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75ce4f7b35
Added missing where conditions and documented `.unconditionally`
251 lines
9.2 KiB
Markdown
251 lines
9.2 KiB
Markdown
# Introduction
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_This page explains select statements with a static structure. If you want to learn about constructing select statements at runtime, you should still read this page first and then move on to [dynamic select statements](Dynamic-Select.md)._
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Lets assume we have a table representing
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```SQL
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CREATE TABLE foo (
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id bigint,
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name varchar(50),
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hasFun bool
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);
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```
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(This is SQL for brevity, not C++, see [here](Tables.md) for details on how to define types representing the tables and columns you want to work with)
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Lets also assume we have an object `db` representing a connection to your [database](Database.md).
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# A Basic example
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This shows how you can select some data from table and iterate over the results:
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```C++
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for (const auto& row : db(select(foo.name, foo.hasFun)
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.from(foo)
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.where(foo.id > 17 and foo.name.like("%bar%"))))
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{
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if (row.name.is_null())
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std::cerr << "name is null" << std::endl;
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else
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std::string name = row.name; // string-like fields are implicitly convertible to string
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bool hasFun = row.hasFun; // bool fields are implicitly convertible to bool
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}
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```
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So, what's happening here? Lets ignore the gory details for a moment. Well, there is a select statement.
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```C++
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select(foo.name, foo.hasFun)
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.from(foo)
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.where(foo.id > 17 and foo.name.like("%bar%"))
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```
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It selects two columns `name` and `hasFun` from table `foo` for rows which match the criteria given in the where condition. That's about as close to _real_ SQL as it can get...
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The select expression is fed into the call operator of the connection object `db`. This method sends the select statement to the database and returns an object representing the results. In the case of select statements, the result object represents zero or more rows.
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One way of accessing the rows is to iterate over them in a range-based for loop.
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```C++
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for (const auto& row : ...)
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```
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Ok, so the variable row is an object that represents a single result row. You really want to use `auto` here, because you don't want to write down the actual type. Trust me. But the wonderful thing about the `row` object is that it has appropriately named and typed members representing the columns you selected. This is one of the utterly cool parts of this library.
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Note that a `select` query requires a `where` condition or a call to `.unconditionally()` to express the intent to omit the `where` condition.
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# The Select Statement
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## Select
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The `select` method takes zero or more named expression arguments.
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Named expressions are expressions with a name. No surprise there. But what kind of expressions have a name? Table columns, for instance. In our example, that would be `foo.id`, `foo.name` and `foo.hasFun`. Most [function](Functions.md) calls also result in named expressions, like `count(foo.id)`.
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So what about unnamed expressions? Results of binary operators like `(foo.id + 17) * 4` have no name. But you can give them a name using the `as(alias)` method. The easiest way is to use a named expression as alias, for instance `((foo.id + 17) * 4).as(foo.id)`, e.g.
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```C++
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for (const auto& row : db(select(((foo.id + 17) * 4).as(foo.id)).from(tab).where(foo.id > 42))
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{
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std::cout << row.id << std::endl;
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}
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```
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Another option is to define an alias like this:
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```C++
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SQLPP_ALIAS_PROVIDER(total);
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for (const auto& row : db(select(sum(id).as(total)).as(foo.id)).from(tab)))
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{
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std::cout << row.total << std::endl;
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}
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```
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Using aliases also comes in handy when you join tables and have several columns of the same name, because no two named expressions in a select must have the same name. So if you want to do something like
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```C++
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select(foo.id, bar.id); // compile error
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```
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One of the columns needs an alias.
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```C++
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SQLPP_ALIAS_PROVIDER(barId);
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select(foo.id, bar.id.as(barId));
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```
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### Select Columns
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All examples above called the `select()` function with one or more arguments, but `select()` can also be called with no arguments. In that case, the selected columns have to be added afterwards
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```C++
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sqlpp::select().columns(foo.id, foo.name);
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```
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See also [dynamic select statements](Dynamic-Select.md).
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### Select Flags
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The following flags are currently supported:
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* sqlpp::all
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* sqlpp::distinct
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Flags are added via the `flags()` method:
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```C++
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sqlpp::select().flags(sqlpp::all).columns(foo.id, foo.name);
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```
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or
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```C++
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select(foo.id, foo.name).flags(sqlpp::all);
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```
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The latter is shorter than the former, but the former is closer to SQL syntax and probably easier to read.
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### Sub-Select
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A select statement with one column also is named expression. This means you can use one select as a sub-select column of another select. For example:
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```
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SQLPP_ALIAS_PROVIDER(cheese_cake); // Declared outside of function
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// ...
