[deliverable/binutils-gdb.git] / gdb / testsuite / gdb.base / call-sc.exp

# This testcase is part of GDB, the GNU debugger.

# Copyright 2004, 2007 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 <http://www.gnu.org/licenses/>.

# Test "return", "finish", and "call" of functions that a scalar (int,
# float, enum) and/or take a single scalar parameter.

if $tracelevel then {
	strace $tracelevel
}

set prms_id 0
set bug_id 0

# Some targets can't call functions, so don't even bother with this
# test.

if [target_info exists gdb,cannot_call_functions] {
    setup_xfail "*-*-*"
    fail "This target can not call functions"
    continue
}

set testfile "call-sc"
set srcfile ${testfile}.c
set binfile ${objdir}/${subdir}/${testfile}

# Create and source the file that provides information about the
# compiler used to compile the test case.

if [get_compiler_info ${binfile}] {
    return -1;
}

# Use the file name, compiler and tuples to set up any needed KFAILs.

proc setup_kfails { file tuples bug } {
    global testfile
    if [string match $file $testfile] {
	foreach f $tuples { setup_kfail $f $bug }
    }
}

proc setup_compiler_kfails { file compiler format tuples bug } {
    global testfile
    if {[string match $file $testfile] && [test_compiler_info $compiler]  && [test_debug_format $format]} {
	foreach f $tuples { setup_kfail $f $bug }
    }
}

# Compile a variant of scalars.c using TYPE to specify the type of the
# parameter and return-type.  Run the compiled program up to "main".
# Also updates the global "testfile" to reflect the most recent build.

proc start_scalars_test { type } {
    global testfile
    global srcfile
    global binfile
    global objdir
    global subdir
    global srcdir
    global gdb_prompt
    global expect_out

    # Create the additional flags
    set flags "debug additional_flags=-DT=${type}"
    set testfile "call-sc-${type}"

    set binfile ${objdir}/${subdir}/${testfile}
    if  { [gdb_compile "${srcdir}/${subdir}/${srcfile}" "${binfile}" executable "${flags}"] != "" } {
	# built the second test case since we can't use prototypes
	warning "Prototypes not supported, rebuilding with -DNO_PROTOTYPES"
	if  { [gdb_compile "${srcdir}/${subdir}/${srcfile}" "${binfile}" executable "${flags} additional_flags=-DNO_PROTOTYPES"] != "" } {
	    untested call-sc.exp
	    return -1
	}
    }

    # Start with a fresh gdb.
    gdb_exit
    gdb_start
    gdb_reinitialize_dir $srcdir/$subdir
    gdb_load ${binfile}

    # Make certain that the output is consistent
    gdb_test "set print sevenbit-strings" "" \
	    "set print sevenbit-strings; ${testfile}"
    gdb_test "set print address off" "" \
	    "set print address off; ${testfile}"
    gdb_test "set width 0" "" \
	    "set width 0; ${testfile}"

    # Advance to main
    if { ![runto_main] } then {
	gdb_suppress_tests;
    }

    # Get the debug format
    get_debug_format

    # check that type matches what was passed in
    set test "ptype; ${testfile}"
    set foo_t "xxx"
    gdb_test_multiple "ptype ${type}" "${test}" {
	-re "type = (\[^\r\n\]*)\r\n$gdb_prompt $" {
	    set foo_t "$expect_out(1,string)"
	    pass "$test (${foo_t})"
	}
    }
    gdb_test "ptype foo" "type = ${foo_t}" "ptype foo; ${testfile} $expect_out(1,string)"
}


# Given N (0..25), return the corresponding alphabetic letter in lower
# or upper case.  This is ment to be i18n proof.

proc i2a { n } {
    return [string range "abcdefghijklmnopqrstuvwxyz" $n $n]
}

proc I2A { n } {
    return [string toupper [i2a $n]]
}


# Use the file name, compiler and tuples to set up any needed KFAILs.

proc setup_kfails { file tuples bug } {
    global testfile
    if [string match $file $testfile] {
	foreach f $tuples { setup_kfail $f $bug }
    }
}

proc setup_compiler_kfails { file compiler format tuples bug } {
    global testfile
    if {[string match $file $testfile] && [test_compiler_info $compiler]  && [test_debug_format $format]} {
	foreach f $tuples { setup_kfail $f $bug }
    }
}

# Test GDB's ability to make inferior function calls to functions
# returning (or passing) in a single scalar.

# start_scalars_test() will have previously built a program with a
# specified scalar type.  To ensure robustness of the output, "p/c" is
# used.

