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chore: import upstream snapshot with attribution
2026-07-13 12:31:17 +08:00

422 lines
13 KiB
Go

/*
* # Licensed to the LF AI & Data foundation under one
* # or more contributor license agreements. See the NOTICE file
* # distributed with this work for additional information
* # regarding copyright ownership. The ASF licenses this file
* # to you under the Apache License, Version 2.0 (the
* # "License"); you may not use this file except in compliance
* # with the License. You may obtain a copy of the License at
* #
* # http://www.apache.org/licenses/LICENSE-2.0
* #
* # Unless required by applicable law or agreed to in writing, software
* # distributed under the License is distributed on an "AS IS" BASIS,
* # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* # See the License for the specific language governing permissions and
* # limitations under the License.
*/
package chain
import (
"strings"
"github.com/apache/arrow/go/v17/arrow/memory"
"github.com/milvus-io/milvus-proto/go-api/v3/schemapb"
"github.com/milvus-io/milvus/internal/util/function/chain/types"
"github.com/milvus-io/milvus/pkg/v3/util/merr"
)
// ChainRepr is the internal representation of a FuncChain.
type ChainRepr struct {
Name string
Stage string
Operators []OperatorRepr
Info ChainReprInfo
}
// OperatorRepr is the internal representation of an Operator.
type OperatorRepr struct {
Type string
Params map[string]*schemapb.FunctionParamValue
Function *FunctionRepr // for map/filter operators that evaluate an expression
Inputs []string // input column names
Outputs []string // output column names
}
// FunctionRepr is the internal representation of a FunctionExpr.
type FunctionRepr struct {
Name string
Params map[string]*schemapb.FunctionParamValue
Args []*schemapb.FunctionChainExprArg
}
// ChainReprInfo contains context-independent structural information derived from a ChainRepr.
// RequiredInputs are names read before any previous op produces them. Callers decide
// whether those names are schema fields, request payload fields, or runtime/system values.
type ChainReprInfo struct {
RequiredInputs []string
WrittenNames []string
Ops []OperatorReprInfo
}
// OperatorReprInfo contains normalized input/output information for one operator.
type OperatorReprInfo struct {
Type string
ReadNames []string
WriteNames []string
}
// ParseFuncChainProto creates a FuncChain from the public FunctionChain proto.
// It uses an empty FunctionBuildContext. Use FuncChainFromReprWithContext when
// constructing functions that require runtime-only context, such as model rerank.
func ParseFuncChainProto(pb *schemapb.FunctionChain, alloc memory.Allocator) (*FuncChain, error) {
repr, err := ProtoChainToRepr(pb)
if err != nil {
return nil, err
}
return funcChainFromRepr(repr, alloc, types.FunctionBuildContext{})
}
// ProtoChainToRepr converts the public FunctionChain proto to the internal representation.
func ProtoChainToRepr(pb *schemapb.FunctionChain) (*ChainRepr, error) {
if pb == nil {
return nil, merr.WrapErrParameterInvalidMsg("function chain proto is nil")
}
stage, err := ProtoStageToReprStage(pb.GetStage())
if err != nil {
return nil, err
}
repr := &ChainRepr{
Name: pb.GetName(),
Stage: stage,
Operators: make([]OperatorRepr, 0, len(pb.GetOps())),
}
for i, opPB := range pb.GetOps() {
opRepr, err := ProtoOpToRepr(opPB)
if err != nil {
return nil, merr.WrapErrParameterInvalidMsg("op[%d]: %v", i, err)
}
repr.Operators = append(repr.Operators, *opRepr)
}
if err := repr.RefreshInfo(); err != nil {
return nil, err
}
return repr, nil
}
// ProtoOpToRepr converts a public FunctionChainOp proto to the internal operator representation.
func ProtoOpToRepr(pb *schemapb.FunctionChainOp) (*OperatorRepr, error) {
if pb == nil {
return nil, merr.WrapErrParameterInvalidMsg("op proto is nil")
}
opType := strings.TrimSpace(pb.GetOp())
if opType == "" {
return nil, merr.WrapErrParameterInvalidMsg("op name is empty")
}
inputs, err := normalizeReprNames(pb.GetInputs(), "input")
if err != nil {
return nil, err
}
outputs, err := normalizeReprNames(pb.GetOutputs(), "output")
if err != nil {
return nil, err
}
repr := &OperatorRepr{
Type: opType,
Params: pb.GetParams(),
Inputs: inputs,
Outputs: outputs,
}
if pb.GetExpr() != nil {
expr, exprInputs, err := ProtoExprToRepr(pb.GetExpr())
if err != nil {
return nil, err
}
repr.Function = expr
repr.Inputs = exprInputs
}
return repr, nil
}
// ProtoExprToRepr converts a public FunctionChainExpr proto to the internal function representation.
