Struct rocket_dyn_templates::minijinja::Environment
source · pub struct Environment<'source> { /* private fields */ }
Expand description
An abstraction that holds the engine configuration.
This object holds the central configuration state for templates. It is also the container for all loaded templates.
The environment holds references to the source the templates were created from. This makes it very inconvenient to pass around unless the templates are static strings.
There are generally two ways to construct an environment:
Environment::new
creates an environment preconfigured with sensible defaults. It will contain all built-in filters, tests and globals as well as a callback for auto escaping based on file extension.Environment::empty
creates a completely blank environment.
Implementations§
source§impl<'source> Environment<'source>
impl<'source> Environment<'source>
sourcepub fn new() -> Environment<'source>
pub fn new() -> Environment<'source>
Creates a new environment with sensible defaults.
This environment does not yet contain any templates but it will have all
the default filters, tests and globals loaded. If you do not want any
default configuration you can use the alternative
empty
method.
sourcepub fn empty() -> Environment<'source>
pub fn empty() -> Environment<'source>
Creates a completely empty environment.
This environment has no filters, no templates, no globals and no default logic for auto escaping configured.
sourcepub fn add_template(
&mut self,
name: &'source str,
source: &'source str,
) -> Result<(), Error>
pub fn add_template( &mut self, name: &'source str, source: &'source str, ) -> Result<(), Error>
Loads a template from a string into the environment.
The name
parameter defines the name of the template which identifies
it. To look up a loaded template use the get_template
method.
let mut env = Environment::new();
env.add_template("index.html", "Hello {{ name }}!").unwrap();
Note that there are situations where the interface of this method is
too restrictive as you need to hold on to the strings for the lifetime
of the environment.
To address this restriction use add_template_owned
.
sourcepub fn add_template_owned<N, S>(
&mut self,
name: N,
source: S,
) -> Result<(), Error>
pub fn add_template_owned<N, S>( &mut self, name: N, source: S, ) -> Result<(), Error>
Adds a template without borrowing.
This lets you place an owned String
in the environment rather than the
borrowed &str
without having to worry about lifetimes.
let mut env = Environment::new();
env.add_template_owned("index.html".to_string(), "Hello {{ name }}!".to_string()).unwrap();
Note: the name is a bit of a misnomer as this API also allows to borrow too as
the parameters are actually Cow
.
sourcepub fn set_loader<F>(&mut self, f: F)
pub fn set_loader<F>(&mut self, f: F)
Register a template loader as source of templates.
When a template loader is registered, the environment gains the ability
to dynamically load templates. The loader is invoked with the name of
the template. If this template exists Ok(Some(template_source))
has
to be returned, otherwise Ok(None)
. Once a template has been loaded
it’s stored on the environment. This means the loader is only invoked
once per template name.
For loading templates from the file system, you can use the
path_loader
function.
§Example
fn create_env() -> Environment<'static> {
let mut env = Environment::new();
env.set_loader(|name| {
if name == "layout.html" {
Ok(Some("...".into()))
} else {
Ok(None)
}
});
env
}
sourcepub fn set_keep_trailing_newline(&mut self, yes: bool)
pub fn set_keep_trailing_newline(&mut self, yes: bool)
Preserve the trailing newline when rendering templates.
The default is false
, which causes a single newline, if present, to be
stripped from the end of the template.
This setting is used whenever a template is loaded into the environment. Changing it at a later point only affects future templates loaded.
sourcepub fn keep_trailing_newline(&self) -> bool
pub fn keep_trailing_newline(&self) -> bool
Returns the value of the trailing newline preservation flag.
sourcepub fn set_trim_blocks(&mut self, yes: bool)
pub fn set_trim_blocks(&mut self, yes: bool)
Remove the first newline after a block.
If this is set to true
then the first newline after a block is removed
(block, not variable tag!). Defaults to false
.
sourcepub fn trim_blocks(&self) -> bool
pub fn trim_blocks(&self) -> bool
Returns the value of the trim blocks flag.
sourcepub fn set_lstrip_blocks(&mut self, yes: bool)
pub fn set_lstrip_blocks(&mut self, yes: bool)
Remove leading spaces and tabs from the start of a line to a block.