# This tests the code paths "which return-value convention?" and
# "extract return-value from registers" called by "infcall.c".

proc test_scalar_calls { } {
    global testfile
    global gdb_prompt

    # Check that GDB can always extract a scalar-return value from an
    # inferior function call.  Since GDB always knows the location of
    # an inferior function call's return value these should never fail
    
    # Implemented by calling the parameterless function "fun" and then
    # examining the return value printed by GDB.

    set tests "call ${testfile}"

    # Call fun, checking the printed return-value.
    gdb_test "p/c fun()" "= 49 '1'" "p/c fun(); ${tests}"

    # Check that GDB can always pass a structure to an inferior function.
    # This test can never fail.

    # Implemented by calling the one parameter function "Fun" which
    # stores its parameter in the global variable "L".  GDB then
    # examining that global to confirm that the value is as expected.

    gdb_test "call Fun(foo)" "" "call Fun(foo); ${tests}"
    gdb_test "p/c L" " = 49 '1'" "p/c L; ${tests}"
}

# Test GDB's ability to both return a function (with "return" or
# "finish") and correctly extract/store any corresponding
# return-value.

# Check that GDB can consistently extract/store structure return
# values.  There are two cases - returned in registers and returned in
# memory.  For the latter case, the return value can't be found and a
# failure is "expected".  However GDB must still both return the
# function and display the final source and line information.

# N identifies the number of elements in the struct that will be used
# for the test case.  FAILS is a list of target tuples that will fail
# this test.

# This tests the code paths "which return-value convention?", "extract
# return-value from registers", and "store return-value in registers".
# Unlike "test struct calls", this test is expected to "fail" when the
# return-value is in memory (GDB can't find the location).  The test
# is in three parts: test "return"; test "finish"; check that the two
# are consistent.  GDB can sometimes work for one command and not the
# other.

proc test_scalar_returns { } {
    global gdb_prompt
    global testfile

    set tests "return ${testfile}"


    # Check that "return" works.

    # GDB must always force the return of a function that has
    # a struct result.  Dependant on the ABI, it may, or may not be
    # possible to store the return value in a register.

    # The relevant code looks like "L{n} = fun{n}()".  The test forces
    # "fun{n}" to "return" with an explicit value.  Since that code
    # snippet will store the the returned value in "L{n}" the return
    # is tested by examining "L{n}".  This assumes that the
    # compiler implemented this as fun{n}(&L{n}) and hence that when
    # the value isn't stored "L{n}" remains unchanged.  Also check for
    # consistency between this and the "finish" case.

    # Get into a call of fun
    gdb_test "advance fun" \
	    "fun .*\[\r\n\]+\[0-9\].*return foo.*" \
	    "advance to fun for return; ${tests}"

    # Check that the program invalidated the relevant global.
    gdb_test "p/c L" " = 90 'Z'" "zed L for return; ${tests}"

    # Force the "return".  This checks that the return is always
    # performed, and that GDB correctly reported this to the user.
    # GDB 6.0 and earlier, when the return-value's location wasn't
    # known, both failed to print a final "source and line" and misplaced
    # the frame ("No frame").

    # The test is writen so that it only reports one FAIL/PASS for the
    # entire operation.  The value returned is checked further down.
    # "return_value_unknown", if non-empty, records why GDB realised
    # that it didn't know where the return value was.

    set test "return foo; ${tests}"
    set return_value_unknown 0
    set return_value_unimplemented 0
    gdb_test_multiple "return foo" "${test}" {
	-re "The location" {
	    # Ulgh, a struct return, remember this (still need prompt).
	    set return_value_unknown 1
	    exp_continue
	}
	-re "A structure or union" {
	    # Ulgh, a struct return, remember this (still need prompt).
	    set return_value_unknown 1
	    # Double ulgh.  Architecture doesn't use return_value and
	    # hence hasn't implemented small structure return.
	    set return_value_unimplemented 1
	    exp_continue
	}
	-re "Make fun return now.*y or n. $" {
	    gdb_test_multiple "y" "${test}" {
		-re "L *= fun.*${gdb_prompt} $" {
		    # Need to step off the function call
		    gdb_test "next" "zed.*" "${test}"
		}
		-re "zed \\(\\);.*$gdb_prompt $" {
		    pass "${test}"
		}
	    }
	}
    }

