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compiler.{iodelay,transforms.iodelay_estimator}: implement.

This commit is contained in:
whitequark 2015-09-02 17:46:09 -06:00
parent 3af54f5ffc
commit b971cc8cdf
28 changed files with 839 additions and 8 deletions

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@ -138,6 +138,12 @@ def fn_print():
def fn_kernel():
return types.TBuiltinFunction("kernel")
def fn_parallel():
return types.TBuiltinFunction("parallel")
def fn_sequential():
return types.TBuiltinFunction("sequential")
def fn_now():
return types.TBuiltinFunction("now")

285
artiq/compiler/iodelay.py Normal file
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@ -0,0 +1,285 @@
"""
The :mod:`iodelay` module contains the classes describing
the statically inferred RTIO delay arising from executing
a function.
"""
from pythonparser import diagnostic
class Expr:
def __add__(lhs, rhs):
assert isinstance(rhs, Expr)
return Add(lhs, rhs)
__iadd__ = __add__
def __sub__(lhs, rhs):
assert isinstance(rhs, Expr)
return Sub(lhs, rhs)
__isub__ = __sub__
def __mul__(lhs, rhs):
assert isinstance(rhs, Expr)
return Mul(lhs, rhs)
__imul__ = __mul__
def __truediv__(lhs, rhs):
assert isinstance(rhs, Expr)
return TrueDiv(lhs, rhs)
__itruediv__ = __truediv__
def __floordiv__(lhs, rhs):
assert isinstance(rhs, Expr)
return FloorDiv(lhs, rhs)
__ifloordiv__ = __floordiv__
def __ne__(lhs, rhs):
return not (lhs == rhs)
def free_vars(self):
return set()
def fold(self, vars=None):
return self
class Const(Expr):
_priority = 1
def __init__(self, value):
assert isinstance(value, (int, float))
self.value = value
def __str__(self):
return str(self.value)
def __eq__(lhs, rhs):
return rhs.__class__ == lhs.__class__ and lhs.value == rhs.value
def eval(self, env):
return self.value
class Var(Expr):
_priority = 1
def __init__(self, name):
assert isinstance(name, str)
self.name = name
def __str__(self):
return self.name
def __eq__(lhs, rhs):
return rhs.__class__ == lhs.__class__ and lhs.value == rhs.value
def free_vars(self):
return {self.name}
def fold(self, vars=None):
if vars is not None and self.name in vars:
return vars[self.name]
else:
return self
class Conv(Expr):
_priority = 1
def __init__(self, operand, ref_period):
assert isinstance(operand, Expr)
assert isinstance(ref_period, float)
self.operand, self.ref_period = operand, ref_period
def free_vars(self):
return self.operand.free_vars()
def fold(self, vars=None):
return self.__class__(self.operand.fold(vars),
ref_period=self.ref_period)
class MUToS(Conv):
def __str__(self):
return "mu->s({})".format(self.operand)
def eval(self, env):
return self.operand.eval(env) * self.ref_period
class SToMU(Conv):
def __str__(self):
return "s->mu({})".format(self.operand)
def eval(self, env):
return self.operand.eval(env) / self.ref_period
class BinOp(Expr):
def __init__(self, lhs, rhs):
self.lhs, self.rhs = lhs, rhs
def __str__(self):
lhs = "({})".format(self.lhs) if self.lhs._priority > self._priority else str(self.lhs)
rhs = "({})".format(self.rhs) if self.rhs._priority > self._priority else str(self.rhs)
return "{} {} {}".format(lhs, self._symbol, rhs)
def __eq__(lhs, rhs):
return rhs.__class__ == lhs.__class__ and lhs.lhs == rhs.lhs and rhs.lhs == rhs.rhs
def eval(self, env):
return self.__class__._op(self.lhs.eval(env), self.rhs.eval(env))
def free_vars(self):
return self.lhs.free_vars() | self.rhs.free_vars()
def _fold_binop(self, lhs, rhs):
if isinstance(lhs, Const) and lhs.__class__ == rhs.__class__:
return Const(self.__class__._op(lhs.value, rhs.value))
elif isinstance(lhs, (MUToS, SToMU)) and lhs.__class__ == rhs.__class__:
return lhs.__class__(self.__class__(lhs.operand, rhs.operand),
ref_period=lhs.ref_period).fold()
else:
return self.__class__(lhs, rhs)
def fold(self, vars=None):
return self._fold_binop(self.lhs.fold(vars), self.rhs.fold(vars))
class BinOpFixpoint(BinOp):
def _fold_binop(self, lhs, rhs):
if isinstance(lhs, Const) and lhs.value == self._fixpoint:
return rhs
elif isinstance(rhs, Const) and rhs.value == self._fixpoint:
return lhs
else:
return super()._fold_binop(lhs, rhs)
class Add(BinOpFixpoint):
_priority = 2
_symbol = "+"
_op = lambda a, b: a + b
_fixpoint = 0
class Sub(BinOpFixpoint):
_priority = 2
_symbol = "-"
_op = lambda a, b: a - b
_fixpoint = 0
class Mul(BinOpFixpoint):
_priority = 1
_symbol = "*"
_op = lambda a, b: a * b
_fixpoint = 1
class Div(BinOp):
def _fold_binop(self, lhs, rhs):
if isinstance(rhs, Const) and rhs.value == 1:
return lhs
else:
return super()._fold_binop(lhs, rhs)
class TrueDiv(Div):
_priority = 1
_symbol = "/"
_op = lambda a, b: a / b if b != 0 else 0
class FloorDiv(Div):
_priority = 1
_symbol = "//"
_op = lambda a, b: a // b if b != 0 else 0
class Max(Expr):
_priority = 1
def __init__(self, operands):
assert isinstance(operands, list)
assert all([isinstance(operand, Expr) for operand in operands])
self.operands = operands
def __str__(self):
return "max({})".format(", ".join([str(operand) for operand in self.operands]))
def __eq__(lhs, rhs):
return rhs.__class__ == lhs.__class__ and lhs.operands == rhs.operands
def free_vars(self):
return reduce(lambda a, b: a | b, [operand.free_vars() for operand in self.operands])
def eval(self, env):
return max([operand.eval() for operand in self.operands])
def fold(self, vars=None):
consts, exprs = [], []
for operand in self.operands:
operand = operand.fold(vars)
if isinstance(operand, Const):
consts.append(operand.value)
else:
exprs.append(operand)
if any(consts):
exprs.append(Const(max(consts)))
if len(exprs) == 1:
return exprs[0]
else:
return Max(exprs)
def is_const(expr, value=None):
expr = expr.fold()
if value is None:
return isinstance(expr, Const)
else:
return isinstance(expr, Const) and expr.value == value
def is_zero(expr):
return is_const(expr, 0)
class Delay:
pass
class Unknown(Delay):
"""
Unknown delay, that is, IO delay that we have not
tried to compute yet.
"""
def __repr__(self):
return "{}.Unknown()".format(__name__)
class Indeterminate(Delay):
"""
Indeterminate delay, that is, IO delay that can vary from
invocation to invocation.
:ivar cause: (:class:`pythonparser.diagnostic.Diagnostic`)
reason for the delay not being inferred
"""
def __init__(self, cause):
assert isinstance(cause, diagnostic.Diagnostic)
self.cause = cause
def __repr__(self):
return "<{}.Indeterminate>".format(__name__)
class Fixed(Delay):
"""
Fixed delay, that is, IO delay that is always the same
for every invocation.
:ivar length: (int) delay in machine units
"""
def __init__(self, length):
assert isinstance(length, Expr)
self.length = length
def __repr__(self):
return "{}.Fixed({})".format(__name__, self.length)
def is_unknown(delay):
return isinstance(delay, Unknown)
def is_indeterminate(delay):
return isinstance(delay, Indeterminate)
def is_fixed(delay, length=None):
if length is None:
return isinstance(delay, Fixed)
else:
return isinstance(delay, Fixed) and delay.length == length

