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Developer(s) | Microsoft |
---|---|
Initial release | September 30, 1995 |
Stable release | 12 Ultimate API / October 5, 2021 |
Operating system | Microsoft Windows, Windows Phone 8, Dreamcast, [1] Xbox, Xbox 360, Xbox One, Xbox Series X and Series S, Linux (Gallium Nine) (DirectX 12 only, Exclusive to Windows Subsystem for Linux) [2] |
Type | API |
Microsoft DirectX is a collection of application programming interfaces (APIs) for handling tasks related to multimedia, especially game programming and video, on Microsoft platforms. Originally, the names of these APIs all began with "Direct", such as Direct3D, DirectDraw, DirectMusic, DirectPlay, DirectSound, and so forth. The name DirectX was coined as a shorthand term for all of these APIs (the X standing in for the particular API names) and soon became the name of the collection. When Microsoft later set out to develop a gaming console, the X was used as the basis of the name Xbox to indicate that the console was based on DirectX technology. [3] The X initial has been carried forward in the naming of APIs designed for the Xbox such as XInput and the Cross-platform Audio Creation Tool (XACT), while the DirectX pattern has been continued for Windows APIs such as Direct2D and DirectWrite.
Direct3D (the 3D graphics API within DirectX) is widely used in the development of video games for Microsoft Windows and the Xbox line of consoles. Direct3D is also used by other software applications for visualization and graphics tasks such as CAD/CAM engineering. As Direct3D is the most widely publicized component of DirectX, it is common to see the names "DirectX" and "Direct3D" used interchangeably.
The DirectX software development kit (SDK) consists of runtime libraries in redistributable binary form, along with accompanying documentation and headers for use in coding. Originally, the runtimes were only installed by games or explicitly by the user. Windows 95 did not launch with DirectX, but DirectX was included with Windows 95 OEM Service Release 2. [4] Windows 98 and Windows NT 4.0 both shipped with DirectX, as has every version of Windows released since. The SDK is available as a free download. While the runtimes are proprietary, closed-source software, source code is provided for most of the SDK samples. Starting with the release of Windows 8 Developer Preview, DirectX SDK has been integrated into Windows SDK. [5]
In late 1994, Microsoft was ready to release Windows 95, its next operating system. An important factor in its value to consumers was the programs that would be able to run on it. Microsoft employee Alex St. John had been in discussions with various game developers asking how likely they would be to bring their MS-DOS games to Windows 95, and found the responses mostly negative, since programmers had found that the Windows environment did not provide the necessary features which were available under MS-DOS using BIOS routines or direct hardware access. [6] There were also strong fears of compatibility; a notable case of this was from Disney's Animated Storybook: The Lion King which was based on the WinG programming interface. [7] Due to numerous incompatible graphics drivers from new Compaq computers that were not tested with the WinG interface which came bundled with the game, it crashed so frequently on many desktop systems that parents had flooded Disney's call-in help lines. [8] [9]
St. John recognized the resistances for game development under Windows would be a limitation, and recruited two additional engineers, Craig Eisler and Eric Engstrom, to develop a better solution to get more programmers to develop games for Windows. The project was codenamed the Manhattan Project, like the World War II project of the same name, and the idea was to displace the Japanese-developed video game consoles with personal computers running Microsoft's operating system. [8] It had initially used the radiation symbol as its logo but Microsoft asked the team to change the logo. [8] Management did not agree to the project as they were already writing off Windows as a gaming platform, but the three committed towards this project's development. [9] Their rebellious nature led Brad Silverberg, the senior vice president of Microsoft's office products, to name the trio the "Beastie Boys". [10]
Most of the work by the three was done among other assigned projects starting near the end of 1994. [9] Within four months and with input from several hardware manufacturers, the team had developed the first set of application programming interfaces (APIs) which they presented at the 1995 Game Developers Conference. [9] The SDK included libraries implementing DirectDraw for bit-mapped graphics, [11] DirectSound for audio, [12] and DirectPlay for communication between players over a network. [13] Furthermore, an extended joystick API already present in Windows 95 was documented for the first time as DirectInput, [14] while a description of how to implement the immediate start of the installation procedure of a software title after inserting its CD-ROM, a feature called AutoPlay, was also part of the SDK. [15] The "Direct" part of the library was so named as these routines bypassed existing core Windows 95 routines and accessed the computer hardware only via a hardware abstraction layer (HAL). [16] Though the team had named it the "Game SDK" (software development kit), the name "DirectX" came from one journalist that had mocked the naming scheme of the various libraries. The team opted to continue to use that naming scheme and call the project DirectX. [8]
The first version of DirectX was released in September 1995 as the Windows Game SDK. Its DirectDraw component was the Win32 replacement for the DCI [17] and WinG APIs for Windows 3.1. [18] DirectX allowed all versions of Microsoft Windows, starting with Windows 95, to incorporate high-performance multimedia. Eisler wrote about the frenzy to build DirectX 1 through 5 in his blog. [19]
To get more developers on board DirectX, Microsoft approached id Software's John Carmack and offered to port Doom and Doom 2 from MS-DOS to DirectX, free of charge, with id retaining all publishing rights to the game. Carmack agreed, and Microsoft's Gabe Newell led the porting project. The first game was released as Doom 95 in August 1996, the first published DirectX game. Microsoft promoted the game heavily with Bill Gates appearing in ads for the title. [8]
DirectX 2.0 became a built-in component of Windows with the releases of Windows 95 OSR2 and Windows NT 4.0 in mid-1996. Since Windows 95 itself was still new and few games had been released for it, Microsoft engaged in heavy promotion of DirectX to developers who were generally distrustful of Microsoft's ability to build a gaming platform in Windows. Alex St. John, the evangelist for DirectX, staged an elaborate event at the 1996 Computer Game Developers Conference which game developer Jay Barnson described as a Roman theme, including real lions, togas, and something resembling an indoor carnival. [20] It was at this event that Microsoft first introduced Direct3D, and demonstrated multiplayer MechWarrior 2 being played over the Internet.
