palladum-lightning/common/test/run-jsonrpc_io.c

/* Body of tests written by ChatGPT 5 */
#include "config.h"
#include <assert.h>
#include <ccan/io/io.h>
#include <common/amount.h>
#include <common/bigsize.h>
#include <common/randbytes.h>
#include <common/setup.h>
#include <stdio.h>
#include <wire/wire.h>

#undef io_read_partial
#define io_read_partial io_read_partial_test

struct jsonrpc_io;

static struct io_plan *io_read_partial_test(struct io_conn *conn,
					    void *data,
					    size_t maxlen,
					    size_t *lenp,
					    struct io_plan *(*next)(struct io_conn *,
								    void *),
					    void *arg);


#include "../jsonrpc_io.c"

/* AUTOGENERATED MOCKS START */
/* Generated stub for amount_asset_is_main */
bool amount_asset_is_main(struct amount_asset *asset UNNEEDED)
{ fprintf(stderr, "amount_asset_is_main called!\n"); abort(); }
/* Generated stub for amount_asset_to_sat */
struct amount_sat amount_asset_to_sat(struct amount_asset *asset UNNEEDED)
{ fprintf(stderr, "amount_asset_to_sat called!\n"); abort(); }
/* Generated stub for amount_feerate */
 bool amount_feerate(u32 *feerate UNNEEDED, struct amount_sat fee UNNEEDED, size_t weight UNNEEDED)
{ fprintf(stderr, "amount_feerate called!\n"); abort(); }
/* Generated stub for amount_sat */
struct amount_sat amount_sat(u64 satoshis UNNEEDED)
{ fprintf(stderr, "amount_sat called!\n"); abort(); }
/* Generated stub for amount_sat_add */
 bool amount_sat_add(struct amount_sat *val UNNEEDED,
				       struct amount_sat a UNNEEDED,
				       struct amount_sat b UNNEEDED)
{ fprintf(stderr, "amount_sat_add called!\n"); abort(); }
/* Generated stub for amount_sat_eq */
bool amount_sat_eq(struct amount_sat a UNNEEDED, struct amount_sat b UNNEEDED)
{ fprintf(stderr, "amount_sat_eq called!\n"); abort(); }
/* Generated stub for amount_sat_greater_eq */
bool amount_sat_greater_eq(struct amount_sat a UNNEEDED, struct amount_sat b UNNEEDED)
{ fprintf(stderr, "amount_sat_greater_eq called!\n"); abort(); }
/* Generated stub for amount_sat_sub */
 bool amount_sat_sub(struct amount_sat *val UNNEEDED,
				       struct amount_sat a UNNEEDED,
				       struct amount_sat b UNNEEDED)
{ fprintf(stderr, "amount_sat_sub called!\n"); abort(); }
/* Generated stub for amount_sat_to_asset */
struct amount_asset amount_sat_to_asset(struct amount_sat *sat UNNEEDED, const u8 *asset UNNEEDED)
{ fprintf(stderr, "amount_sat_to_asset called!\n"); abort(); }
/* Generated stub for amount_tx_fee */
struct amount_sat amount_tx_fee(u32 fee_per_kw UNNEEDED, size_t weight UNNEEDED)
{ fprintf(stderr, "amount_tx_fee called!\n"); abort(); }
/* Generated stub for fromwire */
const u8 *fromwire(const u8 **cursor UNNEEDED, size_t *max UNNEEDED, void *copy UNNEEDED, size_t n UNNEEDED)
{ fprintf(stderr, "fromwire called!\n"); abort(); }
/* Generated stub for fromwire_bool */
bool fromwire_bool(const u8 **cursor UNNEEDED, size_t *max UNNEEDED)
{ fprintf(stderr, "fromwire_bool called!\n"); abort(); }
