// p4rse, Copyright 2026, Will Hawkins
//
// This file is part of p4rse.
//
// This file is free software: you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
//
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with this program. If not, see .
import Common
import P4Lang
import P4Runtime
import SwiftTreeSitter
import TreeSitterP4
protocol CompilableExpression {
static func compile(
node: Node, withContext context: CompilerContext
) -> Result
}
extension TypedIdentifier: CompilableExpression {
static func compile(
node: SwiftTreeSitter.Node, withContext context: CompilerContext
) -> Result {
let node = node.child(at: 0)!
#SkipUnlessNodeType(
node: node, type: "identifier")
guard
case Result.Ok(let type) = context.names.lookup(
identifier: Common.Identifier(name: node.text!))
else {
return .Error(ErrorOnNode(node: node, withError: "Cannot find \(node.text!) in scope"))
}
return .Ok(TypedIdentifier(name: node.text!, withType: type))
}
}
extension P4BooleanValue: CompilableExpression {
static func compile(
node: SwiftTreeSitter.Node, withContext context: CompilerContext
) -> Result {
let node = node.child(at: 0)!
#SkipUnlessNodeType(
node: node, type: "booleanLiteralExpression")
if node.text == "false" {
return .Ok(P4BooleanValue(withValue: false))
} else if node.text == "true" {
return .Ok(P4BooleanValue(withValue: true))
}
return .Error(
ErrorOnNode(node: node, withError: "Failed to parse boolean literal: \(node.text!)"))
}
}
extension P4IntValue: CompilableExpression {
static func compile(
node: SwiftTreeSitter.Node, withContext context: CompilerContext
) -> Result {
let node = node.child(at: 0)!
#SkipUnlessNodeType(node: node, type: "integer")
if let parsed_int = Int(node.text!) {
return .Ok(P4IntValue(withValue: parsed_int))
} else {
return .Error(ErrorOnNode(node: node, withError: "Failed to parse integer: \(node.text!)"))
}
}
}
extension P4StringValue: CompilableExpression {
static func compile(
node: SwiftTreeSitter.Node, withContext scopes: CompilerContext
) -> Result {
let node = node.child(at: 0)!
#SkipUnlessNodeType(
node: node, type: "string_literal")
return .Ok(P4StringValue(withValue: node.text!))
}
}
struct Expression {
public static func Compile(
node: Node, withContext: CompilerContext
) -> Result {
#RequireNodesType(
nodes: node, type: ["expression", "keysetExpression"],
nice_type_names: ["expression", "keyset expression"])
// If the node is a keyset expression, then dig out the expression:
let node =
if node.nodeType == "keysetExpression" {
node.child(at: 0)!
} else {
node
}
let localElementsParsers: [CompilableExpression.Type] = [
P4BooleanValue.self, P4StringValue.self, P4IntValue.self, TypedIdentifier.self,
BinaryOperatorExpression.self, ArrayAccessExpression.self, FieldAccessExpression.self,
]
for le_parser in localElementsParsers {
switch le_parser.compile(
node: node, withContext: withContext)
{
case .Ok(.some(let parsed)): return .Ok(parsed)
case .Error(let e): return .Error(e)
default: continue
}
}
return Result.Error(Error(withMessage: "\(node.range): Could not parse into expression"))
}
}
struct LValue {
public static func Compile(
node: Node, withContext: CompilerContext
) -> Result {
return if let node_text_value = node.text {
.Ok(Common.Identifier(name: node_text_value))
} else {
.Error(Error(withMessage: "Could not parse an identifier for an LValue"))
}
}
}
struct Identifier {
public static func Compile(
node: Node, withContext context: CompilerContext
) -> Result {
return if let node_text_value = node.text {
.Ok(Common.Identifier(name: node_text_value))
} else {
.Error(Error(withMessage: "Could not parse an identifier from \(node)"))
}
}
}
extension SelectExpression: CompilableExpression {
static func compile(
node: Node, withContext context: CompilerContext
) -> Result {
#RequireNodeType(
node: node, type: "selectExpression", nice_type_name: "parser select expression")
guard let selector_node = node.child(at: 2),
selector_node.nodeType == "expression"
else {
return .Error(ErrorOnNode(node: node, withError: "Could not find selector expression"))
}
guard let select_body_node = node.child(at: 5),
select_body_node.nodeType == "selectBody"
else {
return .Error(ErrorOnNode(node: node, withError: "Could not find select expression body"))
}
let maybe_selector = Expression.Compile(node: selector_node, withContext: context)
guard case .Ok(let selector) = maybe_selector else {
return .Error(
Error(
withMessage:
"Could not parse transition select expression selector expression: \(maybe_selector.error()!)"
