acl/lib_acl_cpp/samples/redis/redis_stream/redis_stream.cpp
2018-11-25 23:16:25 +08:00

404 lines
10 KiB
C++

#include "stdafx.h"
static acl::string __key = "stream_key";
static void test_xadd(acl::redis_stream& redis, int n)
{
acl::string name, value, result;
std::map<acl::string, acl::string> fields;
int i;
for (i = 0; i < n; i++) {
name.format("name-%d-1", i);
value.format("value-%d-1", i);
fields[name] = value;
name.format("name-%d-2", i);
value.format("value-%d-2", i);
fields[name] = value;
name.format("name-%d-3", i);
value.format("value-%d-3", i);
fields[name] = value;
if (redis.xadd(__key, fields, result) == false) {
printf("xadd error=%s\r\n", redis.result_error());
break;
}
printf("xadd ok, key=%s, id=%s\r\n",
__key.c_str(), result.c_str());
fields.clear();
}
printf("xadd ok, key=%s, n=%d\r\n", __key.c_str(), i);
}
static void test_xdel(acl::redis_stream& redis, const char* id)
{
std::vector<acl::string> ids;
ids.push_back(id);
int ret = redis.xdel(__key, ids);
printf("xdel=%d, key=%s\r\n", ret, __key.c_str());
}
static void test_xtrim(acl::redis_stream& redis, int n)
{
int ret = redis.xtrim(__key, (size_t) n);
printf("xtrim=%d, key=%s, n=%d\r\n", ret, __key.c_str(), n);
}
static void test_xlen(acl::redis_stream& redis)
{
int ret = redis.xlen(__key);
printf("xlen=%d, key=%s\r\n", ret, __key.c_str());
}
static void test_xgroup_create(acl::redis_stream& redis, const char* group)
{
if (redis.xgroup_create(__key, group) == false) {
printf("xgroup_create error=%s, key=%s, group=%s\r\n",
redis.result_error(), __key.c_str(), group);
} else {
printf("xgroup_create ok, key=%s, group=%s\r\n",
__key.c_str(), group);
}
}
static void show_message(const acl::redis_stream_message& message)
{
printf("\tid=%s\r\n", message.id.c_str());
for (std::vector<acl::redis_stream_field>::const_iterator cit
= message.fields.begin(); cit != message.fields.end(); ++cit) {
printf("\t\tname=%s, value=%s\r\n", (*cit).name.c_str(),
(*cit).value.c_str());
}
}
static void show_messages(const acl::redis_stream_messages& messages)
{
printf("key=%s\r\n", messages.key.c_str());
for (std::vector<acl::redis_stream_message>::const_iterator
it = messages.messages.begin(); it != messages.messages.end();
++it) {
show_message(*it);
}
printf("total messages count=%lu\r\n", (unsigned long) messages.size());
}
static void test_xreadgroup(acl::redis_stream& redis, const char* group,
const char* consumer)
{
acl::redis_stream_messages messages;
std::map<acl::string, acl::string> streams;
streams[__key] = ">";
if (redis.xreadgroup(messages, group, consumer, streams) == false) {
printf("xreadgroup error=%s, key=%s, group=%s, consumer=%s\r\n",
redis.result_error(), __key.c_str(), group, consumer);
const acl::string* req = redis.request_buf();
printf("request=[%s]\r\n", req ? req->c_str() : "NULL");
return;
}
printf("xreadgroup ok, key=%s, group=%s, consumer=%s\r\n",
__key.c_str(), group, consumer);
if (messages.empty()) {
printf("no messages\r\n");
} else {
show_messages(messages);
}
}
static void test_xread(acl::redis_stream& redis, size_t count)
{
acl::redis_stream_messages messages;
std::map<acl::string, acl::string> streams;
streams[__key] = "0-0";
if (redis.xread(messages, streams, count) == false) {
printf("xread error=%s, key=%s\r\n",
redis.result_error(), __key.c_str());
const acl::string* req = redis.request_buf();
printf("request=[%s]\r\n", req ? req->c_str() : "NULL");
return;
}
