Scalpel is a web scraping library inspired by libraries like Parsec and Perl's Web::Scraper. Scalpel builds on top of TagSoup to provide a declarative and monadic interface.
There are two general mechanisms provided by this library that are used to build web scrapers: Selectors and Scrapers.
Selectors describe a location within an HTML DOM tree. The simplest selector,
that can be written is a simple string value. For example, the selector
"div"
matches every single div node in a DOM. Selectors can be combined
using tag combinators. The //
operator to define nested relationships within a
DOM tree. For example, the selector "div" // "a"
matches all anchor tags
nested arbitrarily deep within a div tag.
In addition to describing the nested relationships between tags, selectors can
also include predicates on the attributes of a tag. The @:
operator creates a
selector that matches a tag based on the name and various conditions on the
tag's attributes. An attribute predicate is just a function that takes an
attribute and returns a boolean indicating if the attribute matches a criteria.
There are several attribute operators that can be used to generate common
predicates. The @=
operator creates a predicate that matches the name and
value of an attribute exactly. For example, the selector "div" @: ["id" @= "article"]
matches div tags where the id attribute is equal to "article"
.
Scrapers are values that are parameterized over a selector and produce a value
from an HTML DOM tree. The Scraper
type takes two type parameters. The first
is the string like type that is used to store the text values within a DOM tree.
Any string like type supported by Text.StringLike
is valid. The second type
is the type of value that the scraper produces.
There are several scraper primitives that take selectors and extract content from the DOM. Each primitive defined by this library comes in two variants: singular and plural. The singular variants extract the first instance matching the given selector, while the plural variants match every instance.
Complete examples can be found in the examples folder in the scalpel git repository.
The following is an example that demonstrates most of the features provided by
this library. Supposed you have the following hypothetical HTML located at
"http://example.com/article.html"
and you would like to extract a list of all
of the comments.
<html>
<body>
<div class='comments'>
<div class='comment container'>
<span class='comment author'>Sally</span>
<div class='comment text'>Woo hoo!</div>
</div>
<div class='comment container'>
<span class='comment author'>Bill</span>
<img class='comment image' src='http://example.com/cat.gif' />
</div>
<div class='comment container'>
<span class='comment author'>Susan</span>
<div class='comment text'>WTF!?!</div>
</div>
</div>
</body>
</html>
The following snippet defines a function, allComments
, that will download
the web page, and extract all of the comments into a list:
type Author = String
data Comment
= TextComment Author String
| ImageComment Author URL
deriving (Show, Eq)
allComments :: IO (Maybe [Comment])
allComments = scrapeURL "http://example.com/article.html" comments
where
comments :: Scraper String [Comment]
comments = chroots ("div" @: [hasClass "container"]) comment
comment :: Scraper String Comment
comment = textComment <|> imageComment
textComment :: Scraper String Comment
textComment = do
author <- text $ "span" @: [hasClass "author"]
commentText <- text $ "div" @: [hasClass "text"]
return $ TextComment author commentText
imageComment :: Scraper String Comment
imageComment = do
author <- text $ "span" @: [hasClass "author"]
imageURL <- attr "src" $ "img" @: [hasClass "image"]
return $ ImageComment author imageURL
The primitives provided by scalpel are intentionally minimalistic with the assumption being that users will be able to build up complex functionality by combining them with functions that work on existing type classes (Monad, Applicative, Alternative, etc.).
This section gives examples of common tricks for building up more complex behavior from the simple primitives provided by this library.
Selector
, TagName
and AttributeName
are all IsString
instances, and
thus it is convenient to use scalpel with OverloadedStrings
enabled. If not
using OverloadedStrings
, all tag names must be wrapped with tagSelector
.
Scalpel has 3 different wildcard values each corresponding to a distinct use case.
-
anySelector
is used to match all tags:textOfAllTags = texts anySelector
-
AnyTag
is used when matching all tags with some attribute constraint. For example, to match all tags with the attributeclass
equal to"button"
:textOfTagsWithClassButton = texts $ AnyTag @: [hasClass "button"]
-
AnyAttribute
is used when matching tags with some arbitrary attribute equal to a particular value. For example, to match all tags with some attribute equal to"button"
:textOfTagsWithAnAttributeWhoseValueIsButton = texts $ AnyTag @: [AnyAttribute @= "button"]
It is possible to run into scenarios where the name and attributes of a tag are not sufficient to isolate interesting tags and properties of child tags need to be considered.
