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[/] [openrisc/] [trunk/] [gnu-src/] [gdb-7.2/] [gdb/] [valprint.c] - Rev 635
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/* Print values for GDB, the GNU debugger. Copyright (C) 1986, 1988, 1989, 1990, 1991, 1992, 1993, 1994, 1995, 1996, 1997, 1998, 1999, 2000, 2001, 2002, 2003, 2004, 2005, 2006, 2007, 2008, 2009, 2010 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 3 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, see <http://www.gnu.org/licenses/>. */ #include "defs.h" #include "gdb_string.h" #include "symtab.h" #include "gdbtypes.h" #include "value.h" #include "gdbcore.h" #include "gdbcmd.h" #include "target.h" #include "language.h" #include "annotate.h" #include "valprint.h" #include "floatformat.h" #include "doublest.h" #include "exceptions.h" #include "dfp.h" #include "python/python.h" #include "ada-lang.h" #include <errno.h> /* Prototypes for local functions */ static int partial_memory_read (CORE_ADDR memaddr, gdb_byte *myaddr, int len, int *errnoptr); static void show_print (char *, int); static void set_print (char *, int); static void set_radix (char *, int); static void show_radix (char *, int); static void set_input_radix (char *, int, struct cmd_list_element *); static void set_input_radix_1 (int, unsigned); static void set_output_radix (char *, int, struct cmd_list_element *); static void set_output_radix_1 (int, unsigned); void _initialize_valprint (void); #define PRINT_MAX_DEFAULT 200 /* Start print_max off at this value. */ struct value_print_options user_print_options = { Val_pretty_default, /* pretty */ 0, /* prettyprint_arrays */ 0, /* prettyprint_structs */ 0, /* vtblprint */ 1, /* unionprint */ 1, /* addressprint */ 0, /* objectprint */ PRINT_MAX_DEFAULT, /* print_max */ 10, /* repeat_count_threshold */ 0, /* output_format */ 0, /* format */ 0, /* stop_print_at_null */ 0, /* inspect_it */ 0, /* print_array_indexes */ 0, /* deref_ref */ 1, /* static_field_print */ 1, /* pascal_static_field_print */ 0, /* raw */ 0 /* summary */ }; /* Initialize *OPTS to be a copy of the user print options. */ void get_user_print_options (struct value_print_options *opts) { *opts = user_print_options; } /* Initialize *OPTS to be a copy of the user print options, but with pretty-printing disabled. */ void get_raw_print_options (struct value_print_options *opts) { *opts = user_print_options; opts->pretty = Val_no_prettyprint; } /* Initialize *OPTS to be a copy of the user print options, but using FORMAT as the formatting option. */ void get_formatted_print_options (struct value_print_options *opts, char format) { *opts = user_print_options; opts->format = format; } static void show_print_max (struct ui_file *file, int from_tty, struct cmd_list_element *c, const char *value) { fprintf_filtered (file, _("\ Limit on string chars or array elements to print is %s.\n"), value); } /* Default input and output radixes, and output format letter. */ unsigned input_radix = 10; static void show_input_radix (struct ui_file *file, int from_tty, struct cmd_list_element *c, const char *value) { fprintf_filtered (file, _("\ Default input radix for entering numbers is %s.\n"), value); } unsigned output_radix = 10; static void show_output_radix (struct ui_file *file, int from_tty, struct cmd_list_element *c, const char *value) { fprintf_filtered (file, _("\ Default output radix for printing of values is %s.\n"), value); } /* By default we print arrays without printing the index of each element in the array. This behavior can be changed by setting PRINT_ARRAY_INDEXES. */ static void show_print_array_indexes (struct ui_file *file, int from_tty, struct cmd_list_element *c, const char *value) { fprintf_filtered (file, _("Printing of array indexes is %s.\n"), value); } /* Print repeat counts if there are more than this many repetitions of an element in an array. Referenced by the low level language dependent print routines. */ static void show_repeat_count_threshold (struct ui_file *file, int from_tty, struct cmd_list_element *c, const char *value) { fprintf_filtered (file, _("Threshold for repeated print elements is %s.\n"), value); } /* If nonzero, stops printing of char arrays at first null. */ static void show_stop_print_at_null (struct ui_file *file, int from_tty, struct cmd_list_element *c, const char *value) { fprintf_filtered (file, _("\ Printing of char arrays to stop at first null char is %s.\n"), value); } /* Controls pretty printing of structures. */ static void show_prettyprint_structs (struct ui_file *file, int from_tty, struct cmd_list_element *c, const char *value) { fprintf_filtered (file, _("Prettyprinting of structures is %s.\n"), value); } /* Controls pretty printing of arrays. */ static void show_prettyprint_arrays (struct ui_file *file, int from_tty, struct cmd_list_element *c, const char *value) { fprintf_filtered (file, _("Prettyprinting of arrays is %s.\n"), value); } /* If nonzero, causes unions inside structures or other unions to be printed. */ static void show_unionprint (struct ui_file *file, int from_tty, struct cmd_list_element *c, const char *value) { fprintf_filtered (file, _("\ Printing of unions interior to structures is %s.\n"), value); } /* If nonzero, causes machine addresses to be printed in certain contexts. */ static void show_addressprint (struct ui_file *file, int from_tty, struct cmd_list_element *c, const char *value) { fprintf_filtered (file, _("Printing of addresses is %s.