printf("xread ok, key=%s\r\n", __key.c_str());
if (messages.empty()) {
printf("no messages\r\n");
} else {
show_messages(messages);
}
}
static void test_xack(acl::redis_stream& redis, const char* group, const char* id)
{
int ret = redis.xack(__key, group, id);
const acl::string* req = redis.request_buf();
printf("xack=%d, key=%s, group=%s, id=%s, req=[%s]\r\n",
ret, __key.c_str(), group, id, req ? req->c_str() : "NULL");
}
static void test_xrange(acl::redis_stream& redis, size_t count)
{
acl::redis_stream_messages messages;
if (redis.xrange(messages, __key, "-", "+", count) == false) {
printf("xrange error=%s, key=%lu\r\n",
redis.result_error(), (unsigned long) count);
return;
}
printf("xrange ok, key=%s\r\n", __key.c_str());
if (messages.empty()) {
printf("no messages\r\n");
const acl::string* req = redis.request_buf();
printf("request=[%s]\r\n", req ? req->c_str() : "NULL");
} else {
show_messages(messages);
}
}
static void test_xrevrange(acl::redis_stream& redis, size_t count)
{
acl::redis_stream_messages messages;
if (redis.xrevrange(messages, __key, "+", "-", count) == false) {
printf("xrevrange error=%s, key=%lu\r\n",
redis.result_error(), (unsigned long) count);
return;
}
printf("xrevrange ok, key=%s\r\n", __key.c_str());
const acl::string* req = redis.request_buf();
printf("request=[%s]\r\n", req ? req->c_str() : "NULL");
if (messages.empty()) {
printf("no messages\r\n");
} else {
show_messages(messages);
}
}
static void show_pending_consumer(const acl::redis_pending_consumer& consumer)
{
printf("\tconsumer=%s\r\n", consumer.name.c_str());
printf("\tpending_number=%lu\r\n", (unsigned long) consumer.pending_number);
}
static void show_xpending_summary(const acl::redis_pending_summary& summary)
{
printf("smallest_id=%s\r\n", summary.smallest_id.c_str());
printf("greatest_id=%s\r\n", summary.greatest_id.c_str());
for (std::vector<acl::redis_pending_consumer>::const_iterator cit =
summary.consumers.begin(); cit != summary.consumers.end(); ++cit) {
show_pending_consumer(*cit);
}
}
static void test_xpending_summary(acl::redis_stream& redis, const char* group)
{
acl::redis_pending_summary summary;
if (redis.xpending_summary(__key, group, summary) == false) {
printf("xpending_summary error=%s, key=%s, group=%s\r\n",
redis.result_error(), __key.c_str(), group);
return;
}
show_xpending_summary(summary);
}
static void test_xinfo_help(acl::redis_stream& redis)
{
std::vector<acl::string> infos;
if (redis.xinfo_help(infos)) {
for (std::vector<acl::string>::const_iterator cit = infos.begin();
cit != infos.end(); ++cit) {
printf("%s\r\n", (*cit).c_str());
}
} else {
printf("xinfo_help error=%s\r\n", redis.result_error());
}
}
static void show_xinfo_consumer(const acl::redis_xinfo_consumer& info)
{
printf("\tconsumer=%s\r\n", info.name.c_str());
printf("\tpending=%lu\r\n", (unsigned long) info.pending);
printf("\tidle=%lu\r\n", (unsigned long) info.idle);
}
static void test_xinfo_consumers(acl::redis_stream& redis, const char* group)
{
std::map<acl::string, acl::redis_xinfo_consumer> result;
if (redis.xinfo_consumers(__key, group, result) == false) {
printf("xinfo_consumers error=%s, key=%s, group=%s\r\n",
redis.result_error(), __key.c_str(), group);
return;
}
printf("key=%s, group=%s\r\n", __key.c_str(), group);
for (std::map<acl::string, acl::redis_xinfo_consumer>::const_iterator
cit = result.begin(); cit != result.end(); ++cit) {
show_xinfo_consumer(cit->second);
}
}
