sv-dependency-builds: osx/include/capnp/schema.capnp annotate

annotate osx/include/capnp/schema.capnp @ 54:5f67a29f0fc7

Rebuild MAD with 64-bit FPM

author	Chris Cannam <cannam@all-day-breakfast.com>
date	Wed, 30 Nov 2016 20:59:17 +0000
parents	3ab5a40c4e3b
children	0994c39f1e94

rev	line source
cannam@49	1 # Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors
cannam@49	2 # Licensed under the MIT License:
cannam@49	3 #
cannam@49	4 # Permission is hereby granted, free of charge, to any person obtaining a copy
cannam@49	5 # of this software and associated documentation files (the "Software"), to deal
cannam@49	6 # in the Software without restriction, including without limitation the rights
cannam@49	7 # to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
cannam@49	8 # copies of the Software, and to permit persons to whom the Software is
cannam@49	9 # furnished to do so, subject to the following conditions:
cannam@49	10 #
cannam@49	11 # The above copyright notice and this permission notice shall be included in
cannam@49	12 # all copies or substantial portions of the Software.
cannam@49	13 #
cannam@49	14 # THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
cannam@49	15 # IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
cannam@49	16 # FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
cannam@49	17 # AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
cannam@49	18 # LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
cannam@49	19 # OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
cannam@49	20 # THE SOFTWARE.
cannam@49	21
cannam@49	22 using Cxx = import "/capnp/c++.capnp";
cannam@49	23
cannam@49	24 @0xa93fc509624c72d9;
cannam@49	25 $Cxx.namespace("capnp::schema");
cannam@49	26
cannam@49	27 using Id = UInt64;
cannam@49	28 # The globally-unique ID of a file, type, or annotation.
cannam@49	29
cannam@49	30 struct Node {
cannam@49	31 id @0 :Id;
cannam@49	32
cannam@49	33 displayName @1 :Text;
cannam@49	34 # Name to present to humans to identify this Node. You should not attempt to parse this. Its
cannam@49	35 # format could change. It is not guaranteed to be unique.
cannam@49	36 #
cannam@49	37 # (On Zooko's triangle, this is the node's nickname.)
cannam@49	38
cannam@49	39 displayNamePrefixLength @2 :UInt32;
cannam@49	40 # If you want a shorter version of `displayName` (just naming this node, without its surrounding
cannam@49	41 # scope), chop off this many characters from the beginning of `displayName`.
cannam@49	42
cannam@49	43 scopeId @3 :Id;
cannam@49	44 # ID of the lexical parent node. Typically, the scope node will have a NestedNode pointing back
cannam@49	45 # at this node, but robust code should avoid relying on this (and, in fact, group nodes are not
cannam@49	46 # listed in the outer struct's nestedNodes, since they are listed in the fields). `scopeId` is
cannam@49	47 # zero if the node has no parent, which is normally only the case with files, but should be
cannam@49	48 # allowed for any kind of node (in order to make runtime type generation easier).
cannam@49	49
cannam@49	50 parameters @32 :List(Parameter);
cannam@49	51 # If this node is parameterized (generic), the list of parameters. Empty for non-generic types.
cannam@49	52
cannam@49	53 isGeneric @33 :Bool;
cannam@49	54 # True if this node is generic, meaning that it or one of its parent scopes has a non-empty
cannam@49	55 # `parameters`.
cannam@49	56
cannam@49	57 struct Parameter {
cannam@49	58 # Information about one of the node's parameters.
cannam@49	59
cannam@49	60 name @0 :Text;
cannam@49	61 }
cannam@49	62
cannam@49	63 nestedNodes @4 :List(NestedNode);
cannam@49	64 # List of nodes nested within this node, along with the names under which they were declared.
cannam@49	65
cannam@49	66 struct NestedNode {
cannam@49	67 name @0 :Text;
cannam@49	68 # Unqualified symbol name. Unlike Node.displayName, this can be used programmatically.
cannam@49	69 #
cannam@49	70 # (On Zooko's triangle, this is the node's petname according to its parent scope.)
