# This testcase is part of GDB, the GNU debugger. # Copyright 2002, 2003, 2004 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 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. if $tracelevel { strace $tracelevel } # # test running programs # set prms_id 0 set bug_id 0 set testfile "store" set srcfile ${testfile}.c set binfile ${objdir}/${subdir}/${testfile} # APPLE LOCAL begin quiet about long doubles # APPLE LOCAL: Only gcc-4.0 accepts -Wno-long-double, 4.2 & above do not. get_compiler_info not_used if {[istarget "*-apple-darwin*"] && [regexp {gcc-4-[01]} $compiler_info]} { set additional_flags "additional_flags=-Wno-long-double" } # APPLE LOCAL end quiet about long doubles if { [gdb_compile "${srcdir}/${subdir}/${srcfile}" "${binfile}" executable {debug}] != "" } { gdb_suppress_entire_file "Testcase compile failed, so all tests in this file will automatically fail." } if [get_compiler_info ${binfile}] { return -1; } gdb_exit gdb_start gdb_reinitialize_dir $srcdir/$subdir gdb_load ${binfile} # # set it up at a breakpoint so we can play with the variable values # if ![runto_main] then { perror "couldn't run to breakpoint" continue } # proc check_set { t l r new add } { set prefix "var ${t} l" gdb_test "tbreak wack_${t}" gdb_test "continue" "register ${t} l = u, r = v;" \ "continue to wack_${t}" gdb_test "next" "l = add_${t} .l, r.;" \ "${prefix}; next ${t}" gdb_test "print l" " = ${l}" \ "${prefix}; print old l, expecting ${l}" gdb_test "print r" " = ${r}" \ "${prefix}; print old r, expecting ${r}" gdb_test "set variable l = 4" "" \ "${prefix}; setting l to 4" gdb_test "print l" " = ${new}" \ "${prefix}; print new l, expecting ${new}" gdb_test "next" "return l \\+ r;" \ "${prefix}; next over add call" gdb_test "print l" " = ${add}" \ "${prefix}; print incremented l, expecting ${add}" } check_set "charest" "-1 .*" "-2 .*" "4 ..004." "2 ..002." check_set "short" "-1" "-2" "4" "2" check_set "int" "-1" "-2" "4" "2" check_set "long" "-1" "-2" "4" "2" check_set "longest" "-1" "-2" "4" "2" check_set "float" "-1" "-2" "4" "2" check_set "double" "-1" "-2" "4" "2" check_set "doublest" "-1" "-2" "4" "2" # proc up_set { t l r new } { set prefix "upvar ${t} l" gdb_test "tbreak add_${t}" gdb_test "continue" "return u . v;" \ "continue to add_${t}" gdb_test "up" "l = add_${t} .l, r.;" \ "${prefix}; up" gdb_test "print l" " = ${l}" \ "${prefix}; print old l, expecting ${l}" gdb_test "print r" " = ${r}" \ "${prefix}; print old r, expecting ${r}" gdb_test "set variable l = 4" "" \ "${prefix}; set l to 4" gdb_test "print l" " = ${new}" \ "${prefix}; print new l, expecting ${new}" } up_set "charest" "-1 .*" "-2 .*" "4 ..004." up_set "short" "-1" "-2" "4" up_set "int" "-1" "-2" "4" up_set "long" "-1" "-2" "4" up_set "longest" "-1" "-2" "4" up_set "float" "-1" "-2" "4" up_set "double" "-1" "-2" "4" up_set "doublest" "-1" "-2" "4" # proc check_struct { t old new } { set prefix "var struct ${t} u" gdb_test "tbreak wack_struct_${t}" gdb_test "continue" "int i; register struct s_${t} u = z_${t};" \ "continue to wack_struct_${t}" gdb_test "next 2" "add_struct_${t} .u.;" \ "${prefix}; next to add_struct_${t} call" gdb_test "print u" " = ${old}" \ "${prefix}; print old u, expecting ${old}" gdb_test "set variable u = s_${t}" "" \ "${prefix}; set u to s_${t}" gdb_test "print u" " = ${new}" \ "${prefix}; print new u, expecting ${new}" } check_struct "1" "{s = \\{0}}" "{s = \\{1}}" check_struct "2" "{s = \\{0, 0}}" "{s = \\{1, 2}}" check_struct "3" "{s = \\{0, 0, 0}}" "{s = \\{1, 2, 3}}" check_struct "4" "{s = \\{0, 0, 0, 0}}" "{s = \\{1, 2, 3, 4}}" proc up_struct { t old new } { set prefix "up struct ${t} u" gdb_test "tbreak add_struct_${t}" gdb_test "continue" "for .i = 0; i < sizeof .s. / sizeof .s.s.0..; i..." \ "continue to add_struct_${t}" gdb_test "up" "u = add_struct_${t} .u.;" \ "${prefix}; up" gdb_test "print u" " = ${old}" \ "${prefix}; print old u, expecting ${old}" gdb_test "set variable u = s_${t}" "" \ "${prefix}; set u to s_${t}" gdb_test "print u" " = ${new}" \ "${prefix}; print new u, expecting ${new}" } up_struct "1" "{s = \\{0}}" "{s = \\{1}}" up_struct "2" "{s = \\{0, 0}}" "{s = \\{1, 2}}" up_struct "3" "{s = \\{0, 0, 0}}" "{s = \\{1, 2, 3}}" up_struct "4" "{s = \\{0, 0, 0, 0}}" "{s = \\{1, 2, 3, 4}}" # proc check_field { t } { global gdb_prompt gdb_test "tbreak wack_field_${t}" gdb_test "continue" "register struct f_${t} u = f_${t};" \ "continue field ${t}" # Match either the return statement, or the line immediatly after # it. The compiler can end up merging the return statement into # the return instruction. gdb_test "next" "(return u;|\})" "next field ${t}" gdb_test "print u" " = {i = 1, j = 1, k = 1}" "old field ${t}" gdb_test "set variable u = F_${t}" gdb_test "print u" " = {i = 0, j = 0, k = 0}" "new field ${t}" gdb_test "set variable u = F_${t}, u.i = f_${t}.i" gdb_test "print u" " = {i = 1, j = 0, k = 0}" "f_${t}.i" gdb_test "set variable u = F_${t}, u.j = f_${t}.j" gdb_test "print u" " = {i = 0, j = 1, k = 0}" "f_${t}.j" gdb_test "set variable u = F_${t}, u.k = f_${t}.k" gdb_test "print u" " = {i = 0, j = 0, k = 1}" "f_${t}.k" gdb_test "set variable u = f_${t}, u.i = F_${t}.i" gdb_test "print u" " = {i = 0, j = 1, k = 1}" "F_${t}.i" gdb_test "set variable u = f_${t}, u.j = F_${t}.j" gdb_test "print u" " = {i = 1, j = 0, k = 1}" "F_${t}.j" gdb_test "set variable u = f_${t}, u.k = F_${t}.k" gdb_test "print u" " = {i = 1, j = 1, k = 0}" "F_${t}.k" } check_field 1 check_field 2 check_field 3 check_field 4 # # WANTED: A fairly portable way of convincing the compiler to split a # value across memory and registers.