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|
/*
Copyright 2020 Kyle Gunger
Licensed 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 texec
import (
"tparse"
"fmt"
"strconv"
"strings"
)
/*
So here's what I care to support at present:
Type checking, basic types, writing to stdout or a file
Variable and state contexts
Reading from files
Raw structs
Appending to arrays
Calling functions and methods
libtnsl stub
This subset should theoretically be enough to write a compiler.
*/
var (
// Program to run
prog *TModule
// Current artifact
cart TArtifact
//Default null value
null = TVariable{tNull, nil}
)
//################
//# Helper Funcs #
//################
// Error helper
func errOut(msg string) {
fmt.Println("==== BEGIN ERROR ====")
fmt.Println(msg)
fmt.Println(cart)
fmt.Println("==== END ERROR ====")
panic(">>> PANIC FROM EVAL <<<")
}
func errOutCTX(msg string, ctx VarMap) {
fmt.Println("==== BEGIN ERROR ====")
fmt.Println(msg)
fmt.Println(cart)
fmt.Println(ctx)
fmt.Println("==== END ERROR ====")
panic(">>> PANIC FROM EVAL <<<")
}
// Names of artifacts, finding artifacts
func getDefNames(def tparse.Node) []string {
out := []string{}
for i := 0; i < len(def.Sub); i++ {
if def.Sub[i].Data.Data == "vlist" && def.Sub[i].Data.Type == 10 {
vl := def.Sub[i]
for i := 0; i < len(vl.Sub); i++ {
if vl.Sub[i].Data.Type == tparse.DEFWORD {
out = append(out, vl.Sub[i].Data.Data)
} else if vl.Sub[i].Data.Data == "=" && vl.Sub[i].Sub[0].Data.Type == tparse.DEFWORD {
out = append(out, vl.Sub[i].Sub[0].Data.Data)
}
}
}
}
return out
}
func getBlockName(block tparse.Node) []string {
out := []string{}
for i := 0; i < len(block.Sub[0].Sub); i++ {
if block.Sub[0].Sub[i].Data.Type == tparse.DEFWORD {
out = append(out, block.Sub[0].Sub[i].Data.Data)
} else if block.Sub[0].Sub[i].Data.Data == "method" {
out = append(out, block.Sub[0].Sub[i].Sub[0].Data.Data)
} else if block.Sub[0].Sub[i].Data.Type == tparse.KEYWORD {
switch block.Sub[0].Sub[i].Data.Data {
case "if", "elif", "else", "loop", "match", "case", "default":
out = append(out, block.Sub[0].Sub[i].Data.Data)
default:
}
}
}
fmt.Println(out)
return out
}
func getTypeName(t tparse.Node) []string {
out := []string{}
for i := 0; i < len(t.Sub); i++ {
if t.Sub[i].Data.Type == tparse.DEFWORD {
out = append(out, t.Sub[i].Data.Data)
}
}
return out
}
// Get the list of names defined by the block or variable definition
func getNames(root tparse.Node) []string {
switch root.Data.Data {
case "block":
return getBlockName(root)
case "define":
return getDefNames(root)
case "raw", "struct", "enum":
return getTypeName(root)
}
return []string{}
}
// Attempt to get a module from a path starting at the given module
// Returns nil if the module was not found.
func getModuleRelative(mod *TModule, a TArtifact) *TModule {
if mod == nil {
return nil
}
for i := 0; i < len(a.Path); i++ {
for j := 0; j < len(mod.Sub); j++ {
if mod.Sub[j].Name == a.Path[i] {
mod = &(mod.Sub[j])
break
}
if j + 1 == len(mod.Sub) {
return nil
}
}
}
return mod
}
// Attempt to get a module from the root module using a specified path
// Returns nil if the module was not found.
func getModule(a TArtifact) *TModule {
return getModuleRelative(prog, a)
}
// Get a module ion the current path.
// Returns nil if the index is out of range.
func getModuleInPath(p int) *TModule {
m := len(cart.Path)
if p < 0 || p > m {
return nil
}
return getModule( TArtifact{ cart.Path[:p] , "" } )
}
// Find an artifact from a name and the module to search
// Returns nil if the node is not found in the module
func getNode(mod *TModule, n string) *tparse.Node {
for i := 0; i < len(mod.Artifacts); i++ {
chk := getNames(mod.Artifacts[i])
for j := 0; j < len(chk); j++ {
if chk[j] == n {
return &(mod.Artifacts[i])
}
}
}
return nil
}
func getDef(mod *TModule, n string) *TVariable {
ret, prs := (*mod).Defs[n]
if prs {
return ret
}
return nil
}
// This is a horrible way to search through nodes with this structure. O(n^3).