))
}
var kses: [KeysetExpression] = Array()
var kses_errors: [Error] = Array()
select_body_node.enumerateNamedChildren { current_node in
let maybe_parsed_kse = KeysetExpression.compile(
node: current_node, withContext: context)
if case .Ok(let parsed_kse) = maybe_parsed_kse {
kses.append(parsed_kse as! KeysetExpression)
} else {
kses_errors.append(Error(withMessage: "\(maybe_parsed_kse.error()!)"))
}
}
if !kses_errors.isEmpty {
return .Error(
Error(
withMessage: "Error(s) parsing select cases: "
+ (kses_errors.map { error in
return "\(error.msg)"
}.joined(separator: ";\n"))))
}
return .Ok(
SelectExpression(withSelector: selector, withKeysetExpressions: kses),
)
}
}
extension KeysetExpression: CompilableExpression {
static func compile(
node: Node, withContext context: CompilerContext
) -> Result {
if node.nodeType != "selectCase" {
return Result.Error(Error(withMessage: "Expected select case not found"))
}
guard let keysetexpression_node = node.child(at: 0),
keysetexpression_node.nodeType == "keysetExpression"
else {
return Result.Error(Error(withMessage: "Missing keyset expression in select case"))
}
guard let targetstate_node = node.child(at: 2),
targetstate_node.nodeType == "identifier"
else {
return Result.Error(Error(withMessage: "Missing target state in select case"))
}
let maybe_parsed_keysetexpression = Expression.Compile(
node: keysetexpression_node, withContext: context)
guard case Result.Ok(let keysetexpression) = maybe_parsed_keysetexpression else {
return Result.Error(maybe_parsed_keysetexpression.error()!)
}
let maybe_parsed_targetstate = Identifier.Compile(
node: targetstate_node, withContext: context)
guard case .Ok(let targetstate) = maybe_parsed_targetstate else {
return Result.Error(maybe_parsed_targetstate.error()!)
}
return .Ok(
KeysetExpression(
withKey: keysetexpression, withNextState: targetstate)
)
}
}
extension BinaryOperatorExpression: CompilableExpression {
static func compile(
node: SwiftTreeSitter.Node, withContext context: CompilerContext
) -> Result<(EvaluatableExpression)?> {
let expression = node.child(at: 0)!
#SkipUnlessNodeType(
node: expression, type: "binaryOperatorExpression")
var currentChildIdx = 0
var currentChildIdxSafe = 1
var currentChild: Node? = .none
if expression.childCount < currentChildIdxSafe {
return Result.Error(
ErrorOnNode(node: node, withError: "Malformed binary operator expression"))
}
currentChild = expression.child(at: currentChildIdx)
let binary_operator_expression_node = currentChild!
#RequireNodesType(
nodes: binary_operator_expression_node, type: ["binaryEqualOperatorExpression"],
nice_type_names: ["binary equal operator"])
if binary_operator_expression_node.childCount < currentChildIdxSafe {
return Result.Error(
ErrorOnNode(node: node, withError: "Missing LHS for binary operator expression"))
}
currentChild = binary_operator_expression_node.child(at: currentChildIdx)
let left_hand_side_raw = currentChild!
currentChildIdx = currentChildIdx + 1
currentChildIdxSafe = currentChildIdxSafe + 1
if binary_operator_expression_node.childCount < currentChildIdxSafe {
return Result.Error(
ErrorOnNode(node: node, withError: "Missing binary operator for binary operator expression")
)
}
currentChild = binary_operator_expression_node.child(at: currentChildIdx)
currentChildIdx = currentChildIdx + 1
currentChildIdxSafe = currentChildIdxSafe + 1
if binary_operator_expression_node.childCount < currentChildIdxSafe {
return Result.Error(
ErrorOnNode(node: node, withError: "Missing binary operator for binary operator expression")
)
}
currentChild = binary_operator_expression_node.child(at: currentChildIdx)
let right_hand_side_raw = currentChild!
let maybe_left_hand_side = Expression.Compile(node: left_hand_side_raw, withContext: context)
guard case Result.Ok(let left_hand_side) = maybe_left_hand_side else {
return Result.Error(maybe_left_hand_side.error()!)
}
let maybe_right_hand_side = Expression.Compile(node: right_hand_side_raw, withContext: context)
guard case Result.Ok(let right_hand_side) = maybe_right_hand_side else {
return Result.Error(maybe_right_hand_side.error()!)
}
return .Ok(
BinaryOperatorExpression(
withEvaluator: ("Binary Equal", P4Boolean(), binary_equal_operator_evaluator),
withLhs: left_hand_side, withRhs: right_hand_side))
}
}
extension ArrayAccessExpression: CompilableExpression {
static func compile(
node: SwiftTreeSitter.Node, withContext context: CompilerContext
) -> Common.Result<(any Common.EvaluatableExpression)?> {
let expression = node.child(at: 0)!
