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Direktori : /opt/cloudlinux/venv/lib/python3.11/site-packages/guppy/gsl/ |
Current File : //opt/cloudlinux/venv/lib/python3.11/site-packages/guppy/gsl/Document.py |
class Document: def __init__(self, mod, node, env): self.mod = mod self.env = env self.kindbrackets = mod.kindbrackets self.eitherbrackets = mod.eitherbrackets self.anykind = mod.anykind self.out = [] self.localstack = [] self.outstack = [] self.output_directives = [] self.document_title = None self.specified_definitions = None self.macro_args = None self.subdoc = None self.in_in = 0 self.macro_stack = [] node.accept(self) self.result = self.node_of_taci('string', '', self.out, 0) @property def doc_name_node(self): return self.node_of_taci('text', self.get_doc_name()) def _visit_children(self, node): E = self.mod.ReportedError for ch in node.children: try: ch.accept(self) except E: pass def _visit_subjects(self, subjects): for s in subjects: self.out.append(self.node_of_taci('symbol', s.tgtfullname)) def _visit_gets(self, node, what): self._visit_subjects( getattr(self.get_arg_subject(node), 'get_%s' % what)()) def ap_text(self, text): self.out.append(self.node_of_taci('text', text, (), 0)) def close(self, chktag=None, n=1, chk=None, get=False): for i in range(n): out, tag, arg = self.outstack.pop() node = self.node_of_taci(tag, arg, self.out) if not get: out.append(node) self.out = out if chk is not None: assert chk is out if chktag is not None: assert chktag == tag return node def error(self, msg, context=None, **kwds): msg = 'Document: ' + msg more = [('Macro call site.', ms[0]) for ms in self.macro_stack] more.reverse() self.env.error(msg, context, more=more, **kwds) def error_no_sub_element(self, node, subelement): self.error('No such subelement allowed in the enclosing element %r.' % node.tag, subelement, exception=None) def expand_arg(self, arg): i = len(self.localstack) - 1 while i >= 0: argnode = self.localstack[i].get(arg) if argnode is not None: assert argnode.tag == 'symbol' return argnode.arg.strip() i -= 1 return arg def expand_list(self, li): oldout = self.out self.out = newout = [] for node in li: node.accept(self) self.out = oldout return newout def expand_node(self, node, optarg=0, optmore=0): arg, rest = self.get_arg_rest( node, optarg=optarg, optmore=optmore, nostrip=1) return self.node_of_taci(node.tag, arg, rest, node.index, node.src) def gen_char(self, char): self.gen_tag('char', char) def gen_document_header(self): self.open('document_header') self.close() def gen_document_trailer(self): self.open('document_trailer') self.close() def gen_link_to(self, s, text=None, children=()): if text is not None: children = list(children) children.append(self.node_of_taci('text', text)) ln = self.get_link_name(s) self.gen_tag('link_to', ln, children) def gen_localname(self, s): self.gen_link_to(s, s.get_local_name()) def gen_symbol(self, arg): self.out.append(self.node_of_taci('symbol', arg)) def gen_tag(self, tag, arg='', children=()): self.out.append(self.node_of_taci(tag, arg, children)) def gen_text(self, text): self.gen_tag('text', text) def get_arg_only(self, node): arg, rest = self.get_arg_rest(node) if rest: self.error('Node has extra children, only 1 arg or child expected') return arg def get_arg_rest(self, node, optarg=0, optmore=0, nostrip=0): arg, rest = node.get_arg_rest(nostrip=nostrip) rest = self.expand_list(rest) if arg: arg = self.expand_arg(arg) else: if not (rest and rest[0].tag == 'symbol'): if not optarg: self.error( 'Argument on line or as next children expected.', node) else: arg = rest[0].arg.strip() rest = rest[1:] if rest and rest[0].tag == 'symbol': if not optmore: self.error('More arguments than expected.', rest[0]) return arg, rest def get_arg_subject(self, node): arg = self.get_arg_only(node) return self.get_subject(arg, node) def get_arg_subjects_rest(self, node): args, rest = self.get_arglist_rest(node) return [self.get_subject(a, node) for a in args], rest def get_arglist_only(self, node): args, rest = self.get_arglist_rest(node) if rest: self.error_no_sub_element(node, rest[0]) return args def get_arglist_rest(self, node): args = [] for arg in node.get_arglist(): if not arg: self.error("Empty argument in arg list", node) arg = self.expand_arg(arg) args.append(arg) rest = [] for a in self.expand_list(node.children): if a.tag == 'symbol': if rest: self.error( 'Argument elements must be first in subelements.', a, exception=None) args.append(a.arg.strip()) else: rest.append(a) return args, rest def get_cur_subject(self, node): sd = self.subdoc if not sd: self.error('No subject defined in current environment.', node) return sd.subject def get_doc_name(self): return self.document_name def get_filers(self, output_dir): if not self.output_directives: print('Document %r: No output directives' % self.name) filers = [] r = self.get_result() name = self.get_doc_name() for (handler, opts) in