gdb/testsuite/gdb.dwarf2/implref-array.exp - binutils-gdb - Git at Google

 # Copyright 2016-2021 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 <http://www.gnu.org/licenses/>.

 # Test a C++ reference marked with DW_OP_GNU_implicit_pointer.
 # The referenced value is a global array whose location is a DW_OP_addr.

 if [skip_cplus_tests] {
     continue
 }

 load_lib dwarf.exp

 # This test can only be run on targets which support DWARF-2 and use gas.
 if ![dwarf2_support] {
     return 0
 }

 # We'll place the output of Dwarf::assemble in implref-array.S.
 standard_testfile .c .S

 # ${testfile} is now "implref-array".  srcfile2 is "implref-array.S".
 set executable ${testfile}
 set asm_file [standard_output_file ${srcfile2}]

 # We need to know the size of integer and address types in order
 # to write some of the debugging info we'd like to generate.
 #
 # For that, we ask GDB by debugging our implref-array program.
 # Any program would do, but since we already have implref-array
 # specifically for this testcase, might as well use that.
 if { [prepare_for_testing "failed to prepare" ${testfile} ${srcfile}] } {
     return -1
 }

 set array_length [get_valueof "/u" "sizeof(array) / sizeof(array\[0\])" -1]

 # Create the DWARF.  We need a regular variable which represents the array, and
 # a reference to it that'll be marked with DW_OP_GNU_implicit_pointer.
 # The variable must be global so that its name is an exported symbol that we
 # can reference from the DWARF using gdb_target_symbol.
 Dwarf::assemble ${asm_file} {
     global array_length

     cu {} {
 	DW_TAG_compile_unit {
 	    {DW_AT_language @DW_LANG_C_plus_plus}
 	} {
 	    declare_labels int_label sizetype_label array_label variable_label ref_label
 	    set int_size [get_sizeof "int" -1]
 	    set upper_bound [expr ${array_length} - 1]

 	    # gdb always assumes references are implemented as pointers.
 	    set addr_size [get_sizeof "void *" -1]

 	    int_label: DW_TAG_base_type {
 		{DW_AT_byte_size ${int_size} DW_FORM_udata}
 		{DW_AT_encoding @DW_ATE_signed}
 		{DW_AT_name "int"}
 	    }

 	    sizetype_label: DW_TAG_base_type {
 		{DW_AT_byte_size ${int_size} DW_FORM_udata}
 		{DW_AT_encoding @DW_ATE_unsigned}
 		{DW_AT_name "sizetype"}
 	    }

 	    array_label: DW_TAG_array_type {
 		    {DW_AT_type :${int_label}}
 	    } {
 		DW_TAG_subrange_type {
 		    {DW_AT_type :${sizetype_label}}
 		    {DW_AT_lower_bound 0 DW_FORM_udata}
 		    {DW_AT_upper_bound ${upper_bound} DW_FORM_udata}
 		}
 	    }

 	    ref_label: DW_TAG_reference_type {
 		{DW_AT_byte_size ${addr_size} DW_FORM_udata}
 		{DW_AT_type :${array_label}}
 	    }

 	    variable_label: DW_TAG_variable {
 		{DW_AT_name "array"}
 		{DW_AT_type :${array_label}}
 		{DW_AT_external 1 DW_FORM_flag}
 		{DW_AT_location {DW_OP_addr [gdb_target_symbol "array"]} SPECIAL_expr}
 	    }

 	    DW_TAG_subprogram {
 		{MACRO_AT_func { "main" }}
 		{DW_AT_type :${int_label}}
 		{DW_AT_external 1 DW_FORM_flag}
 	    } {
 		DW_TAG_variable {
 		    {DW_AT_name "ref"}
 		    {DW_AT_type :${ref_label}}
 		    {DW_AT_location {DW_OP_GNU_implicit_pointer ${variable_label} 0} SPECIAL_expr}
 		}
 	    }
 	}
     }
 }

 if [prepare_for_testing "failed to prepare" ${executable} [list ${asm_file} ${srcfile}] {}] {
     return -1
 }

