func TestSelectStatement_IsSimpleDerivative(t *testing.T) {
var tests = []struct {
stmt string
derivative bool
}{
// No derivatives
{
stmt: `SELECT value FROM cpu`,
derivative: false,
},
// Query derivative
{
stmt: `SELECT derivative(value) FROM cpu`,
derivative: true,
},
// Query derivative
{
stmt: `SELECT non_negative_derivative(value) FROM cpu`,
derivative: true,
},
// No GROUP BY time only
{
stmt: `SELECT mean(value) FROM cpu where time < now() GROUP BY time(5ms)`,
derivative: false,
},
// No GROUP BY derivatives, time only
{
stmt: `SELECT non_negative_derivative(mean(value)) FROM cpu where time < now() GROUP BY time(5ms)`,
derivative: false,
},
// Invalid derivative function name
{
stmt: `SELECT typoDerivative(value) FROM cpu where time < now()`,
derivative: false,
},
}
for i, tt := range tests {
// Parse statement.
t.Logf("index: %d, statement: %s", i, tt.stmt)
stmt, err := influxql.NewParser(strings.NewReader(tt.stmt)).ParseStatement()
if err != nil {
t.Fatalf("invalid statement: %q: %s", tt.stmt, err)
}
// Test derivative detection.
if d := stmt.(*influxql.SelectStatement).IsSimpleDerivative(); tt.derivative != d {
t.Errorf("%d. %q: unexpected derivative detection:\n\nexp=%v\n\ngot=%v\n\n", i, tt.stmt, tt.derivative, d)
continue
}
}
}
func TestSelectStatement_HasCountDistinct(t *testing.T) {
var tests = []struct {
stmt string
count bool
}{
// No counts
{
stmt: `SELECT value FROM cpu`,
count: false,
},
// Query count
{
stmt: `SELECT count(value) FROM cpu`,
count: false,
},
// No GROUP BY time only
{
stmt: `SELECT count(distinct(value)) FROM cpu where time < now() GROUP BY time(5ms)`,
count: true,
},
// Query count
{
stmt: `SELECT typoCount(value) FROM cpu`,
count: false,
},
// No GROUP BY time only
{
stmt: `SELECT typoCount(distinct(value)) FROM cpu where time < now() GROUP BY time(5ms)`,
count: false,
},
}
for i, tt := range tests {
// Parse statement.
t.Logf("index: %d, statement: %s", i, tt.stmt)
stmt, err := influxql.NewParser(strings.NewReader(tt.stmt)).ParseStatement()
if err != nil {
t.Fatalf("invalid statement: %q: %s", tt.stmt, err)
}
// Test count detection.
if c := stmt.(*influxql.SelectStatement).HasCountDistinct(); tt.count != c {
t.Errorf("%d. %q: unexpected count detection:\n\nexp=%v\n\ngot=%v\n\n", i, tt.stmt, tt.count, c)
continue
}
}
}
// Ensure the SELECT statement can extract GROUP BY interval.
func TestSelectStatement_GroupByInterval(t *testing.T) {
q := "SELECT sum(value) from foo where time < now() GROUP BY time(10m)"
stmt, err := influxql.NewParser(strings.NewReader(q)).ParseStatement()
if err != nil {
t.Fatalf("invalid statement: %q: %s", stmt, err)
}
s := stmt.(*influxql.SelectStatement)
d, err := s.GroupByInterval()
if d != 10*time.Minute {
t.Fatalf("group by interval not equal:\nexp=%s\ngot=%s", 10*time.Minute, d)
}
if err != nil {
t.Fatalf("error parsing group by interval: %s", err.Error())
}
}
// Ensure that we see if a where clause has only time limitations
func TestOnlyTimeExpr(t *testing.T) {
var tests = []struct {
stmt string
exp bool
}{
{
stmt: `SELECT value FROM myseries WHERE value > 1`,
exp: false,
},
{
stmt: `SELECT value FROM foo WHERE time >= '2000-01-01T00:00:05Z'`,
exp: true,
},
{
stmt: `SELECT value FROM foo WHERE time >= '2000-01-01T00:00:05Z' AND time < '2000-01-01T00:00:05Z'`,
exp: true,
},
{
stmt: `SELECT value FROM foo WHERE time >= '2000-01-01T00:00:05Z' AND asdf = 'bar'`,
exp: false,
},
{
stmt: `SELECT value FROM foo WHERE asdf = 'jkl' AND (time >= '2000-01-01T00:00:05Z' AND time < '2000-01-01T00:00:05Z')`,
exp: false,
},
}
for i, tt := range tests {
// Parse statement.
