# Copyright (C) 2008-2014 Free Software Foundation, Inc. # 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 . # This file is part of the GDB testsuite. # It tests the mechanism exposing values to Guile. load_lib gdb-guile.exp standard_testfile # Build inferior to language specification. # LANG is one of "c" or "c++". proc build_inferior {exefile lang} { global srcdir subdir srcfile testfile hex # Use different names for .o files based on the language. # For Fission, the debug info goes in foo.dwo and we don't want, # for example, a C++ compile to clobber the dwo of a C compile. # ref: http://gcc.gnu.org/wiki/DebugFission switch ${lang} { "c" { set filename ${testfile}.o } "c++" { set filename ${testfile}-cxx.o } } set objfile [standard_output_file $filename] if { [gdb_compile "${srcdir}/${subdir}/${srcfile}" "${objfile}" object "debug $lang"] != "" || [gdb_compile "${objfile}" "${exefile}" executable "debug $lang"] != "" } { untested "Couldn't compile ${srcfile} in $lang mode" return -1 } return 0 } proc test_value_in_inferior {} { global gdb_prompt global testfile gdb_breakpoint [gdb_get_line_number "break to inspect struct and union"] gdb_continue_to_breakpoint "break to inspect struct and union" # Just get inferior variable s in the value history, available to guile. gdb_test "print s" "= {a = 3, b = 5}" "" gdb_scm_test_silent_cmd "gu (define s (history-ref 0))" "set s" gdb_test "gu (print (value-field s \"a\"))" \ "= 3" "access element inside struct using string name" # Append value in the value history. gdb_scm_test_silent_cmd "gu (define i (history-append! (make-value 42)))" \ "append 42" gdb_test "gu i" "\[0-9\]+" gdb_test "gu (history-ref i)" "#" gdb_test "p \$" "= 42" # Verify the recorded history value survives a gc. gdb_test_no_output "guile (gc)" gdb_test "p \$\$" "= 42" # Test dereferencing the argv pointer. # Just get inferior variable argv the value history, available to guile. gdb_test "print argv" "= \\(char \\*\\*\\) 0x.*" "" gdb_scm_test_silent_cmd "gu (define argv (history-ref 0))" \ "set argv" gdb_scm_test_silent_cmd "gu (define arg0 (value-dereference argv))" \ "set arg0" # Check that the dereferenced value is sane. if { ! [target_info exists noargs] } { gdb_test "gu (print arg0)" \ "0x.*$testfile\"" "verify dereferenced value" } # Smoke-test value-optimized-out?. gdb_test "gu (print (value-optimized-out? arg0))" \ "= #f" "Test value-optimized-out?" # Test address attribute. gdb_test "gu (print (value-address arg0))" \ "= 0x\[\[:xdigit:\]\]+" "Test address attribute" # Test address attribute is #f in a non-addressable value. gdb_test "gu (print (value-address (make-value 42)))" \ "= #f" "Test address attribute in non-addressable value" # Test displaying a variable that is temporarily at a bad address. # But if we can examine what's at memory address 0, then we'll also be # able to display it without error. Don't run the test in that case. set can_read_0 0 gdb_test_multiple "x 0" "memory at address 0" { -re "0x0:\[ \t\]*Cannot access memory at address 0x0\r\n$gdb_prompt $" { } -re "0x0:\[ \t\]*Error accessing memory address 0x0\r\n$gdb_prompt $" { } -re "\r\n$gdb_prompt $" { set can_read_0 1 } } # Test memory error. set test "parse_and_eval with memory error" if {$can_read_0} { untested $test } else { gdb_test "gu (print (parse-and-eval \"*(int*)0\"))" \ "ERROR: Cannot access memory at address 0x0.*" $test } # Test Guile lazy value handling set test "memory error and lazy values" if {$can_read_0} { untested $test } else { gdb_test_no_output "gu (define inval (parse-and-eval \"*(int*)0\"))" gdb_test "gu (print (value-lazy? inval))" \ "#t" gdb_test "gu (define inval2 (value-add inval 1))" \ "ERROR: Cannot access memory at address 0x0.*" $test gdb_test "gu (value-fetch-lazy! inval))" \ "ERROR: Cannot access memory at address 0x0.