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decodetree: Move semantic propagation into classes

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Create ExcMultiPattern to hold an set of non-overlapping patterns.
The body of build_tree, prop_format become member functions on this
class.  Add minimal member functions to Pattern and MultiPattern
to allow recusion through the tree.

Move the bulk of build_incmulti_pattern to prop_masks and prop_width
in MultiPattern, since we will need this for both kinds of containers.
Only perform prop_width for variablewidth.

Remove global patterns variable, and pass down container object into
parse_file from main.

No functional change in all of this.

Reviewed-by: Peter Maydell <peter.maydell@linaro.org>
Signed-off-by: Richard Henderson <richard.henderson@linaro.org>
This commit is contained in:
Richard Henderson 2020-05-17 10:14:11 -07:00
parent b44b3449a0
commit 08561fc128
1 changed files with 253 additions and 211 deletions
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464
scripts/decodetree.py
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@ -31,7 +31,6 @@ variablewidth = False
fields = {}
arguments = {}
formats = {}
patterns = []
allpatterns = []
anyextern = False
@ -371,16 +370,27 @@ class Pattern(General):
output(ind, 'u.f_', arg, '.', n, ' = ', f.str_extract(), ';\n')
output(ind, 'if (', translate_prefix, '_', self.name,
'(ctx, &u.f_', arg, ')) return true;\n')
# Normal patterns do not have children.
def build_tree(self):
return
def prop_masks(self):
return
def prop_format(self):
return
def prop_width(self):
return
# end Pattern
class MultiPattern(General):
"""Class representing a set of instruction patterns"""
def __init__(self, lineno, pats):
def __init__(self, lineno):
self.file = input_file
self.lineno = lineno
self.pats = pats
self.pats = []
self.base = None
self.fixedbits = 0
self.fixedmask = 0
@ -396,22 +406,63 @@ class MultiPattern(General):
def output_decl(self):
for p in self.pats:
p.output_decl()
def prop_masks(self):
global insnmask
fixedmask = insnmask
undefmask = insnmask
# Collect fixedmask/undefmask for all of the children.
for p in self.pats:
p.prop_masks()
fixedmask &= p.fixedmask
undefmask &= p.undefmask
# Widen fixedmask until all fixedbits match
repeat = True
fixedbits = 0
while repeat and fixedmask != 0:
fixedbits = None
for p in self.pats:
thisbits = p.fixedbits & fixedmask
if fixedbits is None:
fixedbits = thisbits
elif fixedbits != thisbits:
fixedmask &= ~(fixedbits ^ thisbits)
break
else:
repeat = False
self.fixedbits = fixedbits
self.fixedmask = fixedmask
self.undefmask = undefmask
def build_tree(self):
for p in self.pats:
p.build_tree()
def prop_format(self):
for p in self.pats:
p.build_tree()
def prop_width(self):
width = None
for p in self.pats:
p.prop_width()
if width is None:
width = p.width
elif width != p.width:
error_with_file(self.file, self.lineno,
'width mismatch in patterns within braces')
self.width = width
# end MultiPattern
class IncMultiPattern(MultiPattern):
"""Class representing an overlapping set of instruction patterns"""
def __init__(self, lineno, pats, fixb, fixm, udfm, w):
self.file = input_file
self.lineno = lineno
self.pats = pats
self.base = None
self.fixedbits = fixb
self.fixedmask = fixm
self.undefmask = udfm
self.width = w
def output_code(self, i, extracted, outerbits, outermask):
global translate_prefix
ind = str_indent(i)
@ -431,6 +482,153 @@ class IncMultiPattern(MultiPattern):
#end IncMultiPattern
class Tree:
"""Class representing a node in a decode tree"""
def __init__(self, fm, tm):
self.fixedmask = fm
self.thismask = tm
self.subs = []
self.base = None
def str1(self, i):
ind = str_indent(i)
r = '{0}{1:08x}'.format(ind, self.fixedmask)
if self.format:
r += ' ' + self.format.name
r += ' [\n'
for (b, s) in self.subs:
r += '{0} {1:08x}:\n'.format(ind, b)
r += s.str1(i + 4) + '\n'
r += ind + ']'
return r
def __str__(self):
return self.str1(0)
def output_code(self, i, extracted, outerbits, outermask):
ind = str_indent(i)
# If we identified all nodes below have the same format,
# extract the fields now.
if not extracted and self.base:
output(ind, self.base.extract_name(),
'(ctx, &u.f_', self.base.base.name, ', insn);\n')