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@ -50,6 +50,7 @@ class Module:
inferencer = transforms.Inferencer(engine=self.engine)
monomorphism_validator = validators.MonomorphismValidator(engine=self.engine)
escape_validator = validators.EscapeValidator(engine=self.engine)
iodelay_estimator = transforms.IODelayEstimator(ref_period=ref_period)
artiq_ir_generator = transforms.ARTIQIRGenerator(engine=self.engine,
module_name=src.name,
ref_period=ref_period)
@ -62,6 +63,7 @@ class Module:
inferencer.visit(src.typedtree)
monomorphism_validator.visit(src.typedtree)
escape_validator.visit(src.typedtree)
iodelay_estimator.visit_fixpoint(src.typedtree)
self.artiq_ir = artiq_ir_generator.visit(src.typedtree)
dead_code_eliminator.process(self.artiq_ir)
local_access_validator.process(self.artiq_ir)

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@ -28,6 +28,10 @@ def globals():
# ARTIQ decorators
"kernel": builtins.fn_kernel(),
# ARTIQ context managers
"parallel": builtins.fn_parallel(),
"sequential": builtins.fn_sequential(),
# ARTIQ time management functions
"now": builtins.fn_now(),
"delay": builtins.fn_delay(),

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@ -1,6 +1,6 @@
import sys, fileinput
from pythonparser import diagnostic
from .. import Module, Source
from .. import types, iodelay, Module, Source
def main():
if len(sys.argv) > 1 and sys.argv[1] == "+diag":
@ -13,15 +13,28 @@ def main():
else:
diag = False
def process_diagnostic(diag):
print("\n".join(diag.render()))
print("\n".join(diag.render(colored=True)))
if diag.level in ("fatal", "error"):
exit(1)
if len(sys.argv) > 1 and sys.argv[1] == "+delay":
del sys.argv[1]
force_delays = True
else:
force_delays = False
engine = diagnostic.Engine()
engine.process = process_diagnostic
try:
mod = Module(Source.from_string("".join(fileinput.input()).expandtabs(), engine=engine))
if force_delays:
for var in mod.globals:
typ = mod.globals[var].find()
if types.is_function(typ) and iodelay.is_indeterminate(typ.delay):
process_diagnostic(typ.delay.cause)
print(repr(mod))
except:
if not diag: raise

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@ -1,6 +1,7 @@
from .asttyped_rewriter import ASTTypedRewriter
from .inferencer import Inferencer
from .int_monomorphizer import IntMonomorphizer
from .iodelay_estimator import IODelayEstimator
from .artiq_ir_generator import ARTIQIRGenerator
from .dead_code_eliminator import DeadCodeEliminator
from .llvm_ir_generator import LLVMIRGenerator

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@ -945,13 +945,19 @@ class Inferencer(algorithm.Visitor):
def visit_withitem(self, node):
self.generic_visit(node)
if True: # none are supported yet
typ = node.context_expr.type
if not types.is_builtin(typ, "parallel") or types.is_builtin(typ, "sequential"):
diag = diagnostic.Diagnostic("error",
"value of type {type} cannot act as a context manager",
{"type": types.TypePrinter().name(node.context_expr.type)},
{"type": types.TypePrinter().name(typ)},
node.context_expr.loc)
self.engine.process(diag)
if node.optional_vars is not None:
self._unify(node.optional_vars.type, node.context_expr.type,
node.optional_vars.loc, node.context_expr.loc)
def visit_ExceptHandlerT(self, node):
self.generic_visit(node)

