# Copyright 1992-2021 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 was written by Fred Fish. (fnf@cygnus.com)
# and modified by Bob Manson. (manson@cygnus.com)
standard_testfile
set compile_flags {debug}
if [support_complex_tests] {
lappend compile_flags "additional_flags=-DTEST_COMPLEX"
}
# Some targets can't do function calls, so don't even bother with this
# test.
if [target_info exists gdb,cannot_call_functions] {
unsupported "this target can not call functions"
continue
}
set skip_float_test [gdb_skip_float_test]
# FIXME: Before calling this proc, we should probably verify that
# we can call inferior functions and get a valid integral value
# returned.
# Note that it is OK to check for 0 or 1 as the returned values, because C
# specifies that the numeric value of a relational or logical expression
# (computed in the inferior) is 1 for true and 0 for false.
proc do_function_calls {prototypes} {
global gdb_prompt skip_float_test
# We need to up this because this can be really slow on some boards.
set timeout 60
# If any of these calls segv we don't want to affect subsequent tests.
# E.g., we want to ensure register values are restored.
gdb_test_no_output "set unwindonsignal on"
gdb_test "p t_char_values(0,0)" " = 0"
gdb_test "p t_char_values('a','b')" " = 1"
gdb_test "p t_char_values(char_val1,char_val2)" " = 1"
gdb_test "p t_char_values('a',char_val2)" " = 1"
gdb_test "p t_char_values(char_val1,'b')" " = 1"
gdb_test "p t_short_values(0,0)" " = 0"
gdb_test "p t_short_values(10,-23)" " = 1"
gdb_test "p t_short_values(short_val1,short_val2)" " = 1"
gdb_test "p t_short_values(10,short_val2)" " = 1"
gdb_test "p t_short_values(short_val1,-23)" " = 1"
gdb_test "p t_int_values(0,0)" " = 0"
gdb_test "p t_int_values(87,-26)" " = 1"
gdb_test "p t_int_values(int_val1,int_val2)" " = 1"
gdb_test "p t_int_values(87,int_val2)" " = 1"
gdb_test "p t_int_values(int_val1,-26)" " = 1"
gdb_test "p t_long_values(0,0)" " = 0"
gdb_test "p t_long_values(789,-321)" " = 1"
gdb_test "p t_long_values(long_val1,long_val2)" " = 1"
gdb_test "p t_long_values(789,long_val2)" " = 1"
gdb_test "p t_long_values(long_val1,-321)" " = 1"
if {!$skip_float_test} {
gdb_test "p t_float_values(0.0,0.0)" " = 0"
# These next four tests fail on the mn10300.
# The first value is passed in regs, the other in memory.
# Gcc emits different stabs for the two parameters; the first is
# claimed to be a float, the second a double.
# dbxout.c in gcc claims this is the desired behavior.
# These tests also fail for RealView, because GDB can not tell that
# the function is unprototyped.
setup_xfail "mn10300-*-*"
if { [test_compiler_info "armcc-*"] } { setup_xfail "*-*-*" }
gdb_test "p t_float_values(3.14159,-2.3765)" " = 1"
setup_xfail "mn10300-*-*"
if { [test_compiler_info "armcc-*"] } { setup_xfail "*-*-*" }
gdb_test "p t_float_values(float_val1,float_val2)" " = 1"
setup_xfail "mn10300-*-*"
if { [test_compiler_info "armcc-*"] } { setup_xfail "*-*-*" }
gdb_test "p t_float_values(3.14159,float_val2)" " = 1"
setup_xfail "mn10300-*-*"
if { [test_compiler_info "armcc-*"] } { setup_xfail "*-*-*" }
gdb_test "p t_float_values(float_val1,-2.3765)" " = 1"
# Same, via unprototyped function pointer (t_float_values is
# always unprototyped).
gdb_test "p ((int (*) ()) t_float_values)(float_val1,-2.3765)" " = 1"