\n"), value); } /* A helper function for val_print. When printing in "summary" mode, we want to print scalar arguments, but not aggregate arguments. This function distinguishes between the two. */ static int scalar_type_p (struct type *type) { CHECK_TYPEDEF (type); while (TYPE_CODE (type) == TYPE_CODE_REF) { type = TYPE_TARGET_TYPE (type); CHECK_TYPEDEF (type); } switch (TYPE_CODE (type)) { case TYPE_CODE_ARRAY: case TYPE_CODE_STRUCT: case TYPE_CODE_UNION: case TYPE_CODE_SET: case TYPE_CODE_STRING: case TYPE_CODE_BITSTRING: return 0; default: return 1; } } /* Helper function to check the validity of some bits of a value. If TYPE represents some aggregate type (e.g., a structure), return 1. Otherwise, any of the bytes starting at OFFSET and extending for TYPE_LENGTH(TYPE) bytes are invalid, print a message to STREAM and return 0. The checking is done using FUNCS. Otherwise, return 1. */ static int valprint_check_validity (struct ui_file *stream, struct type *type, int offset, const struct value *val) { CHECK_TYPEDEF (type); if (TYPE_CODE (type) != TYPE_CODE_UNION && TYPE_CODE (type) != TYPE_CODE_STRUCT && TYPE_CODE (type) != TYPE_CODE_ARRAY) { if (! value_bits_valid (val, TARGET_CHAR_BIT * offset, TARGET_CHAR_BIT * TYPE_LENGTH (type))) { fprintf_filtered (stream, _("<value optimized out>")); return 0; } } return 1; } /* Print using the given LANGUAGE the data of type TYPE located at VALADDR (within GDB), which came from the inferior at address ADDRESS, onto stdio stream STREAM according to OPTIONS. If the data are a string pointer, returns the number of string characters printed. FIXME: The data at VALADDR is in target byte order. If gdb is ever enhanced to be able to debug more than the single target it was compiled for (specific CPU type and thus specific target byte ordering), then either the print routines are going to have to take this into account, or the data is going to have to be passed into here already converted to the host byte ordering, whichever is more convenient. */ int val_print (struct type *type, const gdb_byte *valaddr, int embedded_offset, CORE_ADDR address, struct ui_file *stream, int recurse, const struct value *val, const struct value_print_options *options, const struct language_defn *language) { volatile struct gdb_exception except; int ret = 0; struct value_print_options local_opts = *options; struct type *real_type = check_typedef (type); if (local_opts.pretty == Val_pretty_default) local_opts.pretty = (local_opts.prettyprint_structs ? Val_prettyprint : Val_no_prettyprint); QUIT; /* Ensure that the type is complete and not just a stub. If the type is only a stub and we can't find and substitute its complete type, then print appropriate string and return. */ if (TYPE_STUB (real_type)) { fprintf_filtered (stream, _("<incomplete type>")); gdb_flush (stream); return (0); } if (!valprint_check_validity (stream, real_type, embedded_offset, val)) return 0; if (!options->raw) { ret = apply_val_pretty_printer (type, valaddr, embedded_offset, address, stream, recurse, val, options, language); if (ret) return ret; } /* Handle summary mode. If the value is a scalar, print it; otherwise, print an ellipsis. */ if (options->summary && !scalar_type_p (type)) { fprintf_filtered (stream, "..."); return 0; } TRY_CATCH (except, RETURN_MASK_ERROR) { ret = language->la_val_print (type, valaddr, embedded_offset, address, stream, recurse, val, &local_opts); } if (except.reason < 0) fprintf_filtered (stream, _("<error reading variable>")); return ret; } /* Check whether the value VAL is printable. Return 1 if it is; return 0 and print an appropriate error message to STREAM if it is not. */ static int value_check_printable (struct value *val, struct ui_file *stream) { if (val == 0) { fprintf_filtered (stream, _("<address of value unknown>")); return 0; } if (value_entirely_optimized_out (val)) { fprintf_filtered (stream, _("<value optimized out>")); return 0; } if (TYPE_CODE (value_type (val)) == TYPE_CODE_INTERNAL_FUNCTION) { fprintf_filtered (stream, _("<internal function %s>"), value_internal_function_name (val)); return 0; } return 1; } /* Print using the given LANGUAGE the value VAL onto stream STREAM according to OPTIONS. If the data are a string pointer, returns the number of string characters printed. This is a preferable interface to val_print, above, because it uses GDB's value mechanism. */ int common_val_print (struct value *val, struct ui_file *stream, int recurse, const struct value_print_options *options, const struct language_defn *language) { if (!value_check_printable (val, stream)) return 0; if (language->la_language == language_ada) /* The value might have a dynamic type, which would cause trouble below when trying to extract the value contents (since the value size is determined from the type size which is unknown). So get a fixed representation of our value. */ val = ada_to_fixed_value (val); return val_print (value_type (val), value_contents_for_printing (val), value_embedded_offset (val), value_address (val), stream, recurse, val, options, language); } /* Print on stream STREAM the value VAL according to OPTIONS. The value is printed using the current_language syntax. If the object printed is a string pointer, return the number of string bytes printed. */ int value_print (struct value *val, struct ui_file *stream, const struct value_print_options *options) { if (!value_check_printable (val, stream)) return 0; if (!options->raw) { int r = apply_val_pretty_printer (value_type (val), value_contents_for_printing (val), value_embedded_offset (val), value_address (val), stream, 0, val, options, current_language); if (r) return r; } return LA_VALUE_PRINT (val, stream, options); } /* Called by various <lang>_val_print routines to print TYPE_CODE_INT's. TYPE is the type. VALADDR is the address of the value. STREAM is where to print the value. */ void val_print_type_code_int (struct type *type, const gdb_byte *valaddr, struct ui_file *stream) { enum bfd_endian byte_order = gdbarch_byte_order (get_type_arch (type)); if (TYPE_LENGTH (type) > sizeof (LONGEST)) { LONGEST val; if (TYPE_UNSIGNED (type) && extract_long_unsigned_integer (valaddr, TYPE_LENGTH (type), byte_order, &val)) { print_longest (stream, 'u', 0, val); } else { /* Signed, or we couldn't turn an unsigned value into a LONGEST. For signed values, one could assume two's complement (a reasonable assumption, I think) and do better than this. */ print_hex_chars (stream, (unsigned char *) valaddr, TYPE_LENGTH (type), byte_order); } } else { print_longest (stream, TYPE_UNSIGNED (type) ? 