aws-sdk-for-zig/src/aws.zig
Emil Lerch 8e9b85b35f
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make for easier EC2 Query development
2022-02-11 09:28:24 -08:00

830 lines
34 KiB
Zig

const std = @import("std");
const awshttp = @import("aws_http.zig");
const json = @import("json.zig");
const url = @import("url.zig");
const case = @import("case.zig");
const servicemodel = @import("servicemodel.zig");
// const xml_shaper = @import("xml_shaper.zig");
const log = std.log.scoped(.aws);
pub const Options = struct {
region: []const u8 = "aws-global",
dualstack: bool = false,
success_http_code: i64 = 200,
client: Client,
};
/// Using this constant may blow up build times. Recommed using Services()
/// function directly, e.g. const services = Services(.{.sts, .ec2, .s3, .ddb}){};
pub const services = servicemodel.services;
/// Get a service model by importing specific services only. As an example:
/// const services = Services(.{.sts, .ec2, .s3, .ddb}){};
///
/// This will give you a constant with service data for sts, ec2, s3 and ddb only
pub const Services = servicemodel.Services;
pub const ClientOptions = struct {
trust_pem: ?[]const u8 = awshttp.default_root_ca,
};
pub const Client = struct {
allocator: std.mem.Allocator,
aws_http: awshttp.AwsHttp,
const Self = @This();
pub fn init(allocator: std.mem.Allocator, options: ClientOptions) !Self {
return Self{
.allocator = allocator,
.aws_http = try awshttp.AwsHttp.init(allocator, options.trust_pem),
};
}
pub fn deinit(self: *Client) void {
self.aws_http.deinit();
}
/// Calls AWS. Use a comptime request and options. For a runtime interface,
/// see Request
pub fn call(_: Self, comptime request: anytype, options: Options) !FullResponse(@TypeOf(request).metaInfo().action) {
const action = @TypeOf(request).metaInfo().action;
return Request(action).call(request, options);
}
};
/// Establish an AWS request that can be later called with runtime-known
/// parameters. If all parameters are known at comptime, the call function
/// may be simpler to use. request parameter here refers to the action
/// constant from the model, e.g. Request(services.lambda.list_functions)
pub fn Request(comptime action: anytype) type {
return struct {
const ActionRequest = action.Request;
const FullResponseType = FullResponse(action);
const Self = @This();
const action = action;
const meta_info = ActionRequest.metaInfo();
const service_meta = meta_info.service_metadata;
pub fn call(request: ActionRequest, options: Options) !FullResponseType {
// every codegenned request object includes a metaInfo function to get
// pointers to service and action
log.debug("call: prefix {s}, sigv4 {s}, version {s}, action {s}", .{
Self.service_meta.endpoint_prefix,
Self.service_meta.sigv4_name,
Self.service_meta.version,
action.action_name,
});
log.debug("proto: {s}", .{Self.service_meta.aws_protocol});
// It seems as though there are 3 major branches of the 6 protocols.
// 1. query/ec2_query, which are identical until you get to complex
// structures. EC2 query does not allow us to request json though,
// so we need to handle xml returns from this.
// 2. *json*: These three appear identical for input (possible difference
// for empty body serialization), but differ in error handling.
// We're not doing a lot of error handling here, though.