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@ -0,0 +1,252 @@
"""
:class:`IODelayEstimator` calculates the amount of time
elapsed from the point of view of the RTIO core for
every function.
"""
from pythonparser import ast, algorithm, diagnostic
from .. import types, iodelay, builtins, asttyped
class _UnknownDelay(Exception):
pass
class IODelayEstimator(algorithm.Visitor):
def __init__(self, ref_period):
self.ref_period = ref_period
self.changed = False
self.current_delay = iodelay.Const(0)
self.current_args = None
self.current_goto = None
self.current_return = None
def evaluate(self, node, abort):
if isinstance(node, asttyped.NumT):
return iodelay.Const(node.n)
elif isinstance(node, asttyped.CoerceT):
return self.evaluate(node.value, abort)
elif isinstance(node, asttyped.NameT):
if self.current_args is None:
note = diagnostic.Diagnostic("note",
"this variable is not an argument", {},
node.loc)
abort([note])
elif node.id in [arg.arg for arg in self.current_args.args]:
return iodelay.Var(node.id)
else:
notes = [
diagnostic.Diagnostic("note",
"this variable is not an argument of the innermost function", {},
node.loc),
diagnostic.Diagnostic("note",
"only these arguments are in scope of analysis", {},
self.current_args.loc)
]
abort(notes)
elif isinstance(node, asttyped.BinOpT):
lhs = self.evaluate(node.left, abort)
rhs = self.evaluate(node.right, abort)
if isinstance(node.op, ast.Add):
return lhs + rhs
elif isinstance(node.op, ast.Sub):
return lhs - rhs
elif isinstance(node.op, ast.Mult):
return lhs * rhs
elif isinstance(node.op, ast.Div):
return lhs / rhs
elif isinstance(node.op, ast.FloorDiv):
return lhs // rhs
else:
note = diagnostic.Diagnostic("note",
"this operator is not supported", {},
node.op.loc)
abort([note])
else:
note = diagnostic.Diagnostic("note",
"this expression is not supported", {},
node.loc)
abort([note])
def abort(self, message, loc, notes=[]):
diag = diagnostic.Diagnostic("error", message, {}, loc, notes=notes)
raise diagnostic.Error(diag)
def visit_fixpoint(self, node):
while True:
self.changed = False
self.visit(node)
if not self.changed:
return
def visit_ModuleT(self, node):
try:
self.visit(node.body)
except (diagnostic.Error, _UnknownDelay):
pass # we don't care; module-level code is never interleaved
def visit_function(self, args, body, typ):
old_args, self.current_args = self.current_args, args
old_return, self.current_return = self.current_return, None
old_delay, self.current_delay = self.current_delay, iodelay.Const(0)
try:
self.visit(body)
if not iodelay.is_zero(self.current_delay) and self.current_return is not None:
self.abort("only return statement at the end of the function "
"can be interleaved", self.current_return.loc)
delay = iodelay.Fixed(self.current_delay.fold())
except diagnostic.Error as error:
delay = iodelay.Indeterminate(error.diagnostic)
self.current_delay = old_delay
self.current_return = old_return
self.current_args = old_args
if iodelay.is_unknown(typ.delay) or iodelay.is_indeterminate(typ.delay):
typ.delay = delay
elif iodelay.is_fixed(typ.delay):
assert typ.delay.value == delay.value
else:
assert False
def visit_FunctionDefT(self, node):
self.visit(node.args.defaults)
self.visit(node.args.kw_defaults)
# We can only handle return in tail position.
if isinstance(node.body[-1], ast.Return):
body = node.body[:-1]
else:
body = node.body
self.visit_function(node.args, body, node.signature_type.find())
def visit_LambdaT(self, node):
self.visit_function(node.args, node.body, node.type.find())
def get_iterable_length(self, node):
def abort(notes):
self.abort("for statement cannot be interleaved because "
"trip count is indeterminate",
node.loc, notes)
def evaluate(node):
return self.evaluate(node, abort)