 # DW_OP_GNU_implicit_pointer implementation requires a valid frame.
 if ![runto_main] {
     return -1
 }

 # This matches e.g. '(int (&)[5])'
 set ref_type [format {\(int \(&\)\[%d\]\)} ${array_length}]

 # This matches e.g. '(int (*)[5])'
 set ptr_type [format {\(int \(\*\)\[%d\]\)} ${array_length}]

 # Contents of the array.  Trim leading/trailing whitespace, '{' and '}'
 # since they confuse TCL to no end.
 set contents [get_valueof "" "array" ""]
 set contents [string trim ${contents}]
 set contents [string trim ${contents} "{}"]

 # Address of the referenced value.
 set address [get_hexadecimal_valueof "&array" ""]

 # Doing 'print ref' should show us e.g. '(int (&)[5]) 0xdeadbeef: {0, 1, 2, 3, 4}'.
 gdb_test "print ref" " = ${ref_type} @${address}: \\{${contents}\\}"

 # Doing 'print &ref' should show us e.g. '(int (*)[5]) 0xdeadbeef <array>'.
 gdb_test "print &ref" " = ${ptr_type} ${address} <array>"

 # gdb assumes C++ references are implemented as pointers, and print &(&ref)
 # shows us the underlying pointer's address.  Since in this case there's no
 # physical pointer, gdb should tell us so.
 gdb_test "print &(&ref)" "Attempt to take address of value not located in memory."

 # Test assignment through the synthetic reference.
 set first_value 10
 gdb_test_no_output "set (ref\[0\] = ${first_value})"

 # This matches '{10, 1, 2, 3, 4}'.
 set new_contents [format {\{%d, 1, 2, 3, 4\}} ${first_value}]

 # Doing 'print ref' should now show us e.g.
 # '(int (&)[5]) <synthetic pointer>: {10, 1, 2, 3, 4}'.
 gdb_test "print ref" " = ${ref_type} @${address}: ${new_contents}" "print ref after assignment"
 gdb_test "print array" " = ${new_contents}" "print array after assignment"

 # Test treating the array as a pointer.
 set second_value 20
 set new_contents [format {\{%d, %d, 2, 3, 4\}} ${first_value} ${second_value}]

 gdb_test "print *ref" " = ${first_value}"
 gdb_test_no_output "set (*(ref + 1) = ${second_value})"
 gdb_test "print ref\[1\]" " = ${second_value}"
 gdb_test "print array" " = ${new_contents}" "print array after second assignment"
	# Copyright 2016-2021 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 <http://www.gnu.org/licenses/>.

	# Test a C++ reference marked with DW_OP_GNU_implicit_pointer.
	# The referenced value is a global array whose location is a DW_OP_addr.

	if [skip_cplus_tests] {
	continue
	}

	load_lib dwarf.exp

	# This test can only be run on targets which support DWARF-2 and use gas.
	if ![dwarf2_support] {
	return 0
	}

	# We'll place the output of Dwarf::assemble in implref-array.S.
	standard_testfile .c .S

	# ${testfile} is now "implref-array". srcfile2 is "implref-array.S".
	set executable ${testfile}
	set asm_file [standard_output_file ${srcfile2}]

	# We need to know the size of integer and address types in order
	# to write some of the debugging info we'd like to generate.
	#
	# For that, we ask GDB by debugging our implref-array program.
	# Any program would do, but since we already have implref-array
	# specifically for this testcase, might as well use that.
	if { [prepare_for_testing "failed to prepare" ${testfile} ${srcfile}] } {
	return -1
	}

	set array_length [get_valueof "/u" "sizeof(array) / sizeof(array\[0\])" -1]

	# Create the DWARF. We need a regular variable which represents the array, and
	# a reference to it that'll be marked with DW_OP_GNU_implicit_pointer.
	# The variable must be global so that its name is an exported symbol that we
	# can reference from the DWARF using gdb_target_symbol.
	Dwarf::assemble ${asm_file} {
	global array_length

	cu {} {
	DW_TAG_compile_unit {
	{DW_AT_language @DW_LANG_C_plus_plus}
	} {
	declare_labels int_label sizetype_label array_label variable_label ref_label
	set int_size [get_sizeof "int" -1]
	set upper_bound [expr ${array_length} - 1]