'u' : 'd', 0, unpack_long (type, valaddr)); } } void val_print_type_code_flags (struct type *type, const gdb_byte *valaddr, struct ui_file *stream) { ULONGEST val = unpack_long (type, valaddr); int bitpos, nfields = TYPE_NFIELDS (type); fputs_filtered ("[ ", stream); for (bitpos = 0; bitpos < nfields; bitpos++) { if (TYPE_FIELD_BITPOS (type, bitpos) != -1 && (val & ((ULONGEST)1 << bitpos))) { if (TYPE_FIELD_NAME (type, bitpos)) fprintf_filtered (stream, "%s ", TYPE_FIELD_NAME (type, bitpos)); else fprintf_filtered (stream, "#%d ", bitpos); } } fputs_filtered ("]", stream); } /* Print a number according to FORMAT which is one of d,u,x,o,b,h,w,g. The raison d'etre of this function is to consolidate printing of LONG_LONG's into this one function. The format chars b,h,w,g are from print_scalar_formatted(). Numbers are printed using C format. USE_C_FORMAT means to use C format in all cases. Without it, 'o' and 'x' format do not include the standard C radix prefix (leading 0 or 0x). Hilfinger/2004-09-09: USE_C_FORMAT was originally called USE_LOCAL and was intended to request formating according to the current language and would be used for most integers that GDB prints. The exceptional cases were things like protocols where the format of the integer is a protocol thing, not a user-visible thing). The parameter remains to preserve the information of what things might be printed with language-specific format, should we ever resurrect that capability. */ void print_longest (struct ui_file *stream, int format, int use_c_format, LONGEST val_long) { const char *val; switch (format) { case 'd': val = int_string (val_long, 10, 1, 0, 1); break; case 'u': val = int_string (val_long, 10, 0, 0, 1); break; case 'x': val = int_string (val_long, 16, 0, 0, use_c_format); break; case 'b': val = int_string (val_long, 16, 0, 2, 1); break; case 'h': val = int_string (val_long, 16, 0, 4, 1); break; case 'w': val = int_string (val_long, 16, 0, 8, 1); break; case 'g': val = int_string (val_long, 16, 0, 16, 1); break; break; case 'o': val = int_string (val_long, 8, 0, 0, use_c_format); break; default: internal_error (__FILE__, __LINE__, _("failed internal consistency check")); } fputs_filtered (val, stream); } /* This used to be a macro, but I don't think it is called often enough to merit such treatment. */ /* Convert a LONGEST to an int. This is used in contexts (e.g. number of arguments to a function, number in a value history, register number, etc.) where the value must not be larger than can fit in an int. */ int longest_to_int (LONGEST arg) { /* Let the compiler do the work */ int rtnval = (int) arg; /* Check for overflows or underflows */ if (sizeof (LONGEST) > sizeof (int)) { if (rtnval != arg) { error (_("Value out of range.")); } } return (rtnval); } /* Print a floating point value of type TYPE (not always a TYPE_CODE_FLT), pointed to in GDB by VALADDR, on STREAM. */ void print_floating (const gdb_byte *valaddr, struct type *type, struct ui_file *stream) { DOUBLEST doub; int inv; const struct floatformat *fmt = NULL; unsigned len = TYPE_LENGTH (type); enum float_kind kind; /* If it is a floating-point, check for obvious problems. */ if (TYPE_CODE (type) == TYPE_CODE_FLT) fmt = floatformat_from_type (type); if (fmt != NULL) { kind = floatformat_classify (fmt, valaddr); if (kind == float_nan) { if (floatformat_is_negative (fmt, valaddr)) fprintf_filtered (stream, "-"); fprintf_filtered (stream, "nan("); fputs_filtered ("0x", stream); fputs_filtered (floatformat_mantissa (fmt, valaddr), stream); fprintf_filtered (stream, ")"); return; } else if (kind == float_infinite) { if (floatformat_is_negative (fmt, valaddr)) fputs_filtered ("-", stream); fputs_filtered ("inf", stream); return; } } /* NOTE: cagney/2002-01-15: The TYPE passed into print_floating() isn't necessarily a TYPE_CODE_FLT. Consequently, unpack_double needs to be used as that takes care of any necessary type conversions. Such conversions are of course direct to DOUBLEST and disregard any possible target floating point limitations. For instance, a u64 would be converted and displayed exactly on a host with 80 bit DOUBLEST but with loss of information on a host with 64 bit DOUBLEST. */ doub = unpack_double (type, valaddr, &inv); if (inv) { fprintf_filtered (stream, "<invalid float value>"); return; } /* FIXME: kettenis/2001-01-20: The following code makes too much assumptions about the host and target floating point format. */ /* NOTE: cagney/2002-02-03: Since the TYPE of what was passed in may not necessarily be a TYPE_CODE_FLT, the below ignores that and instead uses the type's length to determine the precision of the floating-point value being printed. */ if (len < sizeof (double)) fprintf_filtered (stream, "%.9g", (double) doub); else if (len == sizeof (double)) fprintf_filtered (stream, "%.17g", (double) doub); else #ifdef PRINTF_HAS_LONG_DOUBLE fprintf_filtered (stream, "%.35Lg", doub); #else /* This at least wins with values that are representable as doubles. */ fprintf_filtered (stream, "%.17g", (double) doub); #endif } void print_decimal_floating (const gdb_byte *valaddr, struct type *type, struct ui_file *stream) { enum bfd_endian byte_order = gdbarch_byte_order (get_type_arch (type)); char decstr[MAX_DECIMAL_STRING]; unsigned len = TYPE_LENGTH (type); decimal_to_string (valaddr, len, byte_order, decstr); fputs_filtered (decstr, stream); return; } void print_binary_chars (struct ui_file *stream, const gdb_byte *valaddr, unsigned len, enum bfd_endian byte_order) { #define BITS_IN_BYTES 8 const gdb_byte *p; unsigned int i; int b; /* Declared "int" so it will be signed. * This ensures that right shift will shift in zeros. */ const int mask = 0x080; /* FIXME: We should be not printing leading zeroes in most cases. */ if (byte_order == BFD_ENDIAN_BIG) { for (p = valaddr; p < valaddr + len; p++) { /* Every byte has 8 binary characters; peel off * and print from the MSB end. */ for (i = 0; i < (BITS_IN_BYTES * sizeof (*p)); i++) { if (*p & (mask >> i)) b = 1; else b = 0; fprintf_filtered (stream, "%1d", b); } } } else { for (p = valaddr + len - 1; p >= valaddr; p--) { for (i = 0; i < (BITS_IN_BYTES * sizeof (*p)); i++) { if (*p & (mask >> i)) b = 1; else b = 0; fprintf_filtered (stream, "%1d", b); } } } } /* VALADDR points to an integer of LEN bytes. * Print it in octal on stream or format it in buf. */ void print_octal_chars (struct ui_file *stream, const gdb_byte *valaddr, unsigned len, enum bfd_endian byte_order) { const gdb_byte *p; unsigned char octa1, octa2, octa3, carry; int cycle; /* FIXME: We should be not printing leading zeroes in most cases. */ /* Octal is 3 bits, which doesn't fit. Yuk. So we have to track * the extra bits, which cycle every three bytes: * * Byte side: 0 1 2 3 * | | | | * bit number 123 456 78 | 9 012 345 6 | 78 901 234 | 567 890 12 | * * Octal side: 0 1 carry 3 4 carry ... * * Cycle number: 0 1 2 * * But of course we are printing from the high side, so we have to * figure out where in the cycle we are so that we end up with no * left over bits at the end. */ #define BITS_IN_OCTAL 3 #define HIGH_ZERO 0340 #define LOW_ZERO 0016 #define CARRY_ZERO 0003 #define HIGH_ONE 0200 #define MID_ONE 0160 #define LOW_ONE 0016 #define CARRY_ONE 0001 #define HIGH_TWO 0300 #define MID_TWO 0070 #define LOW_TWO 0007 /* For 32 we start in cycle 2, with two bits and one bit carry; * for 64 in cycle in cycle 1, with one bit and a two bit carry. */ cycle = (len * BITS_IN_BYTES) % BITS_IN_OCTAL; carry = 0; fputs_filtered ("0", stream); if (byte_order == BFD_ENDIAN_BIG) { for (p = valaddr; p < valaddr + len; p++) { switch (cycle) { case 0: /* No carry in, carry out two bits. */ octa1 = (HIGH_ZERO & *p) >> 5; octa2 = (LOW_ZERO & *p) >> 2; carry = (CARRY_ZERO & *p); fprintf_filtered (stream, "%o", octa1); fprintf_filtered (stream, "%o", octa2); break; case 1: /* Carry in two bits, carry out one bit. */ octa1 = (carry << 1) | ((HIGH_ONE & *p) >> 7); octa2 = (MID_ONE & *p) >> 4; octa3 = (LOW_ONE & *p) >> 1; carry = (CARRY_ONE & *p); fprintf_filtered (stream, "%o", octa1); fprintf_filtered (stream, "%o", octa2); fprintf_filtered (stream, "%o", octa3); break; case 2: /* Carry in one bit, no carry out. */ octa1 = (carry << 2) | ((HIGH_TWO & *p) >> 6); octa2 = (MID_TWO & *p) >> 3; octa3 = (LOW_TWO & *p); carry = 0; fprintf_filtered (stream, "%o", octa1); fprintf_filtered (stream, "%o", octa2); fprintf_filtered (stream, "%o", octa3); break; default: error (_("Internal error in octal conversion;")); } cycle++; cycle = cycle % BITS_IN_OCTAL; } } else { for (p = valaddr + len - 1; p >= valaddr; p--) { switch (cycle) { case 0: /* Carry out, no carry in */ octa1 = (HIGH_ZERO & *p) >> 5; octa2 = (LOW_ZERO & *p) >> 2; carry = (CARRY_ZERO & *p); fprintf_filtered (stream, "%o", octa1); fprintf_filtered (stream, "%o", octa2); break; case 1: /* Carry in, carry out */ octa1 = (carry << 1) | ((HIGH_ONE & *p) >> 7); octa2 = (MID_ONE & *p) >> 4; octa3 = (LOW_ONE & *p) >> 1; carry = (CARRY_ONE & *p); fprintf_filtered (stream, "%o", octa1); fprintf_filtered (stream, "%o", octa2); fprintf_filtered (stream, "%o", octa3); break; case 2: /* Carry in, no carry out */ octa1 = (carry << 2) | ((HIGH_TWO & *p) >> 6); octa2 = (MID_TWO & *p) >> 3; octa3 = (LOW_TWO & *p); carry = 0; fprintf_filtered (stream, "%o", octa1); fprintf_filtered (stream, "%o", octa2); fprintf_filtered (stream, "%o", octa3); break; default: error (_("Internal error in octal conversion;")); } cycle++; cycle = cycle % BITS_IN_OCTAL; } } } /* VALADDR points to an integer of LEN bytes. * Print it in decimal on stream or format it in buf. */ void print_decimal_chars (struct ui_file *stream, const gdb_byte *valaddr, unsigned len, enum bfd_endian byte_order) { #define TEN 10 #define CARRY_OUT( x ) ((x) / TEN) /* extend char to int */ #define CARRY_LEFT( x ) ((x) % TEN) #define SHIFT( x ) ((x) << 4) #define LOW_NIBBLE( x ) ( (x) & 0x00F) #define HIGH_NIBBLE( x ) (((x) & 0x0F0) >> 4) const gdb_byte *p; unsigned char *digits; int carry; int decimal_len; int i, j, decimal_digits; int dummy; int flip; /* Base-ten number is less than twice as many digits * as the base 16 number, which is 2 digits per byte. */ decimal_len = len * 2 * 2; digits = xmalloc (decimal_len); for (i = 0; i < decimal_len; i++) { digits[i] = 0; } /* Ok, we have an unknown number of bytes of data to be printed in * decimal. * * Given a hex number (in nibbles) as XYZ, we start by taking X and * decemalizing it as "x1 x2" in two decimal nibbles. Then we multiply * the nibbles by 16, add Y and re-decimalize. Repeat with Z. * * The trick is that "digits" holds a base-10 number, but sometimes * the individual digits are > 10. * * Outer loop is per nibble (hex digit) of input, from MSD end to * LSD end. */ decimal_digits = 0; /* Number of decimal digits so far */ p = (byte_order == BFD_ENDIAN_BIG) ? valaddr : valaddr + len - 1; flip = 0; while ((byte_order == BFD_ENDIAN_BIG) ? (p < valaddr + len) : (p >= valaddr)) { /* * Multiply current base-ten number by 16 in place. * Each digit was between 0 and 9, now is between * 0 and 144. */ for (j = 0; j < decimal_digits; j++) { digits[j] = SHIFT (digits[j]); } /* Take the next nibble off the input and add it to what * we've got in the LSB position. Bottom 'digit' is now * between 