neo-go/cli/cmdargs/parser.go
Roman Khimov 50c8805034 *: drop legacy addresses from examples
They can't even be used now because they'll fail the conversion.

Signed-off-by: Roman Khimov <roman@nspcc.ru>
2023-06-29 11:56:26 +03:00

350 lines
14 KiB
Go

package cmdargs
import (
"errors"
"fmt"
"strings"
"github.com/nspcc-dev/neo-go/cli/flags"
"github.com/nspcc-dev/neo-go/pkg/core/transaction"
"github.com/nspcc-dev/neo-go/pkg/crypto/keys"
"github.com/nspcc-dev/neo-go/pkg/encoding/address"
"github.com/nspcc-dev/neo-go/pkg/rpcclient/actor"
"github.com/nspcc-dev/neo-go/pkg/smartcontract"
"github.com/nspcc-dev/neo-go/pkg/wallet"
"github.com/urfave/cli"
)
const (
// CosignersSeparator marks the start of cosigners cli args.
CosignersSeparator = "--"
// ArrayStartSeparator marks the start of array cli arg.
ArrayStartSeparator = "["
// ArrayEndSeparator marks the end of array cli arg.
ArrayEndSeparator = "]"
)
const (
// ParamsParsingDoc is a documentation for parameters parsing.
ParamsParsingDoc = ` Arguments always do have regular Neo smart contract parameter types, either
specified explicitly or being inferred from the value. To specify the type
manually use "type:value" syntax where the type is one of the following:
'signature', 'bool', 'int', 'hash160', 'hash256', 'bytes', 'key' or 'string'.
Array types are also supported: use special space-separated '[' and ']'
symbols around array values to denote array bounds. Nested arrays are also
supported. Null parameter is supported via 'nil' keyword without additional
type specification.
There is ability to provide an argument of 'bytearray' type via file. Use a
special 'filebytes' argument type for this with a filepath specified after
the colon, e.g. 'filebytes:my_file.txt'.
Given values are type-checked against given types with the following
restrictions applied:
* 'signature' type values should be hex-encoded and have a (decoded)
length of 64 bytes.
* 'bool' type values are 'true' and 'false'.
* 'int' values are decimal integers that can be successfully converted
from the string.
* 'hash160' values are Neo addresses and hex-encoded 20-bytes long (after
decoding) strings.
* 'hash256' type values should be hex-encoded and have a (decoded)
length of 32 bytes.
* 'bytes' type values are any hex-encoded things.
* 'filebytes' type values are filenames with the argument value inside.
* 'key' type values are hex-encoded marshalled public keys.
* 'string' type values are any valid UTF-8 strings. In the value's part of
the string the colon looses it's special meaning as a separator between
type and value and is taken literally.
If no type is explicitly specified, it is inferred from the value using the
following logic:
- anything that can be interpreted as a decimal integer gets
an 'int' type
- 'nil' string gets 'Any' NEP-14 parameter type and nil value which corresponds
to Null stackitem
- 'true' and 'false' strings get 'bool' type
- valid Neo addresses and 20 bytes long hex-encoded strings get 'hash160'
type
- valid hex-encoded public keys get 'key' type
- 32 bytes long hex-encoded values get 'hash256' type
- 64 bytes long hex-encoded values get 'signature' type
- any other valid hex-encoded values get 'bytes' type
- anything else is a 'string'
Backslash character is used as an escape character and allows to use colon in
an implicitly typed string. For any other characters it has no special
meaning, to get a literal backslash in the string use the '\\' sequence.
Examples:
* 'int:42' is an integer with a value of 42
* '42' is an integer with a value of 42
* 'nil' is a parameter with Any NEP-14 type and nil value (corresponds to Null stackitem)
* 'bad' is a string with a value of 'bad'
* 'dead' is a byte array with a value of 'dead'
* 'string:dead' is a string with a value of 'dead'
* 'filebytes:my_data.txt' is bytes decoded from a content of my_data.txt
* 'NSiVJYZej4XsxG5CUpdwn7VRQk8iiiDMPM' is a hash160 with a value
of '682cca3ebdc66210e5847d7f8115846586079d4a'
* '\4\2' is an integer with a value of 42
* '\\4\2' is a string with a value of '\42'
* 'string:string' is a string with a value of 'string'
* 'string\:string' is a string with a value of 'string:string'
* '03b209fd4f53a7170ea4444e0cb0a6bb6a53c2bd016926989cf85f9b0fba17a70c' is a
key with a value of '03b209fd4f53a7170ea4444e0cb0a6bb6a53c2bd016926989cf85f9b0fba17a70c'
* '[ a b c ]' is an array with strings values 'a', 'b' and 'c'
* '[ a b [ c d ] e ]' is an array with 4 values: string 'a', string 'b',
array of two strings 'c' and 'd', string 'e'
* '[ ]' is an empty array`
// SignersParsingDoc is a documentation for signers parsing.