// This could (and should) be made better by using a dictionary like structure for sub-modules and artifacts.
// By sacrificing this type of tree it could probably get down to O(n^2) or even O(n) if you were good enough.
// Most probably, the following is not how it will be implemented in the final version of the compiler.
// If this wasn't a bootstrap/hoby project, I would probably fire myself for the following code.
// Yes, I am aware that the following code is bad.
// No, I don't care.
func searchNode(s TArtifact) *tparse.Node {
// i-- because we are doing a reverse lookup
for i := len(cart.Path); i >= 0; i-- { // O(n)
tst := getModuleInPath(i) // O(n^2) (O(n^3) total here)
tst = getModuleRelative(tst, s) // O(n^2) (O(n^3) total here)
if tst == nil {
continue
}
ret := getNode(tst, s.Name) // O(n^2) (O(n^3) total here)
if ret != nil {
return ret
}
} // Block total complexity 3*O(n^2) * O(n) = 3*O(n^3)
return nil
}
func searchDef(s TArtifact) *TVariable {
// i-- because of reverse lookup
for i := len(cart.Path); i >= 0; i-- {
tst := getModuleInPath(i)
tst = getModuleRelative(tst, s)
if tst == nil {
continue
}
ret := getDef(tst, s.Name)
if ret != nil {
return ret
}
}
return nil
}
// End block of complexity horror
// Type related stuff
// Checking type equality
// Assumes a is an unknown and b is also an unknown.
func equateTypePS(a, b TType, psa, psb int) bool {
if len(a.T.Path) != len(b.T.Path) || len(a.Pre) - psa != len(b.Pre) - psb {
return false
}
for i := 0; i < len(a.Pre) - psa; i++ {
if a.Pre[psa + i] != b.Pre[psb + i] {
return false
}
}
for i := 0; i < len(a.T.Path);i++ {
if a.T.Path[i] != b.T.Path[i] {
return false
}
}
if a.T.Name != b.T.Name || a.Post != b.Post {
return false
}
return true
}
func equateTypePSB(a, b TType, ps int) bool {
return equateTypePS(a, b, ps, ps)
}
// Checking type equality
// Assumes a is an unknown type and b is a known good type.
func equateTypePSO(a, b TType, ps int) bool {
return equateTypePS(a, b, ps, 0)
}
func equateType(a, b TType) bool {
return equateTypePS(a, b, 0, 0)
}
// Generate a TType from a 'type' node
func getType(t tparse.Node) TType {
out := TType{}
i := 0
// Pre
for ; i < len(t.Sub); i++ {
if t.Sub[i].Data.Type == tparse.DEFWORD || t.Sub[i].Data.Type == tparse.KEYTYPE {
break
} else {
out.Pre = append(out.Pre, t.Sub[i].Data.Data)
}
}
// T
for ; i < len(t.Sub); i++ {
if t.Sub[i].Data.Type == tparse.KEYTYPE {
out.T.Name = t.Sub[i].Data.Data
i++
break
} else if t.Sub[i].Data.Type == tparse.DEFWORD {
if i < len(t.Sub) - 1 {
if t.Sub[i + 1].Data.Type == tparse.DEFWORD {
out.T.Path = append(out.T.Path, t.Sub[i].Data.Data)
} else {
out.T.Name = t.Sub[i].Data.Data
break
}
} else {
out.T.Name = t.Sub[i].Data.Data
}
}
}
// Post
if i < len(t.Sub) {
if t.Sub[i].Data.Data == "`" {
out.Post = "`"
}
}
return out
}
// Value generation
func getStringLiteral(v tparse.Node) []byte {
str, err := strconv.Unquote(v.Data.Data)
if err != nil {
errOut(fmt.Sprintf("Failed to parse string literal %v", v.Data))
}
return []byte(str)
}
func getCharLiteral(v tparse.Node) byte {
val, mb, _, err := strconv.UnquoteChar(v.Data.Data, byte('\''))
if err != nil || mb == true{
errOut(fmt.Sprintf("Failed to parse character as single byte. %v", v.Data))
}
return byte(val)
}
func getIntLiteral(v tparse.Node) int {
i, err := strconv.ParseInt(v.Data.Data, 0, 64)
if err != nil {
errOut(fmt.Sprintf("Failed to parse integer literal. %v", v.Data))
}
return int(i)
}
func getLiteralComposite(v tparse.Node) []interface{} {
out := []interface{}{}
for i := 0; i < len(v.Sub); i++ {
if v.Sub[i].Data.Data[0] == '"' {
out = append(out, getStringLiteral(v.Sub[i]))
} else if v.Sub[i].Data.Data[0] == '\'' {
out = append(out, getCharLiteral(v.Sub[i]))
} else if v.Sub[i].Data.Data == "comp" {
out = append(out, getLiteralComposite(v.Sub[i]))
} else {
out = append(out, getIntLiteral(v.Sub[i]))
}
}
return out
}
func getBoolLiteral(v tparse.Node) bool {
return v.Data.Data == "true"
}
func getLiteral(v tparse.Node, t TType) interface{} {
if equateType(t, tInt) {
return getIntLiteral(v)
} else if equateType(t, tCharp) {
return getCharLiteral(v)
} else if equateType(t, tString) {
return getStringLiteral(v)
} else if equateType(t, tBool) {
getBoolLiteral(v)
}
return getLiteralComposite(v)
}
func getLiteralType(v tparse.Node) TType {
if v.Data.Data[0] == '"' {
return tString
} else if v.Data.Data[0] == '\'' {
return tCharp
} else if v.Data.Data == "comp" {
return tStruct
} else if v.Data.Data == "true" || v.Data.Data == "false" {
return tBool
} else {
return tInt
}
return tNull
}
// Convert Value to Struct from Array (cvsa)
// USE ONLY IN THE CASE OF tStruct!