# Test passing of arguments which might not be widened.
gdb_test "p t_float_values2(0.0,0.0)" " = 0"
# Same, via function pointer.
if {$prototypes} {
gdb_test "p ((int (*) (float, float)) t_float_values2)(0.0,0.0)" " = 0"
} else {
gdb_test "p ((int (*) ()) t_float_values2)(0.0,0.0)" " = 0"
}
gdb_test "p t_float_values2(3.14159,float_val2)" " = 1"
if {$prototypes} {
gdb_test "p ((int (*) (float, float)) t_float_values2)(3.14159,float_val2)" " = 1"
} else {
gdb_test "p ((int (*) ()) t_float_values2)(3.14159,float_val2)" " = 1"
}
gdb_test "p t_float_many_args (float_val1, float_val2, float_val3, float_val4, float_val5, float_val6, float_val7, float_val8, float_val9, float_val10, float_val11, float_val12, float_val13, float_val14, float_val15)" " = 1" "call function with many float arguments."
gdb_test "p t_small_values(1,2,3,4,5,6,7,8,9,10)" " = 55"
gdb_test "p t_double_values(0.0,0.0)" " = 0"
gdb_test "p t_double_values(45.654,-67.66)" " = 1"
gdb_test "p t_double_values(double_val1,double_val2)" " = 1"
gdb_test "p t_double_values(45.654,double_val2)" " = 1"
gdb_test "p t_double_values(double_val1,-67.66)" " = 1"
gdb_test "p t_double_many_args (double_val1, double_val2, double_val3, double_val4, double_val5, double_val6, double_val7, double_val8, double_val9, double_val10, double_val11, double_val12, double_val13, double_val14, double_val15)" " = 1" "call function with many double arguments."
gdb_test "p t_double_int(99.0, 1)" " = 0"
gdb_test "p t_double_int(99.0, 99)" " = 1"
gdb_test "p t_int_double(99, 1.0)" " = 0"
gdb_test "p t_int_double(99, 99.0)" " = 1"
}
if [support_complex_tests] {
gdb_test "p t_float_complex_values(fc1, fc2)" " = 1"
gdb_test "p t_float_complex_values(fc3, fc4)" " = 0"
gdb_test "p t_float_complex_many_args(fc1, fc2, fc3, fc4, fc1, fc2, fc3, fc4, fc1, fc2, fc3, fc4, fc1, fc2, fc3, fc4)" " = 1"
gdb_test "p t_float_complex_many_args(fc1, fc1, fc1, fc1, fc1, fc1, fc1, fc1, fc1, fc1, fc1, fc1, fc1, fc1, fc1, fc1)" " = 0"
gdb_test "p t_double_complex_values(dc1, dc2)" " = 1"
gdb_test "p t_double_complex_values(dc3, dc4)" " = 0"
gdb_test "p t_double_complex_many_args(dc1, dc2, dc3, dc4, dc1, dc2, dc3, dc4, dc1, dc2, dc3, dc4, dc1, dc2, dc3, dc4)" " = 1"
gdb_test "p t_double_complex_many_args(dc1, dc1, dc1, dc1, dc1, dc1, dc1, dc1, dc1, dc1, dc1, dc1, dc1, dc1, dc1, dc1)" " = 0"
gdb_test "p t_long_double_complex_values(ldc1, ldc2)" " = 1"
gdb_test "p t_long_double_complex_values(ldc3, ldc4)" " = 0"
gdb_test "p t_long_double_complex_many_args(ldc1, ldc2, ldc3, ldc4, ldc1, ldc2, ldc3, ldc4, ldc1, ldc2, ldc3, ldc4, ldc1, ldc2, ldc3, ldc4)" " = 1"
gdb_test "p t_long_double_complex_many_args(ldc1, ldc1, ldc1, ldc1, ldc1, ldc1, ldc1,ldc1, ldc1, ldc1, ldc1, ldc1, ldc1, ldc1, ldc1, ldc1)" " = 0"
}
gdb_test "p t_string_values(string_val2,string_val1)" " = 0"
gdb_test "p t_string_values(string_val1,string_val2)" " = 1"
gdb_test "p t_string_values(\"string 1\",\"string 2\")" " = 1"
gdb_test "p t_string_values(\"string 1\",string_val2)" " = 1"
gdb_test "p t_string_values(string_val1,\"string 2\")" " = 1"