extracted = True
# Attempt to aid the compiler in producing compact switch statements.
# If the bits in the mask are contiguous, extract them.
sh = is_contiguous(self.thismask)
if sh > 0:
# Propagate SH down into the local functions.
def str_switch(b, sh=sh):
return '(insn >> {0}) & 0x{1:x}'.format(sh, b >> sh)
def str_case(b, sh=sh):
return '0x{0:x}'.format(b >> sh)
else:
def str_switch(b):
return 'insn & 0x{0:08x}'.format(b)
def str_case(b):
return '0x{0:08x}'.format(b)
output(ind, 'switch (', str_switch(self.thismask), ') {\n')
for b, s in sorted(self.subs):
assert (self.thismask & ~s.fixedmask) == 0
innermask = outermask | self.thismask
innerbits = outerbits | b
output(ind, 'case ', str_case(b), ':\n')
output(ind, ' /* ',
str_match_bits(innerbits, innermask), ' */\n')
s.output_code(i + 4, extracted, innerbits, innermask)
output(ind, ' return false;\n')
output(ind, '}\n')
# end Tree
class ExcMultiPattern(MultiPattern):
"""Class representing a non-overlapping set of instruction patterns"""
def output_code(self, i, extracted, outerbits, outermask):
# Defer everything to our decomposed Tree node
self.tree.output_code(i, extracted, outerbits, outermask)
@staticmethod
def __build_tree(pats, outerbits, outermask):
# Find the intersection of all remaining fixedmask.
innermask = ~outermask & insnmask
for i in pats:
innermask &= i.fixedmask
if innermask == 0:
# Edge condition: One pattern covers the entire insnmask
if len(pats) == 1:
t = Tree(outermask, innermask)
t.subs.append((0, pats[0]))
return t
text = 'overlapping patterns:'
for p in pats:
text += '\n' + p.file + ':' + str(p.lineno) + ': ' + str(p)
error_with_file(pats[0].file, pats[0].lineno, text)
fullmask = outermask | innermask
# Sort each element of pats into the bin selected by the mask.
bins = {}
for i in pats:
fb = i.fixedbits & innermask
if fb in bins:
bins[fb].append(i)
else:
bins[fb] = [i]
# We must recurse if any bin has more than one element or if
# the single element in the bin has not been fully matched.
t = Tree(fullmask, innermask)
for b, l in bins.items():
s = l[0]
if len(l) > 1 or s.fixedmask & ~fullmask != 0:
s = ExcMultiPattern.__build_tree(l, b | outerbits, fullmask)
t.subs.append((b, s))
return t
def build_tree(self):
super().prop_format()
self.tree = self.__build_tree(self.pats, self.fixedbits,
self.fixedmask)
@staticmethod
def __prop_format(tree):
"""Propagate Format objects into the decode tree"""
# Depth first search.
for (b, s) in tree.subs:
if isinstance(s, Tree):
ExcMultiPattern.__prop_format(s)
# If all entries in SUBS have the same format, then
# propagate that into the tree.
f = None
for (b, s) in tree.subs:
if f is None:
f = s.base
if f is None:
return
if f is not s.base:
return
tree.base = f
def prop_format(self):
super().prop_format()
self.__prop_format(self.tree)
# end ExcMultiPattern
def parse_field(lineno, name, toks):
"""Parse one instruction field from TOKS at LINENO"""
global fields
@ -587,18 +785,19 @@ def infer_format(arg, fieldmask, flds, width):
# end infer_format
def parse_generic(lineno, is_format, name, toks):
def parse_generic(lineno, parent_pat, name, toks):
"""Parse one instruction format from TOKS at LINENO"""
global fields
global arguments
global formats
global patterns
global allpatterns
global re_ident
global insnwidth
global insnmask
global variablewidth
is_format = parent_pat is None
fixedmask = 0
fixedbits = 0
undefmask = 0
@ -749,7 +948,7 @@ def parse_generic(lineno, is_format, name, toks):
error(lineno, 'field {0} not initialized'.format(f))
pat = Pattern(name, lineno, fmt, fixedbits, fixedmask,
undefmask, fieldmask, flds, width)
patterns.append(pat)
parent_pat.pats.append(pat)
allpatterns.append(pat)
# Validate the masks that we have assembled.
@ -769,61 +968,16 @@ def parse_generic(lineno, is_format, name, toks):
.format(allbits ^ insnmask))
# end parse_general
def build_incmulti_pattern(lineno, pats):
"""Validate the Patterns going into a IncMultiPattern."""