0 and 159. * * "flip" is used to run this loop twice for each byte. */ if (flip == 0) { /* Take top nibble. */ digits[0] += HIGH_NIBBLE (*p); flip = 1; } else { /* Take low nibble and bump our pointer "p". */ digits[0] += LOW_NIBBLE (*p); if (byte_order == BFD_ENDIAN_BIG) p++; else p--; flip = 0; } /* Re-decimalize. We have to do this often enough * that we don't overflow, but once per nibble is * overkill. Easier this way, though. Note that the * carry is often larger than 10 (e.g. max initial * carry out of lowest nibble is 15, could bubble all * the way up greater than 10). So we have to do * the carrying beyond the last current digit. */ carry = 0; for (j = 0; j < decimal_len - 1; j++) { digits[j] += carry; /* "/" won't handle an unsigned char with * a value that if signed would be negative. * So extend to longword int via "dummy". */ dummy = digits[j]; carry = CARRY_OUT (dummy); digits[j] = CARRY_LEFT (dummy); if (j >= decimal_digits && carry == 0) { /* * All higher digits are 0 and we * no longer have a carry. * * Note: "j" is 0-based, "decimal_digits" is * 1-based. */ decimal_digits = j + 1; break; } } } /* Ok, now "digits" is the decimal representation, with * the "decimal_digits" actual digits. Print! */ for (i = decimal_digits - 1; i >= 0; i--) { fprintf_filtered (stream, "%1d", digits[i]); } xfree (digits); } /* VALADDR points to an integer of LEN bytes. Print it in hex on stream. */ void print_hex_chars (struct ui_file *stream, const gdb_byte *valaddr, unsigned len, enum bfd_endian byte_order) { const gdb_byte *p; /* FIXME: We should be not printing leading zeroes in most cases. */ fputs_filtered ("0x", stream); if (byte_order == BFD_ENDIAN_BIG) { for (p = valaddr; p < valaddr + len; p++) { fprintf_filtered (stream, "%02x", *p); } } else { for (p = valaddr + len - 1; p >= valaddr; p--) { fprintf_filtered (stream, "%02x", *p); } } } /* VALADDR points to a char integer of LEN bytes. Print it out in appropriate language form on stream. Omit any leading zero chars. */ void print_char_chars (struct ui_file *stream, struct type *type, const gdb_byte *valaddr, unsigned len, enum bfd_endian byte_order) { const gdb_byte *p; if (byte_order == BFD_ENDIAN_BIG) { p = valaddr; while (p < valaddr + len - 1 && *p == 0) ++p; while (p < valaddr + len) { LA_EMIT_CHAR (*p, type, stream, '\''); ++p; } } else { p = valaddr + len - 1; while (p > valaddr && *p == 0) --p; while (p >= valaddr) { LA_EMIT_CHAR (*p, type, stream, '\''); --p; } } } /* Assuming TYPE is a simple, non-empty array type, compute its upper and lower bound. Save the low bound into LOW_BOUND if not NULL. Save the high bound into HIGH_BOUND if not NULL. Return 1 if the operation was successful. Return zero otherwise, in which case the values of LOW_BOUND and HIGH_BOUNDS are unmodified. We now simply use get_discrete_bounds call to get the values of the low and high bounds. get_discrete_bounds can return three values: 1, meaning that index is a range, 0, meaning that index is a discrete type, or -1 for failure. */ int get_array_bounds (struct type *type, LONGEST *low_bound, LONGEST *high_bound) { struct type *index = TYPE_INDEX_TYPE (type); LONGEST low = 0; LONGEST high = 0; int res; if (index == NULL) return 0; res = get_discrete_bounds (index, &low, &high); if (res == -1) return 0; if (low_bound) *low_bound = low; if (high_bound) *high_bound = high; return 1; } /* Print on STREAM using the given OPTIONS the index for the element at INDEX of an array whose index type is INDEX_TYPE. */ void maybe_print_array_index (struct type *index_type, LONGEST index, struct ui_file *stream, const struct value_print_options *options) { struct value *index_value; if (!options->print_array_indexes) return; index_value = value_from_longest (index_type, index); LA_PRINT_ARRAY_INDEX (index_value, stream, options); } /* Called by various <lang>_val_print routines to print elements of an array in the form "<elem1>, <elem2>, <elem3>, ...". (FIXME?) Assumes array element separator is a comma, which is correct for all languages currently handled. (FIXME?) Some languages have a notation for repeated array elements, perhaps we should try to use that notation when appropriate. */ void val_print_array_elements (struct type *type, const gdb_byte *valaddr, CORE_ADDR address, struct ui_file *stream, int recurse, const struct value *val, const struct value_print_options *options, unsigned int i) { unsigned int things_printed = 0; unsigned len; struct type *elttype, *index_type; unsigned eltlen; /* Position of the array element we are examining to see whether it is repeated. */ unsigned int rep1; /* Number of repetitions we have detected so far. */ unsigned int reps; LONGEST low_bound_index = 0; elttype = TYPE_TARGET_TYPE (type); eltlen = TYPE_LENGTH (check_typedef (elttype)); index_type = TYPE_INDEX_TYPE (type); /* Compute the number of elements in the array. On most arrays, the size of its elements is not zero, and so the number of elements is simply the size of the array divided by the size of the elements. But for arrays of elements whose size is zero, we need to look at the bounds. */ if (eltlen != 0) len = TYPE_LENGTH (type) / eltlen; else { LONGEST low, hi; if (get_array_bounds (type, &low, &hi)) len = hi - low + 1; else { warning (_("unable to get bounds of array, assuming null array")); len = 0; } } /* Get the array low bound. This only makes sense if the array has one or more element in it. */ if (len > 0 && !get_array_bounds (type, &low_bound_index, NULL)) { warning (_("unable to get low bound of array, using zero as default")); low_bound_index = 0; } annotate_array_section_begin (i, elttype); for (; i < len && things_printed < options->print_max; i++) { if (i != 0) { if (options->prettyprint_arrays) { fprintf_filtered (stream, ",\n"); print_spaces_filtered (2 + 2 * recurse, stream); } else { fprintf_filtered (stream, ", "); } } wrap_here (n_spaces (2 + 2 * recurse)); maybe_print_array_index (index_type, i + low_bound_index, stream, options); rep1 = i + 1; reps = 1; while ((rep1 < len) && !memcmp (valaddr + i * eltlen, valaddr + rep1 * eltlen, eltlen)) { ++reps; ++rep1; } if (reps > options->repeat_count_threshold) { val_print (elttype, valaddr + i * eltlen, 0, address + i * eltlen, stream, recurse + 1, val, options, current_language); annotate_elt_rep (reps); fprintf_filtered (stream, " <repeats %u times>", reps); annotate_elt_rep_end (); i = rep1 - 1; things_printed += options->repeat_count_threshold; } else { val_print (elttype, valaddr + i * eltlen, 0, address + i * eltlen, stream, recurse + 1, val, options, current_language); annotate_elt (); things_printed++; } } annotate_array_section_end (); if (i < len) { fprintf_filtered (stream, "..."); } } /* Read LEN bytes of target memory at address MEMADDR, placing the results in GDB's memory at MYADDR. Returns a count of the bytes actually read, and optionally an errno value in the location pointed to by ERRNOPTR if ERRNOPTR is non-null. */ /* FIXME: cagney/1999-10-14: Only used by val_print_string. Can this function be eliminated. */ static int partial_memory_read (CORE_ADDR memaddr, gdb_byte *myaddr, int len, int *errnoptr) { int nread; /* Number of bytes actually read. */ int errcode; /* Error from last read. */ /* First try a complete read. */ errcode = target_read_memory (memaddr, myaddr, len); if (errcode == 0) { /* Got it all. */ nread = len; } else { /* Loop, reading one byte at a time until we get as much as we can. */ for (errcode = 0, nread = 0; len > 0 && errcode == 0; nread++, len--) { errcode = target_read_memory (memaddr++, myaddr++, 1); } /* If an error, the last read was unsuccessful, so adjust count. */ if (errcode != 0) { nread--; } } if (errnoptr != NULL) { *errnoptr = errcode; } return (nread); } /* Read a string from the inferior, at ADDR, with LEN characters of WIDTH bytes each. Fetch at most FETCHLIMIT characters. BUFFER will be set to a newly allocated buffer containing the string, which the caller is responsible to free, and BYTES_READ will be set to the number of bytes read. Returns 0 on success, or errno on failure. If LEN > 0, reads exactly LEN characters (including eventual NULs in the middle or end of the string). If LEN is -1, stops at the first null character (not necessarily the first null byte) up to a maximum of FETCHLIMIT characters. Set FETCHLIMIT to UINT_MAX to read as many characters as possible from the string. Unless an exception is thrown, BUFFER will always be allocated, even on failure. In this case, some characters might have been read before the failure happened. Check BYTES_READ to recognize this situation. Note: There was a FIXME asking to make this code use target_read_string, but this function is more general (can read past null characters, up to given LEN). Besides, it is used much more often than target_read_string so it is more tested. Perhaps callers of target_read_string should use this function instead? */ int read_string (CORE_ADDR addr, int len, int width, unsigned int fetchlimit, enum bfd_endian byte_order, gdb_byte **buffer, int *bytes_read) { int found_nul; /* Non-zero if we found the nul char. */ int errcode; /* Errno returned from bad reads. */ unsigned int nfetch; /* Chars to fetch / chars fetched. */ unsigned int chunksize; /* Size of each fetch, in chars. */ gdb_byte *bufptr; /* Pointer to next available byte in buffer. */ gdb_byte *limit; /* First location past end of fetch buffer. */ struct cleanup *old_chain = NULL; /* Top of the old cleanup chain. */ /* Decide how large of chunks to try to read in one operation. This is also pretty simple. If LEN >= zero, then we want fetchlimit chars, so we might as well read them all in one operation. If LEN is -1, we are looking for a NUL terminator to end the fetching, so we might as well read in blocks that are large enough to be efficient, but not so large as to be slow if fetchlimit happens to be large. So we choose the minimum of 8 and fetchlimit. We used to use 200 instead of 8 but 200 is way too big for remote debugging over a serial line. */ chunksize = (len == -1 ? min (8, fetchlimit) : fetchlimit); /* Loop until we either have all the characters, or we encounter some error, such as bumping into the end of the address space. */ found_nul = 0; *buffer = NULL; old_chain = make_cleanup (free_current_contents, buffer); if (len > 0) { *buffer = (gdb_byte *) xmalloc (len * width); bufptr = *buffer; nfetch = partial_memory_read (addr, bufptr, len * width, &errcode) / width; addr += nfetch * width; bufptr += nfetch * width; } else if (len == -1) { unsigned long bufsize = 0; do { QUIT; nfetch = min (chunksize, fetchlimit - bufsize); if (*buffer == NULL) *buffer = (gdb_byte *) xmalloc (nfetch * width); else *buffer = (gdb_byte *) xrealloc (*buffer, (nfetch + bufsize) * width); bufptr = *buffer + bufsize * width; bufsize += nfetch; /* Read as much as we can. */ nfetch = partial_memory_read (addr, bufptr, nfetch * width, &errcode) / width; /* Scan this chunk for the null character that terminates the string to print. If found, we don't need to fetch any more. Note that bufptr is explicitly left pointing at the next character after the null character, or at the next character after the end of the buffer. */ limit = bufptr + nfetch * width; while (bufptr < limit) { unsigned long c; c = extract_unsigned_integer (bufptr, width, byte_order); addr += width; bufptr += width; if (c == 0) { /* We don't care about any error which happened after the NUL terminator. */ errcode = 0; found_nul = 1; break; } } } while (errcode == 0 /* no error */ && bufptr - *buffer < fetchlimit * width /* no overrun */ && !found_nul); /* haven't found NUL yet */ } else { /* Length