primx.py 21.2 KB
Newer Older
1 2 3 4 5 6 7 8 9 10 11 12 13 14
# Copyright (c) 2022 PaddlePaddle Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
#     http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.

15 16
from collections import OrderedDict

17 18
import paddle
from paddle import compat as cpt
19 20
from paddle.fluid import framework as framework
from paddle.fluid.framework import Operator, default_main_program
21
from paddle.incubate.autograd.utils import as_tensors
22

23 24 25 26 27 28 29
from .primops import add, fill_const
from .primreg import (lookup_orig2prim, lookup_prim2orig, op_position_inputs,
                      op_position_output)
from .primrules import _jvp, _orig2prim, _prim2orig, _transpose
from .utils import (flatten, flatten_and_remove_none, get_input_var_list,
                    get_output_var_list)

30 31 32 33 34 35 36 37 38 39 40 41 42 43 44

def topo_path(xs, ys, block=None):
    """ Returns the list of ops on the path from `xs` to `ys` in topological 
    order.
    
    TODO(Tongxin): supporting control flow and nested blocks.
    Args:
        xs: a list|tuple of vars as source
        ys: a list|tuple of vars as sink
        block: the program block containing the path, optional
    Returns:
        (path, unused_xs, unreached_ys): a tuple comprised of the resulting op
        path, the unused variables in `xs`, and the unreached variables in `ys`
    """

45
    block = default_main_program().current_block() if block is None else block
46 47 48 49 50 51 52 53 54 55 56 57

    path = []
    backpath = []
    reached_vars = OrderedDict()
    used_vars = OrderedDict()

    # Initialize reached vars
    for x in xs:
        assert x is None or x.block == block, f'x is not None and x.block != block'
        reached_vars[id(x)] = x

    # Reaching test, returning whether an op is reached from the given input
58 59 60
    reaching = lambda op: any(
        id(v) in reached_vars
        for v in flatten_and_remove_none(get_input_var_list(op)))
61 62 63 64 65 66 67 68 69 70 71

    # block.ops are supposedly in the order that preserves correct data
    # dependence.
    # Forward pass to identify all reached variables and ops
    for op in block.ops:
        if reaching(op):
            path.append(op)
            for var in flatten_and_remove_none(get_output_var_list(op)):
                reached_vars[id(var)] = var

    used_vars = OrderedDict((id(y), y) for y in ys if id(y) in reached_vars)
72 73 74
    back_reaching = lambda op: any(
        id(out) in used_vars
        for out in flatten_and_remove_none(get_output_var_list(op)))
75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 154 155 156 157 158 159 160 161 162 163 164 165 166 167 168 169

    # Backward pass to find all used variables
    for op in reversed(path):
        if back_reaching(op):
            backpath.append(op)
            for var in flatten_and_remove_none(get_input_var_list(op)):
                used_vars[id(var)] = var

    unused_xs = [x for x in xs if id(x) not in used_vars]
    unreached_ys = [y for y in ys if id(y) not in reached_vars]

    return list(reversed(backpath)), unused_xs, unreached_ys


def output_vars_on_path(path):
    """ Returns the output variables of all the ops on the path from `xs`
    to `ys`.
    
    Args:
        path: a list of ops on which to find the output variables

    Returns:
        vars: the output vars
    """
    vars = OrderedDict()
    for op in path:
        for out in flatten_and_remove_none(get_output_var_list(op)):
            vars[id(out)] = out

    return vars


class VarMap(object):
    """ A general map data structure for linking variables to variables.
    
    An example is linking variables to their gradients.
    """

    __slots__ = ['name', 'varset', 'tab']

    def __init__(self, name, varset):
        self.name = name
        self.varset = varset
        self.tab = OrderedDict()

    def add(self, key_var, value_var):
        self.tab[id(key_var)] = id(value_var)

    def add_rec(self, key_vars, value_vars):
        if value_vars is None:
            return
        if isinstance(key_vars, paddle.fluid.framework.Variable):
            if not isinstance(value_vars, paddle.fluid.framework.Variable):
                raise TypeError(
                    f'value_vars must be Variable, but got {type(value_vars)}')
            self.tab[id(key_vars)] = id(value_vars)
        else:
            assert len(key_vars) == len(value_vars), (
                f'len(key_vars) shoule be equal to len(value_vars), '
                f'but len(key_vars)={len(key_vars)} and len(value_vars)={len(value_vars)}.'
            )
            for key_var, value_var in zip(key_vars, value_vars):
                self.add_rec(key_var, value_var)