if isinstance(node, asttyped.CallT) and types.is_builtin(node.func.type, "range"):
range_min, range_max, range_step = iodelay.Const(0), None, iodelay.Const(1)
if len(node.args) == 3:
range_min, range_max, range_step = map(evaluate, node.args)
elif len(node.args) == 2:
range_min, range_max = map(evaluate, node.args)
elif len(node.args) == 1:
range_max, = map(evaluate, node.args)
return (range_max - range_min) // range_step
else:
note = diagnostic.Diagnostic("note",
"this value is not a constant range literal", {},
node.loc)
abort([note])
def visit_For(self, node):
self.visit(node.iter)
old_goto, self.current_goto = self.current_goto, None
old_delay, self.current_delay = self.current_delay, iodelay.Const(0)
self.visit(node.body)
if iodelay.is_zero(self.current_delay):
self.current_delay = old_delay
else:
if self.current_goto is not None:
self.abort("loop trip count is indeterminate because of control flow",
self.current_goto.loc)
trip_count = self.get_iterable_length(node.iter)
self.current_delay = old_delay + self.current_delay * trip_count
self.current_goto = old_goto
self.visit(node.orelse)
def visit_goto(self, node):
self.current_goto = node
visit_Break = visit_goto
visit_Continue = visit_goto
def visit_control_flow(self, kind, node):
old_delay, self.current_delay = self.current_delay, iodelay.Const(0)
self.generic_visit(node)
if not iodelay.is_zero(self.current_delay):
self.abort("{} cannot be interleaved".format(kind), node.loc)
self.current_delay = old_delay
visit_While = lambda self, node: self.visit_control_flow("while statement", node)
visit_If = lambda self, node: self.visit_control_flow("if statement", node)
visit_IfExpT = lambda self, node: self.visit_control_flow("if expression", node)
visit_Try = lambda self, node: self.visit_control_flow("try statement", node)
def visit_Return(self, node):
self.current_return = node
def visit_With(self, node):
self.visit(node.items)
context_expr = node.items[0].context_expr
if len(node.items) == 1 and types.is_builtin(context_expr.type, "parallel"):
delays = []
for stmt in node.body:
old_delay, self.current_delay = self.current_delay, iodelay.Const(0)
self.visit(stmt)
delays.append(self.current_delay)
self.current_delay = old_delay
self.current_delay += iodelay.Max(delays)
elif len(node.items) == 1 and types.is_builtin(context_expr.type, "serial"):
self.visit(node.body)
else:
self.abort("with statement cannot be interleaved", node.loc)
def visit_CallT(self, node):
typ = node.func.type.find()
def abort(notes):
self.abort("this call cannot be interleaved because "
"an argument cannot be statically evaluated",
node.loc, notes)
if types.is_builtin(typ, "delay"):
value = self.evaluate(node.args[0], abort=abort)
self.current_delay += iodelay.SToMU(value, ref_period=self.ref_period)
elif types.is_builtin(typ, "delay_mu"):
value = self.evaluate(node.args[0], abort=abort)
self.current_delay += value
elif not types.is_builtin(typ):
if types.is_function(typ):
offset = 0
elif types.is_method(typ):
offset = 1
typ = types.get_method_function(typ)
else:
assert False
delay = typ.find().delay
if iodelay.is_unknown(delay):
raise _UnknownDelay()
elif iodelay.is_indeterminate(delay):
cause = delay.cause
note = diagnostic.Diagnostic("note",
"function called here", {},
node.loc)
diag = diagnostic.Diagnostic(cause.level, cause.reason, cause.arguments,
cause.location, cause.highlights, cause.notes + [note])
raise diagnostic.Error(diag)
elif iodelay.is_fixed(delay):
args = {}
for kw_node in node.keywords:
args[kw_node.arg] = kw_node.value
for arg_name, arg_node in zip(typ.args, node.args[offset:]):
args[arg_name] = arg_node
print(args)
free_vars = delay.length.free_vars()
self.current_delay += delay.length.fold(
{ arg: self.evaluate(args[arg], abort=abort) for arg in free_vars })
else:
assert False

