unwrap fate_to_erlang results

fate_to_erlang can only really fail at runtime if the wrong AACI is
provided, in which case the details of how failure occured are not
helpful, or recoverable. Anything else will be so broken that dialyzer
will catch it, or is a bug in hakuzaru, that we want to know about.

doc/overview.edoc

@@ -1,4 +1,5 @@
-@author Craig Everett <craigeverett@qpq.swiss> [https://git.qpq.swiss/QPQ-AG/hakuzaru]
+@author Craig Everett <craigeverett@qpq.swiss> [https://zxq9.com]
+@author Jarvis Carrol <jarviscarrol@qpq.swiss> [https://jarviscarroll.net/]
 @version 0.9.2
 @title Hakuzaru: Gajumaru blockchain bindings for Erlang
 
@@ -21,7 +22,7 @@ After startup `hz_man' must be given the address and port of a list of Gajumaru
 Note that the service nodes will need to have the dry-run endpoint enabled and the internal service query port made available in order to provide dry-runs and transaction submission.
 
 When configuring chain nodes a list of nodes should be provided.
-To avoid sync issues in the case of fast transaction formation/submission to the chain, only one node from the list of chain nodes is used for submitting transactions and querying `next_nonce/1`.
+To avoid sync issues in the case of fast transaction formation/submission to the chain, only one node from the list of chain nodes is used for submitting transactions and querying `next_nonce/1'.
 This node is called "the sticky node".
 
 The first node in the list of chain nodes provided during configuration is designated as the sticky node.

src/hz.erl

@@ -45,7 +45,7 @@
          acc/1, acc_at_height/2, acc_at_block_id/2,
          acc_pending_txs/1,
          next_nonce/1,
-         dry_run/1, dry_run/2, dry_run/3, dry_run_map/1,
+         dry_run/1, dry_run/2, dry_run/3, % dry_run_map/1,
          tx/1, tx_info/1,
          post_tx/1,
          contract/1, contract_code/1, contract_source/1,
@@ -790,7 +790,7 @@ contract_code(ID) ->
          Result :: {ok,      Source}
                  | {project, Bundle}
                  | {error,   Reason},
-         Source :: string(),
+         Source :: binary(),
          Bundle :: [{FilePath :: string(), Contents :: binary()}],
          Reason :: chain_error() | string().
 %% @doc
@@ -811,6 +811,8 @@ extract(Blobby) ->
 
 extract2(TarBaby) ->
     case erl_tar:extract({binary, TarBaby}, [memory, compressed]) of
+        {ok, [{_, Source}]} ->
+            {ok, Source};
         {ok, Bundle} ->
             {project, Bundle};
         {error,invalid_tar_checksum} ->
@@ -899,6 +901,12 @@ request(Path) ->
     hz_man:request(unicode:characters_to_list(Path)).
 
 
+-spec request(Path, Payload) -> {ok, Value} | {error, Reason}
+    when Path    :: unicode:charlist(),
+         Payload :: unicode:charlist(),
+         Value   :: map(),
+         Reason  :: hz:chain_error().
+
 request(Path, Payload) ->
     hz_man:request(unicode:characters_to_list(Path), Payload).
 
@@ -934,7 +942,7 @@ contract_create(CreatorID, Path, InitArgs) ->
             Gas = 500000,
             GasPrice = min_gas_price(),
             contract_create(CreatorID, Nonce,
-                            Amount, TTL, Gas, GasPrice,
+                            Gas, GasPrice, Amount, TTL,
                             Path, InitArgs);
         Error ->
             Error
@@ -1741,6 +1749,7 @@ spend(SenderID, SecKey, RecipientID, Amount, Payload, Height, NetworkID) ->
          TTL         :: non_neg_integer(),
          Nonce       :: non_neg_integer(),
          Payload     :: binary(),
+         NetworkID   :: unicode:chardata(),
          Result      :: term(), % FIXME
          Reason      :: chain_error() | string().
 %% @doc

src/hz_man.erl

@@ -172,7 +172,6 @@ start_link() ->
 %% preparatory work necessary for proper function.
 
 init(none) ->
-    ok = io:format("hz_man starting.~n"),
     State = #s{},
     {ok, State}.
 