global patterns
global insnmask
if len(pats) < 2:
error(lineno, 'less than two patterns within braces')
fixedmask = insnmask
undefmask = insnmask
# Collect fixed/undefmask for all of the children.
# Move the defining lineno back to that of the first child.
for p in pats:
fixedmask &= p.fixedmask
undefmask &= p.undefmask
if p.lineno < lineno:
lineno = p.lineno
width = None
for p in pats:
if width is None:
width = p.width
elif width != p.width:
error(lineno, 'width mismatch in patterns within braces')
repeat = True
fixedbits = 0
while repeat and fixedmask != 0:
fixedbits = None
for p in pats:
thisbits = p.fixedbits & fixedmask
if fixedbits is None:
fixedbits = thisbits
elif fixedbits != thisbits:
fixedmask &= ~(fixedbits ^ thisbits)
break
else:
repeat = False
mp = IncMultiPattern(lineno, pats, fixedbits, fixedmask, undefmask, width)
patterns.append(mp)
# end build_incmulti_pattern
def parse_file(f):
def parse_file(f, parent_pat):
"""Parse all of the patterns within a file"""
global patterns
# Read all of the lines of the file. Concatenate lines
# ending in backslash; discard empty lines and comments.
toks = []
lineno = 0
nesting = 0
saved_pats = []
nesting_pats = []
for line in f:
lineno += 1
@ -868,16 +1022,20 @@ def parse_file(f):
# End nesting?
if name == '}':
if nesting == 0:
error(start_lineno, 'mismatched close brace')
if len(toks) != 0:
error(start_lineno, 'extra tokens after close brace')
if len(parent_pat.pats) < 2:
error(lineno, 'less than two patterns within braces')
try:
parent_pat = nesting_pats.pop()
except:
error(lineno, 'mismatched close brace')
nesting -= 2
if indent != nesting:
error(start_lineno, 'indentation ', indent, ' != ', nesting)
pats = patterns
patterns = saved_pats.pop()
build_incmulti_pattern(lineno, pats)
error(lineno, 'indentation ', indent, ' != ', nesting)
toks = []
continue
@ -889,8 +1047,12 @@ def parse_file(f):
if name == '{':
if len(toks) != 0:
error(start_lineno, 'extra tokens after open brace')
saved_pats.append(patterns)
patterns = []
nested_pat = IncMultiPattern(start_lineno)
parent_pat.pats.append(nested_pat)
nesting_pats.append(parent_pat)
parent_pat = nested_pat
nesting += 2
toks = []
continue
@ -901,121 +1063,13 @@ def parse_file(f):
elif name[0] == '&':
parse_arguments(start_lineno, name[1:], toks)
elif name[0] == '@':
parse_generic(start_lineno, True, name[1:], toks)
parse_generic(start_lineno, None, name[1:], toks)
else:
parse_generic(start_lineno, False, name, toks)
parse_generic(start_lineno, parent_pat, name, toks)
toks = []
# end parse_file
class Tree:
"""Class representing a node in a decode tree"""
def __init__(self, fm, tm):
self.fixedmask = fm
self.thismask = tm
self.subs = []
self.base = None
def str1(self, i):
ind = str_indent(i)
r = '{0}{1:08x}'.format(ind, self.fixedmask)
if self.format:
r += ' ' + self.format.name
r += ' [\n'
for (b, s) in self.subs:
r += '{0} {1:08x}:\n'.format(ind, b)
r += s.str1(i + 4) + '\n'
r += ind + ']'
return r
def __str__(self):
return self.str1(0)
def output_code(self, i, extracted, outerbits, outermask):
ind = str_indent(i)
# If we identified all nodes below have the same format,
# extract the fields now.
if not extracted and self.base:
output(ind, self.base.extract_name(),
'(ctx, &u.f_', self.base.base.name, ', insn);\n')
