-from spec_util import abstract, setnodedefaults
+# Firm node specifications
+# The comments are in (standard python) restructured text format and are used
+# to generate documentation.
+from spec_util import abstract, op
-class Op(object):
- """Base class for firm nodes"""
-abstract(Op)
+name = "ir"
-class Unop(Op):
+@abstract
+@op
+class Unop(object):
"""Unary nodes have exactly 1 input"""
name = "unop"
ins = [
]
op_index = 0
pinned = "no"
-abstract(Unop)
-class Binop(Op):
+@abstract
+@op
+class Binop(object):
"""Binary nodes have exactly 2 inputs"""
name = "binop"
ins = [
]
op_index = 0
pinned = "no"
-abstract(Binop)
+@op
class Add(Binop):
"""returns the sum of its operands"""
flags = [ "commutative" ]
-class Alloc(Op):
+@op
+class Alloc:
"""allocates a block of memory.
- It can be specified whether the variable should be allocated to the stack
- or to the heap."""
+ It can be specified whether the memory should be allocated to the stack
+ or to the heap.
+ Allocates memory for one or more objects (depending on value on count input).
+ """
ins = [
("mem", "memory dependency" ),
("count", "number of objects to allocate" ),
dict(
name = "type",
type = "ir_type*",
- comment = "type of the allocated variable",
+ comment = "type of the objects to allocate",
),
dict(
name = "where",
pinned_init = "op_pin_state_pinned"
attr_struct = "alloc_attr"
-class Anchor(Op):
+@op
+class Anchor:
"""utiliy node used to "hold" nodes in a graph that might possibly not be
reachable by other means or which should be reachable immediately without
searching through the graph.
noconstructor = True
customSerializer = True
+@op
class And(Binop):
"""returns the result of a bitwise and operation of its operands"""
flags = [ "commutative" ]
-class ASM(Op):
- """executes assembler fragments of the target machine"""
+@op
+class ASM:
+ """executes assembler fragments of the target machine.
+
+ The node contains a template for an assembler snippet. The compiler will
+ replace occurences of %0 to %9 with input/output registers,
+ %% with a single % char. Some backends allow additional specifiers (for
+ example %w3, %l3, %h3 on x86 to get a 16bit, 8hit low, 8bit high part
+ of a register).
+ After the replacements the text is emitted into the final assembly.
+
+ The clobber list contains names of registers which have an undefined value
+ after the assembler instruction is executed; it may also contain 'memory'
+ or 'cc' if global state/memory changes or the condition code registers
+ (some backends implicitely set cc, memory clobbers on all ASM statements).
+
+ Example (an i386 instruction)::
+
+ ASM(text="btsl %1, %0",
+ input_constraints = ["=m", "r"],
+ clobbers = ["cc"])
+
+ As there are no output, the %0 references the first input which is just an
+ address which the asm operation writes to. %1 references to an input which
+ is passed as a register. The condition code register has an unknown value
+ after the instruction.
+
+ (This format is inspired by the gcc extended asm syntax)
+ """
mode = "mode_T"
arity = "variable"
flags = [ "keep", "uses_memory" ]
attr_struct = "asm_attr"
attrs_name = "assem"
customSerializer = True
+ ins = [
+ ("mem", "memory dependency"),
+ ]
attrs = [
dict(
name = "input_constraints",
),
dict(
name = "n_output_constraints",
- type = "int",
+ type = "size_t",
noprop = True,
comment = "number of output constraints",
),
),
dict(
name = "n_clobbers",
- type = "int",
+ type = "size_t",
noprop = True,
comment = "number of clobbered registers/memory",
),
# constraints arrays needing special handling (2 arguments for 1 attribute)
noconstructor = True
-class Bad(Op):
+@op
+class Bad:
"""Bad nodes indicate invalid input, which is values which should never be
computed.
that a control flow edge can never be executed.