#SkipUnlessNodeType(
node: expression, type: "arrayAccessExpression")
let array_access_expression_node = expression
var currentChildIdx = 0
var currentChildIdxSafe = 1
var currentChild: Node? = .none
// What is the "name" of the array?
if array_access_expression_node.childCount < currentChildIdxSafe {
return Result.Error(
ErrorOnNode(node: node, withError: "Malformed array access expression"))
}
currentChild = expression.child(at: currentChildIdx)
#RequireNodeType(
node: currentChild!, type: "expression",
nice_type_name: "array identifier expression")
let array_access_identifier_node = currentChild!
// Check for the [
currentChildIdx = currentChildIdx + 1
currentChildIdxSafe = currentChildIdxSafe + 1
if array_access_expression_node.childCount < currentChildIdxSafe {
return Result.Error(
ErrorOnNode(node: node, withError: "Missing [ for array access expression")
)
}
// What is the indexor of the array?
currentChildIdx = currentChildIdx + 1
currentChildIdxSafe = currentChildIdxSafe + 1
if array_access_expression_node.childCount < currentChildIdxSafe {
return Result.Error(
ErrorOnNode(node: node, withError: "Missing indexor expression for array access expression")
)
}
currentChild = array_access_expression_node.child(at: currentChildIdx)
#RequireNodeType(
node: currentChild!, type: "expression",
nice_type_name: "array indexor expression")
let array_access_indexor_node = currentChild!
let maybe_array_identifier = Expression.Compile(
node: array_access_identifier_node, withContext: context)
guard case Result.Ok(let array_identifier) = maybe_array_identifier else {
return Result.Error(maybe_array_identifier.error()!)
}
let maybe_array_type = array_identifier.type()
guard let array_type = maybe_array_type as? P4Array else {
return Result.Error(
ErrorOnNode(
node: array_access_identifier_node,
withError: "\(array_identifier) does not name an array type")
)
}
let maybe_array_indexor = Expression.Compile(
node: array_access_indexor_node, withContext: context)
guard case Result.Ok(let array_indexor) = maybe_array_indexor else {
return Result.Error(maybe_array_indexor.error()!)
}
return .Ok(
ArrayAccessExpression(
withName: array_identifier, withType: array_type, withIndexor: array_indexor))
}
}
extension FieldAccessExpression: CompilableExpression {
static func compile(
node: SwiftTreeSitter.Node, withContext context: CompilerContext
) -> Common.Result<(any Common.EvaluatableExpression)?> {
let expression = node.child(at: 0)!
#SkipUnlessNodeType(
node: expression, type: "fieldAccessExpression")
let field_access_expression_node = expression
var currentChildIdx = 0
var currentChildIdxSafe = 1
var currentChild: Node? = .none
// What is the "name" of the struct?
if field_access_expression_node.childCount < currentChildIdxSafe {
return Result.Error(
ErrorOnNode(node: node, withError: "Malformed field access expression"))
}
currentChild = expression.child(at: currentChildIdx)
#RequireNodeType(
node: currentChild!, type: "expression",
nice_type_name: "struct identifier expression")
let struct_identifier_node = currentChild!
// Check for the .
currentChildIdx = currentChildIdx + 1
currentChildIdxSafe = currentChildIdxSafe + 1
if field_access_expression_node.childCount < currentChildIdxSafe {
return Result.Error(
ErrorOnNode(node: node, withError: "Missing . for field access expression")
)
}
// What is the field of the struct?
currentChildIdx = currentChildIdx + 1
currentChildIdxSafe = currentChildIdxSafe + 1
if field_access_expression_node.childCount < currentChildIdxSafe {
return Result.Error(
ErrorOnNode(node: node, withError: "Missing field name for field access expression")
)
}
currentChild = field_access_expression_node.child(at: currentChildIdx)
#RequireNodeType(
node: currentChild!, type: "identifier",
nice_type_name: "field name")
let field_name_node = currentChild!
// Make sure that the identifier really identifies a struct.
let maybe_struct_identifier = Expression.Compile(
node: struct_identifier_node, withContext: context)
guard case Result.Ok(let struct_identifier) = maybe_struct_identifier else {
return Result.Error(maybe_struct_identifier.error()!)
}
guard let struct_type = struct_identifier.type() as? P4Struct else {
return .Error(
ErrorOnNode(
node: struct_identifier_node,
withError: "\(struct_identifier_node.text!) does not have struct type"))
}
let maybe_field_name = Identifier.Compile(
node: field_name_node, withContext: context)
guard case Result.Ok(let field_name) = maybe_field_name else {
return Result.Error(maybe_field_name.error()!)
}
// Make sure that the field is valid for the struct type.
let maybe_field_type = struct_type.fields.get_field_type(field_name)
guard let field_type = maybe_field_type else {
return .Error(
ErrorOnNode(
node: field_name_node,
withError: "\(field_name) is not a valid field for struct with type \(struct_type)"))
}
return .Ok(
FieldAccessExpression(
withStruct: struct_identifier,
withField: P4StructFieldIdentifier(id: field_name, withType: field_type)))
}
}