// 3. rest_xml: This is a one-off for S3, never used since
switch (Self.service_meta.aws_protocol) {
.query, .ec2_query => return Self.callQuery(request, options),
.json_1_0, .json_1_1 => return Self.callJson(request, options),
.rest_json_1 => return Self.callRestJson(request, options),
.rest_xml => @compileError("XML responses may be blocked on a zig compiler bug scheduled to be fixed in 0.10.0"),
}
}
/// Rest Json is the most complex and so we handle this seperately
fn callRestJson(request: ActionRequest, options: Options) !FullResponseType {
const Action = @TypeOf(action);
var aws_request: awshttp.HttpRequest = .{
.method = Action.http_config.method,
.content_type = "application/json",
.path = Action.http_config.uri,
};
log.debug("Rest JSON v1 method: '{s}'", .{aws_request.method});
log.debug("Rest JSON v1 success code: '{d}'", .{Action.http_config.success_code});
log.debug("Rest JSON v1 raw uri: '{s}'", .{Action.http_config.uri});
aws_request.path = try buildPath(options.client.allocator, Action.http_config.uri, ActionRequest, request);
defer options.client.allocator.free(aws_request.path);
log.debug("Rest JSON v1 processed uri: '{s}'", .{aws_request.path});
aws_request.query = try buildQuery(options.client.allocator, request);
log.debug("Rest JSON v1 query: '{s}'", .{aws_request.query});
defer options.client.allocator.free(aws_request.query);
// We don't know if we need a body...guessing here, this should cover most
var buffer = std.ArrayList(u8).init(options.client.allocator);
defer buffer.deinit();
var nameAllocator = std.heap.ArenaAllocator.init(options.client.allocator);
defer nameAllocator.deinit();
if (std.mem.eql(u8, "PUT", aws_request.method) or std.mem.eql(u8, "POST", aws_request.method)) {
try json.stringify(request, .{ .whitespace = .{} }, buffer.writer());
}
aws_request.body = buffer.items;
return try Self.callAws(aws_request, .{
.success_http_code = Action.http_config.success_code,
.region = options.region,
.dualstack = options.dualstack,
.client = options.client,
});
}
/// Calls using one of the json protocols (json_1_0, json_1_1)
fn callJson(request: ActionRequest, options: Options) !FullResponseType {
const target =
try std.fmt.allocPrint(options.client.allocator, "{s}.{s}", .{
Self.service_meta.name,
action.action_name,
});
defer options.client.allocator.free(target);
var buffer = std.ArrayList(u8).init(options.client.allocator);
defer buffer.deinit();
// The transformer needs to allocate stuff out of band, but we
// can guarantee we don't need the memory after this call completes,
// so we'll use an arena allocator to whack everything.
// TODO: Determine if sending in null values is ok, or if we need another
// tweak to the stringify function to exclude. According to the
// smithy spec, "A null value MAY be provided or omitted
// for a boxed member with no observable difference." But we're
// seeing a lot of differences here between spec and reality
//
var nameAllocator = std.heap.ArenaAllocator.init(options.client.allocator);
defer nameAllocator.deinit();
try json.stringify(request, .{ .whitespace = .{} }, buffer.writer());
var content_type: []const u8 = undefined;
switch (Self.service_meta.aws_protocol) {
.json_1_0 => content_type = "application/x-amz-json-1.0",
.json_1_1 => content_type = "application/x-amz-json-1.1",
else => unreachable,
}
return try Self.callAws(.{
.query = "",
.body = buffer.items,
.content_type = content_type,
.headers = &[_]awshttp.Header{.{ .name = "X-Amz-Target", .value = target }},
}, options);
}
// Call using query protocol. This is documented as an XML protocol, but
// throwing a JSON accept header seems to work. EC2Query is very simliar to
// Query, so we'll handle both here. Realistically we probably don't effectively
// handle lists and maps properly anyway yet, so we'll go for it and see
// where it breaks. PRs and/or failing test cases appreciated.
fn callQuery(request: ActionRequest, options: Options) !FullResponseType {
if (Self.service_meta.aws_protocol == .ec2_query)
@compileError("XML responses from EC2 blocked due to zig compiler bug scheduled to be fixed no earlier than 0.10.0");
var buffer = std.ArrayList(u8).init(options.client.allocator);
defer buffer.deinit();
const writer = buffer.writer();
try url.encode(request, writer, .{
.field_name_transformer = &queryFieldTransformer,
.allocator = options.client.allocator,
});
const continuation = if (buffer.items.len > 0) "&" else "";
const query = if (Self.service_meta.aws_protocol == .query)
try std.fmt.allocPrint(options.client.allocator, "", .{})
else // EC2
try std.fmt.allocPrint(options.client.allocator, "?Action={s}&Version={s}", .{
action.action_name,
Self.service_meta.version,
});
defer options.client.allocator.free(query);
// Note: EC2 avoided the Action={s}&Version={s} in the body, but it's
// but it's required, so I'm not sure why that code was put in
// originally?