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@ -5,6 +5,7 @@ in :mod:`asttyped`.
import string
from collections import OrderedDict
from . import iodelay
class UnificationError(Exception):
@ -191,6 +192,8 @@ class TFunction(Type):
optional arguments
:ivar ret: (:class:`Type`)
return type
:ivar delay: (:class:`iodelay.Delay`)
RTIO delay expression
"""
attributes = OrderedDict([
@ -198,11 +201,12 @@ class TFunction(Type):
('__closure__', _TPointer()),
])
def __init__(self, args, optargs, ret):
def __init__(self, args, optargs, ret, delay=iodelay.Unknown()):
assert isinstance(args, OrderedDict)
assert isinstance(optargs, OrderedDict)
assert isinstance(ret, Type)
self.args, self.optargs, self.ret = args, optargs, ret
assert isinstance(delay, iodelay.Delay)
self.args, self.optargs, self.ret, self.delay = args, optargs, ret, delay
def arity(self):
return len(self.args) + len(self.optargs)
@ -256,7 +260,8 @@ class TRPCFunction(TFunction):
attributes = OrderedDict()
def __init__(self, args, optargs, ret, service):
super().__init__(args, optargs, ret)
super().__init__(args, optargs, ret,
delay=iodelay.Fixed(iodelay.Constant(0)))
self.service = service
def unify(self, other):
@ -278,7 +283,8 @@ class TCFunction(TFunction):
attributes = OrderedDict()
def __init__(self, args, ret, name):
super().__init__(args, OrderedDict(), ret)
super().__init__(args, OrderedDict(), ret,
delay=iodelay.Fixed(iodelay.Constant(0)))
self.name = name
def unify(self, other):
@ -547,6 +553,15 @@ class TypePrinter(object):
args += ["?%s:%s" % (arg, self.name(typ.optargs[arg])) for arg in typ.optargs]
signature = "(%s)->%s" % (", ".join(args), self.name(typ.ret))
if iodelay.is_unknown(typ.delay) or iodelay.is_fixed(typ.delay, 0):
pass
elif iodelay.is_fixed(typ.delay):
signature += " delay({} mu)".format(typ.delay.length)
elif iodelay.is_indeterminate(typ.delay):
signature += " delay(?)"
else:
assert False
if isinstance(typ, TRPCFunction):
return "rpc({}) {}".format(typ.service, signature)
if isinstance(typ, TCFunction):