stmt, err := influxql.NewParser(strings.NewReader(tt.stmt)).ParseStatement()
if err != nil {
t.Fatalf("invalid statement: %q: %s", tt.stmt, err)
}
if influxql.OnlyTimeExpr(stmt.(*influxql.SelectStatement).Condition) != tt.exp {
t.Fatalf("%d. expected statement to return only time dimension to be %t: %s", i, tt.exp, tt.stmt)
}
}
}
// NewContinuousQuery returns a ContinuousQuery object with a parsed influxql.CreateContinuousQueryStatement
func NewContinuousQuery(database string, cqi *meta.ContinuousQueryInfo) (*ContinuousQuery, error) {
stmt, err := influxql.NewParser(strings.NewReader(cqi.Query)).ParseStatement()
if err != nil {
return nil, err
}
q, ok := stmt.(*influxql.CreateContinuousQueryStatement)
if !ok || q.Source.Target == nil || q.Source.Target.Measurement == nil {
return nil, errors.New("query isn't a valid continuous query")
}
cquery := &ContinuousQuery{
Database: database,
Info: cqi,
Resample: ResampleOptions{
Every: q.ResampleEvery,
For: q.ResampleFor,
},
q: q.Source,
}
return cquery, nil
}
// Ensure that the String() value of a statement is parseable
func TestParseString(t *testing.T) {
var tests = []struct {
stmt string
}{
{
stmt: `SELECT "cpu load" FROM myseries`,
},
{
stmt: `SELECT "cpu load" FROM "my series"`,
},
{
stmt: `SELECT "cpu\"load" FROM myseries`,
},
{
stmt: `SELECT "cpu'load" FROM myseries`,
},
{
stmt: `SELECT "cpu load" FROM "my\"series"`,
},
{
stmt: `SELECT "field with spaces" FROM "\"ugly\" db"."\"ugly\" rp"."\"ugly\" measurement"`,
},
{
stmt: `SELECT * FROM myseries`,
},
{
stmt: `DROP DATABASE "!"`,
},
{
stmt: `DROP RETENTION POLICY "my rp" ON "a database"`,
},
{
stmt: `CREATE RETENTION POLICY "my rp" ON "a database" DURATION 1d REPLICATION 1`,
},
{
stmt: `ALTER RETENTION POLICY "my rp" ON "a database" DEFAULT`,
},
{
stmt: `SHOW RETENTION POLICIES ON "a database"`,
},
{
stmt: `SHOW TAG VALUES WITH KEY IN ("a long name", short)`,
},
{
stmt: `DROP CONTINUOUS QUERY "my query" ON "my database"`,
},
// See issues https://github.com/skia-dev/influxdb/issues/1647
// and https://github.com/skia-dev/influxdb/issues/4404
//{
// stmt: `DELETE FROM "my db"."my rp"."my measurement"`,
//},
{
stmt: `DROP SUBSCRIPTION "ugly \"subscription\" name" ON "\"my\" db"."\"my\" rp"`,
},
{
stmt: `CREATE SUBSCRIPTION "ugly \"subscription\" name" ON "\"my\" db"."\"my\" rp" DESTINATIONS ALL 'my host', 'my other host'`,
},
{
stmt: `SHOW MEASUREMENTS WITH MEASUREMENT =~ /foo/`,
},
{
stmt: `SHOW MEASUREMENTS WITH MEASUREMENT = "and/or"`,
},
{
stmt: `DROP USER "user with spaces"`,
},
{
stmt: `GRANT ALL PRIVILEGES ON "db with spaces" TO "user with spaces"`,
},
{
stmt: `GRANT ALL PRIVILEGES TO "user with spaces"`,
},
{
stmt: `SHOW GRANTS FOR "user with spaces"`,
},
{
stmt: `REVOKE ALL PRIVILEGES ON "db with spaces" FROM "user with spaces"`,
},
{
stmt: `REVOKE ALL PRIVILEGES FROM "user with spaces"`,
},
{
stmt: `CREATE DATABASE "db with spaces"`,
},
}
for _, tt := range tests {
// Parse statement.