SignersParsingDoc = ` Signers represent a set of Uint160 hashes with witness scopes and are used
to verify hashes in System.Runtime.CheckWitness syscall. First signer is treated
as a sender. To specify signers use signer[:scope] syntax where
* 'signer' is a signer's address (as Neo address or hex-encoded 160 bit (20 byte)
LE value with or without '0x' prefix).
* 'scope' is a comma-separated set of cosigner's scopes, which could be:
- 'None' - default witness scope which may be used for the sender
to only pay fee for the transaction.
- 'Global' - allows this witness in all contexts. This cannot be combined
with other flags.
- 'CalledByEntry' - means that this condition must hold: EntryScriptHash
== CallingScriptHash. The witness/permission/signature
given on first invocation will automatically expire if
entering deeper internal invokes. This can be default
safe choice for native NEO/GAS.
- 'CustomContracts' - define valid custom contract hashes for witness check.
Hashes are be provided as hex-encoded LE value string.
At lest one hash must be provided. Multiple hashes
are separated by ':'.
- 'CustomGroups' - define custom public keys for group members. Public keys are
provided as short-form (1-byte prefix + 32 bytes) hex-encoded
values. At least one key must be provided. Multiple keys
are separated by ':'.
If no scopes were specified, 'CalledByEntry' used as default. If no signers were
specified, no array is passed. Note that scopes are properly handled by
neo-go RPC server only. C# implementation does not support scopes capability.
Examples:
* 'NNQk4QXsxvsrr3GSozoWBUxEmfag7B6hz5'
* 'NVquyZHoPirw6zAEPvY1ZezxM493zMWQqs:Global'
* '0x0000000009070e030d0f0e020d0c06050e030c02'
* '0000000009070e030d0f0e020d0c06050e030c02:CalledByEntry,` +
`CustomGroups:0206d7495ceb34c197093b5fc1cccf1996ada05e69ef67e765462a7f5d88ee14d0'
* '0000000009070e030d0f0e020d0c06050e030c02:CalledByEntry,` +
`CustomContracts:1011120009070e030d0f0e020d0c06050e030c02:0x1211100009070e030d0f0e020d0c06050e030c02'`
)
// GetSignersFromContext returns signers parsed from context args starting
// from the specified offset.
func GetSignersFromContext(ctx *cli.Context, offset int) ([]transaction.Signer, *cli.ExitError) {
args := ctx.Args()
var (
signers []transaction.Signer
err error
)
if args.Present() && len(args) > offset {
signers, err = ParseSigners(args[offset:])
if err != nil {
return nil, cli.NewExitError(err, 1)
}
}
return signers, nil
}
// ParseSigners returns array of signers parsed from their string representation.
func ParseSigners(args []string) ([]transaction.Signer, error) {
var signers []transaction.Signer
for i, c := range args {
cosigner, err := parseCosigner(c)
if err != nil {
return nil, fmt.Errorf("failed to parse signer #%d: %w", i, err)
}
signers = append(signers, cosigner)
}
return signers, nil
}
func parseCosigner(c string) (transaction.Signer, error) {
var (
err error
res = transaction.Signer{
Scopes: transaction.CalledByEntry,
}
)
data := strings.SplitN(c, ":", 2)
s := data[0]
res.Account, err = flags.ParseAddress(s)
if err != nil {
return res, err
}
if len(data) == 1 {
return res, nil
}
res.Scopes = 0
scopes := strings.Split(data[1], ",")
for _, s := range scopes {
sub := strings.Split(s, ":")
scope, err := transaction.ScopesFromString(sub[0])
if err != nil {
return transaction.Signer{}, err
}
if scope == transaction.Global && res.Scopes&^transaction.Global != 0 ||
scope != transaction.Global && res.Scopes&transaction.Global != 0 {
return transaction.Signer{}, errors.New("Global scope can not be combined with other scopes")
}
res.Scopes |= scope
switch scope {
case transaction.CustomContracts:
if len(sub) == 1 {
return transaction.Signer{}, errors.New("CustomContracts scope must refer to at least one contract")
}
for _, s := range sub[1:] {
addr, err := flags.ParseAddress(s)
if err != nil {
return transaction.Signer{}, err
}
res.AllowedContracts = append(res.AllowedContracts, addr)
}
case transaction.CustomGroups:
if len(sub) == 1 {
return transaction.Signer{}, errors.New("CustomGroups scope must refer to at least one group")
}
for _, s := range sub[1:] {
pub, err := keys.NewPublicKeyFromString(s)
if err != nil {
return transaction.Signer{}, err
}
res.AllowedGroups = append(res.AllowedGroups, pub)
}
}
}
return res, nil
}
// GetDataFromContext returns data parameter from context args.