    # If the previous test did not work, the program counter might
    # still be inside foo() rather than main().  Make sure the program
    # counter is is main().
    #
    # This happens on ppc64 GNU/Linux with gcc 3.4.1 and a buggy GDB

    set test "return foo; synchronize pc to main()"
    for {set loop_count 0} {$loop_count < 2} {incr loop_count} {
      gdb_test_multiple "backtrace 1" $test {
        -re "#0.*main \\(\\).*${gdb_prompt} $" {
          pass $test
          set loop_count 2
        }
        -re "#0.*fun \\(\\).*${gdb_prompt} $" {
          if {$loop_count < 1} {
            gdb_test "finish" ".*" ""
          } else {
            fail $test
            set loop_count 2
          }
        }
      }
    }

    # Check that the return-value is as expected.  At this stage we're
    # just checking that GDB has returned a value consistent with
    # "return_value_unknown" set above.

    set test "value foo returned; ${tests}"
    gdb_test_multiple "p/c L" "${test}" {
	-re " = 49 '1'.*${gdb_prompt} $" {
	    if $return_value_unknown {
		# This contradicts the above claim that GDB didn't
		# know the location of the return-value.
		fail "${test}"
	    } else {
		pass "${test}"
	    }
	}
	-re " = 90 .*${gdb_prompt} $" {
	    if $return_value_unknown {
		# The struct return case.  Since any modification
		# would be by reference, and that can't happen, the
		# value should be unmodified and hence Z is expected.
		# Is this a reasonable assumption?
		pass "${test}"
	    } else {
		# This contradicts the above claim that GDB knew
		# the location of the return-value.
		fail "${test}"
	    }
	}
	-re ".*${gdb_prompt} $" {
	    if $return_value_unimplemented {
		# What a suprize.  The architecture hasn't implemented
		# return_value, and hence has to fail.
		kfail "$test" gdb/1444
	    } else {
		fail "$test"
	    }
	}
    }	
    
    # Check that a "finish" works.

    # This is almost but not quite the same as "call struct funcs".
    # Architectures can have subtle differences in the two code paths.

    # The relevant code snippet is "L{n} = fun{n}()".  The program is
    # advanced into a call to  "fun{n}" and then that function is
    # finished.  The returned value that GDB prints, reformatted using
    # "p/c", is checked.

    # Get into "fun()".
    gdb_test "advance fun" \
	    "fun .*\[\r\n\]+\[0-9\].*return foo.*" \
	    "advance to fun for finish; ${tests}"

    # Check that the program invalidated the relevant global.
    gdb_test "p/c L" " = 90 'Z'" "zed L for finish; ${tests}"

    # Finish the function, set 'finish_value_unknown" to non-empty if the
    # return-value was not found.
    set test "finish foo; ${tests}"
    set finish_value_unknown 0
    gdb_test_multiple "finish" "${test}" {
	-re "Value returned is .*${gdb_prompt} $" {
	    pass "${test}"
	}
	-re "Cannot determine contents.*${gdb_prompt} $" {
	    # Expected bad value.  For the moment this is ok.
	    set finish_value_unknown 1
	    pass "${test}"
	}
    }

    # Re-print the last (return-value) using the more robust
    # "p/c".  If no return value was found, the 'Z' from the previous
    # check that the variable was cleared, is printed.
    set test "value foo finished; ${tests}"
    gdb_test_multiple "p/c" "${test}" {
	-re " = 49 '1'\[\r\n\]+${gdb_prompt} $" {
	    if $finish_value_unknown {
		# This contradicts the above claim that GDB didn't
		# know the location of the return-value.
		fail "${test}"
	    } else {
		pass "${test}"
	    }
	}
	-re " = 90 'Z'\[\r\n\]+${gdb_prompt} $" {
	    # The value didn't get found.  This is "expected".
	    if $finish_value_unknown {
		pass "${test}"
	    } else {
		# This contradicts the above claim that GDB did
		# know the location of the return-value.
		fail "${test}"
	    }
	}
    }

    # Finally, check that "return" and finish" have consistent
    # behavior.

    # Since both "return" and "finish" use equivalent "which
    # return-value convention" logic, both commands should have
    # identical can/can-not find return-value messages.