self.output_directives: print('processing', handler, opts, name) filers.append(handler.doc2filer( self, r, name, output_dir, opts, self.mod.IO)) return filers def get_link_name(self, a): return a.get_link_name() def get_macro_args(self, node): args = self.macro_args if args is None: self.error('Is not in macro', node) return args def get_result(self): return self.result def get_subject(self, name, node=None): return self.env.get_descr_by_name(name, node) def node_of_taci(self, *args): return self.mod.node_of_taci(*args) def open(self, tag, arg=''): self.outstack.append((self.out, tag, arg)) self.out = [] return self.out def subdoc_do(self, m, f): sd = SubDoc(self, m) osd = self.subdoc self.subdoc = sd sd.subdoc = sd try: f(sd) finally: self.subdoc = osd def visit_args(self, node): if self.macro_args is None: self.error('Not in macro', node) else: names = self.get_arglist_only(node) if len(names) != len(self.macro_args): self.error('%d args passed, here is %d names' % (len(self.macro_args), len(names)), node) self.localstack.append(dict([(x.strip(), self.macro_args[i]) for i, x in enumerate(names)])) def visit_arguments_of(self, node): self._visit_gets(node, 'arguments') def visit_attr_name_of(self, node): self.gen_symbol(self.get_arg_subject(node).get_attr_name()) def visit_attributes_of(self, node): self._visit_gets(node, 'attributes') def visit_block(self, node): self.out.append(self.expand_node(node, optarg=1)) def visit_default(self, node): self.out.append(self.expand_node(node, optarg=1, optmore=1)) def visit_define(self, node): arg, rest = self.get_arg_rest(node) arg = self.get_link_name(self.get_subject(arg, node)) self.out.append(self.node_of_taci( node.tag, arg, rest, node.index, node.src)) def visit_defines(self, node): sd = self.specified_definitions if sd is None: sd = self.specified_definitions = [] sd.extend(self.get_arglist_only(node)) def visit_description_of(self, node): self.get_arg_subject(node).gen_description_doc(self) def visit_document(self, node): self.document_name = node.arg.strip() self.open('document') self._visit_children(node) if self.document_title is None: self.open('document_title') self.gen_text('GSL document %s' % self.document_name) self.close() self.close() def visit_document_title(self, node): self.document_title = node self.out.append(self.document_title) def visit_for(self, node): varname = node.get_namearg() if not node.children: self.error('For loop without subelements.', node) if not (node.children[0].tag == 'in'): self.error("First subelement of for loop must be 'in'.", node.children[0]) inode = node.children[0] names = self.get_arglist_only(inode) body = node.children[1:] if not body: self.error('For loop without body.', node) for name in names: self.localstack.append({ varname: self.node_of_taci( 'symbol', name, (), node.index)}) try: for ch in body: ch.accept(self) finally: self.localstack.pop() def visit_gsml(self, node): arg, rest = node.get_arg_rest() if arg: rest = [self.mod.node_of_taci( 'text', arg, (), node.index, node.src)]+list(rest) self.open('block') for a in rest: if a.tag == 'text': a = self.mod.node_of_gsml(a.arg.strip()) a.accept(self) self.close() def visit_id_of(self, node): self.ap_text(self.get_arg_subject(node).get_id_name()) def visit_in(self, node): self.in_in += 1 self.visit_default(node) self.in_in -= 1 def visit_kind_of(self, node): self.gen_symbol(self.get_arg_subject(node).get_kind_name()) def visit_label(self, node): subject = self.get_cur_subject(node) arg, rest = self.get_arg_rest(node) name = subject.get_link_name() + '.label:'+arg self.open('define', name) self.close() for r in rest: self.out.append(r) def visit_link_to(self, node): arg, rest = self.get_arg_rest(node) self.gen_link_to(self.get_subject(arg, node), children=rest) def visit_man_page_of(self, node): self.open('to_document_only') self.open('man_page_mode') subjects, rest = self.get_arg_subjects_rest(node) if rest: self.error_no_sub_element(node, rest[0]) for subject in subjects: self.subdoc_do(subject, lambda sd: sd.gen_man_page(subject)) self.close() self.close() def visit_mappings_of(self, node): self._visit_gets(node, 'mappings') def visit_meta(self, node): arg = node.arg.strip() if arg: colon = arg.find(':') if colon <= 0: self.error('Argument to meta, if any, must be of the form <name>:<content>.', node) name = arg[:colon].strip() content = arg[colon+1:].strip() mknode = self.mod.node_of_taci ch = (mknode('name', name), mknode( 'content', content)) + node.children node = mknode('meta', '', ch) self.out.append(node) def visit_name_of(self, node): self.gen_text(self.get_arg_subject(node).get_name()) def visit_output(self, node): mode, rest = self.get_arg_rest(node) modes = [x.strip() for x in mode.split(',')] for mode in modes: try: handler_name = self.mod.output_handlers[mode.lower()] except KeyError: self.error('Unknown output mode: %r. Expected one of %r.' % ( mode, list(self.mod.output_handlers.keys())), node, exception=None) else: handler = getattr(self.mod, handler_name) self.output_directives.append((handler, rest)) def visit_ref(self, node): self.gen_text(' ') subject = self.get_cur_subject(node) arg, rest = self.get_arg_rest(node) text = arg if arg.startswith('.'): dl = arg.find('.', 1) if dl < 0: dl = len(arg) tag = arg[1:dl].strip() name = arg[dl+1:].strip() else: tag = 'myfile' name = arg if tag == 'mykind': idn = subject.get_link_name() if name: idn = idn + '.' + name text = name else: text = idn.split('.')