src/hz_sophia.erl

@@ -53,7 +53,7 @@ parse_literal2(Result, Pos, String) ->
 
 %% @doc
 %% Parse an untyped Sophia expression into a FATE term
-%% Like parse_literal/2, but will not produce type errors. This function can
+%% Like `parse_literal/2', but will not produce type errors. This function can
 %% still produce parsing errors, and can produce errors when variants or
 %% records are encountered, since they can't be parsed unless you have type
 %% information.
@@ -67,6 +67,7 @@ parse_literal2(Result, Pos, String) ->
 parse_literal(String) ->
     parse_literal(unknown_type(), String).
 
+
 %%% Tokenizer
 
 -define(IS_LATIN_UPPER(C), (((C) >= $A) and ((C) =< $Z))).
@@ -252,6 +253,8 @@ escape_char($\") -> "\\\"";
 escape_char($\\) -> "\\\\";
 escape_char(I) -> I.
 
+
+
 %%% Sophia Literal Parser
 
 %%% This parser is a simple recursive descent parser, written explicitly in
@@ -340,6 +343,12 @@ parse_expression2(_, _, _, Token) ->
 unknown_type() ->
     {unknown_type, already_normalized, unknown_type}.
 
+int_type() ->
+    {integer, already_normalized, integer}.
+
+int_list_type() ->
+    {{list, [integer]}, alread_normalized, {list, [int_type()]}}.
+
 expect_tokens([], Pos, String) ->
     {ok, {Pos, String}};
 expect_tokens([Str | Rest], Pos, String) ->
@@ -374,11 +383,14 @@ parse_alphanum(Type, Pos, String, ["Bits", "all"], Row, Start, End) ->
     typecheck_bits(Type, Pos, String, -1, Row, Start, End);
 parse_alphanum(Type, Pos, String, ["Bits", "none"], Row, Start, End) ->
     typecheck_bits(Type, Pos, String, 0, Row, Start, End);
+parse_alphanum(Type, Pos, String, ["variant"], Row, Start, End) ->
+    parse_anonymous_variant(Type, Pos, String, Row, Start, End);
 parse_alphanum(Type, Pos, String, [[C | _] = S], Row, Start, End) when ?IS_LATIN_LOWER(C) ->
     % From a programming perspective, we are trying to parse a constant, so
     % an alphanum token can really only be a constructor, or a chain object.
-    % Constructors start with uppercase characters, so lowercase can only be a
+    % Constructors start with uppercase characters, and we have handled our
-    % chain object.
+    % made-up 'variant' case explicitly, so the only other lowercase constants
+    % are serialized chain objects.
     try
         case gmser_api_encoder:decode(unicode:characters_to_binary(S)) of
             {account_pubkey, Data} ->
@@ -397,8 +409,8 @@ parse_alphanum(Type, Pos, String, [[C | _] = S], Row, Start, End) when ?IS_LATIN
         _:_ -> {error, {unexpected_identifier, S, Row, Start, End}}
     end;
 parse_alphanum(Type, Pos, String, Path, Row, Start, End) ->
-    % Inversely, chain object prefixes are always lowercase, so any other path
+    % Now having handled all lowercase terms, anything else must be uppercase,
-    % must be a variant constructor, or invalid.
+    % which is either a variant constructor, or totally invalid.
     parse_variant(Type, Pos, String, Path, Row, Start, End).
 
