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2023-01-01Update copyright year range in header of all files managed by GDBJoel Brobecker1-1/+1
This commit is the result of running the gdb/copyright.py script, which automated the update of the copyright year range for all source files managed by the GDB project to be updated to include year 2023.
2022-04-11gdb/fortran: rewrite intrinsic handling and add some missing overloadsNils-Christian Kempke1-28/+154
The operators FLOOR, CEILING, CMPLX, LBOUND, UBOUND, and SIZE accept (some only with Fortran 2003) the optional parameter KIND. This parameter determines the kind of the associated return value. So far, implementation of this kind parameter has been missing in GDB. Additionally, the one argument overload for the CMPLX intrinsic function was not yet available. This patch adds overloads for all above mentioned functions to the Fortran intrinsics handling in GDB. It re-writes the intrinsic function handling section to use the helper methods wrap_unop_intrinsic/wrap_binop_intrinsic/wrap_triop_intrinsic. These methods define the action taken when a Fortran intrinsic function is called with a certain amount of arguments (1/2/3). The helper methods fortran_wrap2_kind and fortran_wrap3_kind have been added as equivalents to the existing wrap and wrap2 methods. After adding more overloads to the intrinsics handling, some of the operation names were no longer accurate. E.g. UNOP_FORTRAN_CEILING has been renamed to FORTRAN_CEILING as it is no longer a purely unary intrinsic function. This patch also introduces intrinsic functions with one, two, or three arguments to the Fortran parser and the UNOP_OR_BINOP_OR_TERNOP_INTRINSIC token has been added.
2022-01-01Automatic Copyright Year update after running gdb/copyright.pyJoel Brobecker1-1/+1
This commit brings all the changes made by running gdb/copyright.py as per GDB's Start of New Year Procedure. For the avoidance of doubt, all changes in this commits were performed by the script.
2021-04-07gdb/fortran: handle dynamic types within arrays and structuresAndrew Burgess1-0/+16
This commit replaces this patch: https://sourceware.org/pipermail/gdb-patches/2021-January/174933.html which was itself a replacement for this patch: https://sourceware.org/pipermail/gdb-patches/2020-July/170335.html The motivation behind the original patch can be seen in the new test, which currently gives a GDB session like this: (gdb) ptype var8 type = Type type6 PTR TO -> ( Type type2 :: ptr_1 ) PTR TO -> ( Type type2 :: ptr_2 ) End Type type6 (gdb) ptype var8%ptr_2 type = PTR TO -> ( Type type2 integer(kind=4) :: spacer Type type1, allocatable :: t2_array(:) <------ Issue #1 End Type type2 ) (gdb) ptype var8%ptr_2%t2_array Cannot access memory at address 0x38 <------ Issue #2 (gdb) Issue #1: Here we see the abstract dynamic type, rather than the resolved concrete type. Though in some cases the user might be interested in the abstract dynamic type, I think that in most cases showing the resolved concrete type will be of more use. Plus, the user can always figure out the dynamic type (by source code inspection if nothing else) given the concrete type, but it is much harder to figure out the concrete type given only the dynamic type. Issue #2: In this example, GDB evaluates the expression in EVAL_AVOID_SIDE_EFFECTS mode (due to ptype). The value returned for var8%ptr_2 will be a non-lazy, zero value of the correct dynamic type. However, when GDB asks about the type of t2_array this requires GDB to access the value of var8%ptr_2 in order to read the dynamic properties. As this value was forced to zero (thanks to the use of EVAL_AVOID_SIDE_EFFECTS) then GDB ends up accessing memory at a base of zero plus some offset. Both this patch, and my previous two attempts, have all tried to resolve this problem by stopping EVAL_AVOID_SIDE_EFFECTS replacing the result value with a zero value in some cases. This new patch is influenced by how Ada handles its tagged typed. There are plenty of examples in ada-lang.c, but one specific case is ada_structop_operation::evaluate. When GDB spots that we