static void show_xinfo_group(const acl::redis_xinfo_group& info)
{
printf("\tgroup=%s\r\n", info.name.c_str());
printf("\tlast_delivered_id=%s\r\n", info.last_delivered_id.c_str());
printf("\tconsumers=%lu\r\n", (unsigned long) info.consumers);
printf("\tpending=%lu\r\n", (unsigned long) info.pending);
}
static void test_xinfo_groups(acl::redis_stream& redis)
{
std::map<acl::string, acl::redis_xinfo_group> result;
if (redis.xinfo_groups(__key, result) == false) {
printf("xinfo_groups error=%s, key=%s\r\n",
redis.result_error(), __key.c_str());
return;
}
printf("key=%s\r\n", __key.c_str());
for (std::map<acl::string, acl::redis_xinfo_group>::const_iterator
cit = result.begin(); cit != result.end(); ++cit) {
show_xinfo_group(cit->second);
}
}
static void test_xinfo_stream(acl::redis_stream& redis)
{
acl::redis_stream_info info;
if (redis.xinfo_stream(__key, info) == false) {
printf("xinfo_stream error=%s, key=%s\r\n",
redis.result_error(), __key.c_str());
return;
}
printf("key=%s\r\n", __key.c_str());
printf("\tlength=%lu\r\n", (unsigned long) info.length);
printf("\tradix_tree_keys=%lu\r\n", (unsigned long) info.radix_tree_keys);
printf("\tradix_tree_nodes=%lu\r\n", (unsigned long) info.radix_tree_nodes);
printf("\tgroups=%lu\r\n", (unsigned long) info.groups);
printf("\tlast_generated_id=%s\r\n", info.last_generated_id.c_str());
printf("\tfirst_entry:\r\n");
show_message(info.first_entry);
printf("\tlast_entry:\r\n");
show_message(info.last_entry);
}
static void usage(const char* procname)
{
printf("usage: %s -h [help]\r\n"
" -s redis_addr[default: 127.0.0.1:6379]\r\n"
" -a cmd[default: xadd, xadd|xlen|xdel|xgroup_create|xreadgroup|xack]\r\n"
" -g group[default: mygroup]\r\n"
" -u consumer[default: consumer]\r\n"
" -i message_id\r\n"
, procname);
}
int main(int argc, char* argv[])
{
acl::string addr("127.0.0.1:16379"), cmd("xadd"), group("mygroup");
acl::string consumer("myconsumer"), id;
int ch, n = 10;
while ((ch = getopt(argc, argv, "hs:a:n:g:u:i:")) > 0) {
switch (ch) {
case 'h':
usage(argv[0]);
return 0;
case 's':
addr = optarg;
break;
case 'a':
cmd = optarg;
break;
case 'n':
n = atoi(optarg);
break;
case 'g':
group = optarg;
break;
case 'u':
consumer = optarg;
break;
case 'i':
id = optarg;
break;
default:
break;
}
}
acl::acl_cpp_init();
acl::log::stdout_open(true);
acl::redis_client_cluster cluster;
cluster.set(addr, 0, 5, 5);
acl::redis_stream redis;
redis.set_cluster(&cluster, 0);
cmd.lower();
if (cmd == "xadd") {
test_xadd(redis, n);
} else if (cmd == "xlen") {
test_xlen(redis);
} else if (cmd == "xdel") {
test_xdel(redis, id);
} else if (cmd == "xtrim") {
test_xtrim(redis, n);
} else if (cmd == "xgroup_create") {
test_xgroup_create(redis, group);
} else if (cmd == "xreadgroup") {
test_xreadgroup(redis, group, consumer);
} else if (cmd == "xread") {
test_xread(redis, n);
} else if (cmd == "xack") {
if (id.empty()) {
printf("message id null\r\n");
} else {
test_xack(redis, group, id);
}
} else if (cmd == "xrange") {
test_xrange(redis, n);
} else if (cmd == "xrevrange") {
test_xrevrange(redis, n);
} else if (cmd == "xpending_summary") {
test_xpending_summary(redis, group);
} else if (cmd == "xinfo_help") {
test_xinfo_help(redis);
} else if (cmd == "xinfo_consumers") {
test_xinfo_consumers(redis, group);
} else if (cmd == "xinfo_groups") {
test_xinfo_groups(redis);
} else if (cmd == "xinfo_stream") {
test_xinfo_stream(redis);
} else {
usage(argv[0]);
return 1;
}
return 0;
}