cannam@49	71
cannam@49	72 id @1 :Id;
cannam@49	73 # ID of the nested node. Typically, the target node's scopeId points back to this node, but
cannam@49	74 # robust code should avoid relying on this.
cannam@49	75 }
cannam@49	76
cannam@49	77 annotations @5 :List(Annotation);
cannam@49	78 # Annotations applied to this node.
cannam@49	79
cannam@49	80 union {
cannam@49	81 # Info specific to each kind of node.
cannam@49	82
cannam@49	83 file @6 :Void;
cannam@49	84
cannam@49	85 struct :group {
cannam@49	86 dataWordCount @7 :UInt16;
cannam@49	87 # Size of the data section, in words.
cannam@49	88
cannam@49	89 pointerCount @8 :UInt16;
cannam@49	90 # Size of the pointer section, in pointers (which are one word each).
cannam@49	91
cannam@49	92 preferredListEncoding @9 :ElementSize;
cannam@49	93 # The preferred element size to use when encoding a list of this struct. If this is anything
cannam@49	94 # other than `inlineComposite` then the struct is one word or less in size and is a candidate
cannam@49	95 # for list packing optimization.
cannam@49	96
cannam@49	97 isGroup @10 :Bool;
cannam@49	98 # If true, then this "struct" node is actually not an independent node, but merely represents
cannam@49	99 # some named union or group within a particular parent struct. This node's scopeId refers
cannam@49	100 # to the parent struct, which may itself be a union/group in yet another struct.
cannam@49	101 #
cannam@49	102 # All group nodes share the same dataWordCount and pointerCount as the top-level
cannam@49	103 # struct, and their fields live in the same ordinal and offset spaces as all other fields in
cannam@49	104 # the struct.
cannam@49	105 #
cannam@49	106 # Note that a named union is considered a special kind of group -- in fact, a named union
cannam@49	107 # is exactly equivalent to a group that contains nothing but an unnamed union.
cannam@49	108
cannam@49	109 discriminantCount @11 :UInt16;
cannam@49	110 # Number of fields in this struct which are members of an anonymous union, and thus may
cannam@49	111 # overlap. If this is non-zero, then a 16-bit discriminant is present indicating which
cannam@49	112 # of the overlapping fields is active. This can never be 1 -- if it is non-zero, it must be
cannam@49	113 # two or more.
cannam@49	114 #
cannam@49	115 # Note that the fields of an unnamed union are considered fields of the scope containing the
cannam@49	116 # union -- an unnamed union is not its own group. So, a top-level struct may contain a
cannam@49	117 # non-zero discriminant count. Named unions, on the other hand, are equivalent to groups
cannam@49	118 # containing unnamed unions. So, a named union has its own independent schema node, with
cannam@49	119 # `isGroup` = true.
cannam@49	120
cannam@49	121 discriminantOffset @12 :UInt32;
cannam@49	122 # If `discriminantCount` is non-zero, this is the offset of the union discriminant, in
cannam@49	123 # multiples of 16 bits.
cannam@49	124
cannam@49	125 fields @13 :List(Field);
cannam@49	126 # Fields defined within this scope (either the struct's top-level fields, or the fields of
cannam@49	127 # a particular group; see `isGroup`).
cannam@49	128 #
cannam@49	129 # The fields are sorted by ordinal number, but note that because groups share the same
cannam@49	130 # ordinal space, the field's index in this list is not necessarily exactly its ordinal.
cannam@49	131 # On the other hand, the field's position in this list does remain the same even as the
cannam@49	132 # protocol evolves, since it is not possible to insert or remove an earlier ordinal.
cannam@49	133 # Therefore, for most use cases, if you want to identify a field by number, it may make the
cannam@49	134 # most sense to use the field's index in this list rather than its ordinal.
cannam@49	135 }
cannam@49	136
cannam@49	137 enum :group {
cannam@49	138 enumerants@14 :List(Enumerant);
cannam@49	139 # Enumerants ordered by numeric value (ordinal).