are dealing with a tagged (dynamic) type, and we're in EVAL_AVOID_SIDE_EFFECTS mode, then GDB re-evaluates the child operation in EVAL_NORMAL mode. This commit handles two cases like this specifically for Fortran, a new fortran_structop_operation, and the already existing fortran_undetermined, which is where we handle array accesses. In these two locations we spot when we are dealing with a dynamic type and re-evaluate the child operation in EVAL_NORMAL mode so that we are able to access the dynamic properties of the type. The rest of this commit message is my attempt to record why my previous patches failed. To understand my second patch, and why it failed lets consider two expressions, this Fortran expression: (gdb) ptype var8%ptr_2%t2_array --<A> Operation: STRUCTOP_STRUCT --(1) Operation: STRUCTOP_STRUCT --(2) Operation: OP_VAR_VALUE --(3) Symbol: var8 Block: 0x3980ac0 String: ptr_2 String: t2_array And this C expression: (gdb) ptype ptr && ptr->a == 3 --<B> Operation: BINOP_LOGICAL_AND --(4) Operation: OP_VAR_VALUE --(5) Symbol: ptr Block: 0x45a2a00 Operation: BINOP_EQUAL --(6) Operation: STRUCTOP_PTR --(7) Operation: OP_VAR_VALUE --(8) Symbol: ptr Block: 0x45a2a00 String: a Operation: OP_LONG --(9) Type: int Constant: 0x0000000000000003 In expression <A> we should assume that t2_array is of dynamic type. Nothing has dynamic type in expression <B>. This is how GDB currently handles expression <A>, in all cases, EVAL_AVOID_SIDE_EFFECTS or EVAL_NORMAL, an OP_VAR_VALUE operation always returns the real value of the symbol, this is not forced to a zero value even in EVAL_AVOID_SIDE_EFFECTS mode. This means that (3), (5), and (8) will always return a real lazy value for the symbol. However a STRUCTOP_STRUCT will always replace its result with a non-lazy, zero value with the same type as its result. So (2) will lookup the field ptr_2 and create a zero value with that type. In this case the type is a pointer to a dynamic type. Then, when we evaluate (1) to figure out the resolved type of t2_array, we need to read the types dynamic properties. These properties are stored in memory relative to the objects base address, and the base address is in var8%ptr_2, which we already figured out has the value zero. GDB then evaluates the DWARF expressions that take the base address, add an offset and dereference. GDB then ends up trying to access addresses like 0x16, 0x8, etc. To fix this, I proposed changing STRUCTOP_STRUCT so that instead of returning a zero value we instead returned the actual value representing the structure's field in the target. My thinking was that GDB would not try to access the value's contents unless it needed it to resolve a dynamic type. This belief was incorrect. Consider expression <B>. We already know that (5) and (8) will return real values for the symbols being referenced. The BINOP_LOGICAL_AND, operation (4) will evaluate both of its children in EVAL_AVOID_SIDE_EFFECTS in order to get the types, this is required for C++ operator lookup. This means that even if the value of (5) would result in the BINOP_LOGICAL_AND returning false (say, ptr is NULL), we still evaluate (6) in EVAL_AVOID_SIDE_EFFECTS mode. Operation (6) will evaluate both children in EVAL_AVOID_SIDE_EFFECTS mode, operation (9) is easy, it just returns a value with the constant packed into it, but (7) is where the problem lies. Currently in GDB this STRUCTOP_STRUCT will always return a non-lazy zero value of the correct type. When the results of (7) and (9) are back in the BINOP_LOGICAL_AND operation (6), the two values are passed to value_equal which performs the comparison and returns a result. Note, the two things compared here are the immediate value (9), and a non-lazy zero value from (7). However, with my proposed patch operation (7) no longer returns a zero value, instead it returns a lazy value representing the actual value in target memory. When we call value_equal in (6) this code causes GDB to try and fetch the actual value from target memory. If `ptr` is NULL then this will cause GDB to access some invalid address at an offset from zero, this will most