*" $test } gdb_test_no_output "gu (define argc-lazy (parse-and-eval \"argc\"))" gdb_test_no_output "gu (define argc-notlazy (parse-and-eval \"argc\"))" gdb_test_no_output "gu (value-fetch-lazy! argc-notlazy)" gdb_test "gu (print (value-lazy? argc-lazy))" "= #t" gdb_test "gu (print (value-lazy? argc-notlazy))" "= #f" gdb_test "print argc" "= 1" "sanity check argc" gdb_test "gu (print (value-lazy? argc-lazy))" "= #t" gdb_test_no_output "set argc=2" gdb_test "gu (print argc-notlazy)" "= 1" gdb_test "gu (print argc-lazy)" "= 2" gdb_test "gu (print (value-lazy? argc-lazy))" "= #f" # Test string fetches, both partial and whole. gdb_test "print st" "\"divide et impera\"" gdb_scm_test_silent_cmd "gu (define st (history-ref 0))" \ "inf: get st value from history" gdb_test "gu (print (value->string st))" \ "= divide et impera" "Test string with no length" gdb_test "gu (print (value->string st #:length -1))" \ "= divide et impera" "Test string (length = -1) is all of the string" gdb_test "gu (print (value->string st #:length 6))" \ "= divide" gdb_test "gu (print (string-append \"---\" (value->string st #:length 0) \"---\"))" \ "= ------" "Test string (length = 0) is empty" gdb_test "gu (print (string-length (value->string st #:length 0)))" \ "= 0" "Test length is 0" # Fetch a string that has embedded nulls. gdb_test "print nullst" "\"divide\\\\000et\\\\000impera\".*" gdb_scm_test_silent_cmd "gu (define nullst (history-ref 0))" \ "inf: get nullst value from history" gdb_test "gu (print (value->string nullst))" \ "divide" "Test string to first null" gdb_scm_test_silent_cmd "gu (set! nullst (value->string nullst #:length 9))" \ "get string beyond null" gdb_test "gu (print nullst)" \ "= divide\\\\000et" } proc test_strings {} { gdb_test "gu (make-value \"test\")" "#" "make string" # Test string conversion errors. set save_charset [get_target_charset] gdb_test_no_output "set target-charset UTF-8" gdb_test_no_output "gu (set-port-conversion-strategy! #f 'error)" gdb_test "gu (print (value->string (make-value (string #\\x1234)) #:encoding \"ASCII\"))" \ "ERROR.*decoding-error.*" \ "value->string with default #:errors = 'error" # There is no 'escape strategy for C->SCM string conversions, but it's # still a legitimate value for %default-port-conversion-strategy. # GDB handles this by, umm, substituting 'substitute. # Use this case to also handle "#:errors #f" which explicitly says # "use %default-port-conversion-strategy". gdb_test_no_output "gu (set-port-conversion-strategy! #f 'escape)" gdb_test "gu (print (value->string (make-value (string #\\x1234)) #:encoding \"ASCII\" #:errors #f))" \ "= \[?\]{3}" "value->string with default #:errors = 'escape" # This is last in the default conversion tests so that # %default-port-conversion-strategy ends up with the default value. gdb_test_no_output "gu (set-port-conversion-strategy! #f 'substitute)" gdb_test "gu (print (value->string (make-value (string #\\x1234)) #:encoding \"ASCII\"))" \ "= \[?\]{3}" "value->string with default #:errors = 'substitute" gdb_test "gu (print (value->string (make-value (string #\\x1234)) #:encoding \"ASCII\" #:errors 'error))" \ "ERROR.*decoding-error.*" "value->string #:errors 'error" gdb_test "gu (print (value->string (make-value (string #\\x1234)) #:encoding \"ASCII\" #:errors 'substitute))" \ "= \[?\]{3}" "value->string #:errors 'substitute" gdb_test "gu (print (value->string (make-value \"abc\") #:errors \"foo\"))" \ "ERROR.*invalid error kind.*" "bad value for #:errors" gdb_test_no_output "set target-charset $save_charset" \ "restore target-charset" } proc test_lazy_strings {} { global hex gdb_test "print sptr" "\"pointer\"" gdb_scm_test_silent_cmd "gu (define sptr (history-ref 0))" \ "lazy strings: get sptr value from history" gdb_scm_test_silent_cmd "gu (define lstr (value->lazy-string sptr))" \ "Aquire lazy string" gdb_test "gu (print (lazy-string-type lstr))" \ "= const char \*." "Test lazy-string type name equality" gdb_test "gu (print (value-type sptr))" \ "= const char \*." "Test string type name equality" gdb_test "print sn" "0x0" gdb_scm_test_silent_cmd "gu (define snptr (history-ref 0))" \ "lazy strings: get snptr value from history" gdb_test "gu (define snstr (value->lazy-string snptr #:length 5))" \ ".