cannam@49	140 }
cannam@49	141
cannam@49	142 interface :group {
cannam@49	143 methods @15 :List(Method);
cannam@49	144 # Methods ordered by ordinal.
cannam@49	145
cannam@49	146 superclasses @31 :List(Superclass);
cannam@49	147 # Superclasses of this interface.
cannam@49	148 }
cannam@49	149
cannam@49	150 const :group {
cannam@49	151 type @16 :Type;
cannam@49	152 value @17 :Value;
cannam@49	153 }
cannam@49	154
cannam@49	155 annotation :group {
cannam@49	156 type @18 :Type;
cannam@49	157
cannam@49	158 targetsFile @19 :Bool;
cannam@49	159 targetsConst @20 :Bool;
cannam@49	160 targetsEnum @21 :Bool;
cannam@49	161 targetsEnumerant @22 :Bool;
cannam@49	162 targetsStruct @23 :Bool;
cannam@49	163 targetsField @24 :Bool;
cannam@49	164 targetsUnion @25 :Bool;
cannam@49	165 targetsGroup @26 :Bool;
cannam@49	166 targetsInterface @27 :Bool;
cannam@49	167 targetsMethod @28 :Bool;
cannam@49	168 targetsParam @29 :Bool;
cannam@49	169 targetsAnnotation @30 :Bool;
cannam@49	170 }
cannam@49	171 }
cannam@49	172 }
cannam@49	173
cannam@49	174 struct Field {
cannam@49	175 # Schema for a field of a struct.
cannam@49	176
cannam@49	177 name @0 :Text;
cannam@49	178
cannam@49	179 codeOrder @1 :UInt16;
cannam@49	180 # Indicates where this member appeared in the code, relative to other members.
cannam@49	181 # Code ordering may have semantic relevance -- programmers tend to place related fields
cannam@49	182 # together. So, using code ordering makes sense in human-readable formats where ordering is
cannam@49	183 # otherwise irrelevant, like JSON. The values of codeOrder are tightly-packed, so the maximum
cannam@49	184 # value is count(members) - 1. Fields that are members of a union are only ordered relative to
cannam@49	185 # the other members of that union, so the maximum value there is count(union.members).
cannam@49	186
cannam@49	187 annotations @2 :List(Annotation);
cannam@49	188
cannam@49	189 const noDiscriminant :UInt16 = 0xffff;
cannam@49	190
cannam@49	191 discriminantValue @3 :UInt16 = Field.noDiscriminant;
cannam@49	192 # If the field is in a union, this is the value which the union's discriminant should take when
cannam@49	193 # the field is active. If the field is not in a union, this is 0xffff.
cannam@49	194
cannam@49	195 union {
cannam@49	196 slot :group {
cannam@49	197 # A regular, non-group, non-fixed-list field.
cannam@49	198
cannam@49	199 offset @4 :UInt32;
cannam@49	200 # Offset, in units of the field's size, from the beginning of the section in which the field
cannam@49	201 # resides. E.g. for a UInt32 field, multiply this by 4 to get the byte offset from the
cannam@49	202 # beginning of the data section.
cannam@49	203
cannam@49	204 type @5 :Type;
cannam@49	205 defaultValue @6 :Value;
cannam@49	206
cannam@49	207 hadExplicitDefault @10 :Bool;
cannam@49	208 # Whether the default value was specified explicitly. Non-explicit default values are always
cannam@49	209 # zero or empty values. Usually, whether the default value was explicit shouldn't matter.
cannam@49	210 # The main use case for this flag is for structs representing method parameters:
cannam@49	211 # explicitly-defaulted parameters may be allowed to be omitted when calling the method.
cannam@49	212 }
cannam@49	213
cannam@49	214 group :group {
cannam@49	215 # A group.
cannam@49	216
cannam@49	217 typeId @7 :Id;
cannam@49	218 # The ID of the group's node.
cannam@49	219 }
cannam@49	220 }
cannam@49	221
cannam@49	222 ordinal :union {
cannam@49	223 implicit @8 :Void;
cannam@49	224 explicit @9 :UInt16;
cannam@49	225 # The original ordinal number given to the field. You probably should NOT use this; if you need
cannam@49	226 # a numeric identifier for a field, use its position within the field array for its scope.