stmt, err := influxql.NewParser(strings.NewReader(tt.stmt)).ParseStatement()
if err != nil {
t.Fatalf("invalid statement: %q: %s", tt.stmt, err)
}
stmtCopy, err := influxql.NewParser(strings.NewReader(stmt.String())).ParseStatement()
if err != nil {
t.Fatalf("failed to parse string: %v\norig: %v\ngot: %v", err, tt.stmt, stmt.String())
}
if !reflect.DeepEqual(stmt, stmtCopy) {
t.Fatalf("statement changed after stringifying and re-parsing:\noriginal : %v\nre-parsed: %v\n", tt.stmt, stmtCopy.String())
}
}
}
// Ensure the SELECT statement can extract substatements.
func TestSelectStatement_Substatement(t *testing.T) {
var tests = []struct {
stmt string
expr *influxql.VarRef
sub string
err string
}{
// 0. Single series
{
stmt: `SELECT value FROM myseries WHERE value > 1`,
expr: &influxql.VarRef{Val: "value"},
sub: `SELECT value FROM myseries WHERE value > 1`,
},
// 1. Simple join
{
stmt: `SELECT sum(aa.value) + sum(bb.value) FROM aa, bb`,
expr: &influxql.VarRef{Val: "aa.value"},
sub: `SELECT "aa.value" FROM aa`,
},
// 2. Simple merge
{
stmt: `SELECT sum(aa.value) + sum(bb.value) FROM aa, bb`,
expr: &influxql.VarRef{Val: "bb.value"},
sub: `SELECT "bb.value" FROM bb`,
},
// 3. Join with condition
{
stmt: `SELECT sum(aa.value) + sum(bb.value) FROM aa, bb WHERE aa.host = 'servera' AND bb.host = 'serverb'`,
expr: &influxql.VarRef{Val: "bb.value"},
sub: `SELECT "bb.value" FROM bb WHERE "bb.host" = 'serverb'`,
},
// 4. Join with complex condition
{
stmt: `SELECT sum(aa.value) + sum(bb.value) FROM aa, bb WHERE aa.host = 'servera' AND (bb.host = 'serverb' OR bb.host = 'serverc') AND 1 = 2`,
expr: &influxql.VarRef{Val: "bb.value"},
sub: `SELECT "bb.value" FROM bb WHERE ("bb.host" = 'serverb' OR "bb.host" = 'serverc') AND 1 = 2`,
},
// 5. 4 with different condition order
{
stmt: `SELECT sum(aa.value) + sum(bb.value) FROM aa, bb WHERE ((bb.host = 'serverb' OR bb.host = 'serverc') AND aa.host = 'servera') AND 1 = 2`,
expr: &influxql.VarRef{Val: "bb.value"},
sub: `SELECT "bb.value" FROM bb WHERE (("bb.host" = 'serverb' OR "bb.host" = 'serverc')) AND 1 = 2`,
},
}
for i, tt := range tests {
// Parse statement.
stmt, err := influxql.NewParser(strings.NewReader(tt.stmt)).ParseStatement()
if err != nil {
t.Fatalf("invalid statement: %q: %s", tt.stmt, err)
}
// Extract substatement.
sub, err := stmt.(*influxql.SelectStatement).Substatement(tt.expr)
if err != nil {
t.Errorf("%d. %q: unexpected error: %s", i, tt.stmt, err)
continue
}
if substr := sub.String(); tt.sub != substr {
t.Errorf("%d. %q: unexpected substatement:\n\nexp=%s\n\ngot=%s\n\n", i, tt.stmt, tt.sub, substr)
continue
}
}
}
// Test SELECT statement wildcard rewrite.