*cannot create a lazy string with address.*" "Test lazy string" gdb_scm_test_silent_cmd "gu (define snstr (value->lazy-string snptr #:length 0))" \ "Successfully create a lazy string" gdb_test "gu (print (lazy-string-length snstr))" \ "= 0" "Test lazy string length" gdb_test "gu (print (lazy-string-address snstr))" \ "= 0" "Test lazy string address" } proc test_inferior_function_call {} { global gdb_prompt hex decimal # Correct inferior call without arguments. gdb_test "p/x fp1" "= $hex.*" gdb_scm_test_silent_cmd "gu (define fp1 (history-ref 0))" \ "get fp1 value from history" gdb_scm_test_silent_cmd "gu (set! fp1 (value-dereference fp1))" \ "dereference fp1" gdb_test "gu (print (value-call fp1 '()))" \ "= void" # Correct inferior call with arguments. gdb_test "p/x fp2" "= $hex.*" gdb_scm_test_silent_cmd "gu (define fp2 (history-ref 0))" \ "get fp2 value from history" gdb_scm_test_silent_cmd "gu (set! fp2 (value-dereference fp2))" \ "dereference fp2" gdb_test "gu (print (value-call fp2 (list 10 20)))" \ "= 30" # Incorrect to call an int value. gdb_test "p i" "= $decimal.*" gdb_scm_test_silent_cmd "gu (define i (history-ref 0))" \ "inf call: get i value from history" gdb_test "gu (print (value-call i '()))" \ "ERROR: .*: Wrong type argument in position 1 \\(expecting function \\(value of TYPE_CODE_FUNC\\)\\): .*" # Incorrect number of arguments. gdb_test "p/x fp2" "= $hex.*" gdb_scm_test_silent_cmd "gu (define fp3 (history-ref 0))" \ "get fp3 value from history" gdb_scm_test_silent_cmd "gu (set! fp3 (value-dereference fp3))" \ "dereference fp3" gdb_test "gu (print (value-call fp3 (list 10)))" \ "ERROR: Too few arguments in function call.*" } proc test_value_after_death {} { # Construct a type while the inferior is still running. gdb_scm_test_silent_cmd "gu (define ptrtype (lookup-type \"PTR\"))" \ "create PTR type" # Kill the inferior and remove the symbols. gdb_test "kill" "" "kill the inferior" \ "Kill the program being debugged. .y or n. $" \ "y" gdb_test "file" "" "Discard the symbols" \ "Discard symbol table from.*y or n. $" \ "y" # First do a garbage collect to delete anything unused. PR 16612. gdb_scm_test_silent_cmd "gu (gc)" "garbage collect" # Now create a value using that type. Relies on arg0, created by # test_value_in_inferior. gdb_scm_test_silent_cmd "gu (define castval (value-cast arg0 (type-pointer ptrtype)))" \ "cast arg0 to PTR" # Make sure the type is deleted. gdb_scm_test_silent_cmd "gu (set! ptrtype #f)" \ "delete PTR type" # Now see if the value's type is still valid. gdb_test "gu (print (value-type castval))" \ "= PTR ." "print value's type" } # Regression test for invalid subscript operations. The bug was that # the type of the value was not being checked before allowing a # subscript operation to proceed. proc test_subscript_regression {exefile lang} { # Start with a fresh gdb. clean_restart ${exefile} if ![gdb_guile_runto_main ] { fail "Can't run to main" return } if {$lang == "c++"} { gdb_breakpoint [gdb_get_line_number "break to inspect pointer by reference"] gdb_continue_to_breakpoint "break to inspect pointer by reference" gdb_scm_test_silent_cmd "print rptr_int" \ "Obtain address" gdb_scm_test_silent_cmd "gu (define rptr (history-ref 0))" \ "set rptr" gdb_test "gu (print (value-subscript rptr 0))" \ "= 2" "Check pointer passed as reference" # Just the most basic test of dynamic_cast -- it is checked in # the C++ tests. gdb_test "gu (print (value->bool (value-dynamic-cast (parse-and-eval \"base\") (type-pointer (lookup-type \"Derived\")))))" \ "= #t" # Likewise. gdb_test "gu (print (value-dynamic-type (parse-and-eval \"base\")))" \ "= Derived \[*\]" # A static type case. gdb_test "gu (print (value-dynamic-type (parse-and-eval \"5\")))" \ "= int" } gdb_breakpoint [gdb_get_line_number "break to inspect struct and union"] gdb_continue_to_breakpoint "break to inspect struct and union" gdb_scm_test_silent_cmd "gu (define intv (make-value 1))" \ "Create int value for subscript test" gdb_scm_test_silent_cmd "gu (define stringv (make-value \"foo\"))" \ "Create string value for subscript test" # Try to access an int with a subscript. This should fail. gdb_test "gu (print intv)" \ "= 1" "Baseline print of an int Guile value" gdb_test "gu (print (value-subscript intv 0))" \ "ERROR: Cannot subscript requested type.