func cvsa(str TType, skip int, dat []interface{}) VarMap {
sv := searchDef(str)
vars := sv.Data.([]TVariable)
if len(vars) != len(cmp) {
return nil
}
out := make(VarMap)
for i:=0;i<len(vars);i++ {
if isStruct(vars[i].Type) {
} else if isArray(vars) {
}
}
return out
}
// Copy Struct To Struct (csts)
func csts(str TType, skp int, dat VarMap) VarMap {
}
// Copy Array To Array (cata)
func cata(str TType, skp int, dat []interface{}) {
}
func convertValPS(from, to TType, sk int, dat interface{}) interface{} {
if equateTypePS(from, tStruct, sk) {
if isStruct(to, sk) {
return cvsa(to, sk)
} else if isArray(to, sk) {
}
} else if isArray(from, sk) {
if isArray(to, sk) {
out := []interface{}
for i := 0; i < len(dat.([]interface{}));i++ {
out = append(out, convertValPS(from, to, sk + 1, dat.([]interface{})[i]))
}
}
} else if equateTypePS(from, tInt, sk) {
if equateTypePS(to, tInt, sk) {
return dat.(int)
} else if equateTypePS(to, tCharp, sk) {
return dat.(byte)
}
}
errOut(fmt.Sprintf("Unable to convert between two types.\nFR: %v\nTO: %v\nSK: %d\nDT: %v", from, to, sk, dat))
return nil
}
func convertVal(from, to TType, dat interface{}) interface{} {
return convertValPS(from, to, 0, dat)
}
//#####################
//# Finding Artifacts #
//#####################
func resolveArtifactCall(a TArtifact, params []TVariable) TVariable {
tres := tnslResolve(a)
if tres == 0 {
if len(params) > 0 {
return tnslEval(params[0], a.Name)
} else {
errOut("Need at least one arg to call tnsl.io func")
}
} else if tres == 1 {
if len(params) > 1 {
return tnslFileEval(params[0], params[1], a.Name)
} else {
errOut("Not enough args recieved to call tnsl.io.File method.")