[-1] elif tag == 'myfile': idn = subject.get_link_name() idn = '.'.join(idn.split('.')[:2]) if name: idn = idn + '.' + name text = name else: self.error('Invalid tag: %r in reference.' % tag, node) if not rest: rest = [self.node_of_taci('text', text)] self.out.append(self.node_of_taci( 'link_to', idn, rest, node.index)) def visit_specified_definitions(self, node): if node.arg.strip() or node.children: self.error('No argument or subelement allowed for element %r.' % node.tag, node, exception=None) if self.specified_definitions is None: self.error('No definitions have been specified.', node) for s in self.specified_definitions: self.out.append(self.node_of_taci( 'symbol', s, (), node.index, node.src)) def visit_symbol(self, node): arg = self.get_arg_only(node) if arg != node.arg.strip(): node = self.node_of_taci(node.tag, arg, (), node.index, node.src) self.out.append(node) def visit_synopsis_of(self, node): self.open('to_document_only') self.open('man_page_mode') m = self.get_arg_subject(node) self.subdoc_do(m, lambda sd: sd.gen_mapping_doc(m)) self.close() self.close() def visit_test_of(self, node): args, rest = self.get_arg_subjects_rest(node) for kind in args: self.open('to_tester_only') self.out.append(self.node_of_taci( node.tag, kind, rest, node.index, node.src)) self.close() def visit_take_all(self, node): for a in self.get_macro_args(node): self.out.append(a) def visit_take_first(self, node): args = self.get_macro_args(node) if not args: self.error('No argument passed', node) self.out.append(args[0]) def visit_take_rest(self, node): args = self.get_macro_args(node) if not args: self.error('No argument passed', node) for ch in args[1:]: self.out.append(ch) def visit_text(self, node): self.out.append(node) def visit_use(self, node): macrocolonarg, args = self.get_arg_rest(node) colonpos = macrocolonarg.find(':') if colonpos <= 0: macroname = macrocolonarg else: macroname = macrocolonarg[:colonpos].strip() macroarg = macrocolonarg[colonpos+1:].strip() if not macroarg: self.error('Argument must be of form <macroname> or <macroname>:<macroarg>.', node) macroarg = self.expand_arg(macroarg) args = [self.node_of_taci('symbol', macroarg)] + args macro = self.get_subject(macroname, node) o = (self.localstack, self.macro_args) try: self.macro_stack.append([node]) self.localstack = [] self.macro_args = args self._visit_children(macro.use(args)) finally: (self.localstack, self.macro_args) = o self.macro_stack.pop() class Attributes: d_tag = 'attributes' def __init__(self, as_): self.as_ = as_ def find_kind_aspects(self): return self.as_[0].find_kind_aspects() def get_link_name(self): return self.as_[0].mod.tgt_prefix+'(%s)' % ','.join([x.get_link_name() for x in self.as_]) def get_name(self): return ', '.join([x.get_name() for x in self.as_]) def get_kind(self): return self.as_[0].get_kind() def get_self_name(self): return self.as_[0].get_self_name() def find_aspects(self, tag): return self.as_[0].find_aspects(tag) def is_method(self): self.as_[0].is_method() class SubDoc(Document): def __init__(self, parent, subject): self.__dict__.update(parent.__dict__) self.parent = parent self.subject = subject self.level = 0 self.no_ret = 0 self.use_self = None def combine_attrs_of_same_kind(self, kas): if len(kas) <= 1: return kas nkas = [] attrs = [] for ka in kas: t = ka.d_tag if t != 'attribute': nkas.append(ka) continue for (i, as_) in attrs: a = as_[0] if (a.src.node is ka.src.node and len(a.aspects) == len(ka.aspects)): as_.append(ka) break else: attrs.append((len(nkas), [ka])) nkas.append(ka) for (i, as_) in attrs: if len(as_) > 1: nkas[i] = Attributes(as_) return nkas def combine_attrs_of_same_kind_and_description(self, kas): return self.combine_attrs_of_same_kind(kas) def gen_anything(self): self.open('strong') self.gen_text(' ' + self.anykind) self.close() def gen_argref(self, a): # a : kind # a = kind t = a.d_tag if t == 'arg': self.gen_posarg_name(a) self.gen_colon() elif t == 'key_arg': self.gen_keyarg_name(a) self.gen_assign() else: assert 0 self.gen_ref(a.get_kind()) def gen_arguments(self, args): def flatten(args): f = [] for a in args: if a.d_tag in ('args', 'seq'): f.extend(flatten(a.find_arg_aspects())) else: f.append(a) return f def gen_sycomma(): if sycomma: self.gen_text(sycomma[0]) sycomma[:] = [', '] def clr_sycomma(): sycomma[:] = [] def gen_lbracket(b): if sycomma: self.gen_text(' ') self.gen_text(b) clr_sycomma() def