= Querying in Sequel This guide is based on http://guides.rubyonrails.org/active_record_querying.html == Purpose of this Guide Sequel is a simple to use, very flexible, and powerful database library that supports a wide variety of different querying methods. This guide aims to be a gentle introduction to Sequel's querying support. While you can easily use raw SQL with Sequel, a large part of the advantage you get from using Sequel is Sequel's ability to abstract SQL from you and give you a much nicer interface. Sequel also ships with a {core_extensions extension}[rdoc-ref:doc/core_extensions.rdoc], which better integrates Sequel's DSL into the ruby language. == Retrieving Objects Sequel provides a few separate methods for retrieving objects from the database. The underlying method is Sequel::Dataset#each, which yields each row as the Sequel::Database provides it. However, while Dataset#each can and often is used directly, in many cases there is a more convenient retrieval method you can use. === Sequel::Dataset If you are new to Sequel and aren't familiar with Sequel, you should probably read the {"Dataset Basics" guide}[rdoc-ref:doc/dataset_basics.rdoc], then come back here. === Retrieving a Single Object Sequel offers quite a few ways to to retrieve a single object. ==== Using a Primary Key [Sequel::Model] The Sequel::Model.[] is the easiest method to use to find a model instance by its primary key value: # Find artist with primary key (id) 1 artist = Artist[1] # SELECT * FROM artists WHERE id = 1 => #"YJM", :id=>1}> If there is no record with the given primary key, nil will be returned. If you want to raise an exception if no record is found, you can use Sequel::Model.with_pk!: artist = Artist.with_pk!(1) ==== Using +first+ If you just want the first record in the dataset, Sequel::Dataset#first is probably the most obvious method to use: artist = Artist.first # SELECT * FROM artists LIMIT 1 => #"YJM", :id=>1}> Any options you pass to +first+ will be used as a filter: artist = Artist.first(:name => 'YJM') # SELECT * FROM artists WHERE (name = 'YJM') LIMIT 1 => #"YJM", :id=>1}> artist = Artist.first(Sequel.like(:name, 'Y%')) # SELECT * FROM artists WHERE (name LIKE 'Y%') LIMIT 1 => #"YJM", :id=>1}> If there is no matching row, +first+ will return nil. If you want to raise an exception instead, use first!. Sequel::Dataset#[] is basically an alias for +first+, except it requires an argument: DB[:artists][:name => 'YJM'] # SELECT * FROM artists WHERE (name = 'YJM') LIMIT 1 => {:name=>"YJM", :id=>1} Note that while Model.[] allows you to pass a primary key directly, Dataset#[] does not (unless it is a model dataset). ==== Using +last+ If you want the last record in the dataset, Sequel::Dataset#last is an obvious method to use. Note that last requires that the dataset be ordered, unless the dataset is a model dataset. For a model dataset, +last+ will do a reverse order by the primary key field: artist = Artist.last # SELECT * FROM artists ORDER BY id DESC LIMIT 1 => #"YJM", :id=>1}> Note that what +last+ does is reverse the order of the dataset and then call +first+. This is why +last+ raises a Sequel::Error if there is no order on a plain dataset, because otherwise it would provide the same record as +first+, and most users would find that confusing. Note that +last+ is not necessarily going to give you the last record in the dataset unless you give the dataset an unambiguous order. ==== Retrieving a Single Column Value Sometimes, instead of wanting an entire row, you only want the value of a specific column. For this Sequel::Dataset#get is the method you want: artist_name = Artist.get(:name) # SELECT name FROM artists LIMIT 1 => "YJM" === Retrieving Multiple Objects ==== As an Array of Hashes or Model Objects In many cases, you want an array of all of the rows associated with the dataset, in which case Sequel::Dataset#all is the method you want to use: artists = Artist.all # SELECT * FROM artists => [#"YJM", :id=>1}>, #"AS", :id=>2}>] ==== Using an Enumerable Interface Sequel::Dataset uses an Enumerable Interface, so