func TestSelectStatement_RewriteWildcards(t *testing.T) {
var tests = []struct {
stmt string
rewrite string
}{
// No wildcards
{
stmt: `SELECT value FROM cpu`,
rewrite: `SELECT value FROM cpu`,
},
// Query wildcard
{
stmt: `SELECT * FROM cpu`,
rewrite: `SELECT host, region, value1, value2 FROM cpu`,
},
// Parser fundamentally prohibits multiple query sources
// Query wildcard with explicit
{
stmt: `SELECT *,value1 FROM cpu`,
rewrite: `SELECT host, region, value1, value2, value1 FROM cpu`,
},
// Query multiple wildcards
{
stmt: `SELECT *,* FROM cpu`,
rewrite: `SELECT host, region, value1, value2, host, region, value1, value2 FROM cpu`,
},
// Query wildcards with group by
{
stmt: `SELECT * FROM cpu GROUP BY host`,
rewrite: `SELECT region, value1, value2 FROM cpu GROUP BY host`,
},
// No GROUP BY wildcards
{
stmt: `SELECT value FROM cpu GROUP BY host`,
rewrite: `SELECT value FROM cpu GROUP BY host`,
},
// No GROUP BY wildcards, time only
{
stmt: `SELECT mean(value) FROM cpu where time < now() GROUP BY time(5ms)`,
rewrite: `SELECT mean(value) FROM cpu WHERE time < now() GROUP BY time(5ms)`,
},
// GROUP BY wildcard
{
stmt: `SELECT value FROM cpu GROUP BY *`,
rewrite: `SELECT value FROM cpu GROUP BY host, region`,
},
// GROUP BY wildcard with time
{
stmt: `SELECT mean(value) FROM cpu where time < now() GROUP BY *,time(1m)`,
rewrite: `SELECT mean(value) FROM cpu WHERE time < now() GROUP BY host, region, time(1m)`,
},
// GROUP BY wildarde with fill
{
stmt: `SELECT mean(value) FROM cpu where time < now() GROUP BY *,time(1m) fill(0)`,
rewrite: `SELECT mean(value) FROM cpu WHERE time < now() GROUP BY host, region, time(1m) fill(0)`,
},
// GROUP BY wildcard with explicit
{
stmt: `SELECT value FROM cpu GROUP BY *,host`,
rewrite: `SELECT value FROM cpu GROUP BY host, region, host`,
},
// GROUP BY multiple wildcards
{
stmt: `SELECT value FROM cpu GROUP BY *,*`,
rewrite: `SELECT value FROM cpu GROUP BY host, region, host, region`,
},
// Combo
{
stmt: `SELECT * FROM cpu GROUP BY *`,
rewrite: `SELECT value1, value2 FROM cpu GROUP BY host, region`,
},
}
for i, tt := range tests {
// Parse statement.
stmt, err := influxql.NewParser(strings.NewReader(tt.stmt)).ParseStatement()
if err != nil {
t.Fatalf("invalid statement: %q: %s", tt.stmt, err)
}
var ic IteratorCreator
ic.FieldDimensionsFn = func(sources influxql.Sources) (fields, dimensions map[string]struct{}, err error) {
fields = map[string]struct{}{"value1": struct{}{}, "value2": struct{}{}}
dimensions = map[string]struct{}{"host": struct{}{}, "region": struct{}{}}
return
}
// Rewrite statement.
rw, err := stmt.(*influxql.SelectStatement).RewriteWildcards(&ic)
if err != nil {
t.Errorf("%d. %q: error: %s", i, tt.stmt, err)
} else if rw == nil {
t.Errorf("%d. %q: unexpected nil statement", i, tt.stmt)
} else if rw := rw.String(); tt.rewrite != rw {
t.Errorf("%d. %q: unexpected rewrite:\n\nexp=%s\n\ngot=%s\n\n", i, tt.stmt, tt.rewrite, rw)
}
}
}
func TestSelectStatement_HasWildcard(t *testing.T) {
var tests = []struct {
stmt string
wildcard bool
}{
// No wildcards
{
stmt: `SELECT value FROM cpu`,
wildcard: false,
},
// Query wildcard
{
stmt: `SELECT * FROM cpu`,
wildcard: true,
},
// No GROUP BY wildcards
{
stmt: `SELECT value FROM cpu GROUP BY host`,
wildcard: false,
},
// No GROUP BY wildcards, time only
{
stmt: `SELECT mean(value) FROM cpu where time < now() GROUP BY time(5ms)`,
wildcard: false,
},
// GROUP BY wildcard
{
stmt: `SELECT value FROM cpu GROUP BY *`,
wildcard: true,
},
// GROUP BY wildcard with time
{
stmt: `SELECT mean(value) FROM cpu where time < now() GROUP BY *,time(1m)`,
wildcard: true,
},
// GROUP BY wildcard with explicit
{
stmt: `SELECT value FROM cpu GROUP BY *,host`,
wildcard: true,
},
// GROUP BY multiple wildcards
{
stmt: `SELECT value FROM cpu GROUP BY *,*`,
wildcard: true,
},
// Combo
{
stmt: `SELECT * FROM cpu GROUP BY *`,
wildcard: true,
},
}
for i, tt := range tests {
// Parse statement.
stmt, err := influxql.NewParser(strings.NewReader(tt.stmt)).ParseStatement()
if err != nil {
t.Fatalf("invalid statement: %q: %s", tt.stmt, err)
}
// Test wildcard detection.