gen_rbracket(b): self.gen_text(b) sycomma[:] = [' '] def gen_su(text, sup='sup'): self.open(sup) self.open('strong') self.gen_text(text) self.close() self.close() def gen_taggy(tag, args, func, brackets='[]'): su = 'sup' colon = ':' if tag: self.gen_text(' ') gen_su(tag+colon, su) sycomma[:] = [] if len(args) != 1: gen_lbracket(brackets[0]) func(args) gen_rbracket(brackets[1]) else: clr_sycomma() func(args) def gen_or(asp, sep, orparneed=False, # Set to True if sequences needs parentheses between or sup=1 ): if asp: if len(asp) == 1: gen_arg(asp[0]) return gen_arg(asp[0], parneed=orparneed) for ch in asp[1:]: if sup: self.open('sup') self.open('strong') if callable(sep): sep() else: self.gen_text(sep) if sup: self.close() self.close() clr_sycomma() gen_arg(ch, parneed=orparneed) def gen_arg(a, parneed=0): t = a.d_tag if t in ('arg', 'key_arg'): gen_sycomma() self.gen_argref(a) elif t == 'alt': args = a.find_arg_aspects() gen_taggy('alt', args, lambda args: gen_or(args, ' or ')) elif t == 'no_arg': self.gen_text('[]') elif t == 'draw': args = a.find_arg_aspects() if len(args) <= 1: gen_lbracket(' [') gen_arg(args[0]) gen_rbracket(']') else: gen_taggy('draw', args, lambda args: gen_or( args, ' , ', sup=0)) elif t == 'optionals': args = a.find_arg_aspects() for s in args: gen_lbracket(' [') gen_arg(s) gen_rbracket(']'*len(args)) elif t == 'superkind': gen_sycomma() self.gen_localname(a) elif t in ('seq', ): args = a.find_arg_aspects() gen_taggy('seq', args, lambda args: gen_or(args, ' , ', sup=0)) elif t in ('args', 'seq'): gen_args(a.find_arg_aspects(), parneed) elif t == 'repeat': gen_taggy(a.get_arg(), a.find_arg_aspects(), gen_args) else: assert 0 def gen_args(args, parneed=0): args = flatten(args) def ga(args): for a in args: gen_arg(a) if parneed and len(args) > 1: #gen_taggy('', args, ga, brackets='<>') gen_taggy('1', args, ga) else: ga(args) sycomma = [] gen_args(args) def gen_assign(self): self.open('strong') self.gen_char('nbsp') self.gen_text('=') self.gen_char('nbsp') self.close() def gen_attribute_def(self, a): def gen_dt(do_kind=0): if dt_done: return dt_done.append(1) self.open('dd') if not define_done: link_name = self.get_link_name(a) self.open('define', link_name) if s: self.out.append(s) if s: self.open('code') self.gen_text('.') self.close() self.open('strong') self.open('big') self.gen_attribute_name(a) self.close() self.close() if not define_done: self.close() define_done.append(1) if do_kind or not kas: if len(kas) == 1 and kas[0].d_tag == 'mapping': self.gen_mapping_kind(kas[0], 1) self.open('dl') self.gen_mapping_description(kas[0]) self.close() else: self.gen_colon() self.gen_def(a.get_kind()) kind_done.append(1) self.close('dd') def gen_afterkind(a): dt_done.pop() gen_dt(1) kind_done.append(1) define_done = [] dt_done = [] kind_done = [] kas = a.find_kind_aspects() s = self.get_self_node(a) self.level += 1 for d in a.find_aspects('*'): t = d.d_tag if t == 'description': gen_dt(0) self.open('dd') self.open('dl') self.gen_description_def(d) self.close() self.close() continue if d in kas: if dt_done or kind_done: pass if not dt_done: gen_dt(do_kind=1) elif not kind_done: gen_afterkind(a) elif t == 'self': pass else: assert 0 if not dt_done: gen_dt(do_kind=1) self.level -= 1 def gen_attribute_name(self, a): self.gen_name(a) def gen_attribute_ref(self, a): s = self.get_self_node(a) if s: self.out.append(s) self.open('big') if s: self.open('code') self.gen_text('.') self.close() link_name = self.get_link_name(a) self.open('link_to', link_name) self.gen_attribute_name(a) self.close() self.close() kas = a.find_kind_aspects() if len(kas) == 1 and kas[0].d_tag == 'mapping': self.gen_mapping_kind(kas[0]) else: self.gen_colon() self.gen_ref(a.get_kind()) def gen_attributes_def(self, a): self.gen_attribute_def(a) def gen_attributes_ref(self, a): self.gen_attribute_ref(a) def gen_colon(self): self.open('spc_colonkind') self.close() def gen_comment_def(self, d): pass def gen_comment_ref(self, d): pass def gen_condition_def(self, cond): self.open('dt') self.gen_condition_ref(cond, 1) self.close() self.level += 1 for d in cond.find_aspects('*'): t = d.d_tag if t == 'description': self.gen_description_dd(d) elif t == 'python_code': self.open('dd') self.open('dl') self.open('dt') self.open('strong') self.gen_text('Python code: ') self.close() self.open('code') self.gen_text(d.src.node.arg.strip()) self.close() self.close() ctx = d.find_aspects('in context') if ctx: self.open('dd') self.open('dl') for ct in ctx: self.open('dt') self.open('strong') self.gen_text('in context: ') self.close() self.open('code') self.gen_text(ct.src.node.arg.strip()) self.close() self.close() self.close() self.close() self.close('dl') self.close('dd') self.level -= 1 def gen_condition_ref(self, cond, define=0): link_name = self.get_link_name(cond) if define: self.open('define', link_name) else: self.open('link_to', link_name) self.open('strong') self.open('big') self.gen_text(cond.get_def_name()) self.close() self.close() self.close() # define self.gen_text('(') self.gen_text(', '.join(cond.get_arg_names())) self.gen_text(')') def gen_constructor_def(self, c): self.open('define', self.get_link_name(c)) self.close() for cc in c.args: self.open('dt') self.gen_link_to(cc) self.close() for d in c.find_aspects('description'): self.gen_description_dd(d) def gen_constructor_ref(self, c): self.gen_self(c) self.gen_text(' = ') self.gen_ref(c.args[0]) def gen_constructor_descriptions(self, li): self.gen_constructor_syn(li, 1) def gen_constructor_syn(self, li, desc=0): ccs = [] descs = [] cdccs = [] for c in li: ds = c.find_aspects('description') descs.extend(ds) ccs.extend(c.args) cdccs.append((c, ds, c.args)) if desc and not descs: return self.open('dt') if desc: self.open('h2') else: self.open('big') self.open('strong') if descs: if desc: self.open('define', li[0].get_link_name()) else: self.open('link_to', li[0].get_link_name()) hd = 'Constructors' if len(ccs) == 1: hd = hd.rstrip('s') self.gen_text(hd) if descs: self.close() self.close() if not desc: self.close() self.close('dt') self.open('dd') self.open('dl') for c, ds, ccs in cdccs: for cc in ccs: self.open('block') self.gen_ref(cc.env) conselfnode = self.close(get=1) self.open('dt') self.use_self = conselfnode self.gen_ref(cc) self.use_self = None self.close('dt') if desc: for d in ds: self.gen_description_dd(d) self.close('dl') self.close('dd') def gen_def(self, a): getattr(self, 'gen_%s_def' % a.d_tag)(a) def gen_delitem_def(self, op): self.open('dt') self.gen_delitem_ref(op, 1) self.close() self.gen_mapping_description(op) def gen_delitem_ref(self, op, subdescript=0): link_name = self.get_link_name(op) if subdescript: self.open('define', link_name) self.open('strong') self.open('big') self.gen_text('del ') self.close() self.close() self.close() else: self.open('link_to', link_name) self.gen_text('del ') self.close() self.gen_self(op) args = op.get_arguments() self.gen_text('[') self.gen_arguments(args) self.gen_text(']') def gen_description(self, k): ats = k.find_aspects('*') ats = self.combine_attrs_of_same_kind_and_description(ats) self.gen_descriptions(ats) def gen_description_dd(self, d): self.open('dd') d.gen_doc(self) self.close() def gen_description_def(self, d): self.gen_description_dd(d) def gen_description_descriptions(self, li): self.gen_outer_dt('Description') for d in li: self.gen_description_dd(d) def gen_description_ref(self, d): pass def gen_description_syn(self, li): pass def gen_descriptions(self, ats, use_attr_header=1): if not ats: return tab = self.sortup_aspects(ats) for typ, li in tab: try: try: gen_desc = getattr(self, 'gen_%s_descriptions' % typ) except AttributeError: hd = typ if (len(li) > 1): hd = hd + 's' hd = hd.capitalize().replace('_', ' ') self.gen_outer_dt(hd) for a in li: self.gen_def(a) else: gen_desc(li) except self.mod.ReportedError: pass def gen_either_def(self, k): self.gen_either_ref(k) def gen_either_ref(self, k): self.open('strong') self.open('sup') self.gen_text(' either:') self.close() self.close() self.gen_text(self.eitherbrackets[0]) kas = k.get_alt_kinds() self.gen_ref(kas[0]) for ka in kas[1:]: self.open('strong') self.open('sup') self.gen_text(' or ') self.close() self.close() self.gen_ref(ka) self.gen_text(self.eitherbrackets[1]) def gen_example_descriptions(self, egs): e = 'Example' if len(egs) > 1: e += 's' self.gen_outer_dt(e) for eg in egs: self.open('dd') self.open('pre') ct = eg.get_ctx_text() if ct: if not ct.endswith('\n'): ct += '\n' self.gen_text(ct) et = eg.get_ex_text() self.open('strong') self.gen_text('return ') self.gen_text(eg.get_ex_text()) self.close() self.close() self.close() continue self.open('dd') self.open('code') self.gen_text(eg.get_ex_text()) ct = eg.get_ctx_text() self.close() if ct: self.open('em') self.gen_text(' # in context:') self.close() self.close() if ct: if '\n' in ct: self.open('pre') self.gen_text(ct) self.close() else: self.open('dd') self.open('code') self.gen_text(ct) self.close() self.close() return self.open('dd') self.open('dl') self.open('dt') self.open('strong') self.gen_text('In context') self.close() self.close() self.open('dd') if '\n' in ct: self.open('pre') else: self.open('code') self.gen_text(ct) self.close() self.close() self.close() self.close('dd') def gen_example_syn(self, eg): pass def gen_function_operator_def(self, op): self.open('dd') self.gen_function_operator_ref(op, 1) self.open('dl') self.gen_mapping_description(op) self.close() self.close() def gen_function_operator_ref(self, op, subdescript=0): link_name = self.get_link_name(op) if not subdescript: self.open('link_to', link_name) else: self.open('define', link_name) self.open('big') self.open('strong') self.gen_text(op.src.node.arg.strip()) self.close() self.close() self.close() self.gen_text('(') self.gen_self(op) for a in op.get_arguments(): t = a.d_tag