it provides a method named each that yields hashes or model objects as they are retrieved from the database: Artist.each{|x| p x.name} # SELECT * FROM artists "YJM" "AS" This means that all of the methods in the Enumerable module are available, such as +map+: artist_names = Artist.map{|x| x.name} # SELECT * FROM artists => ["YJM", "AS"] ==== As an Array of Column Values Sequel also has an extended +map+ method that takes an argument. If you provide an argument to +map+, it will return an array of values for the given column. So the previous example can be handled more easily with: artist_names = Artist.map(:name) # SELECT * FROM artists => ["YJM", "AS"] One difference between these two ways of returning an array of values is that providing +map+ with an argument is really doing: artist_names = Artist.map{|x| x[:name]} # not x.name Note that regardless of whether you provide +map+ with an argument, it does not modify the columns selected. If you only want to select a single column and return an array of the columns values, you can use +select_map+: artist_names = Artist.select_map(:name) # SELECT name FROM artists => ["YJM", "AS"] It's also common to want to order such a map, so Sequel provides a +select_order_map+ method as well: artist_names = Artist.select_order_map(:name) # SELECT name FROM artists ORDER BY name => ["AS", "YJM"] In all of these cases, you can provide an array of column symbols and an array of arrays of values will be returned: artist_names = Artist.select_map([:id, :name]) # SELECT id, name FROM artists => [[1, "YJM"], [2, "AS"]] ==== As a Hash Sequel makes it easy to take an SQL query and return it as a ruby hash, using the +to_hash+ method: artist_names = Artist.to_hash(:id, :name) # SELECT * FROM artists => {1=>"YJM", 2=>"AS"} As you can see, the +to_hash+ method uses the first symbol as the key and the second symbol as the value. So if you swap the two arguments the hash will have its keys and values transposed: artist_names = Artist.to_hash(:name, :id) # SELECT * FROM artists => {"YJM"=>1, "AS"=>2} Now what if you have multiple values for the same key? By default, +to_hash+ will just have the last matching value. If you care about all matching values, use +to_hash_groups+, which makes the values of the array an array of matching values, in the order they were received: artist_names = Artist.to_hash_groups(:name, :id) # SELECT * FROM artists => {"YJM"=>[1, 10, ...], "AS"=>[2, 20, ...]} If you only provide one argument to +to_hash+, it uses the entire hash or model object as the value: artist_names = DB[:artists].to_hash(:name) # SELECT * FROM artists => {"YJM"=>{:id=>1, :name=>"YJM"}, "AS"=>{:id=>2, :name=>"AS"}} and +to_hash_groups+ works similarly: artist_names = DB[:artists].to_hash_groups(:name) # SELECT * FROM artists => {"YJM"=>[{:id=>1, :name=>"YJM"}, {:id=>10, :name=>"YJM"}], ...} Model datasets have a +to_hash+ method that can be called without any arguments, in which case it will use the primary key as the key and the model object as the value. This can be used to easily create an identity map: artist_names = Artist.to_hash # SELECT * FROM artists => {1=>#1, :name=>"YGM"}>, 2=>#2, :name=>"AS"}>} There is no equivalent handling to +to_hash_groups+, since there would only be one matching record, as the primary key must be unique. Note that +to_hash+ never modifies the columns selected. However, just like Sequel has a +select_map+ method to modify the columns selected and return an array, Sequel also has a +select_hash+ method to modify the columns selected and return a hash: artist_names = Artist.select_hash(:name, :id) # SELECT name, id FROM artists => {"YJM"=>1, "AS"=>2} Likewise, +select_hash_groups+ also exists: artist_names = Artist.select_hash_groups(:name, :id) # SELECT name, id FROM artists => {"YJM"=>[1, 10, ...], "AS"=>[2, 20, ...]