode8_r(ctx, CODE_INT8, n);
    } else if (n >= -(1 << 15) && n < (1 << 15)) {
      writecode16_r(ctx, CODE_INT16, n);
#ifdef ARCH_SIXTYFOUR
    } else if (n < -((intnat)1 << 31) || n >= ((intnat)1 << 31)) {
      writecode64_r(ctx, CODE_INT64, n);
#endif
    } else
      writecode32_r(ctx, CODE_INT32, n);
    goto next_item;
  }
  if (Is_in_value_area(v)) {
    header_t hd = Hd_val(v);
    tag_t tag = Tag_hd(hd);
    mlsize_t sz = Wosize_hd(hd);
    //DUMP("dumping %p, tag %i, size %i", (void*)v, (int)tag, (int)sz); // !!!!!!!!!!!!!!!
    if (tag == Forward_tag) {
      value f = Forward_val (v);
      if (Is_block (f)
          && (!Is_in_value_area(f) || Tag_val (f) == Forward_tag
              || Tag_val (f) == Lazy_tag || Tag_val (f) == Double_tag)){
        /* Do not short-circuit the pointer. */
      }else{
        v = f;
        continue;
      }
    }
    /* Atoms are treated specially for two reasons: they are not allocated
       in the externed block, and they are automatically shared. */
    if (sz == 0) {
      if (tag < 16) {
        Write(PREFIX_SMALL_BLOCK + tag);
      } else {
        writecode32_r(ctx, CODE_BLOCK32, hd);
      }
      goto next_item;
    }
    /* Check if already seen */
    if (Color_hd(hd) == Caml_blue) {
      uintnat d = obj_counter - (uintnat) Field(v, 0);
      if (d < 0x100) {
        writecode8_r(ctx, CODE_SHARED8, d);
      } else if (d < 0x10000) {
        writecode16_r(ctx, CODE_SHARED16, d);
      } else {
        writecode32_r(ctx, CODE_SHARED32, d);
      }
      goto next_item;
    }

    /* Output the contents of the object */
    switch(tag) {
    case String_tag: {
      mlsize_t len = caml_string_length(v);
      if (len < 0x20) {
        Write(PREFIX_SMALL_STRING + len);
      } else if (len < 0x100) {
        writecode8_r(ctx, CODE_STRING8, len);
      } else {
        writecode32_r(ctx, CODE_STRING32, len);
      }
      writeblock_r(ctx, String_val(v), len);
      size_32 += 1 + (len + 4) / 4;
      size_64 += 1 + (len + 8) / 8;
      extern_record_location_r(ctx, v);
      break;
    }
    case Double_tag: {
      if (sizeof(double) != 8)
        extern_invalid_argument_r(ctx, "output_value: non-standard floats");
      Write(CODE_DOUBLE_NATIVE);
      writeblock_float8((double *) v, 1);
      size_32 += 1 + 2;
      size_64 += 1 + 1;
      extern_record_location_r(ctx,v);
      break;
    }
    case Double_array_tag: {
      mlsize_t nfloats;
      if (sizeof(double) != 8)
        extern_invalid_argument_r(ctx, "output_value: non-standard floats");
      nfloats = Wosize_val(v) / Double_wosize;
      if (nfloats < 0x100) {
        writecode8_r(ctx, CODE_DOUBLE_ARRAY8_NATIVE, nfloats);
      } else {
        writecode32_r(ctx, CODE_DOUBLE_ARRAY32_NATIVE, nfloats);
      }
      writeblock_float8((double *) v, nfloats);
      size_32 += 1 + nfloats * 2;
      size_64 += 1 + nfloats;
      extern_record_location_r(ctx, v);
      break;
    }
    case Abstract_tag:
      extern_invalid_argument_r(ctx, "output_value: abstract value (Abstract)");
      break;
    case Infix_tag:
      writecode32_r(ctx,CODE_INFIXPOINTER, Infix_offset_hd(hd));
      extern_rec_r(ctx, v - Infix_offset_hd(hd));
      break;
    case Custom_tag: {
      uintnat sz_32, sz_64;
      char * ident = Custom_ops_val(v)->identifier;
      void (*serialize)(value v, uintnat * wsize_32,
                        uintnat * wsize_64);
      //printf("[object at %p, which is a %s custom: BEGIN\n", (void*)v, Custom_ops_val(v)->identifier);
      if(extern_cross_context){
        //printf("About the object at %p, which is a %s custom: USING a cross-context serializer\n", (void*)v, Custom_ops_val(v)->identifier);
        serialize = Custom_ops_val(v)->cross_context_serialize;
      }
      else{
        //printf("About the object at %p, which is a %s custom: NOT using a cross-context serializer\n", (void*)v, Custom_ops_val(v)->identifier);