    def lookup(self, key_var):
        value_id = self.tab.get(id(key_var))
        if value_id is not None:
            return self.varset.get(value_id)
        else:
            return None

    def delete(self, key_var):
        varid = id(key_var)
        if varid in self.tab:
            del self.tab[id(key_var)]

    def delete_keyvars(self, key_vars):
        for var in key_vars:
            varid = id(var)
            if varid in self.tab:
                del self.tab[varid]

    def delete_valuevars(self, value_vars):
        ids = [id(v) for v in value_vars]
        keys = [k for k, v in self.tab.items() if v in ids]
        for k in keys:
            del self.tab[k]

    def contain_var(self, key_var):
        return self.tab.__contains__(id(key_var))

    def contain_value(self, value_var):
        return id(value_var) in self.tab.values()


170
# TODO(lml): supporting control flow, nested blocks, and block other than current block of main program.
171 172 173 174 175
class Transform(object):
    """ An object that maintains the state of transformations applied to a 
    primitve program. """

    def __init__(self, block):
176 177
        assert block == default_main_program().current_block(
        ), f'only support transform on current block of main program.'
178 179 180 181 182 183 184 185 186 187 188 189 190 191 192 193 194 195 196 197 198 199 200 201 202 203 204 205 206 207 208 209 210 211 212 213 214 215 216 217 218 219 220 221 222 223 224 225 226 227 228 229 230 231 232 233 234 235 236 237 238 239 240 241 242 243 244 245 246 247 248 249 250 251 252 253 254 255 256 257 258 259 260 261 262 263 264 265 266 267 268 269 270 271 272 273 274 275 276 277 278 279 280 281 282 283 284 285 286
        self.block = block
        self.vars = self.init_vars(block)
        self.var2dot = VarMap('var2dot', self.vars)
        self.dot2bar = VarMap('dot2var', self.vars)

    def init_vars(self, block):
        vars = OrderedDict()
        for _, var in block.vars.items():
            vars[id(var)] = var
        return vars

    def add_vars(self, new_vars):
        self.vars.update({id(v): v for v in new_vars if v is not None})

    def add_vars_rec(self, new_vars):
        if new_vars is None:
            return
        if isinstance(new_vars, paddle.fluid.framework.Variable):
            self.vars.update({id(new_vars): new_vars})
            return
        if not isinstance(new_vars, list):
            raise TypeError(f'new_vars must be list, but got {type(new_vars)}')
        for var in new_vars:
            self.add_vars_rec(var)

    def erase_ops(self, ordered_indexes):
        block = self.block
        for op_index in reversed(ordered_indexes):
            block.desc._remove_op(op_index, op_index + 1)

        # remove from block.ops
        for op_index in reversed(ordered_indexes):
            del block.ops[op_index]

        block._sync_with_cpp()

    def erase_dots(self, vars_to_erase):
        for var in vars_to_erase:
            if id(var) in self.vars:
                del self.vars[id(var)]
        self.dot2bar.delete_keyvars(vars_to_erase)
        self.var2dot.delete_valuevars(vars_to_erase)
        block = self.block
        for var in vars_to_erase:
            name = var.name
            block.desc._remove_var(cpt.to_bytes(name))
            del block.vars[name]
        block._sync_with_cpp()

    def var2dot_rec(self, vars):
        """ Lookup var2dot recursively."""
        if isinstance(vars, paddle.fluid.framework.Variable):
            dot = self.var2dot.lookup(vars)
            return dot

        dots = [self.var2dot_rec(var) for var in vars]
        return dots

    def dot2bar_rec(self, dots):

        if isinstance(dots, paddle.fluid.framework.Variable):
            bar = self.dot2bar.lookup(dots)
            assert bar is not None, 'bar must be not None'
            return bar

        bars = [self.dot2bar_rec(dot) for dot in dots]
        return bars

    def linearize(self, xs, ys, xs_dot=None):
        """ Performs the linearization transform, a.k.a, forward mode AD 
        transform, on a primitive lowered program.
        