 typecheck_integer({_, _, integer}, Pos, String, Value, _, _, _) ->
@@ -728,6 +740,12 @@ parse_variant({O, N, {variant, Variants}}, Pos, String, [Namespace, Constructor]
         _ ->
             {error, {invalid_constructor, O, N, Namespace ++ "." ++ Constructor, Row, Start, End}}
     end;
+parse_variant({_, _, unknown_type}, Pos, String, ["None"], _, _, _) ->
+    % Special case for None without type info.
+    parse_variant3([0, 1], 0, [], Pos, String);
+parse_variant({_, _, unknown_type}, Pos, String, ["Some"], _, _, _) ->
+    % Also a special case for Some.
+    parse_variant3([0, 1], 1, [unknown_type()], Pos, String);
 parse_variant({_, _, unknown_type}, _, _, _, Row, Start, End) ->
     {error, {unresolved_variant, Row, Start, End}};
 parse_variant({O, N, _}, _, _, _, Row, Start, End) ->
@@ -750,8 +768,7 @@ get_typename(Name) ->
 parse_variant2(O, N, Variants, Pos, String, Prefix, Constructor, Row, Start, End) ->
     case lookup_variant(Constructor, Variants, 0) of
         {ok, {Tag, ElemTypes}} ->
-            GetArity = fun({_, OtherElemTypes}) -> length(OtherElemTypes) end,
+            Arities = get_arities(Variants),
-            Arities = lists:map(GetArity, Variants),
             parse_variant3(Arities, Tag, ElemTypes, Pos, String);
         error ->
             {error, {invalid_constructor, O, N, Prefix ++ Constructor, Row, Start, End}}
@@ -787,6 +804,112 @@ lookup_variant(Ident, [{Ident, ElemTypes} | _], Tag) ->
 lookup_variant(Ident, [_ | Rest], Tag) ->
     lookup_variant(Ident, Rest, Tag + 1).
 
+get_arities(Variants) ->
+    GetArity = fun({_, OtherElemTypes}) -> length(OtherElemTypes) end,
+    lists:map(GetArity, Variants).
+
+parse_anonymous_variant({O, N, {variant, Variants}}, Pos, String, _, _, _) ->
+    parse_anonymous_variant2({O, N, {variant, Variants}}, Pos, String);
+parse_anonymous_variant({O, N, unknown_type}, Pos, String, _, _, _) ->
+    parse_anonymous_variant2({O, N, unknown_type}, Pos, String);
+parse_anonymous_variant({O, N, _}, _, _, Row, Start, End) ->
+    {error, {wrong_type, O, N, variant, Row, Start, End}}.
+
+parse_anonymous_variant2(Type, Pos, String) ->
+    case expect_tokens(["("], Pos, String) of
+        {ok, {NewPos, NewString}} ->
+            parse_anonymous_variant3(Type, NewPos, NewString);
+        {error, Reason} ->
+            {error, Reason}
+    end.
+
+parse_anonymous_variant3(Type, Pos, String) ->
+    case parse_arities(Type, Pos, String) of
+        {ok, {Arities, NewPos, NewString}} ->
+            parse_anonymous_variant4(Type, NewPos, NewString, Arities);
+        {error, Reason} ->
+            {error, Reason}
+    end.
+
+parse_anonymous_variant4(Type, Pos, String, Arities) ->
+    case expect_tokens([","], Pos, String) of
+        {ok, {NewPos, NewString}} ->
+            parse_anonymous_variant5(Type, NewPos, NewString, Arities);
+        {error, Reason} ->
+            {error, Reason}
+    end.
+
+parse_anonymous_variant5(Type, Pos, String, Arities) ->
+    case parse_anonymous_tag(Pos, String, Arities) of
+        {ok, {Tag, NewPos, NewString}} ->
+            parse_anonymous_variant6(Type, NewPos, NewString, Arities, Tag);
+        {error, Reason} ->
+            {error, Reason}
+    end.
+
+parse_anonymous_variant6(Type, Pos, String, Arities, Tag) ->
+    ElemTypes = infer_anonymous_variant_elem_types(Type, Arities, Tag),
+    case parse_multivalue3(ElemTypes, Pos, String, []) of
+        {ok, {Terms, NewPos, NewString}} ->
+            Result = {variant, Arities, Tag, list_to_tuple(Terms)},
+            {ok, {Result, NewPos, NewString}};
+        {error, Reason} ->
+            {error, Reason}
+    end.
+
+parse_arities(Type, Pos, String) ->
+    case next_token(Pos, String) of
+        {ok, {Token, NewPos, NewString}} ->
+            parse_arities2(Type, NewPos, NewString, Token);
+        {error, Reason} ->
+            {error, Reason}
+    end.
+
+parse_arities2(Type, Pos, String, Token = {_, _, _, Row, Start, _}) ->
+    case parse_expression2(int_list_type(), Pos, String, Token) of
+        {ok, {Arities, NewPos, NewString}} ->
+            parse_arities3(Type, NewPos, NewString, Arities, Row, Start);
+        {error, Reason} ->
+            {error, Reason}
+    end.
+
+parse_arities3({O, N, {variant, Variants}}, Pos, String, Arities, Row, Start) ->
+    ExpectedArities = get_arities(Variants),
+    case Arities == ExpectedArities of
+        true ->
+            {ok, {Arities, Pos, String}};
+        false ->
+            {error, {wrong_arities, O, N, Arities, Row, Start}}
+    end;
+parse_arities3(_, Pos, String, Arities, _, _) ->
+    {ok, {Arities, Pos, String}}.
+
+parse_anonymous_tag(Pos, String, Arities) ->
+    case next_token(Pos, String) of
+        {ok, {Token, NewPos, NewString}} ->
+            parse_anonymous_tag2(NewPos, NewString, Arities, Token);
+        {error, Reason} ->
+            {error, Reason}
+    end.
+
+parse_anonymous_tag2(Pos, String, Arities, Token = {_, _, _, Row, Start, End}) ->
+    TagCount = length(Arities),
+    case parse_expression2(int_type(), Pos, String, Token) of
+        {ok, {Tag, _, _}} when Tag < 0 ->
+            {error, {negative_tag, Tag, Row, Start, End}};
+        {ok, {Tag, _, _}} when Tag >= TagCount ->
+            {error, {invalid_tag, Tag, TagCount, Row, Start, End}};
+        Result ->
+            Result
+    end.
+
+infer_anonymous_variant_elem_types({_, _, {variant, Variants}}, _, Tag) ->
+    {_Name, ElemTypes} = lists:nth(Tag + 1, Variants),
+    ElemTypes;
+infer_anonymous_variant_elem_types({_, _, unknown_type}, Arities, Tag) ->
+    Arity = lists:nth(Tag + 1, Arities),
+    lists:duplicate(Arity, unknown_type()).
+
 %%% Record parsing
 
