/* Low level packing and unpacking of values for GDB, the GNU Debugger. Copyright 1986, 1987, 1988, 1989, 1990, 1991, 1992, 1993, 1994, 1995, 1996, 1997, 1998, 1999, 2000, 2002, 2003 Free Software Foundation, Inc. This file is part of GDB. This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program 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 General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ #include "defs.h" #include "gdb_string.h" #include "symtab.h" #include "gdbtypes.h" #include "value.h" #include "gdbcore.h" #include "command.h" #include "gdbcmd.h" #include "target.h" #include "language.h" #include "scm-lang.h" #include "demangle.h" #include "doublest.h" #include "gdb_assert.h" #include "regcache.h" #include "block.h" /* Prototypes for exported functions. */ void _initialize_values (void); /* Prototypes for local functions. */ static void show_values (char *, int); static void show_convenience (char *, int); /* The value-history records all the values printed by print commands during this session. Each chunk records 60 consecutive values. The first chunk on the chain records the most recent values. The total number of values is in value_history_count. */ #define VALUE_HISTORY_CHUNK 60 struct value_history_chunk { struct value_history_chunk *next; struct value *values[VALUE_HISTORY_CHUNK]; }; /* Chain of chunks now in use. */ static struct value_history_chunk *value_history_chain; static int value_history_count; /* Abs number of last entry stored */ /* List of all value objects currently allocated (except for those released by calls to release_value) This is so they can be freed after each command. */ static struct value *all_values; /* Allocate a value that has the correct length for type TYPE. */ struct value * allocate_value (struct type *type) { struct value *val; struct type *atype = check_typedef (type); val = (struct value *) xmalloc (sizeof (struct value) + TYPE_LENGTH (atype)); VALUE_NEXT (val) = all_values; all_values = val; VALUE_TYPE (val) = type; VALUE_ENCLOSING_TYPE (val) = type; VALUE_LVAL (val) = not_lval; VALUE_ADDRESS (val) = 0; VALUE_FRAME_ID (val) = null_frame_id; VALUE_OFFSET (val) = 0; VALUE_BITPOS (val) = 0; VALUE_BITSIZE (val) = 0; VALUE_REGNO (val) = -1; VALUE_LAZY (val) = 0; VALUE_OPTIMIZED_OUT (val) = 0; VALUE_BFD_SECTION (val) = NULL; VALUE_EMBEDDED_OFFSET (val) = 0; VALUE_POINTED_TO_OFFSET (val) = 0; val->modifiable = 1; return val; } /* Allocate a value that has the correct length for COUNT repetitions type TYPE. */ struct value * allocate_repeat_value (struct type *type, int count) { int low_bound = current_language->string_lower_bound; /* ??? */ /* FIXME-type-allocation: need a way to free this type when we are done with it. */ struct type *range_type = create_range_type ((struct type *) NULL, builtin_type_int, low_bound, count + low_bound - 1); /* FIXME-type-allocation: need a way to free this type when we are done with it. */ return allocate_value (create_array_type ((struct type *) NULL, type, range_type)); } /* Return a mark in the value chain. All values allocated after the mark is obtained (except for those released) are subject to being freed if a subsequent value_free_to_mark is passed the mark. */ struct value * value_mark (void) { return all_values; } /* Free all values allocated since MARK was obtained by value_mark (except for those released). */ void value_free_to_mark (struct value *mark) { struct value *val; struct value *next; for (val = all_values; val && val != mark; val = next) { next = VALUE_NEXT (val); value_free (val); } all_values = val; } /* Free all the values that have been allocated (except for those released). Called after each command, successful or not. */ void free_all_values (void) { struct value *val; struct value *next; for (val = all_values; val; val = next) { next = VALUE_NEXT (val); value_free (val); } all_values = 0; } /* Remove VAL from the chain all_values so it will not be freed automatically. */ void release_value (struct value *val) { struct value *v; if (all_values == val) { all_values = val->next; return; } for (v = all_values; v; v = v->next) { if (v->next == val) { v->next = val->next; break; } } } /* Release all values up to mark */ struct value * value_release_to_mark (struct value *mark) { struct value *val; struct value *next; for (val = next = all_values; next; next = VALUE_NEXT (next)) if (VALUE_NEXT (next) == mark) { all_values = VALUE_NEXT (next); VALUE_NEXT (next) = 0; return val; } all_values = 0; return val; } /* Return a copy of the value ARG. It contains the same contents, for same memory address, but it's a different block of storage. */ struct value * value_copy (struct value *arg) { register struct type *encl_type = VALUE_ENCLOSING_TYPE (arg); struct value *val = allocate_value (encl_type); VALUE_TYPE (val) = VALUE_TYPE (arg); VALUE_LVAL (val) = VALUE_LVAL (arg); VALUE_ADDRESS (val) = VALUE_ADDRESS (arg); VALUE_OFFSET (val) = VALUE_OFFSET (arg); VALUE_BITPOS (val) = VALUE_BITPOS (arg); VALUE_BITSIZE (val) = VALUE_BITSIZE (arg); VALUE_FRAME_ID (val) = VALUE_FRAME_ID (arg); VALUE_REGNO (val) = VALUE_REGNO (arg); VALUE_LAZY (val) = VALUE_LAZY (arg); VALUE_OPTIMIZED_OUT (val) = VALUE_OPTIMIZED_OUT (arg); VALUE_EMBEDDED_OFFSET (val) = VALUE_EMBEDDED_OFFSET (arg); VALUE_POINTED_TO_OFFSET (val) = VALUE_POINTED_TO_OFFSET (arg); VALUE_BFD_SECTION (val) = VALUE_BFD_SECTION (arg); val->modifiable = arg->modifiable; if (!VALUE_LAZY (val)) { memcpy (VALUE_CONTENTS_ALL_RAW (val), VALUE_CONTENTS_ALL_RAW (arg), TYPE_LENGTH (VALUE_ENCLOSING_TYPE (arg))); } return val; } /* Access to the value history. */ /* Record a new value in the value history. Returns the absolute history index of the entry. Result of -1 indicates the value was not saved; otherwise it is the value history index of this new item. */ int record_latest_value (struct value *val) { int i; /* We don't want this value to have anything to do with the inferior anymore. In particular, "set $1 = 50" should not affect the variable from which the value was taken, and fast watchpoints should be able to assume that a value on the value history never changes. */ if (VALUE_LAZY (val)) value_fetch_lazy (val); /* We preserve VALUE_LVAL so that the user can find out where it was fetched from. This is a bit dubious, because then *&$1 does not just return $1 but the current contents of that location. c'est la vie... */ val->modifiable = 0; release_value (val); /* Here we treat value_history_count as origin-zero and applying to the value being stored now. */ i = value_history_count % VALUE_HISTORY_CHUNK; if (i == 0) { struct value_history_chunk *new = (struct value_history_chunk *) xmalloc (sizeof (struct value_history_chunk)); memset (new->values, 0, sizeof new->values); new->next = value_history_chain; value_history_chain = new; } value_history_chain->values[i] = val; /* Now we regard value_history_count as origin-one and applying to the value just stored. */ return ++value_history_count; } /* Return a copy of the value in the history with sequence number NUM. */ struct value * access_value_history (int num) { struct value_history_chunk *chunk; register int i; register int absnum = num; if (absnum <= 0) absnum += value_history_count; if (absnum <= 0) { if (num == 0) error ("The history is empty."); else if (num == 1) error ("There is only one value in the history."); else error ("History does not go back to $$%d.", -num); } if (absnum > value_history_count) error ("History has not yet reached $%d.", absnum); absnum--; /* Now absnum is always absolute and origin zero. */ chunk = value_history_chain; for (i = (value_history_count - 1) / VALUE_HISTORY_CHUNK - absnum / VALUE_HISTORY_CHUNK; i > 0; i--) chunk = chunk->next; return value_copy (chunk->values[absnum % VALUE_HISTORY_CHUNK]); } /* Clear the value history entirely. Must be done when new symbol tables are loaded, because the type pointers become invalid. */ void clear_value_history (void) { struct value_history_chunk *next; register int i; struct value *val; while (value_history_chain) { for (i = 0; i < VALUE_HISTORY_CHUNK; i++) if ((val = value_history_chain->values[i]) != NULL) xfree (val); next = value_history_chain->next; xfree (value_history_chain); value_history_chain = next; } value_history_count = 0; } static void show_values (char *num_exp, int from_tty) { register int i; struct value *val; static int num = 1; if (num_exp) { /* "info history +" should print from the stored position. "info history " should print around value number . */ if (num_exp[0] != '+' || num_exp[1] != '\0') num = parse_and_eval_long (num_exp) - 5; } else { /* "info history" means print the last 10 values. */ num = value_history_count - 9; } if (num <= 0) num = 1; for (i = num; i < num + 10 && i <= value_history_count; i++) { val = access_value_history (i); printf_filtered ("$%d = ", i); value_print (val, gdb_stdout, 0, Val_pretty_default); printf_filtered ("\n"); } /* The next "info history +" should start after what we just printed. */ num += 10; /* Hitting just return after this command should do the same thing as "info history +". If num_exp is null, this is unnecessary, since "info history +" is not useful after "info history". */ if (from_tty && num_exp) { num_exp[0] = '+'; num_exp[1] = '\0'; } } /* Internal variables. These are variables within the debugger that hold values assigned by debugger commands. The user refers to them with a '$' prefix that does not appear in the variable names