likely fail, and cause GDB to throw an error instead of returning the expected type. And so, we can now describe the problem that we're facing. The way GDB's expression evaluator is currently written we assume, when in EVAL_AVOID_SIDE_EFFECTS mode, that any value returned from a child operation can safely have its content read without throwing an error. If child operations start returning real values (instead of the fake zero values), then this is simply not true. If we wanted to work around this then we would need to rewrite almost all operations (I would guess) so that EVAL_AVOID_SIDE_EFFECTS mode does not cause evaluation of an operation to try and read the value of a child operation. As an example, consider this current GDB code from eval.c: struct value * eval_op_equal (struct type *expect_type, struct expression *exp, enum noside noside, enum exp_opcode op, struct value *arg1, struct value *arg2) { if (binop_user_defined_p (op, arg1, arg2)) { return value_x_binop (arg1, arg2, op, OP_NULL, noside); } else { binop_promote (exp->language_defn, exp->gdbarch, &arg1, &arg2); int tem = value_equal (arg1, arg2); struct type *type = language_bool_type (exp->language_defn, exp->gdbarch); return value_from_longest (type, (LONGEST) tem); } } We could change this function to be this: struct value * eval_op_equal (struct type *expect_type, struct expression *exp, enum noside noside, enum exp_opcode op, struct value *arg1, struct value *arg2) { if (binop_user_defined_p (op, arg1, arg2)) { return value_x_binop (arg1, arg2, op, OP_NULL, noside); } else { struct type *type = language_bool_type (exp->language_defn, exp->gdbarch); if (noside == EVAL_AVOID_SIDE_EFFECTS) return value_zero (type, VALUE_LVAL (arg1)); else { binop_promote (exp->language_defn, exp->gdbarch, &arg1, &arg2); int tem = value_equal (arg1, arg2); return value_from_longest (type, (LONGEST) tem); } } } Now we don't call value_equal unless we really need to. However, we would need to make the same, or similar change to almost all operations, which would be a big task, and might not be a direction we wanted to take GDB in. So, for now, I'm proposing we go with the more targeted, Fortran specific solution, that does the minimal required in order to correctly resolve the dynamic types. gdb/ChangeLog: * f-exp.h (class fortran_structop_operation): New class. * f-exp.y (exp): Create fortran_structop_operation instead of the generic structop_operation. * f-lang.c (fortran_undetermined::evaluate): Re-evaluate expression as EVAL_NORMAL if the result type was dynamic so we can extract the actual array bounds. (fortran_structop_operation::evaluate): New function. gdb/testsuite/ChangeLog: * gdb.fortran/dynamic-ptype-whatis.exp: New file. * gdb.fortran/dynamic-ptype-whatis.f90: New file.
2021-03-09gdb/fortran: Add 'LOC' intrinsic support.Felix Willgerodt1-0/+7
LOC(X) returns the address of X as an integer: https://gcc.gnu.org/onlinedocs/gfortran/LOC.html Before: (gdb) p LOC(r) No symbol "LOC" in current context. After: (gdb) p LOC(r) $1 = 0xffffdf48 gdb/ChangeLog: 2021-03-09 Felix Willgerodt <felix.willgerodt@intel.com> * f-exp.h (eval_op_f_loc): Declare. (expr::fortran_loc_operation): New typedef. * f-exp.y (exp): Handle UNOP_FORTRAN_LOC after parsing an UNOP_INTRINSIC. (f77_keywords): Add LOC keyword. * f-lang.c (eval_op_f_loc): New function. * std-operator.def (UNOP_FORTRAN_LOC): New operator. gdb/testsuite/ChangeLog: 2020-03-09 Felix Willgerodt <felix.willgerodt@intel.com> * gdb.fortran/intrinsics.exp: Add LOC tests.
2021-03-09gdb/fotran: add support for the 'shape' keywordAndrew Burgess1-0/+12
Add support for the SHAPE keyword to GDB's Fortran expression parser. gdb/ChangeLog: * f-exp.h (eval_op_f_array_shape): Declare. (fortran_array_shape_operation): New type. * f-exp.y (exp): Handle UNOP_FORTRAN_SHAPE after parsing UNOP_INTRINSIC. (f77_keywords): Add "shape" keyword. * f-lang.c (fortran_array_shape): New function. (eval_op_f_array_shape): New function. * std-operator.def (UNOP_FORTRAN_SHAPE): New operator. gdb/testsuite/ChangeLog: * gdb.fortran/shape.exp: New file. * gdb.fortran/shape.f90: New file.