/* Generated stub for fromwire_fail */
void *fromwire_fail(const u8 **cursor UNNEEDED, size_t *max UNNEEDED)
{ fprintf(stderr, "fromwire_fail called!\n"); abort(); }
/* Generated stub for fromwire_secp256k1_ecdsa_signature */
void fromwire_secp256k1_ecdsa_signature(const u8 **cursor UNNEEDED, size_t *max UNNEEDED,
					secp256k1_ecdsa_signature *signature UNNEEDED)
{ fprintf(stderr, "fromwire_secp256k1_ecdsa_signature called!\n"); abort(); }
/* Generated stub for fromwire_sha256 */
void fromwire_sha256(const u8 **cursor UNNEEDED, size_t *max UNNEEDED, struct sha256 *sha256 UNNEEDED)
{ fprintf(stderr, "fromwire_sha256 called!\n"); abort(); }
/* Generated stub for fromwire_tal_arrn */
u8 *fromwire_tal_arrn(const tal_t *ctx UNNEEDED,
		       const u8 **cursor UNNEEDED, size_t *max UNNEEDED, size_t num UNNEEDED)
{ fprintf(stderr, "fromwire_tal_arrn called!\n"); abort(); }
/* Generated stub for fromwire_u32 */
u32 fromwire_u32(const u8 **cursor UNNEEDED, size_t *max UNNEEDED)
{ fprintf(stderr, "fromwire_u32 called!\n"); abort(); }
/* Generated stub for fromwire_u64 */
u64 fromwire_u64(const u8 **cursor UNNEEDED, size_t *max UNNEEDED)
{ fprintf(stderr, "fromwire_u64 called!\n"); abort(); }
/* Generated stub for fromwire_u8 */
u8 fromwire_u8(const u8 **cursor UNNEEDED, size_t *max UNNEEDED)
{ fprintf(stderr, "fromwire_u8 called!\n"); abort(); }
/* Generated stub for fromwire_u8_array */
void fromwire_u8_array(const u8 **cursor UNNEEDED, size_t *max UNNEEDED, u8 *arr UNNEEDED, size_t num UNNEEDED)
{ fprintf(stderr, "fromwire_u8_array called!\n"); abort(); }
/* Generated stub for towire */
void towire(u8 **pptr UNNEEDED, const void *data UNNEEDED, size_t len UNNEEDED)
{ fprintf(stderr, "towire called!\n"); abort(); }
/* Generated stub for towire_bool */
void towire_bool(u8 **pptr UNNEEDED, bool v UNNEEDED)
{ fprintf(stderr, "towire_bool called!\n"); abort(); }
/* Generated stub for towire_secp256k1_ecdsa_signature */
void towire_secp256k1_ecdsa_signature(u8 **pptr UNNEEDED,
			      const secp256k1_ecdsa_signature *signature UNNEEDED)
{ fprintf(stderr, "towire_secp256k1_ecdsa_signature called!\n"); abort(); }
/* Generated stub for towire_sha256 */
void towire_sha256(u8 **pptr UNNEEDED, const struct sha256 *sha256 UNNEEDED)
{ fprintf(stderr, "towire_sha256 called!\n"); abort(); }
/* Generated stub for towire_u32 */
void towire_u32(u8 **pptr UNNEEDED, u32 v UNNEEDED)
{ fprintf(stderr, "towire_u32 called!\n"); abort(); }
/* Generated stub for towire_u64 */
void towire_u64(u8 **pptr UNNEEDED, u64 v UNNEEDED)
{ fprintf(stderr, "towire_u64 called!\n"); abort(); }
/* Generated stub for towire_u8 */
void towire_u8(u8 **pptr UNNEEDED, u8 v UNNEEDED)
{ fprintf(stderr, "towire_u8 called!\n"); abort(); }
/* Generated stub for towire_u8_array */
void towire_u8_array(u8 **pptr UNNEEDED, const u8 *arr UNNEEDED, size_t num UNNEEDED)
{ fprintf(stderr, "towire_u8_array called!\n"); abort(); }
/* AUTOGENERATED MOCKS END */