The gigo optimisations ensures that nodes with Bad as their block, get
- replaced by Bad themselfes. Nodes with at least 1 Bad input get exchanged
+ replaced by Bad themselves. Nodes with at least 1 Bad input get exchanged
with Bad too. Exception to this rule are Block, Phi, Tuple and End node;
This is because removing inputs from a Block is hairy operation (requiring,
Phis to be shortened too for example). So instead of removing block inputs
res->attr.bad.irg.irg = irg;
'''
-class Deleted(Op):
+@op
+class Deleted:
"""Internal node which is temporary set to nodes which are already removed
from the graph."""
mode = "mode_Bad"
flags = [ ]
pinned = "yes"
noconstructor = True
- customSerializer = True
+ customSerializer = True # this has no serializer
-class Block(Op):
+@op
+class Block:
"""A basic block"""
mode = "mode_BB"
knownBlock = True
block = "NULL"
pinned = "yes"
arity = "variable"
- flags = [ "labeled" ]
+ flags = []
attr_struct = "block_attr"
+ attrs = [
+ dict(
+ name = "entity",
+ type = "ir_entity*",
+ comment = "entity representing this block",
+ init = "NULL",
+ ),
+ ]
customSerializer = True
init = '''
res->attr.block.irg.irg = irg;
- res->attr.block.backedge = new_backedge_arr(irg->obst, arity);
+ res->attr.block.backedge = new_backedge_arr(get_irg_obstack(irg), arity);
set_Block_matured(res, 1);
/* Create and initialize array for Phi-node construction. */
- if (get_irg_phase_state(irg) == phase_building) {
- res->attr.block.graph_arr = NEW_ARR_D(ir_node *, irg->obst, irg->n_loc);
- memset(res->attr.block.graph_arr, 0, irg->n_loc * sizeof(ir_node*));
+ if (irg_is_constrained(irg, IR_GRAPH_CONSTRAINT_CONSTRUCTION)) {
+ res->attr.block.graph_arr = NEW_ARR_DZ(ir_node*, get_irg_obstack(irg), irg->n_loc);
}
'''
+@op
class Borrow(Binop):
"""Returns the borrow bit from and implied subtractions of its 2 operands"""
flags = []
-class Bound(Op):
+@op
+class Bound:
"""Performs a bounds-check: if lower <= index < upper then return index,
otherwise throw an exception."""
ins = [
throws_init = "false"
attr_struct = "bound_attr"
-class Builtin(Op):
+@op
+class Builtin:
"""performs a backend-specific builtin."""
ins = [
("mem", "memory dependency"),
assert((get_unknown_type() == type) || is_Method_type(type));
'''
-class Call(Op):
+@op
+class Call:
"""Calls other code. Control flow is transfered to ptr, additional
operands are passed to the called code. Called code usually performs a
return operation. The operands of this return operation are the result
name = "type",
comment = "type of the call (usually type of the called procedure)",
),
- dict(
- type = "unsigned",
- name = "tail_call",
- # the tail call attribute can only be set by analysis
- init = "0",
- )
]
attr_struct = "call_attr"
pinned = "memory"
assert((get_unknown_type() == type) || is_Method_type(type));
'''
+@op
class Carry(Binop):
"""Computes the value of the carry-bit that would result when adding the 2
operands"""
flags = [ "commutative" ]
+@op
class Cast(Unop):
"""perform a high-level type cast"""
mode = "get_irn_mode(irn_op)"
attr_struct = "cast_attr"
init = "assert(is_atomic_type(type));"
+@op
class Cmp(Binop):
"""Compares its two operands and checks whether a specified
relation (like less or equal) is fulfilled."""
]
attr_struct = "cmp_attr"
-class Cond(Op):
- """Conditionally change control flow.
- Input: A value of mode_b
- Output: A tuple of two control flows. The first is taken if the input is
- false, the second if it is true.
- """
+@op
+class Cond:
+ """Conditionally change control flow."""
ins = [
("selector", "condition parameter"),
]
]
attr_struct = "cond_attr"
-class Switch(Op):
+@op
+class Switch:
"""Change control flow. The destination is choosen based on an integer input value which is looked up in a table.