const body =
try std.fmt.allocPrint(options.client.allocator, "Action={s}&Version={s}{s}{s}", .{
action.action_name,
Self.service_meta.version,
continuation,
buffer.items,
});
defer options.client.allocator.free(body);
return try Self.callAws(.{
.query = query,
.body = body,
.content_type = "application/x-www-form-urlencoded",
}, options);
}
fn callAws(aws_request: awshttp.HttpRequest, options: Options) !FullResponseType {
const response = try options.client.aws_http.callApi(
Self.service_meta.endpoint_prefix,
aws_request,
.{
.region = options.region,
.dualstack = options.dualstack,
.sigv4_service_name = Self.service_meta.sigv4_name,
},
);
defer response.deinit();
if (response.response_code != options.success_http_code) {
try reportTraffic(options.client.allocator, "Call Failed", aws_request, response, log.err);
return error.HttpFailure;
}
// EC2 ignores our accept type, but technically query protocol only
// returns XML as well. So, we'll ignore the protocol here and just
// look at the return type
var isJson: bool = undefined;
for (response.headers) |h| {
if (std.ascii.eqlIgnoreCase("Content-Type", h.name)) {
if (std.mem.startsWith(u8, h.value, "application/json")) {
isJson = true;
} else if (std.mem.startsWith(u8, h.value, "application/x-amz-json-1.0")) {
isJson = true;
} else if (std.mem.startsWith(u8, h.value, "application/x-amz-json-1.1")) {
isJson = true;
} else if (std.mem.startsWith(u8, h.value, "text/xml")) {
isJson = false;
} else {
log.err("Unexpected content type: {s}", .{h.value});
return error.UnexpectedContentType;
}
break;
}
}
// TODO: Handle XML
if (!isJson) return error.XmlUnimplemented;
const SResponse = if (Self.service_meta.aws_protocol != .query and Self.service_meta.aws_protocol != .ec2_query)
action.Response
else
ServerResponse(action);
const parser_options = json.ParseOptions{
.allocator = options.client.allocator,
.allow_camel_case_conversion = true, // new option
.allow_snake_case_conversion = true, // new option
.allow_unknown_fields = true, // new option. Cannot yet handle non-struct fields though
.allow_missing_fields = false, // new option. Cannot yet handle non-struct fields though
};
if (std.meta.fields(SResponse).len == 0) // We don't care about the body if there are no fields
// Do we care if an unexpected body comes in?
return FullResponseType{
.response = .{},
.response_metadata = .{
.request_id = try requestIdFromHeaders(aws_request, response, options),
},
.parser_options = parser_options,
.raw_parsed = .{ .raw = .{} },
};
var stream = json.TokenStream.init(response.body);
const parsed_response = json.parse(SResponse, &stream, parser_options) catch |e| {
log.err(
\\Call successful, but unexpected response from service.
\\This could be the result of a bug or a stale set of code generated
\\service models.
\\
\\Model Type: {s}
\\
\\Response from server:
\\
\\{s}
\\
, .{ SResponse, response.body });
return e;
};
if (Self.service_meta.aws_protocol != .query and Self.service_meta.aws_protocol != .ec2_query) {
return FullResponseType{
.response = parsed_response,
.response_metadata = .{
.request_id = try requestIdFromHeaders(aws_request, response, options),
},
.parser_options = parser_options,
.raw_parsed = .{ .raw = parsed_response },
};
}
// Grab the first (and only) object from the server. Server shape expected to be:
// { ActionResponse: {ActionResult: {...}, ResponseMetadata: {...} } }
// ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
// Next line of code pulls this portion
//
//
// And the response property below will pull whatever is the ActionResult object
// We can grab index [0] as structs are guaranteed by zig to be returned in the order
// declared, and we're declaring in that order in ServerResponse().