        Args:
            xs: a list of input variables
            ys: a list of output variables
            xs_dot: optional, a list of gradient input variables. The list size
                must be equal to `len(xs)`. The shape and dtype of each element
                must be the same as in `xs`

        Returns:
            (xs_dot, ys_dot): a tuple of two lists. `xs_dot` is the list of
            gradient inputs of the resulting linearized program. `ys_dot` is 
            the list gradient outputs of the resulting linearized program
            
        """
        if xs_dot is None:
            xs_dot = [fill_const(1.0, shape=x.shape, dtype=x.dtype) for x in xs]
            self.add_vars(xs_dot)
        else:
            assert len(xs) == len(xs_dot), (
                f'len(xs) should be equal to len(xs_dot), '
                f'but len(xs)={len(xs)} and len(xs_dot)={len(xs_dot)}')

        for x, dot in zip(xs, xs_dot):
            assert x.dtype == dot.dtype, (
                f'x.dtype should be equal to dot.dtype, '
                f'but x.dtype={x.dtype} and dot.dtype={dot.dtype}')
            assert x.shape == dot.shape, (
                f'x.shape should be equal to dot.shape, '
                f'but x.shape={x.shape} and dot.shape={dot.shape}')
            self.var2dot.add(x, dot)

        path, unused_xs, _ = topo_path(xs, ys, self.block)

        # No need to track unused inputs
        for x in unused_xs:
            self.var2dot.delete(x)

        for op in path:
287
            # An input var may not be on the input-output path, which implies
288 289 290 291 292 293 294 295 296 297 298 299 300 301 302 303 304 305 306 307 308 309 310 311 312 313 314 315 316 317 318 319 320 321 322 323 324 325 326 327 328 329 330 331 332 333 334 335 336 337 338 339 340 341 342 343 344 345 346 347 348 349 350 351 352 353 354 355 356 357 358 359 360 361 362 363 364 365 366 367 368 369 370 371 372 373 374 375 376 377 378 379 380 381 382 383 384 385 386 387 388 389 390 391 392 393 394 395 396 397 398 399 400 401 402 403 404 405 406 407 408 409 410 411 412
            # there may be None's in `ins_dot`. In this case we place
            # the original input in the position of the otherwise forward
            # gradient.
            ins = op_position_inputs(op)
            jvp_ins = self.var2dot_rec(ins)
            # apply op's forward ad rule
            outs_dot = _jvp(op, *jvp_ins)
            self.add_vars_rec(outs_dot)
            outs = op_position_output(op)
            self.var2dot.add_rec(outs, outs_dot)

        ys_dot = [self.var2dot.lookup(y) for y in ys]
        return xs_dot, ys_dot

    def transpose(self, ys_dot, xs_dot, ys_bar=None, retain_fwd=False):
        """ Performs the transpose transform, a.k.a, reverse mode AD 
        transform, on a linearized primitive program.

        Note, `transpose` is supposed to be used in couple with `linearize`.
        
        Args:
            ys_dot: a list of outputs of the linearized program.
            xs_dot: a list of inputs of the linearized program.
            ys_bar: optional, a list of inputs of the resulting transposed 
                program. The list size must be equal to `len(ys_dot)`. The shape
                and dtype of each element must be the same as in `ys_dot`

        Returns:
            (ys_bar, xs_bar): a tuple of two lists. `ys_bar` is the list of
            inputs of the resulting transposed program. `xs_bar` is 
            the list outputs of the resulting transposed program
            
        """
        assert all(v is not None for v in xs_dot), f'`xs_dot` includes None.'
        assert all(v is not None for v in ys_dot), f'`ys_dot` includes None.'

        if ys_bar is None:
            ys_bar = []
            for y in ys_dot:
                ys_bar.append(fill_const(1.0, shape=y.shape, dtype=y.dtype))
            self.add_vars(ys_bar)
        else:
            assert len(ys_dot) == len(ys_bar), (
                f'len(ys_dot) should be equal to len(ys_bar), '
                f'but len(ys_dot)={len(ys_dot)} and len(ys_bar)={len(ys_bar)}')
            for y_dot, y_bar in zip(ys_dot, ys_bar):
                assert y_dot.shape == y_bar.shape, (
                    f'y_dot.shape should be equal to y_bar.shape, '
                    f'but y_dot.shape={y_dot.shape} and y_bar.shape={y_bar.shape}'
                )
                assert y_dot.dtype == y_bar.dtype, (
                    f'y_dot.dtype should be equal to y_bar.dtype, '
                    f'but y_dot.dtype={y_dot.dtype} and y_bar.dtype={y_bar.dtype}'
                )

        for dot, bar in zip(ys_dot, ys_bar):
            self.dot2bar.add(dot, bar)