Backends can implement this efficiently using a jump table."""
attr_struct = "switch_attr"
attrs_name = "switcha"
-class Confirm(Op):
+@op
+class Confirm:
"""Specifies constraints for a value. This allows explicit representation
of path-sensitive properties. (Example: This value is always >= 0 on 1
if-branch then all users within that branch are rerouted to a confirm-node
]
attr_struct = "confirm_attr"
-class Const(Op):
+@op
+class Const:
"""Returns a constant value."""
flags = [ "constlike", "start_block" ]
block = "get_irg_start_block(irg)"
attr_struct = "const_attr"
attrs_name = "con"
+@op
class Conv(Unop):
"""Converts values between modes"""
flags = []
- attrs = [
- dict(
- name = "strict",
- type = "int",
- init = "0",
- comment = "force floating point to restrict precision even if backend computes in higher precision (deprecated)",
- )
- ]
- attr_struct = "conv_attr"
-class CopyB(Op):
- """Copies a block of memory"""
+@op
+class CopyB:
+ """Copies a block of memory with statically known size/type."""
ins = [
("mem", "memory dependency"),
("dst", "destination address"),
pinned_init = "op_pin_state_pinned"
throws_init = "false"
-class Div(Op):
+@op
+class Div:
"""returns the quotient of its 2 operands"""
ins = [
("mem", "memory dependency"),
op_index = 1
arity_override = "oparity_binary"
-class Dummy(Op):
+@op
+class Dummy:
"""A placeholder value. This is used when constructing cyclic graphs where
you have cases where not all predecessors of a phi-node are known. Dummy
nodes are used for the unknown predecessors and replaced later."""
pinned = "yes"
block = "get_irg_start_block(irg)"
-class End(Op):
+@op
+class End:
"""Last node of a graph. It references nodes in endless loops (so called
keepalive edges)"""
mode = "mode_X"
knownBlock = True
block = "get_irg_end_block(irg)"
singleton = True
- customSerializer = True
+@op
class Eor(Binop):
- """returns the result of a bitwise exclusive or operation of its operands"""
+ """returns the result of a bitwise exclusive or operation of its operands.
+
+ This is also known as the Xor operation."""
flags = [ "commutative" ]
-class Free(Op):
+@op
+class Free:
"""Frees a block of memory previously allocated by an Alloc node"""
ins = [
("mem", "memory dependency" ),
]
attr_struct = "free_attr"
-class Id(Op):
- """Returns its operand unchanged."""
+@op
+class Id:
+ """Returns its operand unchanged.
+
+ This is mainly used when exchanging nodes. Usually you shouldn't see Id
+ nodes since the getters/setters for node inputs skip them automatically."""
ins = [
("pred", "the value which is returned unchanged")
]
pinned = "no"
flags = []
-class IJmp(Op):
+@op
+class IJmp:
"""Jumps to the code in its argument. The code has to be in the same
function and the the destination must be one of the blocks reachable
by the tuple results"""
]
flags = [ "cfopcode", "forking", "keep", "unknown_jump" ]
-class InstOf(Op):
+@op
+class InstOf:
"""Tests whether an object is an instance of a class-type"""
ins = [
("store", "memory dependency"),
pinned = "memory"
pinned_init = "op_pin_state_floats"
-class Jmp(Op):
+@op
+class Jmp:
"""Jumps to the block connected through the out-value"""
mode = "mode_X"
pinned = "yes"
ins = []
flags = [ "cfopcode" ]
-class Load(Op):
+@op
+class Load:
"""Loads a value from memory (heap or stack)."""
ins = [
("mem", "memory dependency"),
name = "volatility",
comment = "volatile loads are a visible side-effect and may not be optimized",
init = "flags & cons_volatile ? volatility_is_volatile : volatility_non_volatile",
+ to_flags = "%s == volatility_is_volatile ? cons_volatile : cons_none"
),
dict(
type = "ir_align",
name = "unaligned",
comment = "pointers to unaligned loads don't need to respect the load-mode/type alignments",
init = "flags & cons_unaligned ? align_non_aligned : align_is_aligned",
+ to_flags = "%s == align_non_aligned ? cons_unaligned : cons_none"
),
]
attr_struct = "load_attr"
pinned_init = "flags & cons_floats ? op_pin_state_floats : op_pin_state_pinned"
throws_init = "(flags & cons_throws_exception) != 0"
+@op
class Minus(Unop):
- """returns the difference between its operands"""
+ """returns the additive inverse of its operand"""
flags = []
-class Mod(Op):
+@op
+class Mod:
"""returns the remainder of its operands from an implied division.