        serialize = Custom_ops_val(v)->serialize;
      }
      //printf("Still alive 100\n");
      if (serialize == NULL){
        //////
        //struct custom_operations *o = Custom_ops_val(v);
        //printf("About the object at %p, which is a %s custom\n", (void*)v, Custom_ops_val(v)->identifier); volatile int a = 1; a /= 0;
        ///////////
        extern_invalid_argument_r(ctx, "output_value: abstract value (Custom)");
      }
      //printf("Still alive 200\n");
      Write(CODE_CUSTOM);
      //printf("Still alive 300\n");
      writeblock_r(ctx, ident, strlen(ident) + 1);
      //printf("Still alive 400\n");
      serialize(v, &sz_32, &sz_64);
      //printf("Still alive 500\n");
      size_32 += 2 + ((sz_32 + 3) >> 2);  /* header + ops + data */
      size_64 += 2 + ((sz_64 + 7) >> 3);
      //printf("Still alive 600\n");
      extern_record_location_r(ctx,v); // This temporarily breaks the object, by replacing it with a forwarding pointer
      //printf("object at %p, which is a custom: END\n", (void*)v);
      break;
    }
    default: {
      value field0;
      if (tag < 16 && sz < 8) {
        Write(PREFIX_SMALL_BLOCK + tag + (sz << 4));
#ifdef ARCH_SIXTYFOUR
      } else if (hd >= ((uintnat)1 << 32)) {
        writecode64_r(ctx, CODE_BLOCK64, Whitehd_hd (hd));
#endif
      } else {
        writecode32_r(ctx, CODE_BLOCK32, Whitehd_hd (hd));
      }
      size_32 += 1 + sz;
      size_64 += 1 + sz;
      field0 = Field(v, 0);
      extern_record_location_r(ctx, v);
      /* Remember that we still have to serialize fields 1 ... sz - 1 */
      if (sz > 1) {
        sp++;
        if (sp >= extern_stack_limit) sp = extern_resize_stack_r(ctx, sp);
        sp->v = &Field(v,1);
        sp->count = sz-1;
      }
      /* Continue serialization with the first field */
      v = field0;
      continue;
    }
    }
  }
  else if ((cf = extern_find_code_r(ctx, (char *) v)) != NULL) {
    if (!extern_closures){
      extern_invalid_argument_r(ctx, "output_value: functional value"); // FIXME: this is the correct version. !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
      //DUMP("output_value: functional value"); {volatile int a = 1; a /= 0;}
      }
    //fprintf(stderr, "ZZZZ dumping a code pointer: BEGIN\n");
    //DUMP("dumping a code pointer 0x%lx, or %li; code start is at %p", v, v, cf->code_start);
    writecode32_r(ctx, CODE_CODEPOINTER, (char *) v - cf->code_start);
    writeblock_r(ctx, (char *) cf->digest, 16);
    //dump_digest(cf->digest);
    //fprintf(stderr, "ZZZZ dumping a code pointer: END\n");
  } else {
    if(extern_cross_context){
      fprintf(stderr, "ZZZZ working on the external pointer: %p, which is to say %li [cf is %p]\n", (void*)v, (long)v, cf);
      //fprintf(stderr, "ZZZZ I'm doing a horrible, horrible thing: serializing the pointer as a tagged 0.\n");
      DUMP("about to crash in the strange case I'm debugging");
      /* DUMP("the object is 0x%lx, or %li ", v, v); */
      /* DUMP("probably crashing now"); */
      /* DUMP("tag is %i", (int)Tag_val(v)); */
      /* DUMP("size is %i", (int)Wosize_val(v)); */
      //volatile int a = 1; a /= 0;
      //extern_rec_r(ctx, Val_int(0));
      /* fprintf(stderr, "ZZZZ [This is probably wrong: I'm marshalling an out-of-heap pointer as an int64]\n"); */
      /* writecode64_r(ctx, CODE_INT64, (v << 1) | 1); */
      extern_invalid_argument_r(ctx, "output_value: abstract value (outside heap) [FIXME: implement]");
    }
    else
      extern_invalid_argument_r(ctx, "output_value: abstract value (outside heap)");
  }
  next_item:
    /* Pop one more item to marshal, if any */
    if (sp == extern_stack) {
        /* We are done.   Cleanup the stack and leave the function */
        extern_free_stack_r(ctx);
        return;
    }
    v = *((sp->v)++);
    if (--(sp->count) == 0) sp--;
  }