const real_response = @field(parsed_response, @typeInfo(SResponse).Struct.fields[0].name);
return FullResponseType{
.response = @field(real_response, @typeInfo(@TypeOf(real_response)).Struct.fields[0].name),
.response_metadata = .{
.request_id = try options.client.allocator.dupe(u8, real_response.ResponseMetadata.RequestId),
},
.parser_options = parser_options,
.raw_parsed = .{ .server = parsed_response },
};
}
};
}
/// Get request ID from headers. Caller responsible for freeing memory
fn requestIdFromHeaders(request: awshttp.HttpRequest, response: awshttp.HttpResult, options: Options) ![]u8 {
var request_id: []u8 = undefined;
var found = false;
for (response.headers) |h| {
if (std.ascii.eqlIgnoreCase(h.name, "X-Amzn-RequestId")) {
found = true;
request_id = try std.fmt.allocPrint(options.client.allocator, "{s}", .{h.value}); // will be freed in FullR.deinit()
}
}
if (!found) {
try reportTraffic(options.client.allocator, "Request ID not found", request, response, log.err);
return error.RequestIdNotFound;
}
return request_id;
}
fn ServerResponse(comptime action: anytype) type {
const T = action.Response;
// NOTE: The non-standard capitalization here is used as a performance
// enhancement and to reduce allocations in json.zig. These fields are
// not (nor are they ever intended to be) exposed outside this codebase
const ResponseMetadata = struct {
RequestId: []u8,
};
const Result = @Type(.{
.Struct = .{
.layout = .Auto,
.fields = &[_]std.builtin.TypeInfo.StructField{
.{
.name = action.action_name ++ "Result",
.field_type = T,
.default_value = null,
.is_comptime = false,
.alignment = 0,
},
.{
.name = "ResponseMetadata",
.field_type = ResponseMetadata,
.default_value = null,
.is_comptime = false,
.alignment = 0,
},
},
.decls = &[_]std.builtin.TypeInfo.Declaration{},
.is_tuple = false,
},
});
return @Type(.{
.Struct = .{
.layout = .Auto,
.fields = &[_]std.builtin.TypeInfo.StructField{
.{
.name = action.action_name ++ "Response",
.field_type = Result,
.default_value = null,
.is_comptime = false,
.alignment = 0,
},
},
.decls = &[_]std.builtin.TypeInfo.Declaration{},
.is_tuple = false,
},
});
}
fn FullResponse(comptime action: anytype) type {
return struct {
response: action.Response,
response_metadata: struct {
request_id: []u8,
},
parser_options: json.ParseOptions,
raw_parsed: union(enum) {
server: ServerResponse(action),
raw: action.Response,
},
// raw_parsed: ServerResponse(request),
const Self = @This();
pub fn deinit(self: Self) void {
switch (self.raw_parsed) {
.server => json.parseFree(ServerResponse(action), self.raw_parsed.server, self.parser_options),
.raw => json.parseFree(action.Response, self.raw_parsed.raw, self.parser_options),
}
self.parser_options.allocator.?.free(self.response_metadata.request_id);
}
};
}
fn queryFieldTransformer(field_name: []const u8, encoding_options: url.EncodingOptions) anyerror![]const u8 {
return try case.snakeToPascal(encoding_options.allocator.?, field_name);
}
fn buildPath(allocator: std.mem.Allocator, raw_uri: []const u8, comptime ActionRequest: type, request: anytype) ![]const u8 {
var buffer = try std.ArrayList(u8).initCapacity(allocator, raw_uri.len);
// const writer = buffer.writer();
defer buffer.deinit();
var in_var = false;
var start: usize = 0;
for (raw_uri) |c, inx| {
switch (c) {
'{' => {
in_var = true;
start = inx + 1;
},
'}' => {
in_var = false;
const replacement_var = raw_uri[start..inx];
inline for (std.meta.fields(ActionRequest)) |field| {
if (std.mem.eql(u8, request.fieldNameFor(field.name), replacement_var)) {
var replacement_buffer = try std.ArrayList(u8).initCapacity(allocator, raw_uri.len);
defer replacement_buffer.deinit();
var encoded_buffer = try std.ArrayList(u8).initCapacity(allocator, raw_uri.len);
defer encoded_buffer.deinit();
const replacement_writer = replacement_buffer.writer();
// std.mem.replacementSize
try json.stringify(
@field(request, field.name),
.{},
replacement_writer,
);
const trimmed_replacement_val = std.mem.trim(u8, replacement_buffer.items, "\"");
try uriEncode(trimmed_replacement_val, encoded_buffer.writer());