if w := stmt.(*influxql.SelectStatement).HasWildcard(); tt.wildcard != w {
t.Errorf("%d. %q: unexpected wildcard detection:\n\nexp=%v\n\ngot=%v\n\n", i, tt.stmt, tt.wildcard, w)
continue
}
}
}
// Ensure the SELECT statement can have its start and end time set
func TestSelectStatement_SetTimeRange(t *testing.T) {
q := "SELECT sum(value) from foo where time < now() GROUP BY time(10m)"
stmt, err := influxql.NewParser(strings.NewReader(q)).ParseStatement()
if err != nil {
t.Fatalf("invalid statement: %q: %s", stmt, err)
}
s := stmt.(*influxql.SelectStatement)
start := time.Now().Add(-20 * time.Hour).Round(time.Second).UTC()
end := time.Now().Add(10 * time.Hour).Round(time.Second).UTC()
s.SetTimeRange(start, end)
min, max := MustTimeRange(s.Condition)
if min != start {
t.Fatalf("start time wasn't set properly.\n exp: %s\n got: %s", start, min)
}
// the end range is actually one nanosecond before the given one since end is exclusive
end = end.Add(-time.Nanosecond)
if max != end {
t.Fatalf("end time wasn't set properly.\n exp: %s\n got: %s", end, max)
}
// ensure we can set a time on a select that already has one set
start = time.Now().Add(-20 * time.Hour).Round(time.Second).UTC()
end = time.Now().Add(10 * time.Hour).Round(time.Second).UTC()
q = fmt.Sprintf("SELECT sum(value) from foo WHERE time >= %ds and time <= %ds GROUP BY time(10m)", start.Unix(), end.Unix())
stmt, err = influxql.NewParser(strings.NewReader(q)).ParseStatement()
if err != nil {
t.Fatalf("invalid statement: %q: %s", stmt, err)
}
s = stmt.(*influxql.SelectStatement)
min, max = MustTimeRange(s.Condition)
if start != min || end != max {
t.Fatalf("start and end times weren't equal:\n exp: %s\n got: %s\n exp: %s\n got:%s\n", start, min, end, max)
}
// update and ensure it saves it
start = time.Now().Add(-40 * time.Hour).Round(time.Second).UTC()
end = time.Now().Add(20 * time.Hour).Round(time.Second).UTC()
s.SetTimeRange(start, end)
min, max = MustTimeRange(s.Condition)
// TODO: right now the SetTimeRange can't override the start time if it's more recent than what they're trying to set it to.
// shouldn't matter for our purposes with continuous queries, but fix this later
if min != start {
t.Fatalf("start time wasn't set properly.\n exp: %s\n got: %s", start, min)
}
// the end range is actually one nanosecond before the given one since end is exclusive
end = end.Add(-time.Nanosecond)
if max != end {
t.Fatalf("end time wasn't set properly.\n exp: %s\n got: %s", end, max)
}
// ensure that when we set a time range other where clause conditions are still there
q = "SELECT sum(value) from foo WHERE foo = 'bar' and time < now() GROUP BY time(10m)"
stmt, err = influxql.NewParser(strings.NewReader(q)).ParseStatement()
if err != nil {
t.Fatalf("invalid statement: %q: %s", stmt, err)
}
s = stmt.(*influxql.SelectStatement)
// update and ensure it saves it
start = time.Now().Add(-40 * time.Hour).Round(time.Second).UTC()
end = time.Now().Add(20 * time.Hour).Round(time.Second).UTC()
s.SetTimeRange(start, end)
min, max = MustTimeRange(s.Condition)
if min != start {
t.Fatalf("start time wasn't set properly.\n exp: %s\n got: %s", start, min)
}
// the end range is actually one nanosecond before the given one since end is exclusive
end = end.Add(-time.Nanosecond)
if max != end {
t.Fatalf("end time wasn't set properly.\n exp: %s\n got: %s", end, max)
}
// ensure the where clause is there
hasWhere := false
influxql.WalkFunc(s.Condition, func(n influxql.Node) {
if ex, ok := n.(*influxql.BinaryExpr); ok {
if lhs, ok := ex.LHS.(*influxql.VarRef); ok {
if lhs.Val == "foo" {
if rhs, ok := ex.RHS.(*influxql.StringLiteral); ok {
if rhs.Val == "bar" {
hasWhere = true
}
}
}
}
}
})
if !hasWhere {
t.Fatal("set time range cleared out the where clause")
}
}