gdb_test "p t_char_array_values(char_array_val2,char_array_val1)" " = 0"
gdb_test "p t_char_array_values(char_array_val1,char_array_val2)" " = 1"
gdb_test "p t_char_array_values(\"carray 1\",\"carray 2\")" " = 1"
gdb_test "p t_char_array_values(\"carray 1\",char_array_val2)" " = 1"
gdb_test "p t_char_array_values(char_array_val1,\"carray 2\")" " = 1"
gdb_test "p doubleit(4)" " = 8"
gdb_test "p add(4,5)" " = 9"
gdb_test "p t_func_values(func_val2,func_val1)" " = 0"
gdb_test "p t_func_values(func_val1,func_val2)" " = 1"
gdb_test "p function_struct.func(5)" " = 10"
gdb_test "p function_struct_ptr->func(10)" " = 20"
# GDB currently screws up the passing of function parameters for
# ABIs that use function descriptors. Instead of passing the
# address of te function descriptor, GDB passes the address of the
# function body. This results in the called function treating the
# first few instructions of the function proper as a descriptor
# and attempting a jump through that (a totally random address).
setup_kfail gdb/1457 "rs6000*-*-aix*"
setup_kfail gdb/1457 "powerpc*-*-aix*"
gdb_test "p t_func_values(add,func_val2)" " = 1"
setup_kfail gdb/1457 "rs6000*-*-aix*"
setup_kfail gdb/1457 "powerpc*-*-aix*"
gdb_test "p t_func_values(func_val1,doubleit)" " = 1"
setup_kfail gdb/1457 "rs6000*-*-aix*"
setup_kfail gdb/1457 "powerpc*-*-aix*"
gdb_test "p t_call_add(add,3,4)" " = 7"
gdb_test "p t_call_add(func_val1,3,4)" " = 7"
gdb_test "p t_enum_value1(enumval1)" " = 1"
gdb_test "p t_enum_value1(enum_val1)" " = 1"
gdb_test "p t_enum_value1(enum_val2)" " = 0"
gdb_test "p t_enum_value2(enumval2)" " = 1"
gdb_test "p t_enum_value2(enum_val2)" " = 1"
gdb_test "p t_enum_value2(enum_val1)" " = 0"
gdb_test "p sum_args(1,{2})" " = 2"
gdb_test "p sum_args(2,{2,3})" " = 5"
gdb_test "p sum_args(3,{2,3,4})" " = 9"
gdb_test "p sum_args(4,{2,3,4,5})" " = 14"
gdb_test "p sum10 (1, 2, 3, 4, 5, 6, 7, 8, 9, 10)" " = 55"
gdb_test "p cmp10 (0, 1, 2, 3, 4, 5, 6, 7, 8, 9)" " = 1"
gdb_test "p t_structs_c(struct_val1)" "= 120 'x'" \
"call inferior func with struct - returns char"
gdb_test "p t_structs_s(struct_val1)" "= 87" \
"call inferior func with struct - returns short"
gdb_test "p t_structs_i(struct_val1)" "= 76" \
"call inferior func with struct - returns int"
gdb_test "p t_structs_l(struct_val1)" "= 51" \
"call inferior func with struct - returns long"
if {!$skip_float_test} {
gdb_test "p t_structs_f(struct_val1)" "= 2.12.*" \
"call inferior func with struct - returns float"
gdb_test "p t_structs_d(struct_val1)" "= 9.87.*" \
"call inferior func with struct - returns double"
}
if [support_complex_tests] {
gdb_test "p t_structs_fc(struct_val1)" ".*= 3 \\+ 3i" \
"call inferior func with struct - returns float _Complex"
gdb_test "p t_structs_dc(struct_val1)" ".*= 4 \\+ 4i" \
"call inferior func with struct - returns double _Complex"
gdb_test "p t_structs_ldc(struct_val1)" "= 5 \\+ 5i" \
"call inferior func with struct - returns long double _Complex"
}
gdb_test "p t_structs_a(struct_val1)" "= (.unsigned char .. )?<.*buf.*> \"foo\"" \
"call inferior func with struct - returns char *"