try buffer.appendSlice(encoded_buffer.items);
}
}
},
else => if (!in_var) {
try buffer.append(c);
} else {},
}
}
return buffer.toOwnedSlice();
}
fn uriEncode(input: []const u8, writer: anytype) !void {
for (input) |c|
try uriEncodeByte(c, writer);
}
fn uriEncodeByte(char: u8, writer: anytype) !void {
switch (char) {
'!' => _ = try writer.write("%21"),
'#' => _ = try writer.write("%23"),
'$' => _ = try writer.write("%24"),
'&' => _ = try writer.write("%26"),
'\'' => _ = try writer.write("%27"),
'(' => _ = try writer.write("%28"),
')' => _ = try writer.write("%29"),
'*' => _ = try writer.write("%2A"),
'+' => _ = try writer.write("%2B"),
',' => _ = try writer.write("%2C"),
'/' => _ = try writer.write("%2F"),
':' => _ = try writer.write("%3A"),
';' => _ = try writer.write("%3B"),
'=' => _ = try writer.write("%3D"),
'?' => _ = try writer.write("%3F"),
'@' => _ = try writer.write("%40"),
'[' => _ = try writer.write("%5B"),
']' => _ = try writer.write("%5D"),
'%' => _ = try writer.write("%25"),
else => {
_ = try writer.writeByte(char);
},
}
}
fn buildQuery(allocator: std.mem.Allocator, request: anytype) ![]const u8 {
// query should look something like this:
// pub const http_query = .{
// .master_region = "MasterRegion",
// .function_version = "FunctionVersion",
// .marker = "Marker",
// };
var buffer = std.ArrayList(u8).init(allocator);
const writer = buffer.writer();
defer buffer.deinit();
var prefix = "?";
const Req = @TypeOf(request);
if (declaration(Req, "http_query") == null)
return buffer.toOwnedSlice();
const query_arguments = Req.http_query;
inline for (@typeInfo(@TypeOf(query_arguments)).Struct.fields) |arg| {
const val = @field(request, arg.name);
if (try addQueryArg(arg.field_type, prefix, @field(query_arguments, arg.name), val, writer))
prefix = "&";
}
return buffer.toOwnedSlice();
}
fn declaration(comptime T: type, name: []const u8) ?std.builtin.TypeInfo.Declaration {
for (std.meta.declarations(T)) |decl| {
if (std.mem.eql(u8, name, decl.name))
return decl;
}
return null;
}
fn addQueryArg(comptime ValueType: type, prefix: []const u8, key: []const u8, value: anytype, writer: anytype) !bool {
switch (@typeInfo(@TypeOf(value))) {
.Optional => {
if (value) |v|
return try addQueryArg(ValueType, prefix, key, v, writer);
return false;
},
// if this is a pointer, we want to make sure it is more than just a string
.Pointer => |ptr| {
if (ptr.child == u8 or ptr.size != .Slice) {
// This is just a string
return try addBasicQueryArg(prefix, key, value, writer);
}
var p = prefix;
for (value) |li| {
if (try addQueryArg(ValueType, p, key, li, writer))
p = "&";
}
return std.mem.eql(u8, "&", p);
},
.Array => |arr| {
if (arr.child == u8)
return try addBasicQueryArg(prefix, key, value, writer);
var p = prefix;
for (value) |li| {
if (try addQueryArg(ValueType, p, key, li, writer))
p = "&";
}
return std.mem.eql(u8, "&", p);
},
else => {
return try addBasicQueryArg(prefix, key, value, writer);
},
}
}
fn addBasicQueryArg(prefix: []const u8, key: []const u8, value: anytype, writer: anytype) !bool {
_ = try writer.write(prefix);
// TODO: url escaping
try uriEncode(key, writer);
_ = try writer.write("=");
try json.stringify(value, .{}, ignoringWriter(uriEncodingWriter(writer).writer(), '"').writer());
return true;
}
pub fn uriEncodingWriter(child_stream: anytype) UriEncodingWriter(@TypeOf(child_stream)) {
return .{ .child_stream = child_stream };
}
/// A Writer that ignores a character
pub fn UriEncodingWriter(comptime WriterType: type) type {
return struct {
child_stream: WriterType,
pub const Error = WriterType.Error;
pub const Writer = std.io.Writer(*Self, Error, write);
const Self = @This();
pub fn write(self: *Self, bytes: []const u8) Error!usize {
try uriEncode(bytes, self.child_stream);
return bytes.len; // We say that all bytes are "written", even if they're not, as caller may be retrying
}
pub fn writer(self: *Self) Writer {
return .{ .context = self };
}
};
}
pub fn ignoringWriter(child_stream: anytype, ignore: u8) IgnoringWriter(@TypeOf(child_stream)) {