 parse_record_or_map({_, _, {map, [KeyType, ValueType]}}, Pos, String, _, _) ->
@@ -961,7 +1084,7 @@ wrap_error(Reason, _) -> Reason.
 %% integers, and strings, but it will misinterpret the types of records and
 %% unicode characters, and will crash the process if variants are encountered.
 %%
-%% fate_to_list/2 should be used whenever possible, especially since
+%% `fate_to_list/2' should be used whenever possible, especially since
 %% transaction results are type checked by nodes at runtime.
 
 fate_to_list(Term) ->
@@ -975,7 +1098,7 @@ fate_to_list(Term) ->
 
 %% @doc
 %% Print a FATE term from gmbytecode in Sophia syntax
-%% Like fate_to_list/1, but now type information from the AACI data structure
+%% Like `fate_to_list/1', but now type information from the AACI data structure
 %% can be provided, in order to correctly interpret types like records,
 %% variants, and unicode characters.  If the type information you provide is
 %% incorrect for the FATE term provided, then the function will fall back to
@@ -988,7 +1111,7 @@ fate_to_list(Type, Term) ->
 
 %% @doc
 %% Print a FATE term in Sophia syntax, without concatenating
-%% The fate_to_list/1 function builds an iolist, and then concatenates it into
+%% The `fate_to_list/1' function builds an iolist, and then concatenates it into
 %% a list. If you are going to put the term into a bigger iolist directly
 %% after, or write it to a streaming device, then it can save effort and memory
 %% to just use the iolist directly.
@@ -1007,7 +1130,7 @@ fate_to_iolist(Term) ->
 
 %% @doc
 %% Print a FATE term in Sophia syntax, without concatenating
-%% Prints using type information, like fate_to_list/2, but without spending
+%% Prints using type information, like `fate_to_list/2', but without spending
 %% time or memory concatenating the result into a list, like fate_to_iolist/1.
 