If this is set to true
then leading spaces and tabs from the start of a line
to the block tag are removed.
sourcepub fn lstrip_blocks(&self) -> bool
pub fn lstrip_blocks(&self) -> bool
Returns the value of the lstrip blocks flag.
sourcepub fn remove_template(&mut self, name: &str)
pub fn remove_template(&mut self, name: &str)
Removes a template by name.
sourcepub fn set_path_join_callback<F>(&mut self, f: F)
pub fn set_path_join_callback<F>(&mut self, f: F)
Sets a callback to join template paths.
By default this returns the template path unchanged, but it can be used to implement relative path resolution between templates. The first argument to the callback is the name of the template to be loaded, the second argument is the parent path.
The following example demonstrates how a basic path joining algorithm can be implemented.
env.set_path_join_callback(|name, parent| {
let mut rv = parent.split('/').collect::<Vec<_>>();
rv.pop();
name.split('/').for_each(|segment| match segment {
"." => {}
".." => { rv.pop(); }
_ => { rv.push(segment); }
});
rv.join("/").into()
});
sourcepub fn set_unknown_method_callback<F>(&mut self, f: F)
pub fn set_unknown_method_callback<F>(&mut self, f: F)
Sets a callback invoked for unknown methods on objects.
This registers a function with the environment that is invoked when invoking a method
on a value results in a UnknownMethod
error.
In that case the callback is invoked with State
, the Value
, the name of
the method as &str
as well as all arguments in a slice.
This for instance implements a .items()
method that invokes the |items
filter:
use minijinja::value::{ValueKind, from_args};
use minijinja::{Error, ErrorKind};
env.set_unknown_method_callback(|state, value, method, args| {
if value.kind() == ValueKind::Map && method == "items" {
let _: () = from_args(args)?;
state.apply_filter("items", &[value.clone()])
} else {
Err(Error::from(ErrorKind::UnknownMethod))
}
});
This can be used to increase the compatibility with Jinja2 templates that might
call Python methods on objects which are not available in minijinja. A range of
common Python methods is implemented in minijinja-contrib
. For more information
see minijinja_contrib::pycompat.
sourcepub fn clear_templates(&mut self)
pub fn clear_templates(&mut self)
Removes all stored templates.
This method is mainly useful when combined with a loader as it causes the loader to “reload” templates. By calling this method one can trigger a reload.
sourcepub fn templates(&self) -> impl Iterator<Item = (&str, Template<'_, '_>)>
pub fn templates(&self) -> impl Iterator<Item = (&str, Template<'_, '_>)>
Returns an iterator over the already loaded templates and their names.
Only templates that are already loaded will be returned.
let mut env = Environment::new();
env.add_template("hello.txt", "Hello {{ name }}!").unwrap();
env.add_template("goodbye.txt", "Goodbye {{ name }}!").unwrap();
for (name, tmpl) in env.templates() {
println!("{}", tmpl.render(context!{ name => "World" }).unwrap());
}
sourcepub fn get_template(&self, name: &str) -> Result<Template<'_, '_>, Error>
pub fn get_template(&self, name: &str) -> Result<Template<'_, '_>, Error>
Fetches a template by name.
This requires that the template has been loaded with
add_template
beforehand. If the template was
not loaded an error of kind TemplateNotFound
is returned. If a loader was
added to the engine this can also dynamically load templates.
let mut env = Environment::new();
env.add_template("hello.txt", "Hello {{ name }}!").unwrap();
let tmpl = env.get_template("hello.txt").unwrap();
println!("{}", tmpl.render(context!{ name => "World" }).unwrap());
sourcepub fn template_from_named_str(
&self,
name: &'source str,
source: &'source str,
) -> Result<Template<'_, 'source>, Error>
pub fn template_from_named_str( &self, name: &'source str, source: &'source str, ) -> Result<Template<'_, 'source>, Error>
Loads a template from a string.