	# gdb always assumes references are implemented as pointers.
	set addr_size [get_sizeof "void *" -1]

	int_label: DW_TAG_base_type {
	{DW_AT_byte_size ${int_size} DW_FORM_udata}
	{DW_AT_encoding @DW_ATE_signed}
	{DW_AT_name "int"}
	}

	sizetype_label: DW_TAG_base_type {
	{DW_AT_byte_size ${int_size} DW_FORM_udata}
	{DW_AT_encoding @DW_ATE_unsigned}
	{DW_AT_name "sizetype"}
	}

	array_label: DW_TAG_array_type {
	{DW_AT_type :${int_label}}
	} {
	DW_TAG_subrange_type {
	{DW_AT_type :${sizetype_label}}
	{DW_AT_lower_bound 0 DW_FORM_udata}
	{DW_AT_upper_bound ${upper_bound} DW_FORM_udata}
	}
	}

	ref_label: DW_TAG_reference_type {
	{DW_AT_byte_size ${addr_size} DW_FORM_udata}
	{DW_AT_type :${array_label}}
	}

	variable_label: DW_TAG_variable {
	{DW_AT_name "array"}
	{DW_AT_type :${array_label}}
	{DW_AT_external 1 DW_FORM_flag}
	{DW_AT_location {DW_OP_addr [gdb_target_symbol "array"]} SPECIAL_expr}
	}

	DW_TAG_subprogram {
	{MACRO_AT_func { "main" }}
	{DW_AT_type :${int_label}}
	{DW_AT_external 1 DW_FORM_flag}
	} {
	DW_TAG_variable {
	{DW_AT_name "ref"}
	{DW_AT_type :${ref_label}}
	{DW_AT_location {DW_OP_GNU_implicit_pointer ${variable_label} 0} SPECIAL_expr}
	}
	}
	}
	}
	}

	if [prepare_for_testing "failed to prepare" ${executable} [list ${asm_file} ${srcfile}] {}] {
	return -1
	}

	# DW_OP_GNU_implicit_pointer implementation requires a valid frame.
	if ![runto_main] {
	return -1
	}

	# This matches e.g. '(int (&)[5])'
	set ref_type [format {\(int \(&\)\[%d\]\)} ${array_length}]

	# This matches e.g. '(int (*)[5])'
	set ptr_type [format {\(int \(\*\)\[%d\]\)} ${array_length}]

	# Contents of the array. Trim leading/trailing whitespace, '{' and '}'
	# since they confuse TCL to no end.
	set contents [get_valueof "" "array" ""]
	set contents [string trim ${contents}]
	set contents [string trim ${contents} "{}"]

	# Address of the referenced value.
	set address [get_hexadecimal_valueof "&array" ""]

	# Doing 'print ref' should show us e.g. '(int (&)[5]) 0xdeadbeef: {0, 1, 2, 3, 4}'.
	gdb_test "print ref" " = ${ref_type} @${address}: \\{${contents}\\}"

	# Doing 'print &ref' should show us e.g. '(int (*)[5]) 0xdeadbeef <array>'.
	gdb_test "print &ref" " = ${ptr_type} ${address} <array>"

	# gdb assumes C++ references are implemented as pointers, and print &(&ref)
	# shows us the underlying pointer's address. Since in this case there's no
	# physical pointer, gdb should tell us so.
	gdb_test "print &(&ref)" "Attempt to take address of value not located in memory."

	# Test assignment through the synthetic reference.
	set first_value 10
	gdb_test_no_output "set (ref\[0\] = ${first_value})"

	# This matches '{10, 1, 2, 3, 4}'.
	set new_contents [format {\{%d, 1, 2, 3, 4\}} ${first_value}]

	# Doing 'print ref' should now show us e.g.
	# '(int (&)[5]) <synthetic pointer>: {10, 1, 2, 3, 4}'.
	gdb_test "print ref" " = ${ref_type} @${address}: ${new_contents}" "print ref after assignment"
	gdb_test "print array" " = ${new_contents}" "print array after assignment"

	# Test treating the array as a pointer.
	set second_value 20
	set new_contents [format {\{%d, %d, 2, 3, 4\}} ${first_value} ${second_value}]

	gdb_test "print *ref" " = ${first_value}"
	gdb_test_no_output "set (*(ref + 1) = ${second_value})"
	gdb_test "print ref\[1\]" " = ${second_value}"
	gdb_test "print array" " = ${new_contents}" "print array after second assignment"