} == Modifying datasets Note that the retrieval methods discussed above just return the row(s) included in the existing dataset. In most cases, you aren't interested in every row in a table, but in a subset of the rows, based on some criteria. In Sequel, filtering the dataset is generally done separately than retrieving the records. There are really two types of dataset methods that you will be using: 1. Methods that return row(s), discussed above 2. Methods that return modified datasets, discussed below Sequel uses a method chaining, functional style API to modify datasets. Let's start with a simple example. This is a basic dataset that includes all records in the table +artists+: ds1 = DB[:artists] # SELECT * FROM artists Let's say we are only interested in the artists whose names start with "A": ds2 = ds1.where(Sequel.like(:name, 'A%')) # SELECT * FROM artists WHERE name LIKE 'A%' Here we see that +where+ returns a dataset that adds a +WHERE+ clause to the query. It's important to note that +where+ does not modify the receiver: ds1 # SELECT * FROM artists ds2 # SELECT * FROM artists WHERE name LIKE 'A%' In Sequel, most dataset methods that you will be using will not modify the dataset itself, so you can freely use the dataset in multiple places without worrying that its usage in one place will affect its usage in another place. This is what is meant by a functional style API. Let's say we only want to select the id and name columns, and that we want to order by name: ds3 = ds.order(:name).select(:id, :name) # SELECT id, name FROM artists WHERE name LIKE 'A%' ORDER BY name Note how you don't need to assign the returned value of order to a variable, and then call select on that. Because order just returns a dataset, you can call select directly on the returned dataset. This is what is meant by a method chaining API. Also note how you can call methods that modify different clauses in any order. In this case, the WHERE clause was added first, then the ORDER clause, then the SELECT clause was modified. This makes for a flexible API, where you can modify any part of the query at any time. == Filters Filtering is probably the most common dataset modifying action done in Sequel. Both the +where+ and +filter+ methods filter the dataset by modifying the dataset's WHERE clause. Both accept a wide variety of input formats, discussed below. === Hashes The most common format for providing filters is via a hash. In general, Sequel treats conditions specified with a hash as equality or inclusion. What type of condition is used depends on the values in the hash. Unless Sequel has special support for the value's class, it uses a simple equality statement: Artist.where(:id=>1) # SELECT * FROM artists WHERE id = 1 Artist.where(:name=>'YJM') # SELECT * FROM artists WHERE name = 'YJM' For arrays, Sequel uses the IN operator. Artist.where(:id=>[1, 2]) # SELECT * FROM artists WHERE id IN (1, 2) For datasets, Sequel uses the IN operator with a subselect: Artist.where(:id=>Album.select(:artist_id)) # SELECT * FROM artists WHERE id IN ( # SELECT artist_id FROM albums) For boolean values such as nil, true, and false, Sequel uses the IS operator: Artist.where(:id=>nil) # SELECT * FROM artists WHERE id IS NULL For ranges, Sequel uses a pair of inequality statements: Artist.where(:id=>1..5) # SELECT * FROM artists WHERE id >= 1 AND id <= 5 Finally, for regexps, Sequel uses an SQL regular expression. Note that this is probably only supported on PostgreSQL and MySQL. Artist.where(:name=>/JM$/) # SELECT * FROM artists WHERE name ~ 'JM$' If there are multiple arguments in the hash, the filters are ANDed together: Artist.where(:id=>1, :name=>/JM$/) # SELECT * FROM artists WHERE id = 1 AND name ~ 'JM$' This works the same as if you used two separate +where+ calls: Artist.where(:id=>1).where(:name=>/JM$/) # SELECT * FROM artists WHERE id = 1 AND name ~ 'JM$' === Array of Two Element Arrays If you use an array of two element arrays, it is treated as a hash. The only advantage to using an array of two element arrays is that it allows you to duplicate keys, so you can do: Artist.where([[:name, /JM$/], [:name, /^YJ/]]) # SELECT * FROM artists WHERE name ~ 'JM$' AND name ~ '^YJ' === Virtual Row Blocks If a block is passed to a filter, it is treated as a virtual row block: Artist.where{id > 5} # SELECT * FROM artists WHERE id > 5 You can learn more about virtual row blocks in the {"Virtual Rows" guide}[rdoc-ref:doc/virtual_rows.rdoc]. You can provide both regular arguments and a block, in which case the results will be ANDed together: Artist.where(:name=>'A'...'M'){id > 5} # SELECT * FROM artists WHERE name >= 'A' AND name < 'M' AND id > 5 === Symbols If you have a boolean column in the database, and you want only true values, you can just provide the column symbol to filter: Artist.where(:retired) # SELECT * FROM artists WHERE retired === SQL::Expression Sequel has a DSL that allows easily creating SQL expressions. These SQL expressions are instances of subclasses of Sequel::SQL::Expression. You've already seen an example earlier: Artist.where(Sequel.like(:name, 'Y%')) # SELECT * FROM artists WHERE name LIKE 'Y%' In this case Sequel.like returns a Sequel::SQL::BooleanExpression object, which is used directly in the filter. You can use the DSL to create arbitrarily complex expressions. SQL::Expression objects can be created via singleton methods on the Sequel module. The most common method is Sequel.expr, which takes any object and wraps it in a SQL::Expression object. In most cases, the SQL::Expression returned supports the & operator for +AND+, the | operator for +OR+, and the ~ operator for inversion: Artist.where(Sequel.like(:name, 'Y%') & (Sequel.expr(:b=>1) | Sequel.~(:c=>3))) # SELECT * FROM artists WHERE name LIKE 'Y%' AND (b = 1 OR c != 3) You can combine these expression operators with the virtual row support: Artist.where{(a > 1) & ~((b(c) < 1) | d)} # SELECT * FROM artists WHERE a > 1 AND b(c) >= 1 AND NOT d Note the use of parentheses when using the & and | operators, as they have lower precedence than other operators. The following will not work: Artist.where{a > 1 & ~(b(c) < 1 | d)} # Raises a TypeError, as it calls Integer#| with a Sequel::SQL::Identifier === Strings with Placeholders Assuming you want to get your hands dirty and write some SQL, Sequel allows you to use strings using placeholders for the values: Artist.where("name LIKE ?", 'Y%') # SELECT * FROM artists WHERE name LIKE 'Y%' This is the most common type of placeholder, where each question mark is substituted with the next argument: Artist.where("name LIKE ? AND id = ?", 'Y%', 5) # SELECT * FROM artists WHERE name LIKE 'Y%' AND id = 5 You can also use named placeholders with a hash, where the named placeholders use colons before the placeholder names: Artist.where("name LIKE :name AND id = :id", :name=>'Y%', :id=>5) # SELECT * FROM artists WHERE name LIKE 'Y%' AND id = 5 You don't have to provide any placeholders if you don't want to: Artist.where("id = 2") # SELECT * FROM artists WHERE id = 2 However, if you are using any untrusted input, you should definitely be using placeholders. In general, unless you are hardcoding values in the strings, you should use placeholders. You should never pass a string that has been built using interpolation, unless you are sure of what you are doing. Artist.where("id = #{params[:id]}") # Don't do this! Artist.where("id = ?", params[:id]) # Do this instead Artist.where(:id=>params[:id].to_i) # Even better === Inverting You may be wondering how to specify a not equals condition in Sequel, or the NOT IN operator. Sequel has generic support for inverting conditions, so to write a not equals condition, you write an equals condition, and invert it: Artist.where(:id=>5).invert # SELECT * FROM artists WHERE id != 5 Note that +invert+ inverts the entire filter: Artist.where(:id=>5).where{name > 'A'}.invert # SELECT * FROM artists WHERE id != 5 OR name <= 'A' In general, +invert+ is used rarely, since +exclude+ allows you to invert only specific filters: Artist.exclude(:id=>5) # SELECT * FROM artists WHERE id != 5 Artist.where(:id=>5).exclude{name > 'A'} # SELECT * FROM artists WHERE id = 5 OR name <= 'A' So to do a NOT IN with an array: Artist.exclude(:id=>[1, 2]) # SELECT * FROM artists WHERE id NOT IN (1, 2) Or to use the NOT LIKE operator: Artist.exclude(Sequel.like(:name, '%J%')) # SELECT * FROM artists WHERE name NOT LIKE '%J%' === Removing To remove all existing filters, use +unfiltered+: Artist.where(:id=>1).unfiltered # SELECT * FROM artists == Ordering Sequel offers quite a few methods to manipulate the SQL ORDER BY clause. The most basic of these is +order+: Artist.order(:id) # SELECT * FROM artists ORDER BY id You can specify multiple arguments to order by more than one column: Album.order(:artist_id, :id) # SELECT * FROM album ORDER BY artist_id, id Note that unlike +where+, +order+ replaces an existing order, it does not append to an existing order: Artist.order(:id).order(:name) # SELECT * FROM artists ORDER BY name If you want to add a column to the end of the existing order: Artist.order(:id).order_append(:name) # SELECT * FROM artists ORDER BY id, name If you want to add a column to the beginning of the existing order: Artist.order(:id).order_prepend(:name) # SELECT * FROM artists ORDER BY name, id === Reversing Just like you can invert an existing filter, you can reverse an existing order, using +reverse+: Artist.order(:id).reverse # SELECT FROM artists ORDER BY id DESC As you might expect, +reverse+ is not used all that much. In general, Sequel.desc is used more commonly to specify a descending order for columns: Artist.order(Sequel.desc(:id)) # SELECT FROM artists ORDER BY id DESC This allows you to easily use both ascending and descending orders: Artist.order(:name, Sequel.desc(:id)) # SELECT FROM artists ORDER BY name, id DESC === Removing Just like you can remove filters with +unfiltered+, you can remove orders with +unordered+: Artist.order(:name).unordered # SELECT * FROM artists == Selected Columns Sequel offers a few methods to manipulate the columns selected. As you may be able to guess, the main method used is +select+: Artist.select(:id, :name) # SELECT id, name FROM artists You just specify all of the columns that you are selecting as arguments to the method. If you are dealing with model objects, you'll want to include the primary key if you want to update or destroy the object. You'll also want to include any keys (primary or foreign) related to associations you plan to use. If a column is not selected, and you attempt to access it, you will get nil: artist = Artist.select(:name).first # SELECT name FROM artists LIMIT 1 artist[:id] # => nil Like +order+, +select+ replaces the existing selected columns: Artist.select(:id).select(:name) # SELECT name FROM artists To add to the existing selected columns, use +select_append+: Artist.select(:id).select_append(:name) # SELECT id, name FROM artists To remove specifically selected columns, and default back to all columns, use +select_all+: Artist.select(:id).select_all # SELECT * FROM artists To select all columns from a given table, provide an argument to +select_all+: Artist.select_all(:artists) # SELECT artists.* FROM artists === Distinct To treat duplicate rows as a single row when retrieving the records, use +distinct+: Artist.distinct.select(:name) # SELECT DISTINCT name FROM artists Note that DISTINCT is a separate SQL clause, it's not a function that you pass to select. == Limit and Offset You can limit the dataset to a given number of rows using +limit+: Artist.limit(5) # SELECT * FROM artists LIMIT 5 You can provide a second argument to +limit+ to specify an offset: Artist.limit(5, 10) # SELECT * FROM artists LIMIT 5 OFFSET 10 You can also call the +offset+ method separately: Artist.limit(5).offset(10) # SELECT * FROM artists LIMIT 5 OFFSET 10 Either of these would return the 11th through 15th records in the original dataset. To remove a limit from a dataset, use +unlimited+: Artist.limit(5, 10).unlimited # SELECT * FROM artists == Grouping The SQL GROUP BY clause is used to combine multiple rows based on the values of a given group of columns. To modify the GROUP BY clause of the SQL statement, you use +group+: Album.group(:artist_id) # SELECT * FROM albums GROUP BY artist_id You can remove an existing grouping using +ungrouped+: Album.group(:artist_id).ungrouped # SELECT * FROM albums A common use of