Examples:
+
* mod(5,3) produces 2
* mod(5,-3) produces 2
* mod(-5,3) produces -2
would not fit into the result mode of a normal Mul anymore)"""
flags = [ "commutative" ]
-class Mux(Op):
+@op
+class Mux:
"""returns the false or true operand depending on the value of the sel
operand"""
ins = [
flags = []
pinned = "no"
-class NoMem(Op):
+@op
+class NoMem:
"""Placeholder node for cases where you don't need any memory input"""
mode = "mode_M"
- flags = [ "dump_noblock", "dump_noinput" ]
+ flags = [ "dump_noblock" ]
pinned = "yes"
knownBlock = True
block = "get_irg_start_block(irg)"
singleton = True
+@op
class Not(Unop):
- """returns the logical complement of a value. Works for integer values too.
- If the input is false/zero then true/one is returned, otherwise false/zero
- is returned."""
+ """returns the bitwise complement of a value. Works for boolean values, too."""
flags = []
+@op
class Or(Binop):
"""returns the result of a bitwise or operation of its operands"""
flags = [ "commutative" ]
-class Phi(Op):
+@op
+class Phi:
"""Choose a value based on control flow. A phi node has 1 input for each
predecessor of its block. If a block is entered from its nth predecessor
all phi nodes produce their nth input as result."""
flags = []
attr_struct = "phi_attr"
init = '''
- res->attr.phi.u.backedge = new_backedge_arr(irg->obst, arity);'''
- init_after_opt = '''
- /* Memory Phis in endless loops must be kept alive.
- As we can't distinguish these easily we keep all of them alive. */
- if (is_Phi(res) && mode == mode_M)
- add_End_keepalive(get_irg_end(irg), res);'''
-
-class Pin(Op):
+ res->attr.phi.u.backedge = new_backedge_arr(get_irg_obstack(irg), arity);'''
+ customSerializer = True
+
+@op
+class Pin:
"""Pin the value of the node node in the current block. No users of the Pin
node can float above the Block of the Pin. The node cannot float behind
this block. Often used to Pin the NoMem node."""
flags = [ "highlevel" ]
pinned = "yes"
-class Proj(Op):
+@op
+class Proj:
"""returns an entry of a tuple value"""
ins = [
("pred", "the tuple value from which a part is extracted"),
knownGraph = True
block = "get_nodes_block(irn_pred)"
graph = "get_irn_irg(irn_pred)"
- customSerializer = True
attrs = [
dict(
type = "long",
]
attr_struct = "proj_attr"
-class Raise(Op):
+@op
+class Raise:
"""Raises an exception. Unconditional change of control flow. Writes an
explicit Except variable to memory to pass it to the exception handler.
Must be lowered to a Call to a runtime check function."""
flags = [ "highlevel", "cfopcode" ]
pinned = "yes"
-class Return(Op):
+@op
+class Return:
"""Returns from the current function. Takes memory and return values as
operands."""
ins = [
operand"""
flags = []
-class Sel(Op):
+@op
+class Sel:
"""Computes the address of a entity of a compound type given the base
- address of an instance of the compound type."""
+ address of an instance of the compound type.
+
+ Optimisations assume that a Sel node can only produce a NULL pointer if the
+ ptr input was NULL."""
ins = [
("mem", "memory dependency"),
("ptr", "pointer to object to select from"),
]
attr_struct = "sel_attr"
+@op
class Shl(Binop):
"""Returns its first operands bits shifted left by the amount of the 2nd
- operand"""
+ operand.
+ The right input (shift amount) must be an unsigned integer value.
+ If the result mode has modulo_shift!=0, then the effective shift amount is
+ the right input modulo this modulo_shift amount."""
flags = []
+@op
class Shr(Binop):
"""Returns its first operands bits shifted right by the amount of the 2nd
- operand. No special handling for the sign bit (zero extension)"""
+ operand. No special handling for the sign bit is performed (zero extension).
+ The right input (shift amount) must be an unsigned integer value.
+ If the result mode has modulo_shift!=0, then the effective shift amount is
+ the right input modulo this modulo_shift amount."""
flags = []
+@op
class Shrs(Binop):
"""Returns its first operands bits shifted right by the amount of the 2nd
operand. The leftmost bit (usually the sign bit) stays the same
- (sign extension)"""
+ (sign extension).