    # Note that since "call" and "finish" use common code paths, a
    # failure here is a strong indicator of problems with "store
    # return-value" code paths.  Suggest looking at "return_value"
    # when investigating a fix.

    set test "return and finish use same convention; ${tests}"
    if {$finish_value_unknown == $return_value_unknown} {
	pass "${test}"
    } else {
	kfail gdb/1444 "${test}"
    }
}

# ABIs pass anything >8 or >16 bytes in memory but below that things
# randomly use register and/and structure conventions.  Check all
# possible sized char scalars in that range.  But only a restricted
# range of the other types.

# NetBSD/PPC returns "unnatural" (3, 5, 6, 7) sized scalars in memory.

# d10v is weird. 5/6 byte scalars go in memory.  2 or more char
# scalars go in memory.  Everything else is in a register!

# Test every single char struct from 1..17 in size.  This is what the
# original "scalars" test was doing.

start_scalars_test tc
test_scalar_calls
test_scalar_returns


# Let the fun begin.

# Assuming that any integer struct larger than 8 bytes goes in memory,
# come up with many and varied combinations of a return struct.  For
# "struct calls" test just beyond that 8 byte boundary, for "struct
# returns" test up to that boundary.

# For floats, assumed that up to two struct elements can be stored in
# floating point registers, regardless of their size.

# The approx size of each structure it is computed assumed that tc=1,
# ts=2, ti=4, tl=4, tll=8, tf=4, td=8, tld=16, and that all fields are
# naturally aligned.  Padding being added where needed.  Note that
# these numbers are just approx, the d10v has ti=2, a 64-bit has has
# tl=8.