// It also returns the column references in expr args, preserving first-seen order.
func ProtoExprToRepr(pb *schemapb.FunctionChainExpr) (*FunctionRepr, []string, error) {
if pb == nil {
return nil, nil, nil
}
name := strings.TrimSpace(pb.GetName())
if name == "" {
return nil, nil, merr.WrapErrParameterInvalidMsg("expr name is empty")
}
inputs, err := ProtoExprArgsToInputs(pb.GetArgs())
if err != nil {
return nil, nil, err
}
return &FunctionRepr{
Name: name,
Params: pb.GetParams(),
Args: pb.GetArgs(),
}, inputs, nil
}
// ProtoExprArgsToInputs extracts column references from public FunctionChainExpr args.
func ProtoExprArgsToInputs(args []*schemapb.FunctionChainExprArg) ([]string, error) {
inputs := make([]string, 0, len(args))
seenInputs := make(map[string]struct{})
for i, arg := range args {
input, err := FunctionChainExprArgInput(arg)
if err != nil {
return nil, merr.WrapErrParameterInvalidMsg("expr arg[%d]: %v", i, err)
}
if input == "" {
continue
}
if _, ok := seenInputs[input]; ok {
continue
}
seenInputs[input] = struct{}{}
inputs = append(inputs, input)
}
return inputs, nil
}
// FunctionChainExprArgInput extracts the input column name from an arg, if it is a column reference.
func FunctionChainExprArgInput(arg *schemapb.FunctionChainExprArg) (string, error) {
if arg == nil {
return "", merr.WrapErrParameterInvalidMsg("function chain expr arg is nil")
}
switch v := arg.GetArg().(type) {
case *schemapb.FunctionChainExprArg_Column:
name := strings.TrimSpace(v.Column.GetName())
if name == "" {
return "", merr.WrapErrParameterInvalidMsg("column name is empty")
}
return name, nil
case *schemapb.FunctionChainExprArg_Literal:
if v.Literal == nil {
return "", merr.WrapErrParameterInvalidMsg("literal: function param value is nil")
}
return "", nil
default:
return "", merr.WrapErrParameterInvalidMsg("function chain expr arg is unset")
}
}
// ProtoStageToReprStage converts public FunctionChainStage enum to chain runtime stage string.
func ProtoStageToReprStage(stage schemapb.FunctionChainStage) (string, error) {
switch stage {
case schemapb.FunctionChainStage_FunctionChainStageIngestion:
return types.StageIngestion, nil
case schemapb.FunctionChainStage_FunctionChainStagePreProcess:
return types.StagePreProcess, nil
case schemapb.FunctionChainStage_FunctionChainStageL0Rerank:
return types.StageL0Rerank, nil
case schemapb.FunctionChainStage_FunctionChainStageL1Rerank:
return types.StageL1Rerank, nil
case schemapb.FunctionChainStage_FunctionChainStageL2Rerank:
return types.StageL2Rerank, nil
case schemapb.FunctionChainStage_FunctionChainStagePostProcess:
return types.StagePostProcess, nil
default:
return "", merr.WrapErrParameterInvalidMsg("unsupported function chain stage: %s", stage.String())
}
}
// RefreshInfo rebuilds context-independent dependency information from a ChainRepr.
// It does not classify names as schema fields, payload fields, or system variables.
func (repr *ChainRepr) RefreshInfo() error {
if repr == nil {
return nil
}
info := ChainReprInfo{
RequiredInputs: make([]string, 0),
WrittenNames: make([]string, 0),
Ops: make([]OperatorReprInfo, 0, len(repr.Operators)),
}
produced := make(map[string]struct{})
seenRequiredInputs := make(map[string]struct{})
seenWrittenNames := make(map[string]struct{})
for i, op := range repr.Operators {
opType := strings.TrimSpace(op.Type)
if opType == "" {
return merr.WrapErrParameterInvalidMsg("op[%d] name is empty", i)
}
inputs, err := normalizeReprNames(op.Inputs, "input")
if err != nil {
return merr.WrapErrParameterInvalidMsg("op[%d]: %v", i, err)
}
outputs, err := normalizeReprNames(op.Outputs, "output")
if err != nil {
return merr.WrapErrParameterInvalidMsg("op[%d]: %v", i, err)
}
repr.Operators[i].Type = opType
repr.Operators[i].Inputs = inputs
repr.Operators[i].Outputs = outputs
info.Ops = append(info.Ops, OperatorReprInfo{
Type: opType,
ReadNames: append([]string(nil), inputs...),
WriteNames: append([]string(nil), outputs...),
})
for _, input := range inputs {
if _, ok := produced[input]; ok {
continue
}
if _, ok := seenRequiredInputs[input]; !ok {
seenRequiredInputs[input] = struct{}{}
info.RequiredInputs = append(info.RequiredInputs, input)
}
}
for _, output := range outputs {
produced[output] = struct{}{}
if _, ok := seenWrittenNames[output]; !ok {
seenWrittenNames[output] = struct{}{}
info.WrittenNames = append(info.WrittenNames, output)
}
}
}
repr.Info = info
return nil
}
// FuncChainFromRepr creates a FuncChain from a ChainRepr.
