github.com/bir3/gocompiler@v0.9.2202/src/go/types/mono.go (about) 1 // Copyright 2021 The Go Authors. All rights reserved. 2 // Use of this source code is governed by a BSD-style 3 // license that can be found in the LICENSE file. 4 5 package types 6 7 import ( 8 "github.com/bir3/gocompiler/src/go/ast" 9 "github.com/bir3/gocompiler/src/go/token" 10 . "github.com/bir3/gocompiler/src/internal/types/errors" 11 ) 12 13 // This file implements a check to validate that a Go package doesn't 14 // have unbounded recursive instantiation, which is not compatible 15 // with compilers using static instantiation (such as 16 // monomorphization). 17 // 18 // It implements a sort of "type flow" analysis by detecting which 19 // type parameters are instantiated with other type parameters (or 20 // types derived thereof). A package cannot be statically instantiated 21 // if the graph has any cycles involving at least one derived type. 22 // 23 // Concretely, we construct a directed, weighted graph. Vertices are 24 // used to represent type parameters as well as some defined 25 // types. Edges are used to represent how types depend on each other: 26 // 27 // * Everywhere a type-parameterized function or type is instantiated, 28 // we add edges to each type parameter from the vertices (if any) 29 // representing each type parameter or defined type referenced by 30 // the type argument. If the type argument is just the referenced 31 // type itself, then the edge has weight 0, otherwise 1. 32 // 33 // * For every defined type declared within a type-parameterized 34 // function or method, we add an edge of weight 1 to the defined 35 // type from each ambient type parameter. 36 // 37 // For example, given: 38 // 39 // func f[A, B any]() { 40 // type T int 41 // f[T, map[A]B]() 42 // } 43 // 44 // we construct vertices representing types A, B, and T. Because of 45 // declaration "type T int", we construct edges T<-A and T<-B with 46 // weight 1; and because of instantiation "f[T, map[A]B]" we construct 47 // edges A<-T with weight 0, and B<-A and B<-B with weight 1. 48 // 49 // Finally, we look for any positive-weight cycles. Zero-weight cycles 50 // are allowed because static instantiation will reach a fixed point. 51 52 type monoGraph struct { 53 vertices []monoVertex 54 edges []monoEdge 55 56 // canon maps method receiver type parameters to their respective 57 // receiver type's type parameters. 58 canon map[*TypeParam]*TypeParam 59 60 // nameIdx maps a defined type or (canonical) type parameter to its 61 // vertex index. 62 nameIdx map[*TypeName]int 63 } 64 65 type monoVertex struct { 66 weight int // weight of heaviest known path to this vertex 67 pre int // previous edge (if any) in the above path 68 len int // length of the above path 69 70 // obj is the defined type or type parameter represented by this 71 // vertex. 72 obj *TypeName 73 } 74 75 type monoEdge struct { 76 dst, src int 77 weight int 78 79 pos token.Pos 80 typ Type 81 } 82 83 func (check *Checker) monomorph() { 84 // We detect unbounded instantiation cycles using a variant of 85 // Bellman-Ford's algorithm. Namely, instead of always running |V| 86 // iterations, we run until we either reach a fixed point or we've 87 // found a path of length |V|. This allows us to terminate earlier 88 // when there are no cycles, which should be the common case. 89 90 again := true 91 for again { 92 again = false 93 94 for i, edge := range check.mono.edges { 95 src := &check.mono.vertices[edge.src] 96 dst := &check.mono.vertices[edge.dst] 97 98 // N.B., we're looking for the greatest weight paths, unlike 99 // typical Bellman-Ford. 100 w := src.weight + edge.weight 101 if w <= dst.weight { 102 continue 103 } 104 105 dst.pre = i 106 dst.len = src.len + 1 107 if dst.len == len(check.mono.vertices) { 108 check.reportInstanceLoop(edge.dst) 109 return 110 } 111 112 dst.weight = w 113 again = true 114 } 115 } 116 } 117 118 func (check *Checker) reportInstanceLoop(v int) { 119 var stack []int 120 seen := make([]bool, len(check.mono.vertices)) 121 122 // We have a path that contains a cycle and ends at v, but v may 123 // only be reachable from the cycle, not on the cycle itself. We 124 // start by walking backwards along the path until we find a vertex 125 // that appears twice. 126 for !seen[v] { 127 stack = append(stack, v) 128 seen[v] = true 129 v = check.mono.edges[check.mono.vertices[v].pre].src 130 } 131 132 // Trim any vertices we visited before visiting v the first 133 // time. Since v is the first vertex we found within the cycle, any 134 // vertices we visited earlier cannot be part of the cycle. 135 for stack[0] != v { 136 stack = stack[1:] 137 } 138 139 // TODO(mdempsky): Pivot stack so we report the cycle from the top? 140 141 obj0 := check.mono.vertices[v].obj 142 check.error(obj0, InvalidInstanceCycle, "instantiation cycle:") 143 144 qf := RelativeTo(check.pkg) 145 for _, v := range stack { 146 edge := check.mono.edges[check.mono.vertices[v].pre] 147 obj := check.mono.vertices[edge.dst].obj 148 149 switch obj.Type().