stored internally. */ static struct internalvar *internalvars; /* Look up an internal variable with name NAME. NAME should not normally include a dollar sign. If the specified internal variable does not exist, one is created, with a void value. */ struct internalvar * lookup_internalvar (char *name) { register struct internalvar *var; for (var = internalvars; var; var = var->next) if (strcmp (var->name, name) == 0) return var; var = (struct internalvar *) xmalloc (sizeof (struct internalvar)); var->name = concat (name, NULL); var->value = allocate_value (builtin_type_void); release_value (var->value); var->next = internalvars; internalvars = var; return var; } struct value * value_of_internalvar (struct internalvar *var) { struct value *val; val = value_copy (var->value); if (VALUE_LAZY (val)) value_fetch_lazy (val); VALUE_LVAL (val) = lval_internalvar; VALUE_INTERNALVAR (val) = var; return val; } void set_internalvar_component (struct internalvar *var, int offset, int bitpos, int bitsize, struct value *newval) { register char *addr = VALUE_CONTENTS (var->value) + offset; if (bitsize) modify_field (addr, value_as_long (newval), bitpos, bitsize); else memcpy (addr, VALUE_CONTENTS (newval), TYPE_LENGTH (VALUE_TYPE (newval))); } void set_internalvar (struct internalvar *var, struct value *val) { struct value *newval; newval = value_copy (val); newval->modifiable = 1; /* Force the value to be fetched from the target now, to avoid problems later when this internalvar is referenced and the target is gone or has changed. */ if (VALUE_LAZY (newval)) value_fetch_lazy (newval); /* Begin code which must not call error(). If var->value points to something free'd, an error() obviously leaves a dangling pointer. But we also get a danling pointer if var->value points to something in the value chain (i.e., before release_value is called), because after the error free_all_values will get called before long. */ xfree (var->value); var->value = newval; release_value (newval); /* End code which must not call error(). */ } char * internalvar_name (struct internalvar *var) { return var->name; } /* Free all internalvars. Done when new symtabs are loaded, because that makes the values invalid. */ void clear_internalvars (void) { register struct internalvar *var; while (internalvars) { var = internalvars; internalvars = var->next; xfree (var->name); xfree (var->value); xfree (var); } } static void show_convenience (char *ignore, int from_tty) { register struct internalvar *var; int varseen = 0; for (var = internalvars; var; var = var->next) { if (!varseen) { varseen = 1; } printf_filtered ("$%s = ", var->name); value_print (var->value, gdb_stdout, 0, Val_pretty_default); printf_filtered ("\n"); } if (!varseen) printf_unfiltered ("No debugger convenience variables now defined.\n\ Convenience variables have names starting with \"$\";\n\ use \"set\" as in \"set $foo = 5\" to define them.\n"); } /* Extract a value as a C number (either long or double). Knows how to convert fixed values to double, or floating values to long. Does not deallocate the value. */ LONGEST value_as_long (struct value *val) { /* This coerces arrays and functions, which is necessary (e.g. in disassemble_command). It also dereferences references, which I suspect is the most logical thing to do. */ COERCE_ARRAY (val); return unpack_long (VALUE_TYPE (val), VALUE_CONTENTS (val)); } DOUBLEST value_as_double (struct value *val) { DOUBLEST foo; int inv; foo = unpack_double (VALUE_TYPE (val), VALUE_CONTENTS (val), &inv); if (inv) error ("Invalid floating value found in program."); return foo; } /* Extract a value as a C pointer. Does not deallocate the value. Note that val's type may not actually be a pointer; value_as_long handles all the cases. */ CORE_ADDR value_as_address (struct value *val) { /* Assume a CORE_ADDR can fit in a LONGEST (for now). Not sure whether we want this to be true eventually. */ #if 0 /* ADDR_BITS_REMOVE is wrong if we are being called for a non-address (e.g. argument to "signal", "info break", etc.), or for pointers to char, in which the low bits *are* significant. */ return ADDR_BITS_REMOVE (value_as_long (val)); #else /* There are several targets (IA-64, PowerPC, and others) which don't represent pointers to functions as simply the address of the function's entry point. For example, on the IA-64, a function pointer points to a two-word descriptor, generated by the linker, which contains the function's entry point, and the value the IA-64 "global pointer" register should have --- to support position-independent code. The linker generates descriptors only for those functions whose addresses are taken. On such targets, it's difficult for GDB to convert an arbitrary function address into