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As with any shorthand property, any individual value that is not specified is set to its corresponding initial value (possibly overriding values previously set using non-shorthand properties). Though not directly settable by font, the longhands font-size-adjust and font-kerning are also reset to their initial values.

Tip: The font-family property should hold several font names as a "fallback" system, to ensure maximum compatibility between browsers/operating systems. Start with the font you want, and end with a generic family (to let the browser pick a similar font in the generic family, if no other fonts are available). The font names should be separated with comma. Read more about fallback fonts in the next chapter.

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A glyph is a shape used to render a character or a sequence of characters. In simple writing systems, such as Latin, typically one glyph represents one character. In general, however, characters and glyphs do not have one-to-one correspondence. For example, the character '' LATIN SMALL LETTER A WITH ACUTE, can be represented by two glyphs: one for 'a' and one for ''. On the other hand, the two-character string "fi" can be represented by a single glyph, an "fi" ligature. In complex writing systems, such as Arabic or the South and South-East Asian writing systems, the relationship between characters and glyphs can be more complicated and involve context-dependent selection of glyphs as well as glyph reordering. A font encapsulates the collection of glyphs needed to render a selected set of characters as well as the tables needed to map sequences of characters to corresponding sequences of glyphs. Physical and Logical Fonts The Java Platform distinguishes between two kinds of fonts: physical fonts and logical fonts. Physical fonts are the actual font libraries containing glyph data and tables to map from character sequences to glyph sequences, using a font technology such as TrueType or PostScript Type 1. All implementations of the Java Platform must support TrueType fonts; support for other font technologies is implementation dependent. Physical fonts may use names such as Helvetica, Palatino, HonMincho, or any number of other font names. Typically, each physical font supports only a limited set of writing systems, for example, only Latin characters or only Japanese and Basic Latin. The set of available physical fonts varies between configurations. Applications that require specific fonts can bundle them and instantiate them using the createFont method. Logical fonts are the five font families defined by the Java platform which must be supported by any Java runtime environment: Serif, SansSerif, Monospaced, Dialog, and DialogInput. These logical fonts are not actual font libraries. Instead, the logical font names are mapped to physical fonts by the Java runtime environment. The mapping is implementation and usually locale dependent, so the look and the metrics provided by them vary. Typically, each logical font name maps to several physical fonts in order to cover a large range of characters. Peered AWT components, such as Label and TextField, can only use logical fonts. For a discussion of the relative advantages and disadvantages of using physical or logical fonts, see the Internationalization FAQ document. Font Faces and Names A Font can have many faces, such as heavy, medium, oblique, gothic and regular. All of these faces have similar typographic design. There are three different names that you can get from a Font object. The logical font name is simply the name that was used to construct the font. The font face name, or just font name for short, is the name of a particular font face, like Helvetica Bold. The family name is the name of the font family that determines the typographic design across several faces, like Helvetica. The Font class represents an instance of a font face from a collection of font faces that are present in the system resources of the host system. As examples, Arial Bold and Courier Bold Italic are font faces. There can be several Font objects associated with a font face, each differing in size, style, transform and font features. The getAllFonts method of the GraphicsEnvironment class returns an array of all font faces available in the system. These font faces are returned as Font objects with a size of 1, identity transform and default font features. These base fonts can then be used to derive new Font objects with varying sizes, styles, transforms and font features via the deriveFont methods in this class. Font and TextAttribute Font supports most TextAttributes. This makes some operations, such as rendering underlined text, convenient since it is not necessary to explicitly construct a TextLayout object. Attributes can be set on a Font by constructing or deriving it using a Map of TextAttribute values. The values of some TextAttributes are not serializable, and therefore attempting to serialize an instance of Font that has such values will not serialize them. This means a Font deserialized from such a stream will not compare equal to the original Font that contained the non-serializable attributes. This should very rarely pose a problem since these attributes are typically used only in special circumstances and are unlikely to be serialized. FOREGROUND and BACKGROUND use Paint values. The subclass Color is serializable, while GradientPaint and TexturePaint are not. CHAR_REPLACEMENT uses GraphicAttribute values. The subclasses ShapeGraphicAttribute and ImageGraphicAttribute are not serializable. INPUT_METHOD_HIGHLIGHT uses InputMethodHighlight values, which are not serializable. See InputMethodHighlight. Clients who create custom subclasses of Paint and GraphicAttribute can make them serializable and avoid this problem. Clients who use input method highlights can convert these to the platform-specific attributes for that highlight on the current platform and set them on the Font as a workaround. The Map-based constructor and deriveFont APIs ignore the FONT attribute, and it is not retained by the Font; the static getFont(java.util.Map) method should be used if the FONT attribute might be present. See TextAttribute.FONT for more information.

We recommend these fonts because they are legible and widely available and because they include special characters such as math symbols and Greek letters. Historically, sans serif fonts have been preferred for online works and serif fonts for print works; however, modern screen resolutions can typically accommodate either type of font, and people who use assistive technologies can adjust font settings to their preferences. For more on how font relates to accessibility, visit the page on the accessibility of APA Style.

Instructors and publishers vary in how they specify length requirements. Different fonts take up different amounts of space on the page; thus, we recommend using word count rather than page count to gauge paper length if possible.

Variable fonts offer continuous ranges of styles, often without additionallatency. This is relevant to responsive design.This dynamic typography uses continuous ranges of styles, offering all theweights between 100 and 900 on a page, and responsively varying the weightbased on some conditions.

Without style specifications, the API provides the default style of therequested family. To request other individual styles, such as specific weights,append a colon (:) after the name of the font family, followed by a list of axisproperty keywords in alphabetical order, an at sign (@), and one or more listsof values for those axis properties.

With static fonts, styles of weight are usually specified as multiples of 100(e.g. 300, 400, 700). Variable fonts offer both the standard weights andintermediate weights. To render an intermediate weight:

Be precise about the styles you are using. The API delivers the requested stylesin the most compact set of fonts. Requesting unused styles may cause your usersto download more font data than they need, causing more latency. If you use only3 specific weights, specify them in your request as individual styles. If youuse a continuous range of weights, specify that weight range in your request.

In these cases, you should consider specifying a text= value in your fontrequest URL. This allows Google Fonts to return a font file that's optimized foryour request. In some cases, this can reduce the size of the font file by up to90%.

From Adobe Fonts, you should be able to copy the URL of the CSS file. If you go to that CSS file, you can copy the code, create a new CSS file on your desktop, paste the code and change the name of the font-family (eg: roc-grotesk-medium).

The easiest way to avoid showing invisible text while custom fonts loadis to temporarily show a system font.By including font-display: swap in your @font-face style,you can avoid FOIT in most modern browsers:

The font-display APIspecifies how a font is displayed.swap tells the browser that text using the font should be displayed immediately using a system font.Once the custom font is ready, it replaces the system font.(See the Avoid invisible text during loading postfor more information.)

next/font includes built-in automatic self-hosting for any font file. This means you can optimally load web fonts with zero layout shift, thanks to the underlying CSS size-adjust property used.

This new font system also allows you to conveniently use all Google Fonts with performance and privacy in mind. CSS and font files are downloaded at build time and self-hosted with the rest of your static assets. No requests are sent to Google by the browser. e24fc04721