func GetDataFromContext(ctx *cli.Context) (int, interface{}, *cli.ExitError) {
var (
data interface{}
offset int
params []smartcontract.Parameter
err error
)
args := ctx.Args()
if args.Present() {
offset, params, err = ParseParams(args, true)
if err != nil {
return offset, nil, cli.NewExitError(fmt.Errorf("unable to parse 'data' parameter: %w", err), 1)
}
if len(params) > 1 {
return offset, nil, cli.NewExitError("'data' should be represented as a single parameter", 1)
}
if len(params) != 0 {
data, err = smartcontract.ExpandParameterToEmitable(params[0])
if err != nil {
return offset, nil, cli.NewExitError(fmt.Sprintf("failed to convert 'data' to emitable type: %s", err.Error()), 1)
}
}
}
return offset, data, nil
}
// EnsureNone returns an error if there are any positional arguments present.
// It can be used to check for them in commands that don't accept arguments.
func EnsureNone(ctx *cli.Context) *cli.ExitError {
if ctx.Args().Present() {
return cli.NewExitError("additional arguments given while this command expects none", 1)
}
return nil
}
// ParseParams extracts array of smartcontract.Parameter from the given args and
// returns the number of handled words, the array itself and an error.
// `calledFromMain` denotes whether the method was called from the outside or
// recursively and used to check if CosignersSeparator and ArrayEndSeparator are
// allowed to be in `args` sequence.
func ParseParams(args []string, calledFromMain bool) (int, []smartcontract.Parameter, error) {
res := []smartcontract.Parameter{}
for k := 0; k < len(args); {
s := args[k]
switch s {
case CosignersSeparator:
if calledFromMain {
return k + 1, res, nil // `1` to convert index to numWordsRead
}
return 0, []smartcontract.Parameter{}, errors.New("invalid array syntax: missing closing bracket")
case ArrayStartSeparator:
numWordsRead, array, err := ParseParams(args[k+1:], false)
if err != nil {
return 0, nil, fmt.Errorf("failed to parse array: %w", err)
}
res = append(res, smartcontract.Parameter{
Type: smartcontract.ArrayType,
Value: array,
})
k += 1 + numWordsRead // `1` for opening bracket
case ArrayEndSeparator:
if calledFromMain {
return 0, nil, errors.New("invalid array syntax: missing opening bracket")
}
return k + 1, res, nil // `1`to convert index to numWordsRead
default:
param, err := smartcontract.NewParameterFromString(s)
if err != nil {
// '--' argument is skipped by urfave/cli library, which leads
// to [--, addr:scope] being transformed to [addr:scope] and
// interpreted as a parameter if other positional arguments are not present.
// Here we fallback to parsing cosigners in this specific case to
// create a better user experience ('-- addr:scope' vs '-- -- addr:scope').
if k == 0 {
if _, err := parseCosigner(s); err == nil {
return 0, nil, nil
}
}
return 0, nil, fmt.Errorf("failed to parse argument #%d: %w", k+1, err)
}
res = append(res, *param)
k++
}
}
if calledFromMain {
return len(args), res, nil
}
return 0, []smartcontract.Parameter{}, errors.New("invalid array syntax: missing closing bracket")
}
// GetSignersAccounts returns the list of signers combined with the corresponding
// accounts from the provided wallet.
func GetSignersAccounts(senderAcc *wallet.Account, wall *wallet.Wallet, signers []transaction.Signer, accScope transaction.WitnessScope) ([]actor.SignerAccount, error) {
signersAccounts := make([]actor.SignerAccount, 0, len(signers)+1)
sender := senderAcc.ScriptHash()
signersAccounts = append(signersAccounts, actor.SignerAccount{
Signer: transaction.Signer{
Account: sender,
Scopes: accScope,
},
Account: senderAcc,
})
for i, s := range signers {
if s.Account == sender {
signersAccounts[0].Signer = s
continue
}
signerAcc := wall.GetAccount(s.Account)
if signerAcc == nil {
return nil, fmt.Errorf("no account was found in the wallet for signer #%d (%s)", i, address.Uint160ToString(s.Account))
}
signersAccounts = append(signersAccounts, actor.SignerAccount{
Signer: s,
Account: signerAcc,
})
}
return signersAccounts, nil
}