struct test_feed {
	const char *data;
	size_t len, off;
	size_t max_chunk; /* 0 => no artificial limit */
	unsigned calls_to_io_read;
};
static struct test_feed FEED;

static void feed_set(const char *s, size_t max_chunk)
{
	FEED.data = s;
	FEED.len = strlen(s);
	FEED.off = 0;
	FEED.max_chunk = max_chunk;
	FEED.calls_to_io_read = 0;
}

static size_t feed_next_chunk(size_t want)
{
	size_t remain = FEED.len - FEED.off;
	size_t cap = (FEED.max_chunk && FEED.max_chunk < want) ? FEED.max_chunk : want;
	return (remain < cap) ? remain : cap;
}

static struct io_plan *io_read_partial_test(struct io_conn *conn,
					    void *data,
					    size_t maxlen,
					    size_t *lenp,
					    struct io_plan *(*next)(struct io_conn *, void *),
					    void *arg)
{
	char *out = (char *)data;
	size_t n = feed_next_chunk(maxlen);

	FEED.calls_to_io_read++;
	if (n) {
		memcpy(out, FEED.data + FEED.off, n);
		FEED.off += n;
	}
	*lenp = n;

	/* No more input -> end the chain */
	if (n == 0)
		return NULL;

	return next(conn, arg);
}

/* ---------- minimal “handler” to count parsed messages ---------- */

struct handler_ctx {
	unsigned called;
	char last_buf[512];
	size_t last_len;
};

static void record_message(const char *buf, const jsmntok_t *toks, struct handler_ctx *hc)
{
	size_t obj_len = (size_t)(toks[0].end - toks[0].start);
	if (obj_len > sizeof(hc->last_buf)) obj_len = sizeof(hc->last_buf);
	memcpy(hc->last_buf, buf + toks[0].start, obj_len);
	hc->last_len = obj_len;
	hc->called++;
}

/* ---------- pump that drives read -> parse -> (maybe) read again ---------- */

struct pump_ctx {
	struct jsonrpc_io *jin;
	struct handler_ctx *hc;
};

static struct io_plan *pump_next(struct io_conn *conn, struct pump_ctx *pc)
{
	for (;;) {
		const jsmntok_t *toks;
		const char *buf;
		const char *err = jsonrpc_io_parse(tmpctx, pc->jin, &toks, &buf);

		assert(!err);
		if (!toks) {
			/* Need more bytes */
			return jsonrpc_io_read(conn, pc->jin, pump_next, pc);
		}

		/* Got a full JSON-RPC message */
		record_message(buf, toks, pc->hc);
		jsonrpc_io_parse_done(pc->jin);

		/* Loop to consume any additional buffered messages
		 * without asking for more input yet. */
	}
}

/* ---------- helpers ---------- */

static struct jsonrpc_io *mk_reader(const tal_t *ctx)
{
	return jsonrpc_io_new(ctx);
}

static void run_once(struct jsonrpc_io *jin, struct handler_ctx *hc)
{
	struct pump_ctx pc = { .jin = jin, .hc = hc };
	jsonrpc_io_read(NULL, jin, pump_next, &pc);
}

/* ---------- tests ---------- */

static size_t test_single_message_chunked(size_t chunksize)
{
	struct handler_ctx hc = {0};
	const char *msg = "{\"jsonrpc\":\"2.0\",\"id\":1,\"result\":true}\n";
	struct jsonrpc_io *jin = mk_reader(NULL);

	feed_set(msg, chunksize);
	run_once(jin, &hc);

	assert(hc.called == 1);
	assert(FEED.off == FEED.len);
	assert(hc.last_len > 0 && hc.last_buf[0] == '{' && hc.last_buf[hc.last_len-1] == '}');

	tal_free(jin);
	return strlen(msg);
}

static size_t test_two_messages_back_to_back(size_t chunksize)
{
	struct handler_ctx hc = {0};
	const char *msgs =
		"{\"jsonrpc\":\"2.0\",\"id\":1,\"method\":\"ping\"}\n"
		"{\"jsonrpc\":\"2.0\",\"id\":2,\"result\":42}\n";
	struct jsonrpc_io *jin = mk_reader(NULL);

	feed_set(msgs, chunksize);
	run_once(jin, &hc);

	assert(hc.called == 2);
	assert(FEED.off == FEED.len);

	tal_free(jin);
	return strlen(msgs);
}

static size_t test_whitespace_only(size_t chunksize)
{
	struct handler_ctx hc = {0};
	const char *ws = " \t \n  \r\n  ";
	struct jsonrpc_io *jin = mk_reader(NULL);

	feed_set(ws, chunksize);
	run_once(jin, &hc);

	assert(hc.called == 0);
	assert(FEED.off == FEED.len);

	tal_free(jin);
	return strlen(ws);
}

static size_t test_message_then_whitespace_then_message(size_t chunksize)
{
	struct handler_ctx hc = {0};
	const char *msgs =
		"{\"jsonrpc\":\"2.0\",\"id\":7,\"result\":true}\n"
		"   \n \t"
		"{\"jsonrpc\":\"2.0\",\"id\":8,\"result\":false}\n";
	struct jsonrpc_io *jin = mk_reader(NULL);

	feed_set(msgs, chunksize);
	run_once(jin, &hc);

	assert(hc.called == 2);
	assert(FEED.off == FEED.len);

	tal_free(jin);
	return strlen(msgs);
}

/* ---------- main ---------- */

int main(int argc, char *argv[])
{
	size_t max = 1;

	common_setup(argv[0]);

	for (size_t i = 0; i < max + 10; i++) {
		max = max_u64(max, test_single_message_chunked(i));
		max = max_u64(max, test_two_messages_back_to_back(i));
		max = max_u64(max, test_whitespace_only(i));
		max = max_u64(max, test_message_then_whitespace_then_message(i));
	}

	common_shutdown();
	return 0;
}