# Approx size: 2, 4, ...
start_scalars_test ts
test_scalar_calls
test_scalar_returns

# Approx size: 4, 8, ...
start_scalars_test ti
test_scalar_calls
test_scalar_returns

# Approx size: 4, 8, ...
start_scalars_test tl
test_scalar_calls
test_scalar_returns

# Approx size: 8, 16, ...
start_scalars_test tll
test_scalar_calls
test_scalar_returns

# Approx size: 4, 8, ...
start_scalars_test tf
test_scalar_calls
test_scalar_returns

# Approx size: 8, 16, ...
start_scalars_test td
test_scalar_calls
test_scalar_returns

# Approx size: 16, 32, ...
start_scalars_test tld
test_scalar_calls
test_scalar_returns

# Approx size: 4, 8, ...
start_scalars_test te
test_scalar_calls
test_scalar_returns

return 0
Commit	Line	Data
71d7dd7c AC	1	# This testcase is part of GDB, the GNU debugger.
71d7dd7c AC	2
6aba47ca	3	# Copyright 2004, 2007 Free Software Foundation, Inc.
71d7dd7c AC	4
	5	# This program is free software; you can redistribute it and/or modify
	6	# it under the terms of the GNU General Public License as published by
e22f8b7c	7	# the Free Software Foundation; either version 3 of the License, or
71d7dd7c	8	# (at your option) any later version.
e22f8b7c	9	#
71d7dd7c AC	10	# This program is distributed in the hope that it will be useful,
	11	# but WITHOUT ANY WARRANTY; without even the implied warranty of
	12	# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	13	# GNU General Public License for more details.
e22f8b7c	14	#
71d7dd7c	15	# You should have received a copy of the GNU General Public License
e22f8b7c	16	# along with this program. If not, see <http://www.gnu.org/licenses/>.
71d7dd7c AC	17
	18	# Test "return", "finish", and "call" of functions that a scalar (int,
	19	# float, enum) and/or take a single scalar parameter.
	20
	21	if $tracelevel then {
	22	strace $tracelevel
	23	}
	24
	25	set prms_id 0
	26	set bug_id 0
	27
	28	# Some targets can't call functions, so don't even bother with this
	29	# test.
	30
	31	if [target_info exists gdb,cannot_call_functions] {
	32	setup_xfail "--*"
	33	fail "This target can not call functions"
	34	continue
	35	}
	36
	37	set testfile "call-sc"
	38	set srcfile ${testfile}.c
	39	set binfile ${objdir}/${subdir}/${testfile}
	40
	41	# Create and source the file that provides information about the
	42	# compiler used to compile the test case.
	43
	44	if [get_compiler_info ${binfile}] {
	45	return -1;
	46	}
	47
	48	# Use the file name, compiler and tuples to set up any needed KFAILs.
	49
	50	proc setup_kfails { file tuples bug } {
	51	global testfile
	52	if [string match $file $testfile] {
	53	foreach f $tuples { setup_kfail $f $bug }
	54	}
	55	}
	56
	57	proc setup_compiler_kfails { file compiler format tuples bug } {
	58	global testfile
	59	if {[string match $file $testfile] && [test_compiler_info $compiler] && [test_debug_format $format]} {
	60	foreach f $tuples { setup_kfail $f $bug }
	61	}
	62	}
	63
	64	# Compile a variant of scalars.c using TYPE to specify the type of the
	65	# parameter and return-type. Run the compiled program up to "main".
	66	# Also updates the global "testfile" to reflect the most recent build.
	67
	68	proc start_scalars_test { type } {
	69	global testfile
	70	global srcfile
	71	global binfile
	72	global objdir
	73	global subdir
	74	global srcdir
	75	global gdb_prompt
	76	global expect_out
	77
	78	# Create the additional flags
	79	set flags "debug additional_flags=-DT=${type}"
	80	set testfile "call-sc-${type}"
81
82	set binfile ${objdir}/${subdir}/${testfile}
83	if { [gdb_compile "${srcdir}/${subdir}/${srcfile}" "${binfile}" executable "${flags}"] != "" } {
84	# built the second test case since we can't use prototypes
85	warning "Prototypes not supported, rebuilding with -DNO_PROTOTYPES"
86	if { [gdb_compile "${srcdir}/${subdir}/${srcfile}" "${binfile}" executable "${flags} additional_flags=-DNO_PROTOTYPES"] != "" } {
b60f0898 JB	87	untested call-sc.exp
b60f0898 JB	88	return -1
71d7dd7c AC	89	}
	90	}
	91
	92	# Start with a fresh gdb.
	93	gdb_exit
	94	gdb_start
	95	gdb_reinitialize_dir $srcdir/$subdir
	96	gdb_load ${binfile}
	97
	98	# Make certain that the output is consistent
	99	gdb_test "set print sevenbit-strings" "" \
	100	"set print sevenbit-strings; ${testfile}"
	101	gdb_test "set print address off" "" \
	102	"set print address off; ${testfile}"
	103	gdb_test "set width 0" "" \
	104	"set width 0; ${testfile}"
	105
	106	# Advance to main
	107	if { ![runto_main] } then {
	108	gdb_suppress_tests;
	109	}
	110