if t == 'arg': self.gen_argref(a) else: assert 0 self.gen_text(')') self.gen_returns(op, subdescript) def gen_header(self, m): link_name = self.get_link_name(m) self.open('define', link_name) self.open('h1') self.gen_text(m.get_name()) self.close() self.close() def gen_inplace_operator_def(self, op): self.gen_operator_def(op) def gen_inplace_operator_ref(self, op, subdescript=0): self.gen_operator_ref(op, subdescript) def gen_keyarg_name(self, a): self.open('code') self.gen_name(a) self.close() def gen_kind_aspects(self, ats, defi): if not ats: self.gen_anything() return self.gen_text(self.kindbrackets[0]) self.open('dl') for a in ats: if a.d_tag in ('kind',) and not a.is_synthetic: self.open('dd') self.open('em') self.gen_text('Subkind of: ') self.close() if defi: self.gen_def(a) else: self.gen_ref(a) self.close() else: if defi: self.open('dd') self.gen_def(a) self.close() else: self.open('dd') self.gen_ref(a) self.close() self.open('dd') self.gen_text(self.kindbrackets[1]) self.close() self.close() def gen_kind_def(self, k): kas = k.find_kind_aspects() self.gen_kind_refodef(k, 1) def gen_kind_of_def(self, k): self.gen_kind_of_ref(k) def gen_kind_of_ref(self, k): kas = k.find_kind_aspects() if len(kas) == 1: self.gen_ref(kas[0]) else: assert 0 # to be tested def gen_kind_ref(self, k, defi=0): self.gen_kind_refodef(k, 0) def gen_kind_refodef(self, k, defi=0): if not k.is_synthetic: self.gen_localname(k) return kas = k.find_kind_aspects() kas = self.combine_attrs_of_same_kind(kas) self.gen_kind_aspects(kas, defi) def gen_man_page(self, m): self.gen_header(m) self.open('dl') self.gen_Name(m) self.gen_synopsis(m) self.gen_description(m) self.close() def gen_mapping_def(self, a): self.gen_mapping_tag(a, 1) self.gen_mapping_kind(a, 1, 1) self.open('dl') self.gen_mapping_description(a) self.close() def gen_mapping_description(self, m): def find_named_args(m): na = [] asp = m.find_arg_aspects() for a in asp: t = a.d_tag if t in ('arg', 'key_arg'): na.append(a) else: na.extend(find_named_args(a)) return na def gen_arguments_descriptions(m): na = find_named_args(m) if not na: return namedesc = {} ada = [] for a in na: t = a.d_tag if t in ('arg', 'key_arg'): da = a.find_aspects('description') ada.append((a, da)) if da: namedesc[(t, a.get_name())] = 1 else: assert 0 if namedesc: label = 'Argument' if len(namedesc) > 1: label += 's' self.gen_outer_dt(label) self.open('dd') self.open('dl') for a, da in ada: t = a.d_tag if not da and (t, a.get_name()) in namedesc: # This arg is considered to be described elsewhere, Notes Aug 10 2005. # This is a bit sublte, may do for now... continue self.open('dt') self.gen_argref(a) self.close() for d in da: self.gen_description_dd(d) self.close() self.close('dd') def gen_condition_ref(a): if a.is_not: self.gen_text('not ') d = a.get_definition() if d is None: self.gen_text(a.cond_doc_name) else: self.open('link_to', self.get_link_name(d)) self.gen_text(a.cond_doc_name) self.close() if a.arg_names: self.gen_text('(') # self.open('var') comma = 0 for an in a.arg_names: if comma: self.gen_text(', ') comma = 1 if an.startswith('<') and an.endswith('>'): self.open('em') self.gen_text(an[1:-1]) self.close() else: # I think it normally is clearer to not have # slanted argument names self.gen_text(an) # self.close() self.gen_text(')') def gen_condition_desc(a): ds = a.find_aspects('description') for d in ds: self.gen_description_dd(d) def gen_conditions_description(m, asp='precondition'): self.open('dd') self.open('dl') pres = m.find_aspects(asp) if pres: self.open('dt') self.open('strong') hd = asp.capitalize() if len(pres) > 1: hd = hd + 's' self.gen_text(hd) self.close() self.close() self.open('dd') self.open('dl') for pre in pres: self.open('dt') gen_condition_ref(pre) self.close() gen_condition_desc(pre) self.close() self.close() self.close() self.close() def gen_description(m): asp = m.find_aspects() args_described = 0 pre_described = 0 post_described = 0 last_t = None last_h = None for a in asp: t = a.d_tag if t == 'description': self.gen_description_dd(a) elif t == 'returns': rds = a.find_aspects('description') if rds: self.open('dd') self.open('dl') self.open('dt') self.open('strong') self.gen_text('Returns ') self.close() rds[0].gen_doc(self) rds = rds[1:] self.close('dt') for rd in rds: self.gen_description_dd(rd) self.close('dl') self.close('dd') elif t in ('precondition', ): if not pre_described: gen_conditions_description(m, t) pre_described = 1 elif t in ('postcondition',): if not post_described: gen_conditions_description(m, t) post_described = 1 elif t in ('equation',): self.open('dd') self.open('dl') self.open('dt') self.open('strong') self.gen_text('Equation') self.close() self.close() self.open('dd') self.open('dl') eqconds_done = 0 for asp in a.find_aspects('*'): t = asp.d_tag if t == 'description': self.gen_description_dd(asp) elif not eqconds_done: eqconds_done = 1 self.open('dt') cs = a.find_aspects( 