+ The right input (shift amount) must be an unsigned integer value.
+ If the result mode has modulo_shift!=0, then the effective shift amount is
+ the right input modulo this modulo_shift amount."""
flags = []
-class Start(Op):
+@op
+class Start:
"""The first node of a graph. Execution starts with this node."""
outs = [
("X_initial_exec", "control flow"),
flags = [ "cfopcode" ]
singleton = True
knownBlock = True
- customSerializer = True
block = "get_irg_start_block(irg)"
-class Store(Op):
+@op
+class Store:
"""Stores a value into memory (heap or stack)."""
ins = [
("mem", "memory dependency"),
name = "volatility",
comment = "volatile stores are a visible side-effect and may not be optimized",
init = "flags & cons_volatile ? volatility_is_volatile : volatility_non_volatile",
+ to_flags = "%s == volatility_is_volatile ? cons_volatile : cons_none"
),
dict(
type = "ir_align",
name = "unaligned",
comment = "pointers to unaligned stores don't need to respect the load-mode/type alignments",
init = "flags & cons_unaligned ? align_non_aligned : align_is_aligned",
+ to_flags = "%s == align_non_aligned ? cons_unaligned : cons_none"
),
]
constructor_args = [
),
]
+@op
class Sub(Binop):
"""returns the difference of its operands"""
flags = []
-class SymConst(Op):
+@op
+class SymConst:
"""A symbolic constant.
- - symconst_type_tag The symbolic constant represents a type tag. The
- type the tag stands for is given explicitly.
- - symconst_type_size The symbolic constant represents the size of a type.
- The type of which the constant represents the size
- is given explicitly.
- - symconst_type_align The symbolic constant represents the alignment of a
- type. The type of which the constant represents the
- size is given explicitly.
- - symconst_addr_ent The symbolic constant represents the address of an
- entity (variable or method). The variable is given
- explicitly by a firm entity.
- - symconst_ofs_ent The symbolic constant represents the offset of an
- entity in its owner type.
- - symconst_enum_const The symbolic constant is a enumeration constant of
- an enumeration type."""
+ - *symconst_type_size* The symbolic constant represents the size of a type.
+ The type of which the constant represents the size
+ is given explicitly.
+ - *symconst_type_align* The symbolic constant represents the alignment of a
+ type. The type of which the constant represents the
+ size is given explicitly.
+ - *symconst_addr_ent* The symbolic constant represents the address of an
+ entity (variable or method). The variable is given
+ explicitly by a firm entity.
+ - *symconst_ofs_ent* The symbolic constant represents the offset of an
+ entity in its owner type.
+ - *symconst_enum_const* The symbolic constant is a enumeration constant of
+ an enumeration type."""
mode = "mode_P"
flags = [ "constlike", "start_block" ]
knownBlock = True
# union argument
noconstructor = True
-class Sync(Op):
+@op
+class Sync:
"""The Sync operation unifies several partial memory blocks. These blocks
have to be pairwise disjunct or the values in common locations have to
be identical. This operation allows to specify all operations that
pinned = "no"
arity = "dynamic"
-class Tuple(Op):
+@op
+class Tuple:
"""Builds a Tuple from single values.
This is needed to implement optimizations that remove a node that produced
arity = "variable"
mode = "mode_T"
pinned = "no"
- flags = [ "labeled" ]
+ flags = []
-class Unknown(Op):
+@op
+class Unknown:
"""Returns an unknown (at compile- and runtime) value. It is a valid
optimisation to replace an Unknown by any other constant value."""
knownBlock = True
pinned = "yes"
block = "get_irg_start_block(irg)"
flags = [ "start_block", "constlike", "dump_noblock" ]
-
-# Prepare node list
-
-def getOpList(namespace):
- nodes = []
- for t in namespace.values():
- if type(t) != type:
- continue
-
- if issubclass(t, Op):
- setnodedefaults(t)
- nodes.append(t)
- return nodes
-
-nodes = getOpList(globals())
-nodes = sorted(nodes, lambda x,y: cmp(x.name, y.name))