a function pointer; it has to either find an existing descriptor for that function, or call malloc and build its own. On some targets, it is impossible for GDB to build a descriptor at all: the descriptor must contain a jump instruction; data memory cannot be executed; and code memory cannot be modified. Upon entry to this function, if VAL is a value of type `function' (that is, TYPE_CODE (VALUE_TYPE (val)) == TYPE_CODE_FUNC), then VALUE_ADDRESS (val) is the address of the function. This is what you'll get if you evaluate an expression like `main'. The call to COERCE_ARRAY below actually does all the usual unary conversions, which includes converting values of type `function' to `pointer to function'. This is the challenging conversion discussed above. Then, `unpack_long' will convert that pointer back into an address. So, suppose the user types `disassemble foo' on an architecture with a strange function pointer representation, on which GDB cannot build its own descriptors, and suppose further that `foo' has no linker-built descriptor. The address->pointer conversion will signal an error and prevent the command from running, even though the next step would have been to convert the pointer directly back into the same address. The following shortcut avoids this whole mess. If VAL is a function, just return its address directly. */ if (TYPE_CODE (VALUE_TYPE (val)) == TYPE_CODE_FUNC || TYPE_CODE (VALUE_TYPE (val)) == TYPE_CODE_METHOD) return VALUE_ADDRESS (val); COERCE_ARRAY (val); /* Some architectures (e.g. Harvard), map instruction and data addresses onto a single large unified address space. For instance: An architecture may consider a large integer in the range 0x10000000 .. 0x1000ffff to already represent a data addresses (hence not need a pointer to address conversion) while a small integer would still need to be converted integer to pointer to address. Just assume such architectures handle all integer conversions in a single function. */ /* JimB writes: I think INTEGER_TO_ADDRESS is a good idea as proposed --- but we must admonish GDB hackers to make sure its behavior matches the compiler's, whenever possible. In general, I think GDB should evaluate expressions the same way the compiler does. When the user copies an expression out of their source code and hands it to a `print' command, they should get the same value the compiler would have computed. Any deviation from this rule can cause major confusion and annoyance, and needs to be justified carefully. In other words, GDB doesn't really have the freedom to do these conversions in clever and useful ways. AndrewC pointed out that users aren't complaining about how GDB casts integers to pointers; they are complaining that they can't take an address from a disassembly listing and give it to `x/i'. This is certainly important. Adding an architecture method like INTEGER_TO_ADDRESS certainly makes it possible for GDB to "get it right" in all circumstances --- the target has complete control over how things get done, so people can Do The Right Thing for their target without breaking anyone else. The standard doesn't specify how integers get converted to pointers; usually, the ABI doesn't either, but ABI-specific code is a more reasonable place to handle it. */ if (TYPE_CODE (VALUE_TYPE (val)) != TYPE_CODE_PTR && TYPE_CODE (VALUE_TYPE (val)) != TYPE_CODE_REF && INTEGER_TO_ADDRESS_P ()) return INTEGER_TO_ADDRESS (VALUE_TYPE (val), VALUE_CONTENTS (val)); return unpack_long (VALUE_TYPE (val), VALUE_CONTENTS (val)); #endif } /* Unpack raw data (copied from debugee, target byte order) at VALADDR as a long, or as a double, assuming the raw data is described by type TYPE. Knows how to convert different sizes of values and can convert between fixed and floating point. We don't assume any alignment for the raw data. Return value is in host byte order. If you want functions and arrays to be coerced to pointers, and references to be dereferenced, call value_as_long() instead. C++: It is assumed that the front-end has taken care of all matters concerning pointers to members. A pointer to member which reaches here is considered to be equivalent to an INT (or some size). After all, it is only an offset. */ LONGEST unpack_long (struct type *type, const char *valaddr) { register enum type_code code = TYPE_CODE (type); register int len = TYPE_LENGTH (type); register int nosign = TYPE_UNSIGNED (type); if (current_language->la_language == language_scm && is_scmvalue_type (type)) return scm_unpack (type, valaddr, TYPE_CODE_INT); switch (code) { case TYPE_CODE_TYPEDEF: return unpack_long (check_typedef (type), valaddr); case TYPE_CODE_ENUM: case TYPE_CODE_BOOL: case TYPE_CODE_INT: case TYPE_CODE_CHAR: case TYPE_CODE_RANGE: if (nosign) return extract_unsigned_integer (valaddr, len); else return extract_signed_integer (valaddr, len); case TYPE_CODE_FLT: return extract_typed_floating (valaddr, type); case TYPE_CODE_PTR: case TYPE_CODE_REF: /* Assume a CORE_ADDR can fit in a LONGEST (for now). Not sure whether we want this to be true eventually. */ return extract_typed_address (valaddr, type); case TYPE_CODE_MEMBER: error ("not implemented: member types in unpack_long"); default: error ("Value can't be converted to integer."); } return 0; /* Placate lint. */ } /* Return a double value from the specified type and address. INVP points to an int which is set to 0 for valid value, 1 for invalid value (bad float format). In either case, the returned double is OK to use. Argument is in target format, result is in host format. */ DOUBLEST unpack_double (struct type *type, const char *valaddr, int *invp) { enum type_code code; int len; int nosign; *invp = 0; /* Assume valid. */ CHECK_TYPEDEF (type); code = TYPE_CODE (type); len = TYPE_LENGTH (type); nosign = TYPE_UNSIGNED (type); if (code == TYPE_CODE_FLT) { /* NOTE: cagney/2002-02-19: There was a test here to see if the floating-point value was valid (using the macro INVALID_FLOAT). That test/macro have been removed. It turns out that only the VAX defined this macro and then only in a non-portable way. Fixing the portability problem wouldn't help since the VAX floating-point code is also badly bit-rotten. The target needs to add definitions for the methods TARGET_FLOAT_FORMAT and TARGET_DOUBLE_FORMAT - these exactly describe the target floating-point format. The problem here is that the corresponding floatformat_vax_f and floatformat_vax_d values these methods should be set to are also not defined either. Oops! Hopefully someone will add both the missing floatformat definitions and the new cases for floatformat_is_valid (). */ if (!floatformat_is_valid (floatformat_from_type (type), valaddr)) { *invp = 1; return 0.0; } return extract_typed_floating (valaddr, type); } else if (nosign) { /* Unsigned -- be sure we compensate for signed LONGEST. */ return (ULONGEST) unpack_long (type, valaddr); } else { /* Signed -- we are OK with unpack_long. */ return unpack_long (type, valaddr); } } /* Unpack raw data (copied from debugee, target byte order) at VALADDR as a CORE_ADDR, assuming the raw data is described by type TYPE. We don't assume any alignment for the raw data. Return value is in host byte order. If you want functions and arrays to be coerced to pointers, and references to be dereferenced, call value_as_address() instead. C++: It is assumed that the front-end has taken care of all matters concerning pointers to members. A pointer to member which reaches here is considered to be equivalent to an INT (or some size). After all, it is only an offset. */ CORE_ADDR unpack_pointer (struct type *type, const char *valaddr) { /* Assume a CORE_ADDR can fit in a LONGEST (for now). Not sure whether we want this to be true eventually. */ return unpack_long (type, valaddr); } /* Get the value of the FIELDN'th field (which must be static) of TYPE. Return NULL if the field doesn't exist or has been optimized out. */ struct value * value_static_field (struct type *type, int fieldno) { struct value *retval; if (TYPE_FIELD_STATIC_HAS_ADDR (type, fieldno)) { retval = value_at (TYPE_FIELD_TYPE (type, fieldno), TYPE_FIELD_STATIC_PHYSADDR (type, fieldno), NULL); } else { char *phys_name = TYPE_FIELD_STATIC_PHYSNAME (type, fieldno); struct symbol *sym = lookup_symbol (phys_name, 0, VAR_DOMAIN, 0, NULL); if (sym == NULL) { /* With some compilers, e.g. HP aCC, static data members are reported as non-debuggable symbols */ struct minimal_symbol *msym = lookup_minimal_symbol (phys_name, NULL, NULL); if (!msym) return NULL; else { retval = value_at (TYPE_FIELD_TYPE (type, fieldno), SYMBOL_VALUE_ADDRESS (msym), SYMBOL_BFD_SECTION (msym)); } } else { /* SYM should never have a SYMBOL_CLASS which will require read_var_value to use the FRAME parameter. */ if (symbol_read_needs_frame (sym)) warning ("static field's value depends on the current " "frame - bad debug info?"); retval = read_var_value (sym, NULL); } if (retval && VALUE_LVAL (retval) == lval_memory) SET_FIELD_PHYSADDR (TYPE_FIELD (type, fieldno), VALUE_ADDRESS (retval)); } return retval; } /* Change the enclosing type of a value object VAL to NEW_ENCL_TYPE. You have to be careful here, since the size of the data area for the value is set by the length of the enclosing type. So if NEW_ENCL_TYPE is bigger than the old enclosing type, you have to allocate more space for the data. The return value is a pointer to the new version of this value structure. */ struct value * value_change_enclosing_type (struct value *val, struct type *new_encl_type) { if (TYPE_LENGTH (new_encl_type) <= TYPE_LENGTH (VALUE_ENCLOSING_TYPE (val))) { VALUE_ENCLOSING_TYPE (val) = new_encl_type; return val; } else { struct value *new_val; struct value *prev; new_val = (struct value *) xrealloc (val, sizeof (struct value) + TYPE_LENGTH (new_encl_type)); VALUE_ENCLOSING_TYPE (new_val) = new_encl_type; /* We have to make sure this ends up in the same place in the value chain as the original copy, so it's clean-up behavior is the same. If the value has been released, this is a waste of time, but there is no way to tell that in advance, so... */ if (val != all_values) { for (prev = all_values; prev != NULL; prev = prev->next) { if (prev->next == val) { prev->next = new_val; break; } } } return new_val; } } /* Given a value ARG1 (offset by OFFSET bytes) of a struct or union type ARG_TYPE, extract and return the value of one of its (non-static) fields. FIELDNO says which field. */ struct value * value_primitive_field (struct value *arg1, int offset, register int fieldno, register struct type *arg_type) { struct value *v; register struct type *type; CHECK_TYPEDEF (arg_type); type = TYPE_FIELD_TYPE (arg_type, fieldno); /* Handle packed fields */ if (TYPE_FIELD_BITSIZE (arg_type, fieldno)) { v = value_from_longest (type, unpack_field_as_long (arg_type, VALUE_CONTENTS (arg1) + offset, fieldno)); VALUE_BITPOS (v) = TYPE_FIELD_BITPOS (arg_type, fieldno) % 8; VALUE_BITSIZE (v) = TYPE_FIELD_BITSIZE (arg_type, fieldno); VALUE_OFFSET (v) = VALUE_OFFSET (arg1) + offset + TYPE_FIELD_BITPOS (arg_type, fieldno) / 8; } else if (fieldno < TYPE_N_BASECLASSES (arg_type)) { /* This field is actually a base subobject, so preserve the entire object's contents for later references to virtual bases, etc. */ v = allocate_value (VALUE_ENCLOSING_TYPE (arg1)); VALUE_TYPE (v) = type; if (VALUE_LAZY (arg1)) VALUE_LAZY (v) = 1; else memcpy (VALUE_CONTENTS_ALL_RAW (v), VALUE_CONTENTS_ALL_RAW (arg1), TYPE_LENGTH (VALUE_ENCLOSING_TYPE (arg1))); VALUE_OFFSET (v) = VALUE_OFFSET (arg1); VALUE_EMBEDDED_OFFSET (v) = offset + VALUE_EMBEDDED_OFFSET (arg1) + TYPE_FIELD_BITPOS (arg_type, fieldno) / 8; } else { /* Plain old data member */ offset += TYPE_FIELD_BITPOS (arg_type, fieldno) / 8; v = allocate_value (type); if (VALUE_LAZY (arg1)) VALUE_LAZY (v) = 1; else memcpy (VALUE_CONTENTS_RAW (v), VALUE_CONTENTS_RAW (arg1) + offset, TYPE_LENGTH (type)); VALUE_OFFSET (v) = VALUE_OFFSET (arg1) + offset + VALUE_EMBEDDED_OFFSET (arg1); } VALUE_LVAL (v) = VALUE_LVAL (arg1); if (VALUE_LVAL (arg1) == lval_internalvar) VALUE_LVAL (v) = lval_internalvar_component; VALUE_ADDRESS (v) = VALUE_ADDRESS (arg1); VALUE_REGNO (v) = VALUE_REGNO (arg1); /* VALUE_OFFSET (v) = VALUE_OFFSET (arg1) + offset + TYPE_FIELD_BITPOS (arg_type, fieldno) / 8; */ return v; } /* Given a value ARG1 of a struct or union type, extract and return the value of one of its (non-static) fields. FIELDNO says which field. */ struct value * value_field (struct value *arg1, register int fieldno) { return value_primitive_field (arg1, 0, fieldno, VALUE_TYPE (arg1)); } /* Return a non-virtual function as a value. F is the list of member functions which contains the desired method. J is an index into F which provides the desired method. We only use the symbol for its address, so be happy with either a full symbol or a minimal symbol. */ struct value * value_fn_field (struct value **arg1p, struct fn_field *f, int j, struct type *type, int offset) { struct value *v; register struct type *ftype = TYPE_FN_FIELD_TYPE (f, j); char *physname = TYPE_FN_FIELD_PHYSNAME (f, j); struct symbol *sym; struct minimal_symbol *msym; sym = lookup_symbol (physname, 0, VAR_DOMAIN, 0, NULL); if (sym != NULL) { msym = NULL; } else { gdb_assert (sym == NULL); msym = lookup_minimal_symbol (physname, NULL, NULL); if (msym == NULL) return NULL; } v = allocate_value (ftype); if (sym) { VALUE_ADDRESS (v) = BLOCK_START (SYMBOL_BLOCK_VALUE (sym)); } else { VALUE_ADDRESS (v) = SYMBOL_VALUE_ADDRESS (msym); } if (arg1p) { if (type != VALUE_TYPE (*arg1p)) *arg1p = value_ind (value_cast (lookup_pointer_type (type), value_addr (*arg1p))); /* Move the `this' pointer according to the offset. VALUE_OFFSET (*arg1p) += offset; */ } return v; } /* Unpack a field FIELDNO of the specified TYPE, from the anonymous object at VALADDR. Extracting bits depends on endianness of the machine. Compute the number of least significant bits to discard. For big endian machines, we compute the total number of bits in the anonymous object, subtract off the bit count from the MSB of the object to the MSB of the bitfield, then the size of the bitfield, which leaves the LSB discard count. For little endian machines, the discard