        # find all the relevant forward gradients
        path, unused_xs_dot, _ = topo_path(xs_dot, ys_dot, self.block)

        # No need to track unused inputs
        for dot in unused_xs_dot:
            self.dot2bar.delete(dot)

        dotvars = output_vars_on_path(path)
        dotvars.update((id(var), var) for var in xs_dot)

        is_dot = lambda v: id(v) in dotvars

        for op in reversed(path):
            out = op_position_output(op)
            out_bar_rec = self.dot2bar_rec(out)
            ins_bar_rec = _transpose(op, is_dot, out_bar_rec)

            # TODO(Tongxin): this is hacky. Tuple implies the Transpose rule
            # returns multiple entities. There should be better ways to handle
            # outputs.
            if isinstance(ins_bar_rec, tuple):
                ins_bar_rec = list(ins_bar_rec)
            else:
                ins_bar_rec = [ins_bar_rec]
            self.add_vars_rec(ins_bar_rec)

            ins_bar = flatten(ins_bar_rec)
            ins = flatten(op_position_inputs(op))
            assert len(ins) == len(ins_bar), (
                f'len(ins) should be equal to len(ins_bar), '
                f'but len(ins)={len(ins)} and len(ins_bar)={len(ins_bar)}')

            for dot, bar in zip(ins, ins_bar):
                if bar is not None:
                    # aggregate gradient
                    grad = self.dot2bar.lookup(dot)
                    if grad is None:
                        self.dot2bar.add(dot, bar)
                    else:
                        grad = add(grad, bar)
                        self.add_vars([grad])
                        self.dot2bar.add(dot, grad)

        xs_bar = [self.dot2bar.lookup(x) for x in xs_dot]

        if not retain_fwd and len(path) > 0:
            vars_to_remove = set()
            for op in path:
                vars_to_remove.update(
                    flatten_and_remove_none(get_output_var_list(op)))

            op_indexes = []

            block = self.block
            for i, op in enumerate(block.ops):
                if op in path:
                    op_indexes.append(i)
                    path.pop(0)
                    if len(path) == 0:
                        break

            self.erase_ops(op_indexes)
            self.erase_dots(vars_to_remove)

        return ys_bar, xs_bar


413
# TODO(lml): supporting control flow, nested blocks, and block other than current block of main program.
414
def _lower(block, reverse, blacklist):
415 416 417 418 419 420 421 422 423 424 425 426 427 428 429 430 431 432 433 434 435 436 437 438 439 440 441 442 443 444 445 446 447 448 449 450 451 452 453 454 455 456 457
    # Some functions which are only used in _lower.
    def bind(args, to_bind, value_table):
        for i in range(len(args)):
            if isinstance(args[i], list):
                bind(args[i], to_bind, value_table)
            elif args[i] is not None and args[i].name in to_bind:
                args[i] = value_table[to_bind[args[i].name]]

    def bind_name(names, to_bind):
        return_list = []
        for name in names:
            if isinstance(name, list):
                return_list.append(bind_name(name, to_bind))
            else:
                return_list.append(to_bind[name] if name in to_bind else name)
        return return_list

    def expand_nested_list(xs):
        return_list = []
        for x in xs:
            if isinstance(x, list):
                return_list = return_list + expand_nested_list(x)
            else:
                return_list.append(x)
        return return_list

    # Step1: Do some preparatory work for lower
    lower_fn = _prim2orig if reverse else _orig2prim
    lookup_fn = lookup_prim2orig if reverse else lookup_orig2prim

    value_table = {}
    to_bind = {}
    to_bind_rev = {}
    for var in block.desc.all_vars():
        value_table[var.name()] = block.var(var.name())

    ops_to_remove = []
    vars_to_remove = set()