# Restore default value.
gdb_test_no_output "set unwindonsignal off"
}
# Procedure to get current content of all registers.
proc fetch_all_registers {test} {
global gdb_prompt
set all_registers_lines {}
set bad -1
# Former trailing `\[\r\n\]+' may eat just \r leaving \n in the buffer
# corrupting the next matches.
if {[gdb_test_multiple "info all-registers" $test {
-re "info all-registers\r\n" {
exp_continue
}
-ex "The program has no registers now" {
set bad 1
exp_continue
}
-re "^bspstore\[ \t\]+\[^\r\n\]+\r\n" {
if [istarget "ia64-*-*"] {
# Filter out bspstore which is specially tied to bsp,
# giving spurious differences.
} else {
lappend all_registers_lines $expect_out(0,string)
}
exp_continue
}
-re "^pstate\[ \t\]+\[^\r\n\]+\r\n" {
if [istarget "sparc64-*-linux-gnu"] {
# Filter out the pstate register, since in sparc64
# targets the Linux kernel disables pstate.PEF when
# returning from traps, giving spurious differences.
} else {
lappend all_registers_lines $expect_out(0,string)
}
exp_continue
}
-re "^last_break\[ \t\]+\[^\r\n\]+\r\n" {
if [istarget "s390*-*-*"] {
# Filter out last_break which is read-only,
# giving spurious differences.
} else {
lappend all_registers_lines $expect_out(0,string)
}
exp_continue
}
-re "^\(?:cycle\|instret\)\[ \t\]+\[^\r\n\]+\r\n" {
if [istarget "riscv*-*-*"] {
# Filter out the cycle counter and instructions
# retired counter CSRs which are read-only, giving
# spurious differences.
} else {
lappend all_registers_lines $expect_out(0,string)
}
exp_continue
}
-re "^\[^ \t\]+\[ \t\]+\[^\r\n\]+\r\n" {
lappend all_registers_lines $expect_out(0,string)
exp_continue
}
-re "$gdb_prompt $" {
incr bad
}
-re "^\[^\r\n\]+\r\n" {
if {!$bad} {
warning "Unrecognized output: $expect_out(0,string)"
set bad 1
}
exp_continue
}
}] != 0} {
return {}
}
if {$bad} {
fail $test
return {}
}
pass $test
return $all_registers_lines
}
# Global used by RERUN_AND_PREPARE to make test names unique.
set rerun_count 0
proc rerun_and_prepare {} {
global rerun_count
incr rerun_count
with_test_prefix "rerun number ${rerun_count}" {
if { ![runto_main] } {
return
}
gdb_test_no_output "set language c"
get_debug_format
# Make sure that malloc gets called and that the floating
# point unit is initialized via a call to t_double_values.
gdb_test "next" \
"t_double_values\\(double_val1, double_val2\\);.*" \
"next to t_double_values"
gdb_test "next" "t_structs_c\\(struct_val1\\);.*" \
"next to t_structs_c"
}
}
proc perform_all_tests {prototypes} {
gdb_test_no_output "set print sevenbit-strings"
gdb_test_no_output "set print address off"
gdb_test_no_output "set width 0"
rerun_and_prepare
# Save all register contents.
set old_reg_content \
[fetch_all_registers "retrieve original register contents 1"]
# Perform function calls.
do_function_calls $prototypes
# Check if all registers still have the same value.
set new_reg_content [fetch_all_registers \
"register contents after gdb function calls"]
if {$old_reg_content == $new_reg_content} then {
pass "gdb function calls preserve register contents"
} else {
set old_reg_content $new_reg_content
fail "gdb function calls preserve register contents"