return .{ .child_stream = child_stream, .ignore = ignore };
}
/// A Writer that ignores a character
pub fn IgnoringWriter(comptime WriterType: type) type {
return struct {
child_stream: WriterType,
ignore: u8,
pub const Error = WriterType.Error;
pub const Writer = std.io.Writer(*Self, Error, write);
const Self = @This();
pub fn write(self: *Self, bytes: []const u8) Error!usize {
for (bytes) |b| {
if (b != self.ignore)
try self.child_stream.writeByte(b);
}
return bytes.len; // We say that all bytes are "written", even if they're not, as caller may be retrying
}
pub fn writer(self: *Self) Writer {
return .{ .context = self };
}
};
}
fn reportTraffic(allocator: std.mem.Allocator, info: []const u8, request: awshttp.HttpRequest, response: awshttp.HttpResult, comptime reporter: fn (comptime []const u8, anytype) void) !void {
var msg = std.ArrayList(u8).init(allocator);
defer msg.deinit();
const writer = msg.writer();
try writer.print("{s}\n\n", .{info});
try writer.print("Return status: {d}\n\n", .{response.response_code});
if (request.query.len > 0) try writer.print("Request Query:\n \t{s}\n", .{request.query});
_ = try writer.write("Unique Request Headers:\n");
if (request.headers.len > 0) {
for (request.headers) |h|
try writer.print("\t{s}: {s}\n", .{ h.name, h.value });
}
try writer.print("\tContent-Type: {s}\n\n", .{request.content_type});
_ = try writer.write("Request Body:\n");
try writer.print("-------------\n{s}\n", .{request.body});
_ = try writer.write("-------------\n");
_ = try writer.write("Response Headers:\n");
for (response.headers) |h|
try writer.print("\t{s}: {s}\n", .{ h.name, h.value });
_ = try writer.write("Response Body:\n");
try writer.print("--------------\n{s}\n", .{response.body});
_ = try writer.write("--------------\n");
reporter("{s}\n", .{msg.items});
}
// TODO: Where does this belong really?
fn typeForField(comptime T: type, field_name: []const u8) !type {
const ti = @typeInfo(T);
switch (ti) {
.Struct => {
inline for (ti.Struct.fields) |field| {
if (std.mem.eql(u8, field.name, field_name))
return field.field_type;
}
},
else => return error.TypeIsNotAStruct, // should not hit this
}
return error.FieldNotFound;
}
test "custom serialization for map objects" {
const allocator = std.testing.allocator;
var buffer = std.ArrayList(u8).init(allocator);
defer buffer.deinit();
var tags = try std.ArrayList(@typeInfo(try typeForField(services.lambda.tag_resource.Request, "tags")).Pointer.child).initCapacity(allocator, 2);
defer tags.deinit();
tags.appendAssumeCapacity(.{ .key = "Foo", .value = "Bar" });
tags.appendAssumeCapacity(.{ .key = "Baz", .value = "Qux" });
const req = services.lambda.tag_resource.Request{ .resource = "hello", .tags = tags.items };
try json.stringify(req, .{ .whitespace = .{} }, buffer.writer());
try std.testing.expectEqualStrings(
\\{
\\ "Resource": "hello",
\\ "Tags": {
\\ "Foo": "Bar",
\\ "Baz": "Qux"
\\ }
\\}
, buffer.items);
}
test "REST Json v1 builds proper queries" {
const allocator = std.testing.allocator;
const svs = Services(.{.lambda}){};
const request = svs.lambda.list_functions.Request{
.max_items = 1,
};
const query = try buildQuery(allocator, request);
defer allocator.free(query);
try std.testing.expectEqualStrings("?MaxItems=1", query);
}
test "REST Json v1 handles reserved chars in queries" {
const allocator = std.testing.allocator;
const svs = Services(.{.lambda}){};
var keys = [_][]const u8{"Foo?I'm a crazy%dude"}; // Would love to have a way to express this without burning a var here
const request = svs.lambda.untag_resource.Request{
.tag_keys = keys[0..],
.resource = "hello",
};
const query = try buildQuery(allocator, request);
defer allocator.free(query);
try std.testing.expectEqualStrings("?tagKeys=Foo%3FI%27m a crazy%25dude", query);
}
test "REST Json v1 serializes lists in queries" {
const allocator = std.testing.allocator;
const svs = Services(.{.lambda}){};
var keys = [_][]const u8{ "Foo", "Bar" }; // Would love to have a way to express this without burning a var here
const request = svs.lambda.untag_resource.Request{
.tag_keys = keys[0..],