 % Special case for singleton records, since they are erased during compilation.
@@ -1024,15 +1147,12 @@ fate_to_iolist(Type, {tuple, Tuple}) ->
         _ ->
             tuple_to_iolist([], Tuple)
     end;
-fate_to_iolist(Type, {variant, _, Tag, Tuple}) ->
+fate_to_iolist(Type, {variant, Arities, Tag, Tuple}) ->
     case Type of
         {O, N, {variant, VariantTypes}} when Tag < length(VariantTypes) ->
             variant_to_iolist(O, N, VariantTypes, Tag, Tuple);
-        {O, N, _} ->
+        {_, _, _} ->
-            % TODO: Make up a special syntax for anonymous variant terms.
+            anonymous_variant_to_iolist(Arities, Tag, Tuple)
-            erlang:exit({untyped_variant, O, N});
-        _ ->
-            erlang:exit({untyped_variant, unknown_type, already_normalized})
     end;
 fate_to_iolist(Type, List) when is_list(List) ->
     case Type of
@@ -1127,6 +1247,22 @@ choose_variant_prefix(O, N) ->
             []
     end.
 
+% We don't have type information, but the Sophia programming language doesn't
+% have syntax for anonymous variants, so we have to make a syntax up. This
+% syntax is also supported when parsing terms, so that the output of one
+% contract call can be fed easily into another contract call.
+anonymous_variant_to_iolist(Arities, Tag, Tuple) ->
+    % Extract the elements of the tuple.
+    Elems = tuple_to_list(Tuple),
+
+    % Turn the arities, tag, and elements into an iolist.
+    AritiesStr = list_to_iolist(int_type(), Arities),
+    TagStr = integer_to_list(Tag),
+    FullTermsStr = list_elems_to_iolist(unknown_type(), Elems, [AritiesStr, ", ", TagStr]),
+
+    % Wrap that iolist in the anonymous 'variant' constructor.
+    ["variant(", FullTermsStr, ")"].
+
 multivalue_to_iolist([FirstType | ElemTypes], [FirstTerm | Elems]) ->
     FirstTermChars = fate_to_iolist(FirstType, FirstTerm),
     multivalue_to_iolist(ElemTypes, Elems, FirstTermChars);
@@ -1279,16 +1415,18 @@ check_parser_roundtrip(Sophia) ->
     % syntax. Let's do a lenient test.
     roundtrip_parser_lenient(unknown_type(), Sophia, Fate).
 
-check_parser_with_typedef(Typedef, Sophia) ->
+check_parser_with_typedef(Typedef, Sophia, UntypedSophia) ->
     % Compile the type definitions alongside the usual literal expression.
     Source = "contract C =\n  " ++ Typedef ++ "\n  entrypoint f() = " ++ Sophia,
     {Fate, Type} = compile_entrypoint_value_and_type(Source, "f"),
 
-    % Do a typed parse, as usual, but there are probably record/variant
+    % Do a typed parse, as usual. Variant namespaces can make pretty printing
-    % definitions in the AACI, so untyped parses probably don't work, and
+    % ambiguous, so make the roundtrip lenient.
-    % variants often have optional namespaces, so the sophia result might not
+    roundtrip_parser_lenient(Type, Sophia, Fate),
-    % match exactly, but should still be equivalent.
+    % Do an untyped parse, but using a second special Sophia expression that
-    roundtrip_parser_lenient(Type, Sophia, Fate).
+    % doesn't require type info to parse. This one *doesn't* need to be
+    % lenient, since we are specifying a distinct sophia expression.
+    roundtrip_parser(unknown_type(), UntypedSophia, Fate).
 
 anon_types_test() ->
     % Integers.
@@ -1320,6 +1458,10 @@ anon_types_test() ->
     check_parser_roundtrip("(1, [2, 3], (4, 5))"),
     % Map.
     check_parser_roundtrip("{[1] = 2, [3] = 4}"),
+    % Option.
+    check_parser_roundtrip("None"),
+    check_parser_roundtrip("Some(1)"),
+    check_parser_roundtrip("Some([1, 2, 3])"),
 
     ok.
 