grouping is to count based on the number of grouped rows, and Sequel provides a +group_and_count+ method to make this easier: Album.group_and_count(:artist_id) # SELECT artist_id, count(*) AS count FROM albums GROUP BY artist_id This will return the number of albums for each artist_id. If you want to select and group on the same columns, you can use +select_group+: Album.select_group(:artist_id) # SELECT artist_id FROM albums GROUP BY artist_id Usually you would add a +select_append+ call after that, to add some sort of aggregation: Album.select_group(:artist_id).select_append{sum(num_tracks).as(tracks)} # SELECT artist_id, sum(num_tracks) AS tracks FROM albums GROUP BY artist_id == Having The SQL HAVING clause is similar to the WHERE clause, except that filters the results after the grouping has been applied, instead of before. One possible use is if you only wanted to return artists who had at least 10 albums: Album.group_and_count(:artist_id).having{count(:*){} >= 10} # SELECT artist_id, count(*) AS count FROM albums # GROUP BY artist_id HAVING count(*) >= 10 Both the WHERE clause and the HAVING clause are removed by +unfiltered+: Album.group_and_count(:artist_id).having{count(:*){} >= 10}. where(:name.like('A%')).unfiltered # SELECT artist_id, count(*) AS count FROM albums GROUP BY artist_id == Joins Sequel makes it very easy to join a dataset to another table or dataset. The underlying method used is +join_table+: Album.join_table(:inner, :artists, :id=>:artist_id) # SELECT * FROM albums # INNER JOIN artists ON artists.id = albums.artist_id In most cases, you won't call +join_table+ directly, as Sequel provides shortcuts for all common (and most uncommon) join types. For example +join+ does an inner join: Album.join(:artists, :id=>:artist_id) # SELECT * FROM albums # INNER JOIN artists ON artists.id = albums.artist_id And +left_join+ does a LEFT JOIN: Album.left_join(:artists, :id=>:artist_id) # SELECT * FROM albums # LEFT JOIN artists ON artists.id = albums.artist_id === Table/Dataset to Join For all of these specialized join methods, the first argument is generally the name of the table to which you are joining. However, you can also provide a model class: Album.join(Artist, :id=>:artist_id) Or a dataset, in which case a subselect is used: Album.join(Artist.where{name < 'A'}, :id=>:artist_id) # SELECT * FROM albums # INNER JOIN (SELECT * FROM artists WHERE (name < 'A')) AS t1 # ON (t1.id = albums.artist_id) === Join Conditions The second argument to the specialized join methods is the conditions to use when joining, which is similar to a filter expression, with a few minor exceptions. ==== Implicit Qualification A hash used as the join conditions operates similarly to a filter, except that unqualified symbol keys are automatically qualified with the table from the first argument, and unqualified symbol values are automatically qualified with the first table or the last table joined. This implicit qualification is one of the reasons that joins in Sequel are easy to specify: Album.join(:artists, :id=>:artist_id) # SELECT * FROM albums # INNER JOIN artists ON artists.id = albums.artist_id Note how the :id symbol is automatically qualified with +artists+, while the +artist_id+ symbol is automatically qualified with +albums+. Because Sequel uses the last joined table for implicit qualifications of values, you can do things like: Album.join(:artists, :id=>:artist_id). join(:members, :artist_id=>:id) # SELECT * FROM albums # INNER JOIN artists ON artists.id = albums.artist_id # INNER JOIN members ON members.artist_id = artists.id Note that when joining to the +members+ table, +artist_id+ is qualified with +members+ and +id+ is qualified with +artists+. While a good default, implicit qualification is not always correct: Album.join(:artists, :id=>:artist_id). join(:tracks, :album_id=>:id) # SELECT * FROM albums # INNER JOIN artists ON artists.id = albums.artist_id # INNER JOIN tracks ON tracks.album_id = artists.id Note here how +id+ is qualified with +artists+ instead of +albums+. This is wrong as the foreign key