*" \ "Attempt to access an integer with a subscript" # Try to access a string with a subscript. This should pass. gdb_test "gu (print stringv)" \ "= \"foo\"" "Baseline print of a string Guile value" gdb_test "gu (print (value-subscript stringv 0))" \ "= 102 'f'" "Attempt to access a string with a subscript" # Try to access an int array via a pointer with a subscript. # This should pass. gdb_scm_test_silent_cmd "print p" "Build pointer to array" gdb_scm_test_silent_cmd "gu (define pointer (history-ref 0))" "set pointer" gdb_test "gu (print (value-subscript pointer 0))" \ "= 1" "Access array via pointer with int subscript" gdb_test "gu (print (value-subscript pointer intv))" \ "= 2" "Access array via pointer with value subscript" # Try to access a single dimension array with a subscript to the # result. This should fail. gdb_test "gu (print (value-subscript (value-subscript pointer intv) 0))" \ "ERROR: Cannot subscript requested type.*" \ "Attempt to access an integer with a subscript 2" # Lastly, test subscript access to an array with multiple # dimensions. This should pass. gdb_scm_test_silent_cmd "print {\"fu \",\"foo\",\"bar\"}" "Build array" gdb_scm_test_silent_cmd "gu (define marray (history-ref 0))" "" gdb_test "gu (print (value-subscript (value-subscript marray 1) 2))" \ "o." "Test multiple subscript" } # A few tests of gdb:parse-and-eval. proc test_parse_and_eval {} { gdb_test "gu (print (parse-and-eval \"23\"))" \ "= 23" "parse-and-eval constant test" gdb_test "gu (print (parse-and-eval \"5 + 7\"))" \ "= 12" "parse-and-eval simple expression test" gdb_test "gu (raw-print (parse-and-eval \"5 + 7\"))" \ "#" "parse-and-eval type test" } # Test that values are hashable. # N.B.: While smobs are hashable, the hash is really non-existent, # they all get hashed to the same value. Guile may provide a hash function # for smobs in a future release. In the meantime one should use a custom # hash table that uses gdb:hash-gsmob. proc test_value_hash {} { gdb_test_multiline "Simple Guile value dictionary" \ "guile" "" \ "(define one (make-value 1))" "" \ "(define two (make-value 2))" "" \ "(define three (make-value 3))" "" \ "(define vdict (make-hash-table 5))" "" \ "(hash-set! vdict one \"one str\")" "" \ "(hash-set! vdict two \"two str\")" "" \ "(hash-set! vdict three \"three str\")" "" \ "end" gdb_test "gu (print (hash-ref vdict one))" \ "one str" "Test dictionary hash 1" gdb_test "gu (print (hash-ref vdict two))" \ "two str" "Test dictionary hash 2" gdb_test "gu (print (hash-ref vdict three))" \ "three str" "Test dictionary hash 3" } # Build C version of executable. C++ is built later. if { [build_inferior "${binfile}" "c"] < 0 } { return } # Start with a fresh gdb. clean_restart ${binfile} # Skip all tests if Guile scripting is not enabled. if { [skip_guile_tests] } { continue } gdb_install_guile_utils gdb_install_guile_module test_parse_and_eval test_value_hash # The following tests require execution. if ![gdb_guile_runto_main] { fail "Can't run to main" return } test_value_in_inferior test_inferior_function_call test_strings test_lazy_strings test_value_after_death # Test either C or C++ values. test_subscript_regression "${binfile}" "c" if ![skip_cplus_tests] { if { [build_inferior "${binfile}-cxx" "c++"] < 0 } { return } with_test_prefix "c++" { test_subscript_regression "${binfile}-cxx" "c++" } }