    # Step2: Process all ops in the target block
    for op_idx in range(len(block.ops)):
        op = block.ops[op_idx]
        ops_to_remove.append(op_idx)
458
        if lookup_fn(op.type) is not None and op.type not in blacklist:
459 460 461 462 463
            input_args = get_input_var_list(op)
            bind(input_args, to_bind, value_table)

            for orig_out, new_out in zip(
                    expand_nested_list(get_output_var_list(op)),
464
                    expand_nested_list(as_tensors(lower_fn(op, *input_args)))):
465 466 467 468 469 470 471 472 473 474 475 476 477 478 479 480 481 482 483 484 485 486
                assert not (orig_out is None) ^ (
                    new_out is None), "orig_out and new_out should match."
                vars_to_remove.add(new_out.name)
                value_table[new_out.name] = new_out
                to_bind[orig_out.name] = new_out.name
                to_bind_rev[new_out.name] = orig_out.name
        else:
            inputs = {}
            for i in range(len(op.input_names)):
                inputs[op.input_names[i]] = bind_name(
                    op.input(op.input_names[i]), to_bind)

            outputs = {}
            for i in range(len(op.output_names)):
                outputs[op.output_names[i]] = op.output(op.output_names[i])

            attrs = {}
            for name in sorted(op.attr_names):
                attrs[name] = op.attr(name)
            from paddle.fluid.dygraph.base import param_guard
            new_op_desc = block.desc.append_op()
            with param_guard(inputs), param_guard(outputs):
487 488 489 490 491 492
                op = Operator(block=block,
                              desc=new_op_desc,
                              type=op.type,
                              inputs=inputs,
                              outputs=outputs,
                              attrs=attrs)
493 494 495 496 497 498 499 500 501 502 503 504 505 506 507 508 509 510 511 512 513 514 515 516 517 518 519 520 521 522 523 524
            block.ops.append(op)

    # Step3: Do some post-processing work
    for op_idx in reversed(ops_to_remove):
        block.desc._remove_op(op_idx, op_idx + 1)
        del block.ops[op_idx]
    block._sync_with_cpp()

    for op_idx in range(len(block.ops)):
        op = block.ops[op_idx]
        for in_name in op.input_arg_names:
            if in_name in to_bind_rev:
                op._rename_input(in_name, to_bind_rev[in_name])

        for out_name in op.output_arg_names:
            if out_name in to_bind_rev:
                op._rename_output(out_name, to_bind_rev[out_name])

    for var_name in sorted(vars_to_remove):
        assert var_name in to_bind_rev, 'var_name "{}" is not in to_bind_rev.'.format(
            var_name)
        if var_name != to_bind_rev[var_name]:
            block.desc._remove_var(cpt.to_bytes(var_name))
            del block.vars[var_name]
    block._sync_with_cpp()


@framework.static_only
def orig2prim(block=None):
    """ 
    .. note::
        **This API is ONLY available in the static mode.**
525
        **Args block must be None or current block of main program.**
526 527 528 529 530 531 532

    All operators in the target block are processed as follows.
    If it is an original operator, it will be transformed into
    one or a series of automatic differential basic operators with
    equivalent function.
    
    Args:
533
        block(paddle.static.Block|None, optional): The
534 535 536
            target block to process on. Default None, and will
            process on the current block of main program.
    """
537 538 539 540

    block = default_main_program().current_block() if block is None else block
    assert block == default_main_program().current_block(
    ), f'block is neither None nor current block of main program'
541
    _lower(block, reverse=False, blacklist=[])
542 543 544


@framework.static_only
545
def prim2orig(block=None, blacklist=None):
546 547 548
    """
    .. note::
        **ONLY available in the static mode.**
549
        **Args block must be None or current block of main program.**
550 551 552 553 554 555 556

    All operators in the target block are processed as follows.
    If it is an automatic differential basic operator, it will be
    transformed into one or a series of original operators with
    equivalent function to support execution.
    
    Args:
557
        block(paddle.static.Block|None, optional): The
558 559
            target block to process on. Default None, and will
            process on the current block of main program.
560 561 562 563 564
        blacklist(list[string]|None, optional): The names of automatic
            differential basic operator that will not be transformed
            into original operators. Default None, and the blacklist
            is treated as empty list.

565 566 567 568 569 570 571 572 573 574 575 576 577 578 579 580 581
    Examples:

        .. code-block:: python

            import paddle
            from paddle.incubate.autograd import enable_prim, prim_enabled, prim2orig
            
            paddle.enable_static()
            enable_prim()
            
            x = paddle.ones(shape=[2, 2], dtype='float32')
            x.stop_gradients = False
            y = x * x
            dy_dx = paddle.static.gradients(y, x)
            if prim_enabled():
                prim2orig()
    """
582 583 584 585

    block = default_main_program().current_block() if block is None else block
    assert block == default_main_program().current_block(
    ), f'block is neither None nor current block of main program'
586 587
    blacklist = [] if blacklist is None else blacklist
    _lower(block, reverse=True, blacklist=blacklist)