tracks.album_id refers to albums.id, not artists.id. To fix this, you need to explicitly qualify when joining: Album.join(:artists, :id=>:artist_id). join(:tracks, :album_id=>:albums__id) # SELECT * FROM albums # INNER JOIN artists ON artists.id = albums.artist_id # INNER JOIN tracks ON tracks.album_id = albums.id Just like in filters, an array of two element arrays is treated the same as a hash, but allows for duplicate keys: Album.join(:artists, [[:id, :artist_id], [:id, 1..5]]) # SELECT * FROM albums INNER JOIN artists # ON artists.id = albums.artist_id # AND artists.id >= 1 AND artists.id <= 5 And just like in the hash case, unqualified symbol elements in the array are implicitly qualified. By default, Sequel only qualifies unqualified symbols in the conditions. However, You can provide an options hash with a :qualify=>:deep option to do a deep qualification, which can qualify subexpressions. For example, let's say you are doing a JOIN using case insensitive string comparison: Album.join(:artists, {Sequel.function(:lower, :name) => Sequel.function(:lower, :artist_name)}, :qualify => :deep) # SELECT * FROM albums INNER JOIN artists # ON (lower(artists.name) = lower(albums.artist_name)) Note how the arguments to lower were qualified correctly in both cases. Starting in Sequel 4, the :qualify=>:deep option is going to become the default. ==== USING Joins The most common type of join conditions is a JOIN ON, as displayed above. However, the SQL standard allows for join conditions to be specified with JOIN USING, which Sequel makes easy to use. JOIN USING is useful when the columns you are using have the same names in both tables. For example, if instead of having a primary column named +id+ in all of your tables, you use +artist_id+ in your +artists+ table and +album_id+ in your +albums+ table, you could do: Album.join(:artists, [:artist_id]) # SELECT * FROM albums INNER JOIN artists USING (artist_id) See here how you specify the USING columns as an array of symbols. ==== NATURAL Joins NATURAL Joins take it one step further than USING joins, by assuming that all columns with the same names in both tables should be used for joining: Album.natural_join(:artists) # SELECT * FROM albums NATURAL JOIN artists In this case, you don't even need to specify any conditions. ==== Join Blocks You can provide a block to any of the join methods that accept conditions. This block should accept 3 arguments, the table alias for the table currently being joined, the table alias for the last table joined (or first table), and an array of previous Sequel::SQL::JoinClauses. This allows you to qualify columns similar to how the implicit qualification works, without worrying about the specific aliases being used. For example, lets say you wanted to join the albums and artists tables, but only want albums where the artist's name comes before the album's name. Album.join(:artists, :id=>:artist_id) do |j, lj, js| Sequel.qualify(j, :name) < Sequel.qualify(lj, :name) end # SELECT * FROM albums INNER JOIN artists # ON artists.id = albums.artist_id # AND artists.name < albums.name Because greater than can't be expressed with a hash in Sequel, you need to use a block and qualify the tables manually. == From In general, the FROM table is the first clause populated when creating a dataset. For a standard Sequel::Model, the dataset already has the FROM clause populated, and the most common way to create datasets is with the Database#[] method, which populates the FROM clause. However, you can modify the tables you are selecting FROM using +from+: Album.from(:albums, :old_albums) # SELECT * FROM albums, old_albums Be careful with this, as multiple tables in the FROM clause use a cross join by default, so the number of rows will be number of albums times the number of old albums. Using multiple FROM tables and setting conditions in the WHERE clause is an old-school way of joining tables: DB.from(:albums, :artists).where(:artists__id=>:albums__artist_id) # SELECT * FROM albums, artists WHERE artists.id = albums.artist_id === Using the current dataset