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@ -0,0 +1,5 @@
# RUN: %python -m artiq.compiler.testbench.inferencer %s >%t
# RUN: OutputCheck %s --file-to-check=%t
# CHECK-L: as x:<function parallel>
with parallel as x: pass

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@ -0,0 +1,7 @@
# RUN: %python -m artiq.compiler.testbench.signature %s >%t
# RUN: OutputCheck %s --file-to-check=%t
# CHECK-L: f: (a:float, b:int(width=64))->NoneType delay(s->mu(a) + b mu)
def f(a, b):
delay(a)
delay_mu(b)

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@ -0,0 +1,8 @@
# RUN: %python -m artiq.compiler.testbench.signature %s >%t
# RUN: OutputCheck %s --file-to-check=%t
# CHECK-L: f: (a:int(width=32), b:int(width=32), c:int(width=32), d:int(width=32), e:int(width=32))->NoneType delay(s->mu(a * b // c + d - 10 / e) mu)
def f(a, b, c, d, e):
delay(a * b // c + d - 10 / e)
f(1,2,3,4,5)

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@ -0,0 +1,10 @@
# RUN: %python -m artiq.compiler.testbench.signature %s >%t
# RUN: OutputCheck %s --file-to-check=%t
def f():
delay(1.0)
# CHECK-L: g: ()->NoneType delay(s->mu(2.0) mu)
def g():
f()
f()

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@ -0,0 +1,13 @@
# RUN: %python -m artiq.compiler.testbench.signature %s >%t
# RUN: OutputCheck %s --file-to-check=%t
def pulse(len):
# "on"
delay_mu(len)
# "off"
delay_mu(len)
# CHECK-L: f: ()->NoneType delay(600 mu)
def f():
pulse(100)
pulse(200)

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@ -0,0 +1,21 @@
# RUN: %python -m artiq.compiler.testbench.signature +diag +delay %s >%t
# RUN: OutputCheck %s --file-to-check=%t
def f(a):
b = 1.0
# CHECK-L: ${LINE:+3}: error: this call cannot be interleaved
# CHECK-L: ${LINE:+2}: note: this variable is not an argument of the innermost function
# CHECK-L: ${LINE:-4}: note: only these arguments are in scope of analysis
delay(b)
def g():
# CHECK-L: ${LINE:+2}: error: this call cannot be interleaved
# CHECK-L: ${LINE:+1}: note: this operator is not supported
delay(2.0**2)
def h():
# CHECK-L: ${LINE:+2}: error: this call cannot be interleaved
# CHECK-L: ${LINE:+1}: note: this expression is not supported
delay_mu(1 if False else 2)
f(1)

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@ -0,0 +1,14 @@
# RUN: %python -m artiq.compiler.testbench.signature +diag +delay %s >%t
# RUN: OutputCheck %s --file-to-check=%t
def f():
x = 1
# CHECK-L: ${LINE:+1}: error: this call cannot be interleaved because an argument cannot be statically evaluated
delay_mu(x)
def g():
x = 1.0
# CHECK-L: ${LINE:+1}: error: this call cannot be interleaved
delay(x)

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# RUN: %python -m artiq.compiler.testbench.signature +diag +delay %s >%t
# RUN: OutputCheck %s --file-to-check=%t
def f():
# CHECK-L: ${LINE:+1}: error: this call cannot be interleaved
delay(1.0**2)
def g():
# CHECK-L: ${LINE:+1}: note: function called here
f()
f()

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# RUN: %python -m artiq.compiler.testbench.signature +diag +delay %s >%t
# RUN: OutputCheck %s --file-to-check=%t
def pulse(len):
# "on"
delay_mu(len)
# "off"
delay_mu(len)
def f():
a = 100
# CHECK-L: ${LINE:+1}: error: this call cannot be interleaved
pulse(a)

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# RUN: %python -m artiq.compiler.testbench.signature +diag +delay %s >%t
# RUN: OutputCheck %s --file-to-check=%t
def f():
# CHECK-L: ${LINE:+1}: error: while statement cannot be interleaved
while True:
delay_mu(1)
def g():
# CHECK-L: ${LINE:+1}: error: if statement cannot be interleaved
if True:
delay_mu(1)
def h():
# CHECK-L: ${LINE:+1}: error: if expression cannot be interleaved
delay_mu(1) if True else delay_mu(2)
def i():
# CHECK-L: ${LINE:+1}: error: try statement cannot be interleaved
try:
delay_mu(1)
finally:
pass