(type) { 150 default: 151 panic("unexpected type") 152 case *Named: 153 check.errorf(atPos(edge.pos), InvalidInstanceCycle, "\t%s implicitly parameterized by %s", obj.Name(), TypeString(edge.typ, qf)) // secondary error, \t indented 154 case *TypeParam: 155 check.errorf(atPos(edge.pos), InvalidInstanceCycle, "\t%s instantiated as %s", obj.Name(), TypeString(edge.typ, qf)) // secondary error, \t indented 156 } 157 } 158 } 159 160 // recordCanon records that tpar is the canonical type parameter 161 // corresponding to method type parameter mpar. 162 func (w *monoGraph) recordCanon(mpar, tpar *TypeParam) { 163 if w.canon == nil { 164 w.canon = make(map[*TypeParam]*TypeParam) 165 } 166 w.canon[mpar] = tpar 167 } 168 169 // recordInstance records that the given type parameters were 170 // instantiated with the corresponding type arguments. 171 func (w *monoGraph) recordInstance(pkg *Package, pos token.Pos, tparams []*TypeParam, targs []Type, xlist []ast.Expr) { 172 for i, tpar := range tparams { 173 pos := pos 174 if i < len(xlist) { 175 pos = xlist[i].Pos() 176 } 177 w.assign(pkg, pos, tpar, targs[i]) 178 } 179 } 180 181 // assign records that tpar was instantiated as targ at pos. 182 func (w *monoGraph) assign(pkg *Package, pos token.Pos, tpar *TypeParam, targ Type) { 183 // Go generics do not have an analog to C++`s template-templates, 184 // where a template parameter can itself be an instantiable 185 // template. So any instantiation cycles must occur within a single 186 // package. Accordingly, we can ignore instantiations of imported 187 // type parameters. 188 // 189 // TODO(mdempsky): Push this check up into recordInstance? All type 190 // parameters in a list will appear in the same package. 191 if tpar.Obj().Pkg() != pkg { 192 return 193 } 194 195 // flow adds an edge from vertex src representing that typ flows to tpar. 196 flow := func(src int, typ Type) { 197 weight := 1 198 if typ == targ { 199 weight = 0 200 } 201 202 w.addEdge(w.typeParamVertex(tpar), src, weight, pos, targ) 203 } 204 205 // Recursively walk the type argument to find any defined types or 206 // type parameters. 207 var do func(typ Type) 208 do = func(typ Type) { 209 switch typ := Unalias(typ).(type) { 210 default: 211 panic("unexpected type") 212 213 case *TypeParam: 214 assert(typ.Obj().Pkg() == pkg) 215 flow(w.typeParamVertex(typ), typ) 216 217 case *Named: 218 if src := w.localNamedVertex(pkg, typ.Origin()); src >= 0 { 219 flow(src, typ) 220 } 221 222 targs := typ.TypeArgs() 223 for i := 0; i < targs.Len(); i++ { 224 do(targs.At(i)) 225 } 226 227 case *Array: 228 do(typ.Elem()) 229 case *Basic: 230 // ok 231 case *Chan: 232 do(typ.Elem()) 233 case *Map: 234 do(typ.Key()) 235 do(typ.Elem()) 236 case *Pointer: 237 do(typ.Elem()) 238 case *Slice: 239 do(typ.Elem()) 240 241 case *Interface: 242 for i := 0; i < typ.NumMethods(); i++ { 243 do(typ.Method(i).Type()) 244 } 245 case *Signature: 246 tuple := func(tup *Tuple) { 247 for i := 0; i < tup.Len(); i++ { 248 do(tup.At(i).Type()) 249 } 250 } 251 tuple(typ.Params()) 252 tuple(typ.Results()) 253 case *Struct: 254 for i := 0; i < typ.NumFields(); i++ { 255 do(typ.Field(i).Type()) 256 } 257 } 258 } 259 do(targ) 260 } 261 262 // localNamedVertex returns the index of the vertex representing 263 // named, or -1 if named doesn't need representation. 264 func (w *monoGraph) localNamedVertex(pkg *Package, named *Named) int { 265 obj := named.Obj() 266 if obj.Pkg() != pkg { 267 return -1 // imported type 268 } 269 270 root := pkg.Scope() 271 if obj.Parent() == root { 272 return -1 // package scope, no ambient type parameters 273 } 274 275 if idx, ok := w.nameIdx[obj]; ok { 276 return idx 277 } 278 279 idx := -1 280 281 // Walk the type definition's scope to find any ambient type 282 // parameters that it's implicitly parameterized by. 283 for scope := obj.Parent(); scope != root; scope = scope.Parent() { 284 for _, elem := range scope.elems { 285 if elem, ok := elem.(*TypeName); ok && !elem.IsAlias() && cmpPos(elem.Pos(), obj.Pos()) < 0 { 286 if tpar, ok := elem.Type().(*TypeParam); ok { 287 if idx < 0 { 288 idx = len(w.vertices) 289 w.vertices = append(w.vertices, monoVertex{obj: obj}) 290 } 291 292 w.addEdge(idx, w.typeParamVertex(tpar), 1, obj.Pos(), tpar) 293 } 294 } 295 } 296 } 297 298 if w.nameIdx == nil { 299 w.nameIdx = make(map[*TypeName]int) 300 } 301 w.nameIdx[obj] = idx 302 return idx 303 } 304 305 // typeParamVertex returns the index of the vertex representing tpar. 306 func (w *monoGraph) typeParamVertex(tpar *TypeParam) int { 307 if x, ok := w.canon[tpar]; ok { 308 tpar = x 309 } 310 311 obj := tpar.Obj() 312 313 if idx, ok := w.nameIdx[obj]; ok { 314 return idx 315 } 316 317 if w.nameIdx == nil { 318 w.nameIdx = make(map[*TypeName]int) 319 } 320 321 idx := len(w.vertices) 322 w.vertices = append(w.vertices, monoVertex{obj: obj}) 323 w.nameIdx[obj] = idx 324 return idx 325 } 326 327 func (w *monoGraph) addEdge(dst, src, weight int, pos token.Pos, typ Type) { 328 // TODO(mdempsky): Deduplicate redundant edges? 329 w.edges = append(w.edges, monoEdge{ 330 dst: dst, 331 src: src, 332 weight: weight, 333 334 pos: pos, 335 typ: typ, 336 }) 337 }