'precondition', 'postcondition') for cr in cs: if cr.d_tag == 'precondition': self.open('strong') self.open('sup') self.gen_text('pre:') self.close() self.close() elif cr.d_tag == 'postcondition': self.open('strong') self.open('sup') self.gen_text('post:') self.close() self.close() gen_condition_ref(cr) if cr is not cs[-1]: self.open('big') self.gen_text(' == ') self.close() self.close() self.close() self.close() self.close() self.close() else: if not args_described: self.open('dd') self.open('dl') gen_arguments_descriptions(m) args_described = 1 self.close() self.close() else: t = last_t last_t = t self.level += 1 gen_description(m) self.level -= 1 def gen_getitem_def(self, op): self.open('dt') self.gen_getitem_ref(op, 1) self.close() self.gen_mapping_description(op) def gen_getitem_ref(self, op, subdescript=0): link_name = self.get_link_name(op) if subdescript: self.open('define', link_name) if subdescript: self.close() else: self.open('link_to', link_name) self.gen_text('# ') self.close() self.gen_self(op) self.gen_index(op) self.gen_returns(op, subdescript) def gen_index(self, op): self.gen_text('[') self.gen_arguments(op.get_arguments()) self.gen_text(']') def gen_link_to_operator(self, link_name): self.open('to_html_only') self.open('link_to', link_name) self.gen_text('# ') self.close() self.close() def gen_mapping_doc(self, m): def gen_synopsis(m): self.gen_outer_dt('Synopsis') self.open('dd') self.gen_mapping_ref(m) self.close() self.gen_header(m) self.open('dl') self.gen_Name(m) gen_synopsis(m) self.gen_mapping_description(m) self.close() def gen_mapping_kind(self, m, subdescript=0, withself=0): if withself and self.get_self_node(m): self.gen_self(m) self.gen_text('(') self.gen_arguments(m.get_arguments()) self.gen_text(')') self.gen_returns(m, subdescript) def gen_mapping_ref(self, m): self.gen_mapping_tag(m) self.gen_mapping_kind(m, 0, 1) def gen_mapping_tag(self, a, subdescript=0): link_name = self.get_link_name(a) if not subdescript: self.open('link_to', link_name) else: self.open('define', link_name) self.open('strong') self.gen_text('callable') self.close() self.close() self.gen_colon() def gen_Name(self, m): self.gen_outer_dt('Name') self.open('dd') self.open('h2') self.gen_text(m.get_Name()) self.close() self.close() def gen_name(self, a): self.gen_text(a.get_name()) def gen_operator_def(self, op): self.open('dd') self.gen_operator_ref(op, 1) self.open('dl') self.gen_mapping_description(op) self.close() self.close() def gen_operator_ref(self, op, subdescript=0): # self.gen_text('(') link_name = self.get_link_name(op) if subdescript: self.open('define', link_name) if subdescript: self.close() else: self.gen_link_to_operator(link_name) self.gen_self(op) self.gen_text(' ') self.open('big') self.open('strong') self.gen_text(op.src.node.arg.strip()) self.close() self.close() for a in op.get_arguments(): self.gen_text(' ') t = a.d_tag if t == 'arg': self.gen_argref(a) else: assert 0 # self.gen_text(')') self.gen_returns(op, subdescript) def gen_outer_dt(self, text): # Synopsis, Description etc self.open('dt') if not self.level: self.open('h2') else: self.open('strong') if self.level == 1: self.open('big') if callable(text): text() else: self.gen_text(text) if self.level == 1: self.close('big') self.close() self.close() def gen_posarg_name(self, a): self.open('var') self.gen_name(a) self.close() def gen_ref(self, k): t = k.d_tag getattr(self, 'gen_%s_ref' % t)(k) def gen_returns(self, m, subdescript): if self.no_ret: return ars = m.find_aspects('returns') if not ars: return self.open('spc_mapsto') self.close() rk = m.get_return_kind() if subdescript: t = rk.d_tag if t in ('mapping',): self.gen_kind_aspects([rk], 1) else: self.gen_def(rk) else: self.gen_ref(rk) def gen_reverse_operator_def(self, op): self.open('dd') self.gen_reverse_operator_ref(op, 1) self.open('dl') self.gen_mapping_description(op) self.close() self.close() def gen_reverse_operator_ref(self, op, subdescript=0): # self.gen_text('(') link_name = self.get_link_name(op) if subdescript: self.open('define', link_name) self.close() else: self.gen_link_to_operator(link_name) for a in op.get_arguments(): t = a.d_tag if t == 'arg': self.gen_argref(a) else: assert 0 self.open('big') self.gen_text(' ') self.open('strong') self.gen_text(op.src.node.arg.strip()) self.close() self.gen_text(' ') self.close() self.gen_self(op) # self.gen_text(')') self.gen_returns(op, subdescript) def gen_self(self, op): s = self.get_self_node(op) if not s: self.open('em') self.gen_text('self') self.close() else: self.out.append(s) def gen_self_def(self, k): pass def gen_self_descriptions(self, li): pass def gen_self_ref(self, k): self.open('h3') self.gen_text('For any object ') self.open('var') self.gen_text(k.src.node.arg.strip()) self.close() self.gen_text(' of kind ') self.gen_localname(k.env) self.gen_text(':') self.close() def gen_self_syn(self, li): for k in li: self.open('dt') self.gen_self_ref(k) self.close() def gen_setitem_def(self, op): self.open('dt') self.gen_setitem_ref(op, 1) self.close() self.gen_mapping_description(op) def gen_setitem_ref(self, op, subdescript=0): link_name = self.get_link_name(op) if subdescript: self.open('define', link_name) if subdescript: self.close() else: self.gen_link_to_operator(link_name) self.gen_self(op) args = op.get_arguments() self.gen_text('[') self.gen_arguments(args[:-1]) self.gen_text(']') self.open('strong') self.open('big') self.gen_text(' = ') self.close() self.close() self.gen_arguments(args[-1:]) def gen_subkind_of_def(self, k): ds = k.find_aspects('description') if not ds: return self.open('dt') self.gen_subkind_of_ref(k, 1) self.close() self.level += 1 for d in ds: self.gen_description_dd(d) self.level -= 1 def gen_subkind_of_descriptions(self, li): for a in li: self.gen_outer_dt(lambda: self.gen_subkind_of_ref(a, 1)) for d in a.find_aspects('description'): self.gen_description_dd(d) def gen_subkind_of_ref(self, k, subdescript=0): link_name = self.get_link_name(k) if subdescript: self.open('define', link_name) else: self.open('link_to', link_name) self.gen_text('Subkind of') self.close() self.gen_colon() comma = 0 for a in k.args: if comma: self.gen_text(', ') comma = 1 self.gen_localname(a) def gen_subkind_of_syn(self, li): for a in li: self.gen_outer_dt(lambda: self.gen_subkind_of_ref(a, 0)) def gen_superkind_of_ref(self, k): kas = k.find_kind_aspects() if len(kas) == 1: self.gen_ref(kas[0]) else: assert 0 # to be tested def gen_superkind_ref(self, k): self.gen_localname(k) def gen_synopsis(self, m): ats = m.find_aspects('*') ats = self.combine_attrs_of_same_kind(ats) tab = self.sortup_aspects(ats, synopsis=1) if tab: self.gen_outer_dt('Synopsis') self.open('dd') self.open('dl') self.level += 1 for typ, li in tab: try: gen_syn = getattr(self, 'gen_%s_syn' % typ) except AttributeError: name = typ.capitalize().replace('_', ' ') if len(li) != 1: name = name+'s' self.gen_outer_dt(name) for a in li: self.open('dd') self.gen_ref(a) self.close() else: gen_syn(li) self.level -= 1 self.close() self.close() def get_self_node(self, a): sn = self.use_self if sn is None: sn = a.get_self_name() if sn is not None: sn = self.node_of_taci('text', sn) return sn def sortup_aspects(self, ats, synopsis=0): # Get aspects sorted up in the same order for synopsis and main description order = ('description', 'subkind_of', 'constructor', 'self', 'method', 'operator', 'mapping', 'attribute', 'condition', 'example', ) tab = {} def gen_outer(what): assert what in order if what not in tab: tab[what] = [] tab[what].append(a) for a in ats: t = a.d_tag if t == 'comment' or t == 'description' and synopsis: pass elif t in ('attribute', 'attributes', 'either'): if a.is_method(): gen_outer('method') else: gen_outer('attribute') elif a.d_type == 'operator' or t in ('getitem', 'delitem', 'setitem'): gen_outer('operator') else: gen_outer(t) otab = [] for typ in order: if not typ in tab: continue li = tab[typ] otab.append((typ, li)) return otab class _GLUECLAMP_: _imports_ = ( '_parent.FileIO:IO', '_parent.Gsml:node_of_gsml', '_parent:Html', '_parent:Latex', '_parent.Main:ReportedError', '_parent.SpecNodes:node_of_string', '_parent.SpecNodes:node_of_taci', '_parent.SpecNodes:node_aliases', '_parent:Tester', '_parent:XHTML' ) # Map from output mode spelling in output directive to handler name # -- Why should we need to map anyway? # or should we just say they are case insensitive? # If they are case insenitive, we need to map here. # I hereby decide they are case insensitive! output_handlers = {'html': 'Html', 'xhtml': 'XHTML', 'latex': 'Latex', 'tester': 'Tester'} # Brackets to use when rendering kind references kindbrackets = ('[', ']') #kindbrackets = ('{','\n}') kindbrackets = (' (', ' )') #kindbrackets = ' ' # Brackets to use when rendering either kinds eitherbrackets = '[]' # Text to use to render any kind anykind = 'anything' def document(self, node, env): return Document(self, node, env) def _test_main_(self): class TestSubject: def __init__(self, mod, name): self.mod = mod self.name = name self.node_of_string = mod._parent.SpecNodes.node_of_string def use(self, args): name = self.name if name == 'A': return self.node_of_string("""\ .text: hello """) elif name == 'reverse': args.reverse() return self.mod.node_of_taci('string', '', args, 0) else: assert 0 class TestEnv: def __init__(self, mod): self.mod = mod def get_descr_by_name(self, name, node): return TestSubject(self.mod, name) env = TestEnv(self) x = """ .h1: Description of subject ..em ...use: A .h1: Reversing arguments .use: reverse ..text: A ..text: B ..text: C """ node = self._parent.SpecNodes.node_of_string(x) y = self.document(node, env) r = y.get_result() # FIXME: Assert equals to something? print(r) h = self._parent.Html.node2text(r) assert h == ''' <h1>Description of subject<em> hello </em></h1> <h1>Reversing arguments</h1> C B A'''