}
}
return null
}
func resolveArtifact(a TArtifact, ctx *VarMap) *TVariable {
if len(a.Path) == 0 {
val, prs := (*ctx)[a.Name]
if !prs {
errOutCTX(fmt.Sprintf("Could not resolve %s in the current context.", a.Name), *ctx)
}
return val
}
return nil
}
//#################
//# Runtime funcs #
//#################
// Value statement parsing
func isStruct(t TType, skp int) bool {
ch := false
ch = ch || isPointer(t, skp)
ch = ch || isArray(t, skp)
ch = ch || equateTypePS(t, tFile, skp)
ch = ch || equateTypePS(t, tInt, skp)
ch = ch || equateTypePS(t, tByte, skp)
ch = ch || equateTypePS(t, tFloat, skp)
ch = ch || equateTypePS(t, tCharp, skp)
ch = ch || equateTypePS(t, tBool, skp)
ch = ch || equateTypePS(t, tNull, skp)
return !ch
}
func isPointer(t TType, skp int) bool {
for ;skp < len(t.Pre) && t.Pre[skp] == "const"; skp++ {}
if len(t.Pre) >= skp {
return false
}
return t.Pre[skp] == "~"
}
func isArray(t TType, skp int) bool {
for ;skp < len(t.Pre) && t.Pre[skp] == "const"; skp++ {}
if len(t.Pre) >= skp {
return false
}
return t.Pre[skp] == "{}"
}
func evalDotChain(v tparse.Node, ctx *VarMap, wk *TVariable) *TVariable {
var wrvm *VarMap
wrvm = ctx
if isStruct((*wk).Type, 0) {
wrvm = (*wk).Data.(*VarMap)
}
// Check if current name relates to a variable in context or working var
dat, prs := (*wrvm)[v.Sub[0].Data.Data]
if prs {
return evalDotChain(v.Sub[1], ctx, dat)
}
//
return &null
}
func evalSet(v tparse.Node, ctx *VarMap, val TVariable) {
}
// Parse a value node
func evalValue(v tparse.Node, ctx *VarMap) TVariable {
if v.Data.Type == tparse.LITERAL {
if v.Data.Data[0] == '"' {
return TVariable{tString, getStringLiteral(v)}
} else if v.Data.Data[0] == '\'' {
return TVariable{tCharp, getCharLiteral(v)}
} else if v.Data.Data == "comp" {
return TVariable{tStruct, getLiteralComposite(v)}
} else {
return TVariable{tInt, getIntLiteral(v)}
}
} else if v.Data.Type == tparse.DEFWORD {
} else if v.Data.Type == tparse.AUGMENT {
switch v.Data.Data {
case "=":
rval := evalValue(v.Sub[1], ctx)
evalSet(v.Sub[0], ctx, rval)
return rval
case "+":
a := evalValue(v.Sub[0], ctx)
b := evalValue(v.Sub[1], ctx)
return TVariable{tInt, a.Data.(int) + b.Data.(int)}
case "-":
a := evalValue(v.Sub[0], ctx)
b := evalValue(v.Sub[1], ctx)
return TVariable{tInt, a.Data.(int) - b.Data.(int)}
case "*":
a := evalValue(v.Sub[0], ctx)
b := evalValue(v.Sub[1], ctx)
return TVariable{tInt, a.Data.(int) * b.Data.(int)}
case "/":
a := evalValue(v.Sub[0], ctx)
b := evalValue(v.Sub[1], ctx)
return TVariable{tInt, a.Data.(int) / b.Data.(int)}
case "%":
a := evalValue(v.Sub[0], ctx)
b := evalValue(v.Sub[1], ctx)
return TVariable{tInt, a.Data.(int) % b.Data.(int)}
case "&&":
a := evalValue(v.Sub[0], ctx)
b := evalValue(v.Sub[1], ctx)
return TVariable{tBool, a.Data.(bool) && b.Data.(bool)}
case "||":
a := evalValue(v.Sub[0], ctx)
b := evalValue(v.Sub[1], ctx)
return TVariable{tInt, a.Data.(bool) || b.Data.(bool)}
case "==":
a := evalValue(v.Sub[0], ctx)
b := evalValue(v.Sub[1], ctx)
if equateType(a.Type, b.Type) {
return TVariable{tBool, a.Data == b.Data}
}
return TVariable{tBool, a.Data.(int) == b.Data.(int)}
case "!":
a := evalValue(v.Sub[0], ctx)
return TVariable{tBool, !(a.Data.(bool))}
case ".":
return *evalDotChain(v, ctx, &null)
}
}
return null
}
// Generate a value for a definition
func evalDefVal(v tparse.Node, ctx *VarMap) {
}
// Eval a definition
func evalDef(v tparse.Node, ctx *VarMap) {
}
// Eval a control flow
func evalCF(v tparse.Node, ctx *VarMap) (bool, TVariable) {
//scopeVars := []string{}
return false, null
}
func evalBlock(b tparse.Node, params []TVariable) TVariable {
ctx := make(VarMap)
for i := 0; i < len(b.Sub); i++ {
switch b.Sub[i].Data.Data {
case "define":
evalDef(b.Sub[i], &ctx)
case "value":
evalValue(b.Sub[i], &ctx)
case "block":
ret, val := evalCF(b.Sub[i], &ctx)
if ret {
return val
}
case "return":
return evalValue(b.Sub[i].Sub[0], &ctx)
}
}
return null
}
func EvalTNSL(root *TModule, args string) TVariable {
prog = root
cart = TArtifact { []string{}, "main" }
sarg := strings.Split(args, " ")
targ := TVariable {
TType {
[]string{"{}", "{}"},
TArtifact { []string{}, "charp" },
"" },
sarg }
mainNod := getNode(prog, "main")
fmt.Println(mainNod)
return evalBlock(*mainNod, []TVariable{targ})
}
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