}
rerun_and_prepare
# Save all register contents.
set old_reg_content \
[fetch_all_registers "retrieve original register contents 2"]
# Set breakpoint at a function we will call from gdb.
gdb_breakpoint add
# Call function (causing a breakpoint hit in the call dummy) and do a continue,
# make sure we are back at main and still have the same register contents.
gdb_test "print add(4,5)" \
"The program being debugged stopped while.*" \
"stop at breakpoint in call dummy function"
gdb_test "continue" "Continuing.*" "continue from call dummy breakpoint"
if ![gdb_test "bt 2" \
"#0 main.*" \
"bt after continuing from call dummy breakpoint"] then {
set new_reg_content [fetch_all_registers \
"register contents after stop in call dummy"]
if {$old_reg_content == $new_reg_content} then {
pass "continue after stop in call dummy preserves register contents"
} else {
fail "continue after stop in call dummy preserves register contents"
}
}
rerun_and_prepare
# Set breakpoint at a function we will call from gdb.
gdb_breakpoint add
# Save all register contents.
set old_reg_content \
[fetch_all_registers "retrieve original register contents 3"]
# Call function (causing a breakpoint hit in the call dummy) and do a finish,
# make sure we are back at main and still have the same register contents.
gdb_test "print add(4,5)" "The program being debugged stopped while.*" \
"call function causing a breakpoint then do a finish"
gdb_test "finish" \
"Value returned is .* = 9" \
"finish from call dummy breakpoint returns correct value"
if ![gdb_test "bt 2" \
"#0 main.*" \
"bt after finishing from call dummy breakpoint"] then {
set new_reg_content [fetch_all_registers \
"register contents after finish in call dummy"]
if {$old_reg_content == $new_reg_content} then {
pass "finish after stop in call dummy preserves register contents"
} else {
fail "finish after stop in call dummy preserves register contents"
}
}
rerun_and_prepare
# Set breakpoint at a function we will call from gdb.
gdb_breakpoint add
# Save all register contents.
set old_reg_content \
[fetch_all_registers "retrieve original register contents 4"]
# Call function (causing a breakpoint hit in the call dummy) and do a return
# with a value, make sure we are back at main with the same register contents.
gdb_test "print add(4,5)" "The program being debugged stopped while.*" \
"call function causing a breakpoint and then do a return"
if ![gdb_test "return 7" \
"#0 main.*" \
"back at main after return from call dummy breakpoint" \
"Make add return now. .y or n.*" \
"y"] then {
set new_reg_content [fetch_all_registers \
"register contents after return in call dummy"]
if {$old_reg_content == $new_reg_content} then {
pass "return after stop in call dummy preserves register contents"
} else {
fail "return after stop in call dummy preserves register contents"
}
}
rerun_and_prepare
# Set breakpoint at a function we will call from gdb.
gdb_breakpoint add
set old_reg_content \
[fetch_all_registers "retrieve original register contents 5"]