of string is really 0! */ /* We always allocate *buffer. */ *buffer = bufptr = xmalloc (1); errcode = 0; } /* bufptr and addr now point immediately beyond the last byte which we consider part of the string (including a '\0' which ends the string). */ *bytes_read = bufptr - *buffer; QUIT; discard_cleanups (old_chain); return errcode; } /* Print a string from the inferior, starting at ADDR and printing up to LEN characters, of WIDTH bytes a piece, to STREAM. If LEN is -1, printing stops at the first null byte, otherwise printing proceeds (including null bytes) until either print_max or LEN characters have been printed, whichever is smaller. */ int val_print_string (struct type *elttype, CORE_ADDR addr, int len, struct ui_file *stream, const struct value_print_options *options) { int force_ellipsis = 0; /* Force ellipsis to be printed if nonzero. */ int errcode; /* Errno returned from bad reads. */ int found_nul; /* Non-zero if we found the nul char */ unsigned int fetchlimit; /* Maximum number of chars to print. */ int bytes_read; gdb_byte *buffer = NULL; /* Dynamically growable fetch buffer. */ struct cleanup *old_chain = NULL; /* Top of the old cleanup chain. */ struct gdbarch *gdbarch = get_type_arch (elttype); enum bfd_endian byte_order = gdbarch_byte_order (gdbarch); int width = TYPE_LENGTH (elttype); /* First we need to figure out the limit on the number of characters we are going to attempt to fetch and print. This is actually pretty simple. If LEN >= zero, then the limit is the minimum of LEN and print_max. If LEN is -1, then the limit is print_max. This is true regardless of whether print_max is zero, UINT_MAX (unlimited), or something in between, because finding the null byte (or available memory) is what actually limits the fetch. */ fetchlimit = (len == -1 ? options->print_max : min (len, options->print_max)); errcode = read_string (addr, len, width, fetchlimit, byte_order, &buffer, &bytes_read); old_chain = make_cleanup (xfree, buffer); addr += bytes_read; /* We now have either successfully filled the buffer to fetchlimit, or terminated early due to an error or finding a null char when LEN is -1. */ /* Determine found_nul by looking at the last character read. */ found_nul = extract_unsigned_integer (buffer + bytes_read - width, width, byte_order) == 0; if (len == -1 && !found_nul) { gdb_byte *peekbuf; /* We didn't find a NUL terminator we were looking for. Attempt to peek at the next character. If not successful, or it is not a null byte, then force ellipsis to be printed. */ peekbuf = (gdb_byte *) alloca (width); if (target_read_memory (addr, peekbuf, width) == 0 && extract_unsigned_integer (peekbuf, width, byte_order) != 0) force_ellipsis = 1; } else if ((len >= 0 && errcode != 0) || (len > bytes_read / width)) { /* Getting an error when we have a requested length, or fetching less than the number of characters actually requested, always make us print ellipsis. */ force_ellipsis = 1; } /* If we get an error before fetching anything, don't print a string. But if we fetch something and then get an error, print the string and then the error message. */ if (errcode == 0 || bytes_read > 0) { if (options->addressprint) { fputs_filtered (" ", stream); } LA_PRINT_STRING (stream, elttype, buffer, bytes_read / width, NULL, force_ellipsis, options); } if (errcode != 0) { if (errcode == EIO) { fprintf_filtered (stream, " <Address "); fputs_filtered (paddress (gdbarch, addr), stream); fprintf_filtered (stream, " out of bounds>"); } else { fprintf_filtered (stream, " <Error reading address "); fputs_filtered (paddress (gdbarch, addr), stream); fprintf_filtered (stream, ": %s>", safe_strerror (errcode)); } } gdb_flush (stream); do_cleanups (old_chain); return (bytes_read / width); } /* The 'set input-radix' command writes to this auxiliary variable. If the requested radix is valid, INPUT_RADIX is updated; otherwise, it is left unchanged. */ static unsigned input_radix_1 = 10; /* Validate an input or output radix setting, and make sure the user knows what they really did here. Radix setting is confusing, e.g. setting the input radix to "10" never changes it! */ static void set_input_radix (char *args, int from_tty, struct cmd_list_element *c) { set_input_radix_1 (from_tty, input_radix_1); } static void set_input_radix_1 (int from_tty, unsigned radix) { /* We don't currently disallow any input radix except 0 or 1, which don't make any mathematical sense. In theory, we can deal with any input radix greater than 1, even if we don't have unique digits for every value from 0 to radix-1, but in practice we lose on large radix values. We should either fix the lossage or restrict the radix range more. (FIXME). */ if (radix < 2) { input_radix_1 = input_radix; error (_("Nonsense input radix ``decimal %u''; input radix unchanged."), radix); } input_radix_1 = input_radix = radix; if (from_tty) { printf_filtered (_("Input radix now set to decimal %u, hex %x, octal %o.\n"), radix, radix, radix); } } /* The 'set output-radix' command writes to this auxiliary variable. If the requested radix is valid, OUTPUT_RADIX is updated, otherwise, it is left unchanged. */ static unsigned output_radix_1 = 10; static void set_output_radix (char *args, int from_tty, struct cmd_list_element *c) { set_output_radix_1 (from_tty, output_radix_1); } static void set_output_radix_1 (int from_tty, unsigned radix) { /* Validate the radix and disallow ones that we aren't prepared to handle correctly, leaving the radix unchanged. */ switch (radix) { case 16: user_print_options.output_format = 'x'; /* hex */ break; case 10: user_print_options.output_format = 0; /* decimal */ break; case 8: user_print_options.output_format = 'o'; /* octal */ break; default: output_radix_1 = output_radix; error (_("Unsupported output radix ``decimal %u''; output radix unchanged."), radix); } output_radix_1 = output_radix = radix; if (from_tty) { printf_filtered (_("Output radix now set to decimal %u, hex %x, octal %o.