public void apply(CallContext ctx) throws Throwable { Object proc = func.eval(ctx); int n = args.length; Object[] vals = new Object[n]; for (int i = 0; i < n; i++) vals[i] = args[i].eval(ctx); ((Procedure) proc).checkN(vals, ctx); }
public int effectiveIndex(int[] indexes) { Object obj; try { obj = proc.apply1(indexes); } catch (Throwable ex) { throw new RuntimeException("index transformer throw " + ex, ex); } if (obj instanceof int[]) return base.effectiveIndex((int[]) obj); IntSequence ind = Sequences.asIntSequenceOrNull(obj); if (ind == null) throw new ClassCastException("not an integer sequence"); if (ind instanceof S32Vector) return base.effectiveIndex(((S32Vector) ind).getBuffer()); else { int rank = ind.size(); switch (rank) { case 0: return base.effectiveIndex(); case 1: return base.effectiveIndex(ind.getInt(0)); case 2: return base.effectiveIndex(ind.getInt(0), ind.getInt(1)); default: int[] rest = rank == 3 ? AbstractSequence.noInts : new int[rank - 3]; for (int i = 3; i < rank; i++) rest[i - 3] = ind.getInt(i); return base.effectiveIndex(ind.getInt(0), ind.getInt(1), ind.getInt(2), rest); } } }
public E get(int[] indexes) { try { return (E) proc.apply1(new S32Vector(indexes)); } catch (Throwable ex) { throw new RuntimeException("caught " + ex + " evaluating array procedure", ex); } }
private static int effectiveIndex(Array array, Procedure proc, Object[] args, int[] work) throws Throwable { Object mapval = proc.applyN(args); if (mapval instanceof Values) { Values mapvals = (Values) mapval; for (int i = 0, j = 0; (i = mapvals.nextPos(i)) != 0; j++) { work[j] = ((Number) mapvals.getPosPrevious(i)).intValue(); } } else work[0] = ((Number) mapval).intValue(); if (array instanceof GeneralArray) return ((GeneralArray) array).resolve(work); else return work[0]; }
/** * Inline this ApplyExp if parameters are constant. * * @param proc the procedure bound to this.func. * @return the constant result (as a QuoteExp) if inlining was possible; otherwise this ApplyExp. * If applying proc throws an exception, print a warning on walker.messages. */ public final Expression inlineIfConstant(Procedure proc, SourceMessages messages) { int len = args.length; Object[] vals = new Object[len]; for (int i = len; --i >= 0; ) { Expression arg = args[i]; if (arg instanceof ReferenceExp) { Declaration decl = ((ReferenceExp) arg).getBinding(); if (decl != null) { arg = decl.getValue(); if (arg == QuoteExp.undefined_exp) return this; } } if (!(arg instanceof QuoteExp)) return this; vals[i] = ((QuoteExp) arg).getValue(); } try { return new QuoteExp(proc.applyN(vals), type); } catch (Throwable ex) { if (messages != null) messages.error('w', "call to " + proc + " throws " + ex); return this; } }
static void compile(ApplyExp exp, Compilation comp, Target target, boolean checkInlineable) { int args_length = exp.args.length; Expression exp_func = exp.func; LambdaExp func_lambda = null; String func_name = null; Declaration owner = null; Object quotedValue = null; if (exp_func instanceof LambdaExp) { func_lambda = (LambdaExp) exp_func; func_name = func_lambda.getName(); if (func_name == null) func_name = "<lambda>"; } else if (exp_func instanceof ReferenceExp) { ReferenceExp func_ref = (ReferenceExp) exp_func; owner = func_ref.contextDecl(); Declaration func_decl = func_ref.binding; while (func_decl != null && func_decl.isAlias() && func_decl.value instanceof ReferenceExp) { func_ref = (ReferenceExp) func_decl.value; if (owner != null || func_decl.needsContext() || func_ref.binding == null) break; func_decl = func_ref.binding; owner = func_ref.contextDecl(); } if (!func_decl.getFlag(Declaration.IS_UNKNOWN)) { Expression value = func_decl.getValue(); func_name = func_decl.getName(); if (value != null && value instanceof LambdaExp) func_lambda = (LambdaExp) value; if (value != null && value instanceof QuoteExp) quotedValue = ((QuoteExp) value).getValue(); } } else if (exp_func instanceof QuoteExp) { quotedValue = ((QuoteExp) exp_func).getValue(); } if (checkInlineable && quotedValue instanceof Procedure) { Procedure proc = (Procedure) quotedValue; if (target instanceof IgnoreTarget && proc.isSideEffectFree()) { for (int i = 0; i < args_length; i++) exp.args[i].compile(comp, target); return; } try { if (inlineCompile(proc, exp, comp, target)) return; } catch (Throwable ex) { comp.getMessages() .error('e', "caught exception in inline-compiler for " + quotedValue + " - " + ex, ex); return; } } gnu.bytecode.CodeAttr code = comp.getCode(); Method method; if (func_lambda != null) { if ((func_lambda.max_args >= 0 && args_length > func_lambda.max_args) || args_length < func_lambda.min_args) // This is supposed to get caught by InlineCalls. throw new Error("internal error - wrong number of parameters for " + func_lambda); int conv = func_lambda.getCallConvention(); // Mostly duplicates logic with LambdaExp.validateApply. // See comment there. if (comp.inlineOk(func_lambda) && (conv <= Compilation.CALL_WITH_CONSUMER || (conv == Compilation.CALL_WITH_TAILCALLS && !exp.isTailCall())) && (method = func_lambda.getMethod(args_length)) != null) { PrimProcedure pproc = new PrimProcedure(method, func_lambda); boolean is_static = method.getStaticFlag(); boolean extraArg = false; // ?? Procedure.checkArgCount(this, args.length); // FIXME if (!is_static || func_lambda.declareClosureEnv() != null) { if (is_static) extraArg = true; if (comp.curLambda == func_lambda) // Recursive call. code.emitLoad( func_lambda.closureEnv != null ? func_lambda.closureEnv : func_lambda.thisVariable); else if (owner != null) owner.load(null, 0, comp, Target.pushObject); else func_lambda.getOwningLambda().loadHeapFrame(comp); } pproc.compile(extraArg ? Type.voidType : null, exp, comp, target); return; } } /* if (comp.usingCPStyle()) { { Label l = new Label(code); gnu.bytecode.SwitchState fswitch = comp.fswitch; int pc = fswitch.getMaxValue() + 1; fswitch.addCase(pc, code, l); exp_func.compile(comp, new StackTarget(Compilation.typeProcedure)); comp.loadCallContext(); // Emit: context->pc = pc. comp.loadCallContext(); code.emitPushInt(pc); code.emitPutField(Compilation.pcCallContextField); code.emitInvokeVirtual(Compilation.applyCpsMethod); // emit[save java stack, if needed] Type[] stackTypes = code.saveStackTypeState(false); java.util.Stack stackFields = new java.util.Stack(); if (stackTypes != null) { for (int i = stackTypes.length; --i >= 0; ) { Field fld = comp.allocLocalField (stackTypes[i], null); code.emitPushThis(); code.emitSwap(); code.emitPutField(fld); stackFields.push(fld); } } code.emitReturn(); l.define(code); // emit[restore java stack, if needed] if (stackTypes != null) { for (int i = stackTypes.length; --i >= 0; ) { Field fld = (Field) stackFields.pop(); code.emitPushThis(); code.emitGetField(fld); comp.freeLocalField(fld); } } // FIXME // Load result from stack.value to target. comp.loadCallContext(); code.emitGetField(comp.valueCallContextField); target.compileFromStack(comp, Type.pointer_type); } return; } */ // Check for tail-recursion. boolean tail_recurse = exp.isTailCall() && func_lambda != null && func_lambda == comp.curLambda; if (func_lambda != null && func_lambda.getInlineOnly() && !tail_recurse && func_lambda.min_args == args_length) { pushArgs(func_lambda, exp.args, null, comp); if (func_lambda.getFlag(LambdaExp.METHODS_COMPILED)) { popParams(code, func_lambda, null, false); code.emitTailCall(false, func_lambda.getVarScope()); return; } func_lambda.flags |= LambdaExp.METHODS_COMPILED; LambdaExp saveLambda = comp.curLambda; comp.curLambda = func_lambda; func_lambda.allocChildClasses(comp); func_lambda.allocParameters(comp); popParams(code, func_lambda, null, false); func_lambda.enterFunction(comp); func_lambda.body.compileWithPosition(comp, target); func_lambda.compileEnd(comp); func_lambda.generateApplyMethods(comp); code.popScope(); comp.curLambda = saveLambda; return; } if (comp.curLambda.isHandlingTailCalls() && (exp.isTailCall() || target instanceof ConsumerTarget) && !comp.curLambda.getInlineOnly()) { ClassType typeContext = Compilation.typeCallContext; exp_func.compile(comp, new StackTarget(Compilation.typeProcedure)); // evaluate args to frame-locals vars; // may recurse! if (args_length <= 4) { for (int i = 0; i < args_length; ++i) exp.args[i].compileWithPosition(comp, Target.pushObject); comp.loadCallContext(); code.emitInvoke( Compilation.typeProcedure.getDeclaredMethod("check" + args_length, args_length + 1)); } else { compileToArray(exp.args, comp); comp.loadCallContext(); code.emitInvoke(Compilation.typeProcedure.getDeclaredMethod("checkN", 2)); } if (exp.isTailCall()) { code.emitReturn(); } else if (((ConsumerTarget) target).isContextTarget()) { comp.loadCallContext(); code.emitInvoke(typeContext.getDeclaredMethod("runUntilDone", 0)); } else { comp.loadCallContext(); code.emitLoad(((ConsumerTarget) target).getConsumerVariable()); code.emitInvoke(typeContext.getDeclaredMethod("runUntilValue", 1)); } return; } if (!tail_recurse) exp_func.compile(comp, new StackTarget(Compilation.typeProcedure)); boolean toArray = (tail_recurse ? func_lambda.min_args != func_lambda.max_args : args_length > 4); int[] incValues = null; // Increments if we can use iinc. if (toArray) { compileToArray(exp.args, comp); method = Compilation.applyNmethod; } else if (tail_recurse) { incValues = new int[exp.args.length]; pushArgs(func_lambda, exp.args, incValues, comp); method = null; } else { for (int i = 0; i < args_length; ++i) { exp.args[i].compileWithPosition(comp, Target.pushObject); if (!code.reachableHere()) break; } method = Compilation.applymethods[args_length]; } if (!code.reachableHere()) { comp.error('e', "unreachable code"); return; } if (tail_recurse) { popParams(code, func_lambda, incValues, toArray); code.emitTailCall(false, func_lambda.getVarScope()); return; } code.emitInvokeVirtual(method); target.compileFromStack(comp, Type.pointer_type); }