2021-03-09gdb/fortran: add support for 'SIZE' keywordAndrew Burgess1-0/+28
Add support for the 'SIZE' keyword to the Fortran expression parser. This returns the number of elements either in an entire array (passing a single argument to SIZE), or in a particular dimension of an array (passing two arguments to SIZE). At this point I have not added support for the optional third argument to SIZE, which controls the exact integer type of the result. gdb/ChangeLog: * f-exp.y (eval_op_f_array_size): Declare 1 and 2 argument forms of this function. (expr::fortran_array_size_1arg): New type. (expr::fortran_array_size_2arg): Likewise. * f-exp.y (exp): Handle FORTRAN_ARRAY_SIZE after parsing UNOP_OR_BINOP_INTRINSIC. (f77_keywords): Add "size" keyword. * f-lang.c (fortran_array_size): New function. (eval_op_f_array_size): New function, has a 1 arg and 2 arg form. * std-operator.def (FORTRAN_ARRAY_SIZE): New operator. gdb/testsuite/ChangeLog: * gdb.fortran/size.exp: New file. * gdb.fortran/size.f90: New file.
2021-03-09gdb/fortran: add support for RANK keywordAndrew Burgess1-0/+13
gfortran supports the RANK keyword, see: https://gcc.gnu.org/onlinedocs/gfortran/RANK.html#RANK this commit adds support for this keyword to GDB's Fortran expression parser. gdb/ChangeLog: * f-exp.h (eval_op_f_rank): Declare. (expr::fortran_rank_operation): New typedef. * f-exp.y (exp): Handle UNOP_FORTRAN_RANK after parsing an UNOP_INTRINSIC. (f77_keywords): Add "rank" keyword. * f-lang.c (eval_op_f_rank): New function. * std-operator.def (UNOP_FORTRAN_RANK): New operator. gdb/testsuite/ChangeLog: * gdb.fortran/rank.exp: New file. * gdb.fortran/rank.f90: New file.
2021-03-08Implement fortran_allocated_operationTom Tromey1-1/+8
This implements the Fortran ALLOCATED intrinsic. gdb/ChangeLog 2021-03-08 Tom Tromey <tom@tromey.com> * f-exp.h (eval_op_f_allocated): Declare. (fortran_allocated_operation): New typedef. * f-lang.c (eval_op_f_allocated): No longer static.
2021-03-08Implement Fortran associated operationsTom Tromey1-0/+15
This implements the Fortran 1- and 2-argument "associated" operations. gdb/ChangeLog 2021-03-08 Tom Tromey <tom@tromey.com> * f-lang.c (eval_op_f_associated): New functions. * f-exp.h (fortran_associated_1arg, fortran_associated_2arg): New typedefs.
2021-03-08Introduce classes for Fortran bound intrinsicsTom Tromey1-0/+32
This adds class fortran_bound_1arg and fortran_bound_2arg, to implement the Fortran lbound and ubound intrinsics. gdb/ChangeLog 2021-03-08 Tom Tromey <tom@tromey.com> * f-lang.c (fortran_bound_1arg::evaluate) (fortran_bound_2arg::evaluate): New methods. * f-exp.h (class fortran_bound_1arg, class fortran_bound_2arg): New.
2021-03-08Introduce fortran_undeterminedTom Tromey1-0/+63
This adds class fortran_undetermined, which implements OP_F77_UNDETERMINED_ARGLIST. fortran_range_operation is also added here, as it is needed by fortran_undetermined. gdb/ChangeLog 2021-03-08 Tom Tromey <tom@tromey.com> * expop.h (class unop_addr_operation) <get_expression>: New method. * f-lang.c (fortran_undetermined::value_subarray) (fortran_undetermined::evaluate): New methods. (fortran_prepare_argument): New overload. * f-exp.h (class fortran_range_operation) (class fortran_undetermined): New classes.
2021-03-08Implement several Fortran operationsTom Tromey1-0/+101
This implements several straightforward Fortran operations, primarily by reusing existing template classes. gdb/ChangeLog 2021-03-08 Tom Tromey <tom@tromey.com> * f-lang.c (eval_op_f_abs, eval_op_f_mod, eval_op_f_ceil) (eval_op_f_floor, eval_op_f_modulo, eval_op_f_cmplx) (eval_op_f_kind): No longer static. Add "opcode" parameter. (evaluate_subexp_f): Update. * f-exp.h: New file.