cannam@49	227 # The ordinal is given here mainly just so that the original schema text can be reproduced given
cannam@49	228 # the compiled version -- i.e. so that `capnp compile -ocapnp` can do its job.
cannam@49	229 }
cannam@49	230 }
cannam@49	231
cannam@49	232 struct Enumerant {
cannam@49	233 # Schema for member of an enum.
cannam@49	234
cannam@49	235 name @0 :Text;
cannam@49	236
cannam@49	237 codeOrder @1 :UInt16;
cannam@49	238 # Specifies order in which the enumerants were declared in the code.
cannam@49	239 # Like Struct.Field.codeOrder.
cannam@49	240
cannam@49	241 annotations @2 :List(Annotation);
cannam@49	242 }
cannam@49	243
cannam@49	244 struct Superclass {
cannam@49	245 id @0 :Id;
cannam@49	246 brand @1 :Brand;
cannam@49	247 }
cannam@49	248
cannam@49	249 struct Method {
cannam@49	250 # Schema for method of an interface.
cannam@49	251
cannam@49	252 name @0 :Text;
cannam@49	253
cannam@49	254 codeOrder @1 :UInt16;
cannam@49	255 # Specifies order in which the methods were declared in the code.
cannam@49	256 # Like Struct.Field.codeOrder.
cannam@49	257
cannam@49	258 implicitParameters @7 :List(Node.Parameter);
cannam@49	259 # The parameters listed in [] (typically, type / generic parameters), whose bindings are intended
cannam@49	260 # to be inferred rather than specified explicitly, although not all languages support this.
cannam@49	261
cannam@49	262 paramStructType @2 :Id;
cannam@49	263 # ID of the parameter struct type. If a named parameter list was specified in the method
cannam@49	264 # declaration (rather than a single struct parameter type) then a corresponding struct type is
cannam@49	265 # auto-generated. Such an auto-generated type will not be listed in the interface's
cannam@49	266 # `nestedNodes` and its `scopeId` will be zero -- it is completely detached from the namespace.
cannam@49	267 # (Awkwardly, it does of course inherit generic parameters from the method's scope, which makes
cannam@49	268 # this a situation where you can't just climb the scope chain to find where a particular
cannam@49	269 # generic parameter was introduced. Making the `scopeId` zero was a mistake.)
cannam@49	270
cannam@49	271 paramBrand @5 :Brand;
cannam@49	272 # Brand of param struct type.
cannam@49	273
cannam@49	274 resultStructType @3 :Id;
cannam@49	275 # ID of the return struct type; similar to `paramStructType`.
cannam@49	276
cannam@49	277 resultBrand @6 :Brand;
cannam@49	278 # Brand of result struct type.
cannam@49	279
cannam@49	280 annotations @4 :List(Annotation);
cannam@49	281 }
cannam@49	282
cannam@49	283 struct Type {
cannam@49	284 # Represents a type expression.
cannam@49	285
cannam@49	286 union {
cannam@49	287 # The ordinals intentionally match those of Value.
cannam@49	288
cannam@49	289 void @0 :Void;
cannam@49	290 bool @1 :Void;
cannam@49	291 int8 @2 :Void;
cannam@49	292 int16 @3 :Void;
cannam@49	293 int32 @4 :Void;
cannam@49	294 int64 @5 :Void;
cannam@49	295 uint8 @6 :Void;
cannam@49	296 uint16 @7 :Void;
cannam@49	297 uint32 @8 :Void;
cannam@49	298 uint64 @9 :Void;
cannam@49	299 float32 @10 :Void;
cannam@49	300 float64 @11 :Void;
cannam@49	301 text @12 :Void;
cannam@49	302 data @13 :Void;
cannam@49	303
cannam@49	304 list :group {
cannam@49	305 elementType @14 :Type;
cannam@49	306 }
cannam@49	307
cannam@49	308 enum :group {
cannam@49	309 typeId @15 :Id;
cannam@49	310 brand @21 :Brand;
cannam@49	311 }
cannam@49	312 struct :group {
cannam@49	313 typeId @16 :Id;
cannam@49	314 brand @22 :Brand;
cannam@49	315 }
cannam@49	316 interface :group {
cannam@49	317 typeId @17 :Id;
cannam@49	318 brand @23 :Brand;
cannam@49	319 }
cannam@49	320
cannam@49	321 anyPointer :union {
cannam@49	322 unconstrained :union {
cannam@49	323 # A regular AnyPointer.