In some cases you really only need to work with (eg: render) a template to be rendered once only.
let env = Environment::new();
let tmpl = env.template_from_named_str("template_name", "Hello {{ name }}").unwrap();
let rv = tmpl.render(context! { name => "World" });
println!("{}", rv.unwrap());
sourcepub fn template_from_str(
&self,
source: &'source str,
) -> Result<Template<'_, 'source>, Error>
pub fn template_from_str( &self, source: &'source str, ) -> Result<Template<'_, 'source>, Error>
Loads a template from a string, with name <string>
.
This is a shortcut to template_from_named_str
with name set to <string>
.
sourcepub fn render_named_str<S>(
&self,
name: &str,
source: &str,
ctx: S,
) -> Result<String, Error>where
S: Serialize,
pub fn render_named_str<S>(
&self,
name: &str,
source: &str,
ctx: S,
) -> Result<String, Error>where
S: Serialize,
Parses and renders a template from a string in one go with name.
Like render_str
, but provide a name for the
template to be used instead of the default <string>
. This is an
alias for template_from_named_str
paired with
render
.
let env = Environment::new();
let rv = env.render_named_str(
"template_name",
"Hello {{ name }}",
context!{ name => "World" }
);
println!("{}", rv.unwrap());
Note on values: The Value
type implements Serialize
and can be
efficiently passed to render. It does not undergo actual serialization.
sourcepub fn render_str<S>(&self, source: &str, ctx: S) -> Result<String, Error>where
S: Serialize,
pub fn render_str<S>(&self, source: &str, ctx: S) -> Result<String, Error>where
S: Serialize,
Parses and renders a template from a string in one go.
In some cases you really only need a template to be rendered once from
a string and returned. The internal name of the template is <string>
.
This is an alias for template_from_str
paired with
render
.
Note on values: The Value
type implements Serialize
and can be
efficiently passed to render. It does not undergo actual serialization.
sourcepub fn set_auto_escape_callback<F>(&mut self, f: F)
pub fn set_auto_escape_callback<F>(&mut self, f: F)
Sets a new function to select the default auto escaping.
This function is invoked when templates are loaded into the environment
to determine the default auto escaping behavior. The function is
invoked with the name of the template and can make an initial auto
escaping decision based on that. The default implementation
(default_auto_escape_callback
)
turn on escaping depending on the file extension.
env.set_auto_escape_callback(|name| {
if matches!(name.rsplit('.').next().unwrap_or(""), "html" | "htm" | "aspx") {
AutoEscape::Html
} else {
AutoEscape::None
}
});
sourcepub fn set_undefined_behavior(&mut self, behavior: UndefinedBehavior)
pub fn set_undefined_behavior(&mut self, behavior: UndefinedBehavior)
Changes the undefined behavior.
This changes the runtime behavior of undefined
values in
the template engine. For more information see UndefinedBehavior
. The
default is UndefinedBehavior::Lenient
.
sourcepub fn undefined_behavior(&self) -> UndefinedBehavior
pub fn undefined_behavior(&self) -> UndefinedBehavior
Returns the current undefined behavior.
This is particularly useful if a filter function or similar wants to change its behavior with regards to undefined values.
sourcepub fn set_formatter<F>(&mut self, f: F)
pub fn set_formatter<F>(&mut self, f: F)
Sets a different formatter function.
The formatter is invoked to format the given value into the provided
Output
. The default implementation is
escape_formatter
.
When implementing a custom formatter it depends on if auto escaping
should be supported or not. If auto escaping should be supported then
it’s easiest to just wrap the default formatter. The
following example swaps out None
values before rendering for
Undefined
which renders as an empty string instead.