.resource = "hello",
};
const query = try buildQuery(allocator, request);
defer allocator.free(query);
try std.testing.expectEqualStrings("?tagKeys=Foo&tagKeys=Bar", query);
}
test "REST Json v1 buildpath substitutes" {
const allocator = std.testing.allocator;
const svs = Services(.{.lambda}){};
const request = svs.lambda.list_functions.Request{
.max_items = 1,
};
const input_path = "https://myhost/{MaxItems}/";
const output_path = try buildPath(allocator, input_path, @TypeOf(request), request);
defer allocator.free(output_path);
try std.testing.expectEqualStrings("https://myhost/1/", output_path);
}
test "REST Json v1 buildpath handles restricted characters" {
const allocator = std.testing.allocator;
const svs = Services(.{.lambda}){};
const request = svs.lambda.list_functions.Request{
.marker = ":",
};
const input_path = "https://myhost/{Marker}/";
const output_path = try buildPath(allocator, input_path, @TypeOf(request), request);
defer allocator.free(output_path);
try std.testing.expectEqualStrings("https://myhost/%3A/", output_path);
}
test "basic json request serialization" {
const allocator = std.testing.allocator;
const svs = Services(.{.dynamo_db}){};
const request = svs.dynamo_db.list_tables.Request{
.limit = 1,
};
var buffer = std.ArrayList(u8).init(allocator);
defer buffer.deinit();
// The transformer needs to allocate stuff out of band, but we
// can guarantee we don't need the memory after this call completes,
// so we'll use an arena allocator to whack everything.
// TODO: Determine if sending in null values is ok, or if we need another
// tweak to the stringify function to exclude. According to the
// smithy spec, "A null value MAY be provided or omitted
// for a boxed member with no observable difference." But we're
// seeing a lot of differences here between spec and reality
//
var nameAllocator = std.heap.ArenaAllocator.init(allocator);
defer nameAllocator.deinit();
try json.stringify(request, .{ .whitespace = .{} }, buffer.writer());
try std.testing.expectEqualStrings(
\\{
\\ "ExclusiveStartTableName": null,
\\ "Limit": 1
\\}
, buffer.items);
}
test "layer object only" {
const TestResponse = struct {
arn: ?[]const u8 = null,
// uncompressed_code_size: ?i64 = null,
pub fn jsonFieldNameFor(_: @This(), comptime field_name: []const u8) []const u8 {
const mappings = .{
.arn = "Arn",
};
return @field(mappings, field_name);
}
};
const response =
\\ {
\\ "UncompressedCodeSize": 2,
\\ "Arn": "blah"
\\ }
;
// const response =
// \\ {
// \\ "UncompressedCodeSize": 22599541,
// \\ "Arn": "arn:aws:lambda:us-west-2:550620852718:layer:PollyNotes-lib:4"
// \\ }
// ;
const allocator = std.testing.allocator;
var stream = json.TokenStream.init(response);
const parser_options = json.ParseOptions{
.allocator = allocator,
.allow_camel_case_conversion = true, // new option
.allow_snake_case_conversion = true, // new option
.allow_unknown_fields = true, // new option. Cannot yet handle non-struct fields though
.allow_missing_fields = false, // new option. Cannot yet handle non-struct fields though
};
const r = try json.parse(TestResponse, &stream, parser_options);
json.parseFree(TestResponse, r, parser_options);
}
// Use for debugging json responses of specific requests
// test "dummy request" {
// const allocator = std.testing.allocator;
// const svs = Services(.{.sts}){};
// const request = svs.sts.get_session_token.Request{
// .duration_seconds = 900,
// };
// const FullR = FullResponse(request);
// const response =
// var stream = json.TokenStream.init(response);
//
// const parser_options = json.ParseOptions{
// .allocator = allocator,
// .allow_camel_case_conversion = true, // new option
// .allow_snake_case_conversion = true, // new option
// .allow_unknown_fields = true, // new option. Cannot yet handle non-struct fields though
// .allow_missing_fields = false, // new option. Cannot yet handle non-struct fields though
// };
// const SResponse = ServerResponse(request);
// const r = try json.parse(SResponse, &stream, parser_options);
// json.parseFree(SResponse, r, parser_options);
// }