cannam@49	324 #
cannam@49	325 # The name "unconstained" means as opposed to constraining it to match a type parameter.
cannam@49	326 # In retrospect this name is probably a poor choice given that it may still be constrained
cannam@49	327 # to be a struct, list, or capability.
cannam@49	328
cannam@49	329 anyKind @18 :Void; # truly AnyPointer
cannam@49	330 struct @25 :Void; # AnyStruct
cannam@49	331 list @26 :Void; # AnyList
cannam@49	332 capability @27 :Void; # Capability
cannam@49	333 }
cannam@49	334
cannam@49	335 parameter :group {
cannam@49	336 # This is actually a reference to a type parameter defined within this scope.
cannam@49	337
cannam@49	338 scopeId @19 :Id;
cannam@49	339 # ID of the generic type whose parameter we're referencing. This should be a parent of the
cannam@49	340 # current scope.
cannam@49	341
cannam@49	342 parameterIndex @20 :UInt16;
cannam@49	343 # Index of the parameter within the generic type's parameter list.
cannam@49	344 }
cannam@49	345
cannam@49	346 implicitMethodParameter :group {
cannam@49	347 # This is actually a reference to an implicit (generic) parameter of a method. The only
cannam@49	348 # legal context for this type to appear is inside Method.paramBrand or Method.resultBrand.
cannam@49	349
cannam@49	350 parameterIndex @24 :UInt16;
cannam@49	351 }
cannam@49	352 }
cannam@49	353 }
cannam@49	354 }
cannam@49	355
cannam@49	356 struct Brand {
cannam@49	357 # Specifies bindings for parameters of generics. Since these bindings turn a generic into a
cannam@49	358 # non-generic, we call it the "brand".
cannam@49	359
cannam@49	360 scopes @0 :List(Scope);
cannam@49	361 # For each of the target type and each of its parent scopes, a parameterization may be included
cannam@49	362 # in this list. If no parameterization is included for a particular relevant scope, then either
cannam@49	363 # that scope has no parameters or all parameters should be considered to be `AnyPointer`.
cannam@49	364
cannam@49	365 struct Scope {
cannam@49	366 scopeId @0 :Id;
cannam@49	367 # ID of the scope to which these params apply.
cannam@49	368
cannam@49	369 union {
cannam@49	370 bind @1 :List(Binding);
cannam@49	371 # List of parameter bindings.
cannam@49	372
cannam@49	373 inherit @2 :Void;
cannam@49	374 # The place where this Brand appears is actually within this scope or a sub-scope,
cannam@49	375 # and the bindings for this scope should be inherited from the reference point.
cannam@49	376 }
cannam@49	377 }
cannam@49	378
cannam@49	379 struct Binding {
cannam@49	380 union {
cannam@49	381 unbound @0 :Void;
cannam@49	382 type @1 :Type;
cannam@49	383
cannam@49	384 # TODO(someday): Allow non-type parameters? Unsure if useful.
cannam@49	385 }
cannam@49	386 }
cannam@49	387 }
cannam@49	388
cannam@49	389 struct Value {
cannam@49	390 # Represents a value, e.g. a field default value, constant value, or annotation value.
cannam@49	391
cannam@49	392 union {
cannam@49	393 # The ordinals intentionally match those of Type.