The current value of the auto escape flag can be retrieved directly
from the State
.
use minijinja::escape_formatter;
use minijinja::value::Value;
env.set_formatter(|out, state, value| {
escape_formatter(
out,
state,
if value.is_none() {
&Value::UNDEFINED
} else {
value
},
)
});
sourcepub fn set_debug(&mut self, enabled: bool)
pub fn set_debug(&mut self, enabled: bool)
Enable or disable the debug mode.
When the debug mode is enabled the engine will dump out some of the execution state together with the source information of the executing template when an error is created. The cost of this is relatively high as the data including the template source is cloned.
When this is enabled templates will print debug information with source context when the error is printed.
This requires the debug
feature. This is enabled by default if
debug assertions are enabled and false otherwise.
sourcepub fn set_recursion_limit(&mut self, level: usize)
pub fn set_recursion_limit(&mut self, level: usize)
Reconfigures the runtime recursion limit.
This defaults to 500
. Raising it above that level requires the stacker
feature to be enabled. Otherwise the limit is silently capped at that safe
maximum. Note that the maximum is not necessarily safe if the thread uses
a lot of stack space already, it’s just a value that was validated once to
provide basic protection.
Every operation that requires recursion in MiniJinja increments an internal recursion counter. The actual cost attributed to that recursion depends on the cost of the operation. If statements and for loops for instance only increase the counter by 1, whereas template includes and macros might increase it to 10 or more.
Note on stack growth: even if the stacker feature is enabled it does not mean that in all cases stack can grow to the limits desired. For instance in WASM the maximum limits are additionally enforced by the runtime.
sourcepub fn recursion_limit(&self) -> usize
pub fn recursion_limit(&self) -> usize
Returns the current max recursion limit.
sourcepub fn compile_expression(
&self,
expr: &'source str,
) -> Result<Expression<'_, 'source>, Error>
pub fn compile_expression( &self, expr: &'source str, ) -> Result<Expression<'_, 'source>, Error>
Compiles an expression.
This lets one compile an expression in the template language and
receive the output. This lets one use the expressions of the language
be used as a minimal scripting language. For more information and an
example see Expression
.
sourcepub fn compile_expression_owned<E>(
&self,
expr: E,
) -> Result<Expression<'_, 'source>, Error>
pub fn compile_expression_owned<E>( &self, expr: E, ) -> Result<Expression<'_, 'source>, Error>
Compiles an expression without capturing the lifetime.
This works exactly like compile_expression
but
lets you pass an owned string without capturing the lifetime.
sourcepub fn add_filter<N, F, Rv, Args>(&mut self, name: N, f: F)where
N: Into<Cow<'source, str>>,
F: Filter<Rv, Args> + for<'a> Filter<Rv, <Args as FunctionArgs<'a>>::Output>,
Rv: FunctionResult,
Args: for<'a> FunctionArgs<'a>,
pub fn add_filter<N, F, Rv, Args>(&mut self, name: N, f: F)where
N: Into<Cow<'source, str>>,
F: Filter<Rv, Args> + for<'a> Filter<Rv, <Args as FunctionArgs<'a>>::Output>,
Rv: FunctionResult,
Args: for<'a> FunctionArgs<'a>,
Adds a new filter function.
Filter functions are functions that can be applied to values in
templates. For details about filters have a look at
Filter
.
sourcepub fn remove_filter(&mut self, name: &str)
pub fn remove_filter(&mut self, name: &str)
Removes a filter by name.
sourcepub fn add_test<N, F, Rv, Args>(&mut self, name: N, f: F)where
N: Into<Cow<'source, str>>,
F: Test<Rv, Args> + for<'a> Test<Rv, <Args as FunctionArgs<'a>>::Output>,
Rv: TestResult,
Args: for<'a> FunctionArgs<'a>,
pub fn add_test<N, F, Rv, Args>(&mut self, name: N, f: F)where
N: Into<Cow<'source, str>>,
F: Test<Rv, Args> + for<'a> Test<Rv, <Args as FunctionArgs<'a>>::Output>,
Rv: TestResult,
Args: for<'a> FunctionArgs<'a>,
Adds a new test function.