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for (const auto& row : db(
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select(all_of(foo),
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select(sum(bar.value)).from(bar).where(bar.id > foo.id)),
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select(bar.value.as(cheese_cake)).from(bar).where(bar.id > foo.id))
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.from(foo)))
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{
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const int x = row.id;
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const int64_t a = row.sum;
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const int b = row.cheese_cake;
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}
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```
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The name of the sub select is the name of the one column. If required, you can rename it using `as()`, as usual.
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### Select All Columns
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Statements like `SELECT * from foo` is used pretty often in SQL. sqlpp11 offers something similar:
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```C++
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select(all_of(foo));
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```
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## From
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The `from` method expects one argument. The following subsections expand on the types of valid arguments:
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* tables
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* tables with an alias (via the `as` method)
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* sub-selects with an alias
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* joins
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### Tables
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This is the most simple case.
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```C++
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select(all_of(foo)).from(foo).where(foo.id == 17);
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```
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### Aliased Tables
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Table aliases are useful in self-joins.
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```C++
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SQLPP_ALIAS_PROVIDER(left);
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SQLPP_ALIAS_PROVIDER(right);
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auto l = foo.as(left);
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auto r = foo.as(right);
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select(all_of(l)).from(l.join(r).on(l.x == r.y)).unconditionally();
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```
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Aliased tables might also be used to increase the readability of generated SQL code, for instance if you have very long table names.
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### Aliased Sub-Select
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A select can be used as a pseudo table in another select. You just have to give it a name.
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```C++
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SQLPP_ALIAS_PROVIDER(sub);
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auto sub_select = select(all_of(foo)).from(foo).where(foo.id == 42).as(sub);
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```
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The variable `sub_select` can be used as a table now.
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### Joins
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You can join two tables like this:
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```C++
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foo.join(bar).on(foo.id == bar.foo);
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```
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If you want to join more tables, you can chain joins.
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```C++
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foo.join(bar).on(foo.id == bar.foo).left_outer_join(baz).on(bar.id == baz.ref);
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```
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_Hint_: Omitting the call to `on` will result in mildly horrible error messages. But if you really want to join without a condition, then you can call `.unconditionally()` to express the intent.
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## Where
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The where condition can be set via the `where` method, which takes a boolean expression argument, for instance:
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```C++
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select(all_of(foo)).from(foo).where(foo.id != 17 and foo.name.like("%cake"));
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```
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In order to prevent users from accidentally forgetting the `.where()` clause, the library requires a call to `.where()` or `.unconditionally()`. The latter expresses the intent to select all rows unconditionally.
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## Group By
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The method `group_by` takes one or more expression arguments, for instance:
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```C++
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select(all_of(foo)).from(foo).group_by(foo.name);
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```
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## Having
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The having condition can be set via the `having` method, just like the `where` method.
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## Order By
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The `order_by` method takes one of more order expression, which are normal expression adorned with `.asc()` or `.desc()`, e.g.
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```C++
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select(all_of(foo)).from(foo).order_by(foo.name.asc());
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```
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## Limit And Offset
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The methods `limit` and `offset` take a size_t argument, for instance:
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```C++
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select(all_of(foo)).from(foo).unconditionally().limit(10u).offset(20u);
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```
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## For Update
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The `for_update` method modifies the query with a simplified "FOR UPDATE" clause without columns.
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```C++
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select(all_of(foo)).from(foo).where(foo.id != 17).for_update();
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```
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# Running The Statement
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OK, so now we know how to create a select statement. But the statement does not really do anything unless we hand it over to the database:
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```C++
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db(select(all_of(foo)).from(foo).unconditionally());
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```
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This call returns a result object of a pretty complex type. Thus, you would normally want to use `auto`:
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```C++
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auto result = db(select(all_of(foo)).from(foo).unconditionally());
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```
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# Accessing The Results
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The `result` object created by executing a `select` query is a container of result rows.
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## Range-based For Loops
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Not surprisingly, you can iterate over the rows using a range-based for-loop like this:
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```C++
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for (const auto& row : db(select(all_of(foo)).from(foo)).unconditionally())
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{
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std::cerr << row.id << std::endl;
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std::cerr << row.name << std::endl;
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}
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```
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Lovely, isn't it? The row objects have types specifically tailored for the select query you wrote. You can access their member by name, and these members have the expected type.
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## Function-based Access
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If for some reason, you don't want to use range-based for-loops, you can use `front()` and `pop_front()` on the result, like this:
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```C++
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while(!result.empty())
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{
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const auto& row = result.front();
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std::cerr << row.id << std::endl;
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std::cerr << row.name << std::endl;
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result.pop_front();
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}
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