\n"), radix, radix, radix); } } /* Set both the input and output radix at once. Try to set the output radix first, since it has the most restrictive range. An radix that is valid as an output radix is also valid as an input radix. It may be useful to have an unusual input radix. If the user wishes to set an input radix that is not valid as an output radix, he needs to use the 'set input-radix' command. */ static void set_radix (char *arg, int from_tty) { unsigned radix; radix = (arg == NULL) ? 10 : parse_and_eval_long (arg); set_output_radix_1 (0, radix); set_input_radix_1 (0, radix); if (from_tty) { printf_filtered (_("Input and output radices now set to decimal %u, hex %x, octal %o.\n"), radix, radix, radix); } } /* Show both the input and output radices. */ static void show_radix (char *arg, int from_tty) { if (from_tty) { if (input_radix == output_radix) { printf_filtered (_("Input and output radices set to decimal %u, hex %x, octal %o.\n"), input_radix, input_radix, input_radix); } else { printf_filtered (_("Input radix set to decimal %u, hex %x, octal %o.\n"), input_radix, input_radix, input_radix); printf_filtered (_("Output radix set to decimal %u, hex %x, octal %o.\n"), output_radix, output_radix, output_radix); } } } static void set_print (char *arg, int from_tty) { printf_unfiltered ( "\"set print\" must be followed by the name of a print subcommand.\n"); help_list (setprintlist, "set print ", -1, gdb_stdout); } static void show_print (char *args, int from_tty) { cmd_show_list (showprintlist, from_tty, ""); } void _initialize_valprint (void) { add_prefix_cmd ("print", no_class, set_print, _("Generic command for setting how things print."), &setprintlist, "set print ", 0, &setlist); add_alias_cmd ("p", "print", no_class, 1, &setlist); /* prefer set print to set prompt */ add_alias_cmd ("pr", "print", no_class, 1, &setlist); add_prefix_cmd ("print", no_class, show_print, _("Generic command for showing print settings."), &showprintlist, "show print ", 0, &showlist); add_alias_cmd ("p", "print", no_class, 1, &showlist); add_alias_cmd ("pr", "print", no_class, 1, &showlist); add_setshow_uinteger_cmd ("elements", no_class, &user_print_options.print_max, _("\ Set limit on string chars or array elements to print."), _("\ Show limit on string chars or array elements to print."), _("\ \"set print elements 0\" causes there to be no limit."), NULL, show_print_max, &setprintlist, &showprintlist); add_setshow_boolean_cmd ("null-stop", no_class, &user_print_options.stop_print_at_null, _("\ Set printing of char arrays to stop at first null char."), _("\ Show printing of char arrays to stop at first null char."), NULL, NULL, show_stop_print_at_null, &setprintlist, &showprintlist); add_setshow_uinteger_cmd ("repeats", no_class, &user_print_options.repeat_count_threshold, _("\ Set threshold for repeated print elements."), _("\ Show threshold for repeated print elements."), _("\ \"set print repeats 0\" causes all elements to be individually printed."), NULL, show_repeat_count_threshold, &setprintlist, &showprintlist); add_setshow_boolean_cmd ("pretty", class_support, &user_print_options.prettyprint_structs, _("\ Set prettyprinting of structures."), _("\ Show prettyprinting of structures."), NULL, NULL, show_prettyprint_structs, &setprintlist, &showprintlist); add_setshow_boolean_cmd ("union", class_support, &user_print_options.unionprint, _("\ Set printing of unions interior to structures."), _("\ Show printing of unions interior to structures."), NULL, NULL, show_unionprint, &setprintlist, &showprintlist); add_setshow_boolean_cmd ("array", class_support, &user_print_options.prettyprint_arrays, _("\ Set prettyprinting of arrays."), _("\ Show prettyprinting of arrays."), NULL, NULL, show_prettyprint_arrays, &setprintlist, &showprintlist); add_setshow_boolean_cmd ("address", class_support, &user_print_options.addressprint, _("\ Set printing of addresses."), _("\ Show printing of addresses."), NULL, NULL, show_addressprint, &setprintlist, &showprintlist); add_setshow_zuinteger_cmd ("input-radix", class_support, &input_radix_1, _("\ Set default input radix for entering numbers."), _("\ Show default input radix for entering numbers."), NULL, set_input_radix, show_input_radix, &setlist, &showlist); add_setshow_zuinteger_cmd ("output-radix", class_support, &output_radix_1, _("\ Set default output radix for printing of values."), _("\ Show default output radix for printing of values."), NULL, set_output_radix, show_output_radix, &setlist, &showlist); /* The "set radix" and "show radix" commands are special in that they are like normal set and show commands but allow two normally independent variables to be either set or shown with a single command. So the usual deprecated_add_set_cmd() and [deleted] add_show_from_set() commands aren't really appropriate. */ /* FIXME: i18n: With the new add_setshow_integer command, that is no longer true - show can display anything. */ add_cmd ("radix", class_support, set_radix, _("\ Set default input and output number radices.\n\ Use 'set input-radix' or 'set output-radix' to independently set each.\n\ Without an argument, sets both radices back to the default value of 10."), &setlist); add_cmd ("radix", class_support, show_radix, _("\ Show the default input and output number radices.\n\ Use 'show input-radix' or 'show output-radix' to independently show each."), &showlist); add_setshow_boolean_cmd ("array-indexes", class_support, &user_print_options.print_array_indexes, _("\ Set printing of array indexes."), _("\ Show printing of array indexes"), NULL, NULL, show_print_array_indexes, &setprintlist, &showprintlist); }
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