extracted = True
# Attempt to aid the compiler in producing compact switch statements.
# If the bits in the mask are contiguous, extract them.
sh = is_contiguous(self.thismask)
if sh > 0:
# Propagate SH down into the local functions.
def str_switch(b, sh=sh):
return '(insn >> {0}) & 0x{1:x}'.format(sh, b >> sh)
def str_case(b, sh=sh):
return '0x{0:x}'.format(b >> sh)
else:
def str_switch(b):
return 'insn & 0x{0:08x}'.format(b)
def str_case(b):
return '0x{0:08x}'.format(b)
output(ind, 'switch (', str_switch(self.thismask), ') {\n')
for b, s in sorted(self.subs):
assert (self.thismask & ~s.fixedmask) == 0
innermask = outermask | self.thismask
innerbits = outerbits | b
output(ind, 'case ', str_case(b), ':\n')
output(ind, ' /* ',
str_match_bits(innerbits, innermask), ' */\n')
s.output_code(i + 4, extracted, innerbits, innermask)
output(ind, ' return false;\n')
output(ind, '}\n')
# end Tree
def build_tree(pats, outerbits, outermask):
# Find the intersection of all remaining fixedmask.
innermask = ~outermask & insnmask
for i in pats:
innermask &= i.fixedmask
if innermask == 0:
# Edge condition: One pattern covers the entire insnmask
if len(pats) == 1:
t = Tree(outermask, innermask)
t.subs.append((0, pats[0]))
return t
text = 'overlapping patterns:'
for p in pats:
text += '\n' + p.file + ':' + str(p.lineno) + ': ' + str(p)
error_with_file(pats[0].file, pats[0].lineno, text)
fullmask = outermask | innermask
# Sort each element of pats into the bin selected by the mask.
bins = {}
for i in pats:
fb = i.fixedbits & innermask
if fb in bins:
bins[fb].append(i)
else:
bins[fb] = [i]
# We must recurse if any bin has more than one element or if
# the single element in the bin has not been fully matched.
t = Tree(fullmask, innermask)
for b, l in bins.items():
s = l[0]
if len(l) > 1 or s.fixedmask & ~fullmask != 0:
s = build_tree(l, b | outerbits, fullmask)
t.subs.append((b, s))
return t
# end build_tree
class SizeTree:
"""Class representing a node in a size decode tree"""
@ -1157,28 +1211,6 @@ def build_size_tree(pats, width, outerbits, outermask):
# end build_size_tree
def prop_format(tree):
"""Propagate Format objects into the decode tree"""
# Depth first search.
for (b, s) in tree.subs:
if isinstance(s, Tree):
prop_format(s)
# If all entries in SUBS have the same format, then
# propagate that into the tree.
f = None
for (b, s) in tree.subs:
if f is None:
f = s.base
if f is None:
return
if f is not s.base:
return
tree.base = f
# end prop_format
def prop_size(tree):
"""Propagate minimum widths up the decode size tree"""
@ -1199,7 +1231,6 @@ def prop_size(tree):
def main():
global arguments
global formats
global patterns
global allpatterns
global translate_scope
global translate_prefix
@ -1246,18 +1277,29 @@ def main():
if len(args) < 1:
error(0, 'missing input file')
toppat = ExcMultiPattern(0)
for filename in args:
input_file = filename
f = open(filename, 'r')
parse_file(f)
parse_file(f, toppat)
f.close()
if variablewidth:
stree = build_size_tree(patterns, 8, 0, 0)
prop_size(stree)
# We do not want to compute masks for toppat, because those masks
# are used as a starting point for build_tree. For toppat, we must
# insist that decode begins from naught.
for i in toppat.pats:
i.prop_masks()
dtree = build_tree(patterns, 0, 0)
prop_format(dtree)
toppat.build_tree()
toppat.prop_format()
if variablewidth:
for i in toppat.pats:
i.prop_width()
stree = build_size_tree(toppat.pats, 8, 0, 0)
prop_size(stree)
if output_file:
output_fd = open(output_file, 'w')
@ -1316,7 +1358,7 @@ def main():
f = arguments[n]
output(i4, i4, f.struct_name(), ' f_', f.name, ';\n')
output(i4, '} u;\n\n')
dtree.output_code(4, False, 0, 0)
toppat.output_code(4, False, 0, 0)
output(i4, 'return false;\n')
output('}\n')