in a subselect In some cases, you may want to wrap the current dataset in a subselect. Here's an example using +from_self+: Album.order(:artist_id).limit(100).from_self.group(:artist_id) # SELECT * FROM (SELECT * FROM albums ORDER BY artist_id LIMIT 100) # AS t1 GROUP BY artist_id This is slightly different than without +from_self+: Album.order(:artist_id).limit(100).group(:artist_id) # SELECT * FROM albums GROUP BY artist_id ORDER BY name LIMIT 100 Without +from_self+, you are doing the grouping, and limiting the number of grouped records returned to 100. So assuming you have albums by more than 100 artists, you'll end up with 100 results. With +from_self+, you are limiting the number of records before grouping. So if the artist with the lowest id had 100 albums, you'd get 1 result, not 100. == Locking for Update Sequel allows you to easily add a FOR UPDATE clause to your queries so that the records returned can't be modified by another query until the current transaction commits. You just use the +for_update+ dataset method when returning the rows: DB.transaction do album = Album.for_update.first(:id=>1) # SELECT * FROM albums WHERE id = 1 FOR UPDATE album.num_tracks += 1 album.save end This will ensure that no other connection modifies the row between when you select it and when the transaction ends. === Optimistic Locking One of the model plugins that ships with Sequel is an optimistic locking plugin, which provides a database independent way to detect and raise an error if two different connections modify the same row. It's useful for things like web forms where you cannot keep a transaction open while the user is looking at the form, because of the web's stateless nature. == Custom SQL Sequel makes it easy to use custom SQL by providing it to the Database#[] method as a string: DB["SELECT * FROM artists"] # SELECT * FROM artists You can also use the +with_sql+ dataset method to return a dataset that uses that exact SQL: DB[:albums].with_sql("SELECT * FROM artists") # SELECT * FROM artists With either of these methods, you can use placeholders: DB["SELECT * FROM artists WHERE id = ?", 5] # SELECT * FROM artists WHERE id = 5 DB[:albums].with_sql("SELECT * FROM artists WHERE id = :id", :id=>5) # SELECT * FROM artists WHERE id = 5 Note that if you specify the dataset using custom SQL, you can still call the dataset modification methods, but in many cases they will appear to have no affect: DB["SELECT * FROM artists"].select(:name).order(:id) # SELECT * FROM artists If you must drop down to using custom SQL, it's recommended that you only do so for specific parts of a query. For example, if the reason you are using custom SQL is to use a custom operator in the database in the SELECT clause: DB["SELECT name, (foo !@# ?) AS baz FROM artists", 'bar'] it's better to use Sequel's DSL, and use a literal string for the custom operator: DB[:artists].select(:name, Sequel.lit("(foo !@# ?)", 'bar').as(:baz)) That way Sequel's method chaining still works, and it increases Sequel's ability to introspect the code. == Checking for Records If you just want to know whether the current dataset would return any rows, use empty?: Album.empty? # SELECT 1 FROM albums LIMIT 1 => false Album.where(:id=>0).empty? # SELECT 1 FROM albums WHERE id = 0 LIMIT 1 => true Album.where(Sequel.like(:name, 'R%')).empty? # SELECT 1 FROM albums WHERE name LIKE 'R%' LIMIT 1 => false == Aggregate Calculations The SQL standard defines a few helpful methods to get aggreate information about datasets, such as +count+, +sum+, +avg+, +min+, and +max+. There are dataset methods for each of these aggregate functions. +count+ just returns the number of records in the dataset. Album.count # SELECT count(*) AS count FROM albums LIMIT 1 => 2 The other methods take a column argument and call the aggregate function with the argument: Album.sum(:id) # SELECT sum(id) FROM albums LIMIT 1 => 3 Album.avg(:id) # SELECT avg(id) FROM albums LIMIT 1 => 1.5 Album.min(:id) # SELECT min(id) FROM albums LIMIT 1 => 1 Album.max(:id) # SELECT max(id) FROM albums LIMIT 1 => 2