	111	# Get the debug format
	112	get_debug_format
	113
	114	# check that type matches what was passed in
	115	set test "ptype; ${testfile}"
	116	set foo_t "xxx"
	117	gdb_test_multiple "ptype ${type}" "${test}" {
0ef32fd9	118	-re "type = (\[^\r\n\]*)\r\n$gdb_prompt $" {
71d7dd7c AC	119	set foo_t "$expect_out(1,string)"
	120	pass "$test (${foo_t})"
	121	}
	122	}
	123	gdb_test "ptype foo" "type = ${foo_t}" "ptype foo; ${testfile} $expect_out(1,string)"
	124	}
	125
	126
	127	# Given N (0..25), return the corresponding alphabetic letter in lower
	128	# or upper case. This is ment to be i18n proof.
	129
	130	proc i2a { n } {
	131	return [string range "abcdefghijklmnopqrstuvwxyz" $n $n]
	132	}
	133
	134	proc I2A { n } {
	135	return [string toupper [i2a $n]]
	136	}
	137
	138
	139	# Use the file name, compiler and tuples to set up any needed KFAILs.
	140
	141	proc setup_kfails { file tuples bug } {
	142	global testfile
	143	if [string match $file $testfile] {
	144	foreach f $tuples { setup_kfail $f $bug }
	145	}
	146	}
	147
	148	proc setup_compiler_kfails { file compiler format tuples bug } {
	149	global testfile
	150	if {[string match $file $testfile] && [test_compiler_info $compiler] && [test_debug_format $format]} {
	151	foreach f $tuples { setup_kfail $f $bug }
	152	}
	153	}
	154
	155	# Test GDB's ability to make inferior function calls to functions
	156	# returning (or passing) in a single scalar.
	157
	158	# start_scalars_test() will have previously built a program with a
	159	# specified scalar type. To ensure robustness of the output, "p/c" is
	160	# used.
	161
	162	# This tests the code paths "which return-value convention?" and
	163	# "extract return-value from registers" called by "infcall.c".
	164
	165	proc test_scalar_calls { } {
	166	global testfile
	167	global gdb_prompt
	168
	169	# Check that GDB can always extract a scalar-return value from an
	170	# inferior function call. Since GDB always knows the location of
	171	# an inferior function call's return value these should never fail
	172
	173	# Implemented by calling the parameterless function "fun" and then
	174	# examining the return value printed by GDB.
	175
	176	set tests "call ${testfile}"
	177
	178	# Call fun, checking the printed return-value.
	179	gdb_test "p/c fun()" "= 49 '1'" "p/c fun(); ${tests}"
	180
	181	# Check that GDB can always pass a structure to an inferior function.
	182	# This test can never fail.
183
184	# Implemented by calling the one parameter function "Fun" which
185	# stores its parameter in the global variable "L". GDB then
186	# examining that global to confirm that the value is as expected.
187
188	gdb_test "call Fun(foo)" "" "call Fun(foo); ${tests}"
189	gdb_test "p/c L" " = 49 '1'" "p/c L; ${tests}"
190	}
191
192	# Test GDB's ability to both return a function (with "return" or
193	# "finish") and correctly extract/store any corresponding
194	# return-value.
195
196	# Check that GDB can consistently extract/store structure return
197	# values. There are two cases - returned in registers and returned in
198	# memory. For the latter case, the return value can't be found and a
199	# failure is "expected". However GDB must still both return the
200	# function and display the final source and line information.
201
202	# N identifies the number of elements in the struct that will be used
203	# for the test case. FAILS is a list of target tuples that will fail
204	# this test.
205
206	# This tests the code paths "which return-value convention?", "extract
207	# return-value from registers", and "store return-value in registers".
208	# Unlike "test struct calls", this test is expected to "fail" when the
209	# return-value is in memory (GDB can't find the location). The test
210	# is in three parts: test "return"; test "finish"; check that the two
211	# are consistent. GDB can sometimes work for one command and not the
212	# other.
213
214	proc test_scalar_returns { } {
215	global gdb_prompt
216	global testfile
217
218	set tests "return ${testfile}"
219
220
221	# Check that "return" works.
222
223	# GDB must always force the return of a function that has
224	# a struct result. Dependant on the ABI, it may, or may not be
225	# possible to store the return value in a register.
226
227	# The relevant code looks like "L{n} = fun{n}()". The test forces
228	# "fun{n}" to "return" with an explicit value. Since that code
229	# snippet will store the the returned value in "L{n}" the return
