Esempio n. 1
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// mustParseSelectStatement parses a select statement. Panic on error.
func mustParseSelectStatement(s string) *influxql.SelectStatement {
	stmt, err := influxql.NewParser(strings.NewReader(s)).ParseStatement()
	if err != nil {
		panic(err)
	}
	return stmt.(*influxql.SelectStatement)
}
// MustParseQuery parses an InfluxQL query. Panic on error.
func mustParseQuery(s string) *influxql.Query {
	q, err := influxql.NewParser(strings.NewReader(s)).ParseQuery()
	if err != nil {
		panic(err.Error())
	}
	return q
}
Esempio n. 3
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// 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 * FROM myseries`,
		},
	}

	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)
		}

		_, 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())
		}
	}
}
Esempio n. 4
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// 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())
	}
}
Esempio n. 5
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// 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,
		q:        q.Source,
	}

	return cquery, nil
}
Esempio n. 6
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func (s *Store) CreateMapper(shardID uint64, query string, chunkSize int) (Mapper, error) {
	q, err := influxql.NewParser(strings.NewReader(query)).ParseStatement()
	if err != nil {
		return nil, err
	}
	stmt, ok := q.(*influxql.SelectStatement)
	if !ok {
		return nil, fmt.Errorf("query is not a SELECT statement: %s", err.Error())
	}

	shard := s.Shard(shardID)
	if shard == nil {
		// This can happen if the shard has been assigned, but hasn't actually been created yet.
		return nil, nil
	}

	if (stmt.IsRawQuery && !stmt.HasDistinct()) || stmt.IsSimpleDerivative() {
		return NewRawMapper(shard, stmt, chunkSize), nil
	}
	return NewAggMapper(shard, stmt), nil
}
Esempio n. 7
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// Ensure that we see if a where clause has only time limitations
func TestSelectStatement_OnlyTimeDimensions(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 stmt.(*influxql.SelectStatement).OnlyTimeDimensions() != tt.exp {
			t.Fatalf("%d. expected statement to return only time dimension to be %t: %s", i, tt.exp, tt.stmt)
		}
	}
}
Esempio n. 8
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// Test SELECT statement wildcard rewrite.
func TestSelectStatement_RewriteWildcards(t *testing.T) {
	var fields = influxql.Fields{
		&influxql.Field{Expr: &influxql.VarRef{Val: "value1"}},
		&influxql.Field{Expr: &influxql.VarRef{Val: "value2"}},
	}
	var dimensions = influxql.Dimensions{
		&influxql.Dimension{Expr: &influxql.VarRef{Val: "host"}},
		&influxql.Dimension{Expr: &influxql.VarRef{Val: "region"}},
	}

	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 value1, value2 FROM cpu GROUP BY host, region`,
		},

		// Parser fundamentally prohibits multiple query sources

		// Query wildcard with explicit
		// {
		//	stmt:    `SELECT *,value1 FROM cpu`,
		//		rewrite: `SELECT value1, value2, value1 FROM cpu`,
		//	},

		// Query multiple wildcards
		//	{
		//			stmt:    `SELECT *,* FROM cpu`,
		//			rewrite: `SELECT value1,value2,value1,value2 FROM cpu`,
		//  },

		// 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 {
		t.Logf("index: %d, statement: %s", i, tt.stmt)
		// Parse statement.
		stmt, err := influxql.NewParser(strings.NewReader(tt.stmt)).ParseStatement()
		if err != nil {
			t.Fatalf("invalid statement: %q: %s", tt.stmt, err)
		}

		// Rewrite statement.
		rw := stmt.(*influxql.SelectStatement).RewriteWildcards(fields, dimensions)
		if rw == nil {
			t.Errorf("%d. %q: unexpected nil statement", i, tt.stmt)
			continue
		}
		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)
			continue
		}
	}
}
Esempio n. 9
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// 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 > 1.000`,
		},

		// 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 1.000 = 2.000`,
		},

		// 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 1.000 = 2.000`,
		},
	}

	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
		}
	}
}
Esempio n. 10
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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.
		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 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
		}
	}
}
Esempio n. 11
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// 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)
	min, max := influxql.TimeRange(s.Condition)
	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 = influxql.TimeRange(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 = influxql.TimeRange(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 = influxql.TimeRange(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 = influxql.TimeRange(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")
	}
}
Esempio n. 12
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// serveQuery parses an incoming query and, if valid, executes the query.
func (h *Handler) serveQuery(w http.ResponseWriter, r *http.Request, user *meta.UserInfo) {
	q := r.URL.Query()
	pretty := q.Get("pretty") == "true"

	qp := strings.TrimSpace(q.Get("q"))
	if qp == "" {
		httpError(w, `missing required parameter "q"`, pretty, http.StatusBadRequest)
		return
	}

	epoch := strings.TrimSpace(q.Get("epoch"))

	p := influxql.NewParser(strings.NewReader(qp))
	db := q.Get("db")

	// Parse query from query string.
	query, err := p.ParseQuery()
	if err != nil {
		httpError(w, "error parsing query: "+err.Error(), pretty, http.StatusBadRequest)
		return
	}

	// Sanitize statements with passwords.
	for _, s := range query.Statements {
		switch stmt := s.(type) {
		case *influxql.CreateUserStatement:
			sanitize(r, stmt.Password)
		case *influxql.SetPasswordUserStatement:
			sanitize(r, stmt.Password)
		}
	}

	// Check authorization.
	if h.requireAuthentication {
		err = h.QueryExecutor.Authorize(user, query, db)
		if err != nil {
			httpError(w, "error authorizing query: "+err.Error(), pretty, http.StatusUnauthorized)
			return
		}
	}

	// Parse chunk size. Use default if not provided or unparsable.
	chunked := (q.Get("chunked") == "true")
	chunkSize := DefaultChunkSize
	if chunked {
		if n, err := strconv.ParseInt(q.Get("chunk_size"), 10, 64); err == nil {
			chunkSize = int(n)
		}
	}

	// Execute query.
	w.Header().Add("content-type", "application/json")
	results, err := h.QueryExecutor.ExecuteQuery(query, db, chunkSize)

	if err != nil {
		w.WriteHeader(http.StatusInternalServerError)
		return
	}

	// if we're not chunking, this will be the in memory buffer for all results before sending to client
	resp := Response{Results: make([]*influxql.Result, 0)}

	// Status header is OK once this point is reached.
	w.WriteHeader(http.StatusOK)

	// pull all results from the channel
	for r := range results {
		// Ignore nil results.
		if r == nil {
			continue
		}

		// if requested, convert result timestamps to epoch
		if epoch != "" {
			convertToEpoch(r, epoch)
		}

		// Write out result immediately if chunked.
		if chunked {
			w.Write(MarshalJSON(Response{
				Results: []*influxql.Result{r},
			}, pretty))
			w.(http.Flusher).Flush()
			continue
		}

		// It's not chunked so buffer results in memory.
		// Results for statements need to be combined together.
		// We need to check if this new result is for the same statement as
		// the last result, or for the next statement
		l := len(resp.Results)
		if l == 0 {
			resp.Results = append(resp.Results, r)
		} else if resp.Results[l-1].StatementID == r.StatementID {
			cr := resp.Results[l-1]
			cr.Series = append(cr.Series, r.Series...)
		} else {
			resp.Results = append(resp.Results, r)
		}
	}

	// If it's not chunked we buffered everything in memory, so write it out
	if !chunked {
		w.Write(MarshalJSON(resp, pretty))
	}
}