In these cases the guard
function of the Alternative
type class can be
combined with chroot
and anySelector
to implement predicates of arbitrary
complexity.
Building off the above example, consider a use case where we would like find the html contents of a comment that mentions the word "cat".
The strategy will be the following:
-
Isolate the comment div using
chroot
. -
Then within the context of that div the textual contents can be retrieved with
text anySelector
. This works because the first tag within the current context is the div tag selected by chroot, and theanySelector
selector will match the first tag within the current context. -
Then the predicate that
"cat"
appear in the text of the comment will be enforced usingguard
. If the predicate fails, scalpel will backtrack and continue the search for divs until one is found that matches the predicate. -
Return the desired HTML content of the comment div.
catComment :: Scraper String String
catComment =
-- 1. First narrow the current context to the div containing the comment's
-- textual content.
chroot ("div" @: [hasClass "comment", hasClass "text"]) $ do
-- 2. anySelector can be used to access the root tag of the current context.
contents <- text anySelector
-- 3. Skip comment divs that do not contain "cat".
guard ("cat" `isInfixOf` contents)
-- 4. Generate the desired value.
html anySelector
For the full source of this example, see complex-predicates in the examples directory.
The pluralized versions of the primitive scrapers (texts
, attrs
, htmls
)
allow the user to extract content from all of the tags matching a given
selector. For more complex scraping tasks it will at times be desirable to be
able to extract multiple values from the same tag.
Like the previous example, the trick here is to use a combination of the
chroots
function and the anySelector
selector.
Consider an extension to the original example where image comments may contain some alt text and the desire is to return a tuple of the alt text and the URLs of the images.
The strategy will be the following:
-
to isolate each img tag using
chroots
. -
Then within the context of each img tag, use the
anySelector
selector to extract the alt and src attributes from the current tag. -
Create and return a tuple of the extracted attributes.
altTextAndImages :: Scraper String [(String, URL)]
altTextAndImages =
-- 1. First narrow the current context to each img tag.
chroots "img" $ do
-- 2. Use anySelector to access all the relevant content from the the currently
-- selected img tag.
altText <- attr "alt" anySelector
srcUrl <- attr "src" anySelector
-- 3. Combine the retrieved content into the desired final result.
return (altText, srcUrl)
For the full source of this example, see generalized-repetition in the examples directory.
The scalpel
package depends on 'http-client' and 'http-client-tls' to provide
networking support. For projects with an existing HTTP client these dependencies
may be unnecessary.
For these scenarios users can instead depend on scalpel-core which does not provide networking support and has minimal dependencies.
Some websites return different markup depending on the user agent sent along with the request. In some cases, this even means returning no markup at all in an effort to prevent scraping.
To work around this, you can add your own user agent string.
#!/usr/local/bin/stack
-- stack runghc --resolver lts-6.24 --install-ghc --package scalpel-0.6.0
{-# LANGUAGE NamedFieldPuns #-}
{-# LANGUAGE OverloadedStrings #-}
import Text.HTML.Scalpel
import qualified Network.HTTP.Client as HTTP
import qualified Network.HTTP.Client.TLS as HTTP
import qualified Network.HTTP.Types.Header as HTTP
-- Create a new manager settings based on the default TLS manager that updates
-- the request headers to include a custom user agent.
managerSettings :: HTTP.ManagerSettings
managerSettings = HTTP.tlsManagerSettings {
HTTP.managerModifyRequest = \req -> do
req' <- HTTP.managerModifyRequest HTTP.tlsManagerSettings req
return $ req' {
HTTP.requestHeaders = (HTTP.hUserAgent, "My Custom UA")
: HTTP.requestHeaders req'
}
}
main = do
manager <- Just <$> HTTP.newManager managerSettings
html <- scrapeURLWithConfig (def { manager }) url $ htmls anySelector
maybe printError printHtml html
where
url = "https://www.google.com"
printError = putStrLn "Failed"
printHtml = mapM_ putStrLn
A list of user agent strings can be found here.