230	# is tested by examining "L{n}". This assumes that the
231	# compiler implemented this as fun{n}(&L{n}) and hence that when
232	# the value isn't stored "L{n}" remains unchanged. Also check for
233	# consistency between this and the "finish" case.
234
235	# Get into a call of fun
236	gdb_test "advance fun" \
237	"fun .\[\r\n\]+\[0-9\].return foo.*" \
238	"advance to fun for return; ${tests}"
239
240	# Check that the program invalidated the relevant global.
241	gdb_test "p/c L" " = 90 'Z'" "zed L for return; ${tests}"
242
243	# Force the "return". This checks that the return is always
244	# performed, and that GDB correctly reported this to the user.
245	# GDB 6.0 and earlier, when the return-value's location wasn't
246	# known, both failed to print a final "source and line" and misplaced
247	# the frame ("No frame").
248
249	# The test is writen so that it only reports one FAIL/PASS for the
250	# entire operation. The value returned is checked further down.
251	# "return_value_unknown", if non-empty, records why GDB realised
252	# that it didn't know where the return value was.
253
254	set test "return foo; ${tests}"
255	set return_value_unknown 0
256	set return_value_unimplemented 0
71d7dd7c AC	257	gdb_test_multiple "return foo" "${test}" {
	258	-re "The location" {
	259	# Ulgh, a struct return, remember this (still need prompt).
	260	set return_value_unknown 1
	261	exp_continue
	262	}
	263	-re "A structure or union" {
	264	# Ulgh, a struct return, remember this (still need prompt).
	265	set return_value_unknown 1
	266	# Double ulgh. Architecture doesn't use return_value and
	267	# hence hasn't implemented small structure return.
	268	set return_value_unimplemented 1
	269	exp_continue
	270	}
	271	-re "Make fun return now.*y or n. $" {
	272	gdb_test_multiple "y" "${test}" {
	273	-re "L = fun.${gdb_prompt} $" {
	274	# Need to step off the function call
	275	gdb_test "next" "zed.*" "${test}"
	276	}
2f193b69	277	-re "zed \\(\\);.*$gdb_prompt $" {
71d7dd7c AC	278	pass "${test}"
	279	}
	280	}
	281	}
	282	}
	283
3a77aa28 MC	284	# If the previous test did not work, the program counter might
	285	# still be inside foo() rather than main(). Make sure the program
	286	# counter is is main().
	287	#
	288	# This happens on ppc64 GNU/Linux with gcc 3.4.1 and a buggy GDB
	289
	290	set test "return foo; synchronize pc to main()"
	291	for {set loop_count 0} {$loop_count < 2} {incr loop_count} {
	292	gdb_test_multiple "backtrace 1" $test {
	293	-re "#0.main \\(\\).${gdb_prompt} $" {
	294	pass $test
	295	set loop_count 2
	296	}
	297	-re "#0.fun \\(\\).${gdb_prompt} $" {
	298	if {$loop_count < 1} {
	299	gdb_test "finish" ".*" ""
	300	} else {
	301	fail $test
	302	set loop_count 2
	303	}
	304	}
	305	}
	306	}
	307
71d7dd7c AC	308	# Check that the return-value is as expected. At this stage we're
	309	# just checking that GDB has returned a value consistent with
	310	# "return_value_unknown" set above.
	311
	312	set test "value foo returned; ${tests}"
71d7dd7c AC	313	gdb_test_multiple "p/c L" "${test}" {
	314	-re " = 49 '1'.*${gdb_prompt} $" {
	315	if $return_value_unknown {
	316	# This contradicts the above claim that GDB didn't
	317	# know the location of the return-value.
	318	fail "${test}"
	319	} else {
	320	pass "${test}"
	321	}
	322	}
	323	-re " = 90 .*${gdb_prompt} $" {
	324	if $return_value_unknown {
	325	# The struct return case. Since any modification
	326	# would be by reference, and that can't happen, the
	327	# value should be unmodified and hence Z is expected.
	328	# Is this a reasonable assumption?
	329	pass "${test}"
	330	} else {
	331	# This contradicts the above claim that GDB knew
	332	# the location of the return-value.
	333	fail "${test}"
	334	}
	335	}
	336	-re ".*${gdb_prompt} $" {
	337	if $return_value_unimplemented {
	338	# What a suprize. The architecture hasn't implemented
	339	# return_value, and hence has to fail.
	340	kfail "$test" gdb/1444
	341	} else {
	342	fail "$test"
	343	}
	344	}
	345	}
	346
	347	# Check that a "finish" works.
	348
	349	# This is almost but not quite the same as "call struct funcs".
	350	# Architectures can have subtle differences in the two code paths.
	351
	352	# The relevant code snippet is "L{n} = fun{n}()". The program is
	353	# advanced into a call to "fun{n}" and then that function is
	354	# finished. The returned value that GDB prints, reformatted using
	355	# "p/c", is checked.
	356
	357	# Get into "fun()".
	358	gdb_test "advance fun" \