@@ -1339,7 +1481,7 @@ string_escape_codes_test() ->
 records_test() ->
     TypeDef = "record pair = {x: int, y: int}",
     Sophia = "{x = 1, y = 2}",
-    check_parser_with_typedef(TypeDef, Sophia),
+    check_parser_with_typedef(TypeDef, Sophia, "(1, 2)"),
     % The above won't run an untyped parse on the expression, but we can. It
     % will error, though.
     {error, {unresolved_record, _, _, _}} = parse_literal(unknown_type(), Sophia).
@@ -1347,11 +1489,11 @@ records_test() ->
 variant_test() ->
     TypeDef = "datatype multi('a) = Zero | One('a) | Two('a, 'a)",
 
-    check_parser_with_typedef(TypeDef, "Zero"),
+    check_parser_with_typedef(TypeDef, "Zero", "variant([0, 1, 2], 0)"),
-    check_parser_with_typedef(TypeDef, "One(0)"),
+    check_parser_with_typedef(TypeDef, "One(0)", "variant([0, 1, 2], 1, 0)"),
-    check_parser_with_typedef(TypeDef, "Two(0, 1)"),
+    check_parser_with_typedef(TypeDef, "Two(0, 1)", "variant([0, 1, 2], 2, 0, 1)"),
-    check_parser_with_typedef(TypeDef, "Two([], [1, 2, 3])"),
+    check_parser_with_typedef(TypeDef, "Two([], [1, 2, 3])", "variant([0, 1, 2], 2, [], [1, 2, 3])"),
-    check_parser_with_typedef(TypeDef, "C.Zero"),
+    check_parser_with_typedef(TypeDef, "C.Zero", "variant([0, 1, 2], 0)"),
 
     {error, {unresolved_variant, _, _, _}} = parse_literal(unknown_type(), "Zero"),
 
@@ -1359,10 +1501,10 @@ variant_test() ->
 
 ambiguous_variant_test() ->
     TypeDef = "datatype mytype = C | D",
-    check_parser_with_typedef(TypeDef, "C"),
+    check_parser_with_typedef(TypeDef, "C", "variant([0, 0], 0)"),
-    check_parser_with_typedef(TypeDef, "D"),
+    check_parser_with_typedef(TypeDef, "D", "variant([0, 0], 1)"),
-    check_parser_with_typedef(TypeDef, "C.C"),
+    check_parser_with_typedef(TypeDef, "C.C", "variant([0, 0], 0)"),
-    check_parser_with_typedef(TypeDef, "C.D"),
+    check_parser_with_typedef(TypeDef, "C.D", "variant([0, 0], 1)"),
 
     ok.
 
@@ -1407,9 +1549,9 @@ bits_test() ->
 
 singleton_records_test() ->
     TypeDef = "record singleton('a) = {it: 'a}",
-    check_parser_with_typedef(TypeDef, "{it = 123}"),
+    check_parser_with_typedef(TypeDef, "{it = 123}", "123"),
-    check_parser_with_typedef(TypeDef, "{it = {it = {it = 5}}}"),
+    check_parser_with_typedef(TypeDef, "{it = {it = {it = 5}}}", "5"),
-    check_parser_with_typedef(TypeDef, "[{it = 1}, {it = 2}, {it = 3}]"),
+    check_parser_with_typedef(TypeDef, "[{it = 1}, {it = 2}, {it = 3}]", "[1, 2, 3]"),
 
     ok.
 
@@ -1418,9 +1560,9 @@ singleton_variants_test() ->
     % actually a special case; singleton variants are in fact wrapped in the
     % FATE too.
     TypeDef = "datatype wrapped('a) = Wrap('a)",
-    check_parser_with_typedef(TypeDef, "Wrap(123)"),
+    check_parser_with_typedef(TypeDef, "Wrap(123)", "variant([1], 0, 123)"),
-    check_parser_with_typedef(TypeDef, "Wrap(Wrap(123))"),
+    check_parser_with_typedef(TypeDef, "Wrap(Wrap(123))", "variant([1], 0, variant([1], 0, 123))"),
-    check_parser_with_typedef(TypeDef, "[Wrap(1), Wrap(2), Wrap(3)]"),
+    check_parser_with_typedef(TypeDef, "[Wrap(1), Wrap(2), Wrap(3)]", "[variant([1], 0, 1), variant([1], 0, 2), variant([1], 0, 3)]"),
 
     ok.