// Stage is required and validates that all functions support the stage.
// alloc must not be nil.
// It uses an empty FunctionBuildContext. Use FuncChainFromReprWithContext when
// constructing functions that require runtime-only context, such as model rerank.
func FuncChainFromRepr(repr *ChainRepr, alloc memory.Allocator) (*FuncChain, error) {
return funcChainFromRepr(repr, alloc, types.FunctionBuildContext{})
}
// FuncChainFromReprWithContext creates a FuncChain from a ChainRepr with runtime-only context.
func FuncChainFromReprWithContext(repr *ChainRepr, alloc memory.Allocator, buildCtx types.FunctionBuildContext) (*FuncChain, error) {
return funcChainFromRepr(repr, alloc, buildCtx)
}
// funcChainFromRepr creates a FuncChain from a ChainRepr.
func funcChainFromRepr(repr *ChainRepr, alloc memory.Allocator, buildCtx types.FunctionBuildContext) (*FuncChain, error) {
if alloc == nil {
return nil, merr.WrapErrServiceInternal("alloc is nil")
}
if repr.Stage == "" {
return nil, merr.WrapErrParameterMissingMsg("stage is required")
}
chain := NewFuncChainWithAllocator(alloc)
if repr.Name != "" {
chain.SetName(repr.Name)
}
chain.SetStage(repr.Stage)
for i, opRepr := range repr.Operators {
op, err := operatorFromReprWithContext(&opRepr, buildCtx)
if err != nil {
return nil, merr.WrapErrServiceInternalMsg("operator[%d]: %v", i, err)
}
chain.Add(op)
}
// Validate the chain (including stage compatibility)
if err := chain.Validate(); err != nil {
return nil, err
}
return chain, nil
}
// operatorFromRepr creates an Operator from an OperatorRepr.
func operatorFromRepr(repr *OperatorRepr) (Operator, error) {
return operatorFromReprWithContext(repr, types.FunctionBuildContext{})
}
func operatorFromReprWithContext(repr *OperatorRepr, buildCtx types.FunctionBuildContext) (Operator, error) {
switch repr.Type {
case types.OpTypeMap:
return NewMapOpFromReprWithContext(repr, buildCtx)
case types.OpTypeFilter:
return NewFilterOpFromReprWithContext(repr, buildCtx)
}
factory, ok := GetOperatorFactory(repr.Type)
if !ok {
return nil, merr.WrapErrParameterInvalidMsg("unknown operator type: %s", repr.Type)
}
return factory(repr)
}
// FunctionFromRepr creates a FunctionExpr from a FunctionRepr.
// It uses an empty FunctionBuildContext. Use FunctionFromReprWithContext when
// constructing functions that require runtime-only context, such as model rerank.
func FunctionFromRepr(repr *FunctionRepr) (types.FunctionExpr, error) {
return FunctionFromReprWithContext(repr, types.FunctionBuildContext{})
}
// FunctionFromReprWithContext creates a FunctionExpr from a FunctionRepr and build context.
func FunctionFromReprWithContext(repr *FunctionRepr, buildCtx types.FunctionBuildContext) (types.FunctionExpr, error) {
if repr == nil {
return nil, merr.WrapErrParameterInvalidMsg("function repr is nil")
}
if repr.Name == "" {
return nil, merr.WrapErrParameterMissingMsg("function name is required")
}
fn, err := types.CreateFunction(buildCtx, types.FunctionConfig{
Name: repr.Name,
Params: repr.Params,
Args: repr.Args,
})
if err != nil {
return nil, err
}
if validator, ok := fn.(types.FunctionArgValidator); ok {
if err := validator.ValidateArgs(repr.Args); err != nil {
return nil, err
}
}
return fn, nil
}
func normalizeReprNames(names []string, label string) ([]string, error) {
result := make([]string, 0, len(names))
for _, name := range names {
name = strings.TrimSpace(name)
if name == "" {
return nil, merr.WrapErrParameterInvalidMsg("%s name is empty", label)
}
result = append(result, name)
}
return result, nil
}
// IsFunctionChainSystemName reports whether name uses the function-chain system-name prefix.
// It does not validate whether the current caller or stage may provide that name.
func IsFunctionChainSystemName(name string) bool {
return strings.HasPrefix(name, "$")
}