# Call function (causing a breakpoint hit in the call dummy), and
# call another function from the call dummy frame (thereby setting up
# several nested call dummy frames). Test that backtrace and finish
# work when several call dummies are nested.
gdb_breakpoint sum10
gdb_breakpoint t_small_values
gdb_test "print add(2,3)" "The program being debugged stopped while.*" \
"stop at nested call level 1"
gdb_test "backtrace" \
"\#0 add \\(a=2, b=3\\).*\#1 .*\#2 main.*" \
"backtrace at nested call level 1"
gdb_test "print add(4,5)" "The program being debugged stopped while.*" \
"stop at nested call level 2"
gdb_test "backtrace" \
"\#0 add \\(a=4, b=5\\).*\#1 .*\#2 add \\(a=2, b=3\\).*\#3 .*\#4 main.*" \
"backtrace at nested call level 2"
gdb_test "print sum10(2,4,6,8,10,12,14,16,18,20)" \
"The program being debugged stopped while.*" \
"stop at nested call level 3"
gdb_test "backtrace" \
"\#0 sum10 \\(i0=2, i1=4, i2=6, i3=8, i4=10, i5=12, i6=14, i7=16, i8=18, i9=20\\).*\#1 .*\#2 add \\(a=4, b=5\\).*\#3 .*\#4 add \\(a=2, b=3\\).*\#5 .*\#6 main.*" \
"backtrace at nested call level 3"
gdb_test "print t_small_values(1,3,5,7,9,11,13,15,17,19)" \
"The program being debugged stopped while.*" \
"stop at nested call level 4"
gdb_test "backtrace" \
"\#0 t_small_values \\(arg1=1 '.001', arg2=3, arg3=5, arg4=7 '.a', arg5=9, arg6=11 '.v', arg7=13, arg8=15, arg9=17, arg10=19\\).*\#2 sum10 \\(i0=2, i1=4, i2=6, i3=8, i4=10, i5=12, i6=14, i7=16, i8=18, i9=20\\).*\#3 .*\#4 add \\(a=4, b=5\\).*\#5 .*\#6 add \\(a=2, b=3\\).*\#7 .*\#8 main.*" \
"backtrace at nested call level 4"
gdb_test "finish" "Value returned is .* = 100" \
"Finish from nested call level 4"
gdb_test "backtrace" \
"\#0 sum10 \\(i0=2, i1=4, i2=6, i3=8, i4=10, i5=12, i6=14, i7=16, i8=18, i9=20\\).*\#1 .*\#2 add \\(a=4, b=5\\).*\#3 .*\#4 add \\(a=2, b=3\\).*\#5 .*\#6 main.*" \
"backtrace after finish from nested call level 4"
gdb_test "finish" "Value returned is .* = 110" \
"Finish from nested call level 3"
gdb_test "backtrace" \
"\#0 add \\(a=4, b=5\\).*\#1 .*\#2 add \\(a=2, b=3\\).*\#3 .*\#4 main.*" \
"backtrace after finish from nested call level 3"
gdb_test "finish" "Value returned is .* = 9" \
"Finish from nested call level 2"
gdb_test "backtrace" \
"\#0 add \\(a=2, b=3\\).*\#1 .*\#2 main.*" \
"backtrace after finish from nested call level 2"
gdb_test "finish" "Value returned is .* = 5" \
"Finish from nested call level 1"
gdb_test "backtrace" "\#0 main .*" \
"backtrace after finish from nested call level 1"
set new_reg_content [fetch_all_registers \
"register contents after nested call dummies"]
if {$old_reg_content == $new_reg_content} then {
pass "nested call dummies preserve register contents"
} else {
fail "nested call dummies preserve register contents"
}
# GDB should not crash by internal error on $sp underflow during the inferior
# call. It is OK it will stop on some: Cannot access memory at address 0x$hex.
if {![target_info exists gdb,nosignals] && ![istarget "*-*-uclinux*"]} {
gdb_test {set $old_sp = $sp}
gdb_test {set $sp = 0}
gdb_test "call doubleit (1)" ".*" "sp == 0: call doubleit (1)"
gdb_test {set $sp = -1}
gdb_test "call doubleit (1)" ".*" "sp == -1: call doubleit (1)"
gdb_test {set $sp = $old_sp}
}
# Test function descriptor resolution - the separate debug info .opd section
# handling vs. local labels `.L'... as `Lcallfunc' starts with `L'.
gdb_test "print callfunc (Lcallfunc, 5)" " = 12"
# Regression test for function pointer cast.
gdb_test "print *((int *(*) (void)) voidfunc)()" " = 23"
}
# Perform all tests with and without function prototypes.
if { ![prepare_for_testing "failed to prepare" $testfile $srcfile "$compile_flags additional_flags=-DPROTOTYPES"] } {
perform_all_tests 1
}
if { ![prepare_for_testing "failed to prepare" $testfile $srcfile "$compile_flags additional_flags=-DNO_PROTOTYPES"] } {
with_test_prefix "noproto" {
perform_all_tests 0
}
}