count is simply the number of bits from the LSB of the anonymous object to the LSB of the bitfield. If the field is signed, we also do sign extension. */ LONGEST unpack_field_as_long (struct type *type, const char *valaddr, int fieldno) { ULONGEST val; ULONGEST valmask; int bitpos = TYPE_FIELD_BITPOS (type, fieldno); int bitsize = TYPE_FIELD_BITSIZE (type, fieldno); int lsbcount; struct type *field_type; val = extract_unsigned_integer (valaddr + bitpos / 8, sizeof (val)); field_type = TYPE_FIELD_TYPE (type, fieldno); CHECK_TYPEDEF (field_type); /* Extract bits. See comment above. */ if (BITS_BIG_ENDIAN) lsbcount = (sizeof val * 8 - bitpos % 8 - bitsize); else lsbcount = (bitpos % 8); val >>= lsbcount; /* If the field does not entirely fill a LONGEST, then zero the sign bits. If the field is signed, and is negative, then sign extend. */ if ((bitsize > 0) && (bitsize < 8 * (int) sizeof (val))) { valmask = (((ULONGEST) 1) << bitsize) - 1; val &= valmask; if (!TYPE_UNSIGNED (field_type)) { if (val & (valmask ^ (valmask >> 1))) { val |= ~valmask; } } } return (val); } /* Modify the value of a bitfield. ADDR points to a block of memory in target byte order; the bitfield starts in the byte pointed to. FIELDVAL is the desired value of the field, in host byte order. BITPOS and BITSIZE indicate which bits (in target bit order) comprise the bitfield. */ void modify_field (char *addr, LONGEST fieldval, int bitpos, int bitsize) { LONGEST oword; /* If a negative fieldval fits in the field in question, chop off the sign extension bits. */ if (bitsize < (8 * (int) sizeof (fieldval)) && (~fieldval & ~((1 << (bitsize - 1)) - 1)) == 0) fieldval = fieldval & ((1 << bitsize) - 1); /* Warn if value is too big to fit in the field in question. */ if (bitsize < (8 * (int) sizeof (fieldval)) && 0 != (fieldval & ~((1 << bitsize) - 1))) { /* FIXME: would like to include fieldval in the message, but we don't have a sprintf_longest. */ warning ("Value does not fit in %d bits.", bitsize); /* Truncate it, otherwise adjoining fields may be corrupted. */ fieldval = fieldval & ((1 << bitsize) - 1); } oword = extract_signed_integer (addr, sizeof oword); /* Shifting for bit field depends on endianness of the target machine. */ if (BITS_BIG_ENDIAN) bitpos = sizeof (oword) * 8 - bitpos - bitsize; /* Mask out old value, while avoiding shifts >= size of oword */ if (bitsize < 8 * (int) sizeof (oword)) oword &= ~(((((ULONGEST) 1) << bitsize) - 1) << bitpos); else oword &= ~((~(ULONGEST) 0) << bitpos); oword |= fieldval << bitpos; store_signed_integer (addr, sizeof oword, oword); } /* Convert C numbers into newly allocated values */ struct value * value_from_longest (struct type *type, register LONGEST num) { struct value *val = allocate_value (type); register enum type_code code; register int len; retry: code = TYPE_CODE (type); len = TYPE_LENGTH (type); switch (code) { case TYPE_CODE_TYPEDEF: type = check_typedef (type); goto retry; case TYPE_CODE_INT: case TYPE_CODE_CHAR: case TYPE_CODE_ENUM: case TYPE_CODE_BOOL: case TYPE_CODE_RANGE: store_signed_integer (VALUE_CONTENTS_RAW (val), len, num); break; case TYPE_CODE_REF: case TYPE_CODE_PTR: store_typed_address (VALUE_CONTENTS_RAW (val), type, (CORE_ADDR) num); break; default: error ("Unexpected type (%d) encountered for integer constant.", code); } return val; } /* Create a value representing a pointer of type TYPE to the address ADDR. */ struct value * value_from_pointer (struct type *type, CORE_ADDR addr) { struct value *val = allocate_value (type); store_typed_address (VALUE_CONTENTS_RAW (val), type, addr); return val; } /* Create a value for a string constant to be stored locally (not in the inferior's memory space, but in GDB memory). This is analogous to value_from_longest, which also does not use inferior memory. String shall NOT contain embedded nulls. */ struct value * value_from_string (char *ptr) { struct value *val; int len = strlen (ptr); int lowbound = current_language->string_lower_bound; struct type *rangetype = create_range_type ((struct type *) NULL, builtin_type_int, lowbound, len + lowbound - 1); struct type *stringtype = create_array_type ((struct type *) NULL, *current_language->string_char_type, rangetype); val = allocate_value (stringtype); memcpy (VALUE_CONTENTS_RAW (val), ptr, len); return val; } struct value * value_from_double (struct type *type, DOUBLEST num) { struct value *val = allocate_value (type); struct type *base_type = check_typedef (type); register enum type_code code = TYPE_CODE (base_type); register int len = TYPE_LENGTH (base_type); if (code == TYPE_CODE_FLT) { store_typed_floating (VALUE_CONTENTS_RAW (val), base_type, num); } else error ("Unexpected type encountered for floating constant."); return