cannam@49	394
cannam@49	395 void @0 :Void;
cannam@49	396 bool @1 :Bool;
cannam@49	397 int8 @2 :Int8;
cannam@49	398 int16 @3 :Int16;
cannam@49	399 int32 @4 :Int32;
cannam@49	400 int64 @5 :Int64;
cannam@49	401 uint8 @6 :UInt8;
cannam@49	402 uint16 @7 :UInt16;
cannam@49	403 uint32 @8 :UInt32;
cannam@49	404 uint64 @9 :UInt64;
cannam@49	405 float32 @10 :Float32;
cannam@49	406 float64 @11 :Float64;
cannam@49	407 text @12 :Text;
cannam@49	408 data @13 :Data;
cannam@49	409
cannam@49	410 list @14 :AnyPointer;
cannam@49	411
cannam@49	412 enum @15 :UInt16;
cannam@49	413 struct @16 :AnyPointer;
cannam@49	414
cannam@49	415 interface @17 :Void;
cannam@49	416 # The only interface value that can be represented statically is "null", whose methods always
cannam@49	417 # throw exceptions.
cannam@49	418
cannam@49	419 anyPointer @18 :AnyPointer;
cannam@49	420 }
cannam@49	421 }
cannam@49	422
cannam@49	423 struct Annotation {
cannam@49	424 # Describes an annotation applied to a declaration. Note AnnotationNode describes the
cannam@49	425 # annotation's declaration, while this describes a use of the annotation.
cannam@49	426
cannam@49	427 id @0 :Id;
cannam@49	428 # ID of the annotation node.
cannam@49	429
cannam@49	430 brand @2 :Brand;
cannam@49	431 # Brand of the annotation.
cannam@49	432 #
cannam@49	433 # Note that the annotation itself is not allowed to be parameterized, but its scope might be.
cannam@49	434
cannam@49	435 value @1 :Value;
cannam@49	436 }
cannam@49	437
cannam@49	438 enum ElementSize {
cannam@49	439 # Possible element sizes for encoded lists. These correspond exactly to the possible values of
cannam@49	440 # the 3-bit element size component of a list pointer.
cannam@49	441
cannam@49	442 empty @0; # aka "void", but that's a keyword.
cannam@49	443 bit @1;
cannam@49	444 byte @2;
cannam@49	445 twoBytes @3;
cannam@49	446 fourBytes @4;
cannam@49	447 eightBytes @5;
cannam@49	448 pointer @6;
cannam@49	449 inlineComposite @7;
cannam@49	450 }
cannam@49	451
cannam@49	452 struct CodeGeneratorRequest {
cannam@49	453 nodes @0 :List(Node);
cannam@49	454 # All nodes parsed by the compiler, including for the files on the command line and their
cannam@49	455 # imports.
cannam@49	456
cannam@49	457 requestedFiles @1 :List(RequestedFile);
cannam@49	458 # Files which were listed on the command line.
cannam@49	459
cannam@49	460 struct RequestedFile {
cannam@49	461 id @0 :Id;
cannam@49	462 # ID of the file.
cannam@49	463
cannam@49	464 filename @1 :Text;
cannam@49	465 # Name of the file as it appeared on the command-line (minus the src-prefix). You may use
cannam@49	466 # this to decide where to write the output.
cannam@49	467
cannam@49	468 imports @2 :List(Import);
cannam@49	469 # List of all imported paths seen in this file.
cannam@49	470
cannam@49	471 struct Import {
cannam@49	472 id @0 :Id;
cannam@49	473 # ID of the imported file.
cannam@49	474
cannam@49	475 name @1 :Text;
cannam@49	476 # Name which this file used to refer to the foreign file. This may be a relative name.
cannam@49	477 # This information is provided because it might be useful for code generation, e.g. to
cannam@49	478 # generate #include directives in C++. We don't put this in Node.file because this
cannam@49	479 # information is only meaningful at compile time anyway.
cannam@49	480 #
cannam@49	481 # (On Zooko's triangle, this is the import's petname according to the importing file.)
cannam@49	482 }
cannam@49	483 }
cannam@49	484 }

Mercurial > hg > sv-dependency-builds

annotate osx/include/capnp/schema.capnp @ 54:5f67a29f0fc7