Test functions are similar to filters but perform a check on a value
where the return value is always true or false. For details about tests
have a look at Test
.
sourcepub fn remove_test(&mut self, name: &str)
pub fn remove_test(&mut self, name: &str)
Removes a test by name.
sourcepub fn add_function<N, F, Rv, Args>(&mut self, name: N, f: F)where
N: Into<Cow<'source, str>>,
F: Function<Rv, Args> + for<'a> Function<Rv, <Args as FunctionArgs<'a>>::Output>,
Rv: FunctionResult,
Args: for<'a> FunctionArgs<'a>,
pub fn add_function<N, F, Rv, Args>(&mut self, name: N, f: F)where
N: Into<Cow<'source, str>>,
F: Function<Rv, Args> + for<'a> Function<Rv, <Args as FunctionArgs<'a>>::Output>,
Rv: FunctionResult,
Args: for<'a> FunctionArgs<'a>,
sourcepub fn add_global<N, V>(&mut self, name: N, value: V)
pub fn add_global<N, V>(&mut self, name: N, value: V)
Adds a global variable.
sourcepub fn remove_global(&mut self, name: &str)
pub fn remove_global(&mut self, name: &str)
Removes a global function or variable by name.
sourcepub fn empty_state(&self) -> State<'_, '_>
pub fn empty_state(&self) -> State<'_, '_>
Returns an empty State
for testing purposes and similar.
Trait Implementations§
source§impl<'source> Clone for Environment<'source>
impl<'source> Clone for Environment<'source>
source§fn clone(&self) -> Environment<'source>
fn clone(&self) -> Environment<'source>
1.0.0 · source§fn clone_from(&mut self, source: &Self)
fn clone_from(&mut self, source: &Self)
source
. Read moresource§impl<'source> Debug for Environment<'source>
impl<'source> Debug for Environment<'source>
source§impl<'source> Default for Environment<'source>
impl<'source> Default for Environment<'source>
source§fn default() -> Environment<'source>
fn default() -> Environment<'source>
Auto Trait Implementations§
impl<'source> !Freeze for Environment<'source>
impl<'source> !RefUnwindSafe for Environment<'source>
impl<'source> Send for Environment<'source>
impl<'source> Sync for Environment<'source>
impl<'source> Unpin for Environment<'source>
impl<'source> !UnwindSafe for Environment<'source>
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use yansi::Paint;
painted.bold();
source§fn underline(&self) -> Painted<&T>
fn underline(&self) -> Painted<&T>
Returns self
with the
attr()
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Attribute::Underline
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§Example
println!("{}", value.underline());
source§fn rapid_blink(&self) -> Painted<&T>
fn rapid_blink(&self) -> Painted<&T>
Returns self
with the
attr()
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Attribute::RapidBlink
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§Example
println!("{}", value.rapid_blink());
source§fn quirk(&self, value: Quirk) -> Painted<&T>
fn quirk(&self, value: Quirk) -> Painted<&T>
Enables the yansi
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This method should be used rarely. Instead, prefer to use quirk-specific
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§Example
Enable wrapping using .quirk()
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use yansi::{Paint, Quirk};
painted.quirk(Quirk::Wrap);
Enable wrapping using wrap()
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use yansi::Paint;
painted.wrap();
source§fn clear(&self) -> Painted<&T>
👎Deprecated since 1.0.1: renamed to resetting()
due to conflicts with Vec::clear()
.
The clear()
method will be removed in a future release.
fn clear(&self) -> Painted<&T>
resetting()
due to conflicts with Vec::clear()
.
The clear()
method will be removed in a future release.source§fn whenever(&self, value: Condition) -> Painted<&T>
fn whenever(&self, value: Condition) -> Painted<&T>
Conditionally enable styling based on whether the Condition
value
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See the crate level docs for more details.
§Example
Enable styling painted
only when both stdout
and stderr
are TTYs:
use yansi::{Paint, Condition};
painted.red().on_yellow().whenever(Condition::STDOUTERR_ARE_TTY);