val; } /* Deal with the value that is "about to be returned". */ /* Return the value that a function returning now would be returning to its caller, assuming its type is VALTYPE. RETBUF is where we look for what ought to be the contents of the registers (in raw form). This is because it is often desirable to restore old values to those registers after saving the contents of interest, and then call this function using the saved values. struct_return is non-zero when the function in question is using the structure return conventions on the machine in question; 0 when it is using the value returning conventions (this often means returning pointer to where structure is vs. returning value). */ /* ARGSUSED */ struct value * value_being_returned (struct type *valtype, struct regcache *retbuf, int struct_return) { struct value *val; CORE_ADDR addr; /* If this is not defined, just use EXTRACT_RETURN_VALUE instead. */ if (EXTRACT_STRUCT_VALUE_ADDRESS_P ()) if (struct_return) { addr = EXTRACT_STRUCT_VALUE_ADDRESS (retbuf); if (!addr) error ("Function return value unknown."); return value_at (valtype, addr, NULL); } /* If this is not defined, just use EXTRACT_RETURN_VALUE instead. */ if (DEPRECATED_EXTRACT_STRUCT_VALUE_ADDRESS_P ()) if (struct_return) { char *buf = deprecated_grub_regcache_for_registers (retbuf); addr = DEPRECATED_EXTRACT_STRUCT_VALUE_ADDRESS (buf); if (!addr) error ("Function return value unknown."); return value_at (valtype, addr, NULL); } val = allocate_value (valtype); CHECK_TYPEDEF (valtype); /* If the function returns void, don't bother fetching the return value. */ if (TYPE_CODE (valtype) != TYPE_CODE_VOID) EXTRACT_RETURN_VALUE (valtype, retbuf, VALUE_CONTENTS_RAW (val)); return val; } /* Should we use EXTRACT_STRUCT_VALUE_ADDRESS instead of EXTRACT_RETURN_VALUE? GCC_P is true if compiled with gcc and TYPE is the type (which is known to be struct, union or array). On most machines, the struct convention is used unless we are using gcc and the type is of a special size. */ /* As of about 31 Mar 93, GCC was changed to be compatible with the native compiler. GCC 2.3.3 was the last release that did it the old way. Since gcc2_compiled was not changed, we have no way to correctly win in all cases, so we just do the right thing for gcc1 and for gcc2 after this change. Thus it loses for gcc 2.0-2.3.3. This is somewhat unfortunate, but changing gcc2_compiled would cause more chaos than dealing with some struct returns being handled wrong. */ int generic_use_struct_convention (int gcc_p, struct type *value_type) { return !((gcc_p == 1) && (TYPE_LENGTH (value_type) == 1 || TYPE_LENGTH (value_type) == 2 || TYPE_LENGTH (value_type) == 4 || TYPE_LENGTH (value_type) == 8)); } /* Return true if the function specified is using the structure returning convention on this machine to return arguments, or 0 if it is using the value returning convention. FUNCTION is the value representing the function, FUNCADDR is the address of the function, and VALUE_TYPE is the type returned by the function. GCC_P is nonzero if compiled with GCC. */ /* ARGSUSED */ int using_struct_return (struct value *function, CORE_ADDR funcaddr, struct type *value_type, int gcc_p) { register enum type_code code = TYPE_CODE (value_type); if (code == TYPE_CODE_ERROR) error ("Function return type unknown."); if (code == TYPE_CODE_STRUCT || code == TYPE_CODE_UNION || code == TYPE_CODE_ARRAY || RETURN_VALUE_ON_STACK (value_type)) return USE_STRUCT_CONVENTION (gcc_p, value_type); return 0; } /* Store VAL so it will be returned if a function returns now. Does not verify that VAL's type matches what the current function wants to return. */ void set_return_value (struct value *val) { struct type *type = check_typedef (VALUE_TYPE (val)); register enum type_code code = TYPE_CODE (type); if (code == TYPE_CODE_ERROR) error ("Function return type unknown."); if (code == TYPE_CODE_STRUCT || code == TYPE_CODE_UNION) /* FIXME, implement struct return. */ error ("GDB does not support specifying a struct or union return value."); STORE_RETURN_VALUE (type, current_regcache, VALUE_CONTENTS (val)); } void _initialize_values (void) { add_cmd ("convenience", no_class, show_convenience, "Debugger convenience (\"$foo\") variables.\n\ These variables are created when you assign them values;\n\ thus, \"print $foo=1\" gives \"$foo\" the value 1. Values may be any type.\n\n\ A few convenience variables are given values automatically:\n\ \"$_\"holds the last address examined with \"x\" or \"info lines\",\n\ \"$__\" holds the contents of the last address examined with \"x\".", &showlist); add_cmd ("values", no_class, show_values, "Elements of value history around item number IDX (or last ten).", &showlist); }