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# RUN: %python -m artiq.compiler.testbench.signature +diag +delay %s >%t
# RUN: OutputCheck %s --file-to-check=%t
def f():
r = range(10)
# CHECK-L: ${LINE:+2}: error: for statement cannot be interleaved because trip count is indeterminate
# CHECK-L: ${LINE:+1}: note: this value is not a constant range literal
for _ in r:
delay_mu(1)

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# RUN: %python -m artiq.compiler.testbench.signature +diag +delay %s >%t
# RUN: OutputCheck %s --file-to-check=%t
def f():
for _ in range(10):
delay_mu(10)
# CHECK-L: ${LINE:+1}: error: loop trip count is indeterminate because of control flow
break
def g():
for _ in range(10):
delay_mu(10)
# CHECK-L: ${LINE:+1}: error: loop trip count is indeterminate because of control flow
continue

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# RUN: %python -m artiq.compiler.testbench.signature +diag +delay %s >%t
# RUN: OutputCheck %s --file-to-check=%t
def f():
if True:
# CHECK-L: ${LINE:+1}: error: only return statement at the end of the function can be interleaved
return 1
delay_mu(1)

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# RUN: %python -m artiq.compiler.testbench.signature %s >%t
# RUN: OutputCheck %s --file-to-check=%t
# CHECK-L: f: ()->NoneType delay(10 mu)
def f():
delay_mu(10)
for _ in range(10):
break
# CHECK-L: g: ()->NoneType delay(10 mu)
def g():
delay_mu(10)
for _ in range(10):
continue

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# RUN: %python -m artiq.compiler.testbench.signature %s >%t
# RUN: OutputCheck %s --file-to-check=%t
# CHECK-L: f: ()->NoneType delay(s->mu(1.0) + 1000 mu)
def f():
delay(1.0)
delay_mu(1000)
# CHECK-L: g: ()->NoneType delay(s->mu(5.0) mu)
def g():
delay(1.0)
delay(2.0 * 2)

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# RUN: %python -m artiq.compiler.testbench.signature %s >%t
# RUN: OutputCheck %s --file-to-check=%t
# CHECK-L: f: ()->NoneType delay(s->mu(1.5) * 10 mu)
def f():
for _ in range(10):
delay(1.5)
# CHECK-L: g: ()->NoneType delay(s->mu(1.5) * 2 * 10 mu)
def g():
for _ in range(10):
for _ in range(2):
delay(1.5)

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# RUN: %python -m artiq.compiler.testbench.signature %s >%t
# RUN: OutputCheck %s --file-to-check=%t
# CHECK-L: f: (a:int(width=64), b:int(width=64))->NoneType delay(max(a, b) mu)
def f(a, b):
with parallel:
delay_mu(a)
delay_mu(b)
# CHECK-L: g: (a:int(width=64))->NoneType delay(max(a, 200) mu)
def g(a):
with parallel:
delay_mu(100)
delay_mu(200)
delay_mu(a)

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# RUN: %python -m artiq.compiler.testbench.signature %s >%t
# RUN: OutputCheck %s --file-to-check=%t
# CHECK-L: f: (a:int(width=32))->NoneType delay(s->mu(1.5) * a mu)
def f(a):
for _ in range(a):
delay(1.5)
# CHECK-L: g: (a:int(width=32), b:int(width=32))->NoneType delay(s->mu(1.5) * (b - a) mu)
def g(a, b):
for _ in range(a, b):
delay(1.5)
# CHECK-L: h: (a:int(width=32), b:int(width=32), c:int(width=32))->NoneType delay(s->mu(1.5) * (b - a) // c mu)
def h(a, b, c):
for _ in range(a, b, c):
delay(1.5)
f(1)
g(1,2)
h(1,2,3)

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# RUN: %python -m artiq.compiler.testbench.signature %s >%t
# RUN: OutputCheck %s --file-to-check=%t
# CHECK-L: f: ()->int(width=32) delay(s->mu(1.5) * 10 mu)
def f():
for _ in range(10):
delay(1.5)
return 10
# CHECK-L: g: (x:float)->int(width=32) delay(0 mu)
def g(x):
if x > 1.0:
return 1
return 0
g(1.0)