	359	"fun .\[\r\n\]+\[0-9\].return foo.*" \
	360	"advance to fun for finish; ${tests}"
	361
	362	# Check that the program invalidated the relevant global.
	363	gdb_test "p/c L" " = 90 'Z'" "zed L for finish; ${tests}"
	364
	365	# Finish the function, set 'finish_value_unknown" to non-empty if the
	366	# return-value was not found.
	367	set test "finish foo; ${tests}"
	368	set finish_value_unknown 0
	369	gdb_test_multiple "finish" "${test}" {
	370	-re "Value returned is .*${gdb_prompt} $" {
	371	pass "${test}"
	372	}
	373	-re "Cannot determine contents.*${gdb_prompt} $" {
	374	# Expected bad value. For the moment this is ok.
	375	set finish_value_unknown 1
	376	pass "${test}"
377	}
378	}
379
380	# Re-print the last (return-value) using the more robust
381	# "p/c". If no return value was found, the 'Z' from the previous
382	# check that the variable was cleared, is printed.
383	set test "value foo finished; ${tests}"
384	gdb_test_multiple "p/c" "${test}" {
385	-re " = 49 '1'\[\r\n\]+${gdb_prompt} $" {
386	if $finish_value_unknown {
387	# This contradicts the above claim that GDB didn't
388	# know the location of the return-value.
389	fail "${test}"
390	} else {
391	pass "${test}"
392	}
393	}
394	-re " = 90 'Z'\[\r\n\]+${gdb_prompt} $" {
395	# The value didn't get found. This is "expected".
396	if $finish_value_unknown {
397	pass "${test}"
398	} else {
399	# This contradicts the above claim that GDB did
400	# know the location of the return-value.
401	fail "${test}"
402	}
403	}
404	}
405
406	# Finally, check that "return" and finish" have consistent
407	# behavior.
408
409	# Since both "return" and "finish" use equivalent "which
410	# return-value convention" logic, both commands should have
411	# identical can/can-not find return-value messages.
412
413	# Note that since "call" and "finish" use common code paths, a
414	# failure here is a strong indicator of problems with "store
415	# return-value" code paths. Suggest looking at "return_value"
416	# when investigating a fix.
417
418	set test "return and finish use same convention; ${tests}"
419	if {$finish_value_unknown == $return_value_unknown} {
420	pass "${test}"
421	} else {
422	kfail gdb/1444 "${test}"
423	}
424	}
425
426	# ABIs pass anything >8 or >16 bytes in memory but below that things
427	# randomly use register and/and structure conventions. Check all
428	# possible sized char scalars in that range. But only a restricted
429	# range of the other types.
430
431	# NetBSD/PPC returns "unnatural" (3, 5, 6, 7) sized scalars in memory.
432
433	# d10v is weird. 5/6 byte scalars go in memory. 2 or more char
434	# scalars go in memory. Everything else is in a register!
435
436	# Test every single char struct from 1..17 in size. This is what the
437	# original "scalars" test was doing.
438
439	start_scalars_test tc
440	test_scalar_calls
441	test_scalar_returns
442
443
444	# Let the fun begin.
445
446	# Assuming that any integer struct larger than 8 bytes goes in memory,
447	# come up with many and varied combinations of a return struct. For
448	# "struct calls" test just beyond that 8 byte boundary, for "struct
449	# returns" test up to that boundary.
450
451	# For floats, assumed that up to two struct elements can be stored in
452	# floating point registers, regardless of their size.
453
454	# The approx size of each structure it is computed assumed that tc=1,
455	# ts=2, ti=4, tl=4, tll=8, tf=4, td=8, tld=16, and that all fields are
456	# naturally aligned. Padding being added where needed. Note that
457	# these numbers are just approx, the d10v has ti=2, a 64-bit has has
458	# tl=8.
459
460	# Approx size: 2, 4, ...
461	start_scalars_test ts
462	test_scalar_calls
463	test_scalar_returns
464
465	# Approx size: 4, 8, ...
466	start_scalars_test ti
467	test_scalar_calls
468	test_scalar_returns
469
470	# Approx size: 4, 8, ...
471	start_scalars_test tl
472	test_scalar_calls
473	test_scalar_returns
474
475	# Approx size: 8, 16, ...
476	start_scalars_test tll
477	test_scalar_calls
478	test_scalar_returns
479
480	# Approx size: 4, 8, ...
481	start_scalars_test tf
482	test_scalar_calls
483	test_scalar_returns
484
485	# Approx size: 8, 16, ...
486	start_scalars_test td
487	test_scalar_calls
488	test_scalar_returns
489
490	# Approx size: 16, 32, ...
491	start_scalars_test tld
492	test_scalar_calls
493	test_scalar_returns
494
495	# Approx size: 4, 8, ...
496	start_scalars_test te
497	test_scalar_calls
498	test_scalar_returns
499
500	return 0