The DirectX team faced the challenging task of testing each DirectX release against an array of computer hardware and software. A variety of different graphics cards, audio cards, motherboards, CPUs, input devices, games, and other multimedia applications were tested with each beta and final release. The DirectX team also built and distributed tests that allowed the hardware industry to confirm that new hardware designs and driver releases would be compatible with DirectX.
Prior to DirectX Microsoft had added OpenGL to their Windows NT platform. [21] OpenGL had been designed as a cross-platform, window system independent software interface to graphics hardware by Silicon Graphics, Inc. to bring 3D graphics programming into the mainstream of application programming. Besides it could also be used for 2D graphics and imaging and was controlled by the Architectural Review Board (ARB) which included Microsoft. [22] [23] Direct3D was intended to be a Microsoft controlled alternative to OpenGL, focused initially on game use. As 3D gaming grew game developers were discovering that OpenGL could be used effectively for game development. [24] At that point a "battle" began between supporters of the cross-platform OpenGL and the Windows-only Direct3D. [25] Incidentally, OpenGL was supported at Microsoft by the DirectX team. If a developer chose to use the OpenGL 3D graphics API in computer games, the other APIs of DirectX besides Direct3D were often combined with OpenGL because OpenGL does not include all of DirectX's functionality (such as sound or joystick support).
In a console-specific version, DirectX was used as a basis for Microsoft's Xbox, Xbox 360 and Xbox One console API. The API was developed jointly between Microsoft and Nvidia, which developed the custom graphics hardware used by the original Xbox. The Xbox API was similar to DirectX version 8.1, but is non-updateable like other console technologies. The Xbox was code named DirectXbox, but this was shortened to Xbox for its commercial name. [26]
In 2002, Microsoft released DirectX 9 with support for the use of much longer shader programs than before with pixel and vertex shader version 2.0. Microsoft has continued to update the DirectX suite since then, introducing Shader Model 3.0 in DirectX 9.0c, released in August 2004.
As of April 2005, DirectShow was removed from DirectX and moved to the Microsoft Platform SDK instead.
DirectX has been confirmed to be present in Microsoft's Windows Phone 8. [27]
Real-time raytracing was announced as DXR in 2018. Support for compiling HLSL to SPIR-V was also added in the DirectX Shader Compiler the same year. [28]
DirectX is composed of multiple APIs:
Microsoft has deprecated the following components:
DirectX functionality is provided in the form of COM-style objects and interfaces. Additionally, while not DirectX components themselves, managed objects have been built on top of some parts of DirectX, such as Managed Direct3D [31] and the XNA graphics library [32] on top of Direct3D 9.
Microsoft distributes debugging tool for DirectX called "PIX". [33]
Introduced by Microsoft in 2002, DirectX 9 was a significant release in the DirectX family. It brought many important features and enhancements to the graphics capabilities of Windows. At the time of its release, it supported Windows 98, Windows Me, Windows 2000, and Windows XP. As of August 2024 it remains supported by all subsequent versions of Windows for backward compatibility.
One of the key features introduced in DirectX 9 was Shader Model 2.0, which included Pixel Shader 2.0 and Vertex Shader 2.0. These allowed for more complex and realistic graphics rendering. It also brought much needed performance improvements through better hardware acceleration capabilities, and better utilization of GPU resources. It also introduced HLSL, which provided a more accessible way for developers to produce shaders.
DirectX 9.0c was an update to the original, and has been continuously changed over the years affecting its compatibility with older operating systems. As of January 2007, Windows 2000 and Windows XP became the minimum required operating systems. This means support was officially dropped for Windows 98 and Windows Me. As of August 2024, DirectX 9.0c is still regularly updated.
Windows XP SP2 and newer include DirectX 9.0c, [34] but may require a newer DirectX runtime redistributable installation for DirectX 9.0c applications compiled with the February 2005 DirectX 9.0 SDK or newer.
DirectX 9 had a significant impact on game development. Many games from the mid-2000s to early 2010s were developed using DirectX 9 and it became a standard target for developers. Even today, some games still use DirectX 9 as an option for older or less powerful hardware.
A major update to DirectX API, DirectX 10 ships with and is only available with Windows Vista (launched in late 2006) and later. Previous versions of Windows such as Windows XP are not able to run DirectX 10-exclusive applications. Rather, programs that are run on a Windows XP system with DirectX 10 hardware simply resort to the DirectX 9.0c code path, the latest available for Windows XP computers. [35]
Changes for DirectX 10 were extensive. Many former parts of DirectX API were deprecated in the latest DirectX SDK and are preserved for compatibility only: DirectInput was deprecated in favor of XInput, DirectSound was deprecated in favor of the Cross-platform Audio Creation Tool system (XACT) and additionally lost support for hardware accelerated audio, since the Vista audio stack renders sound in software on the CPU. The DirectPlay DPLAY.DLL was also removed and was replaced with dplayx.dll; games that rely on this DLL must duplicate it and rename it to dplay.dll.
In order to achieve backwards compatibility, DirectX in Windows Vista contains several versions of Direct3D: [36]
Direct3D 10.1 is an incremental update of Direct3D 10.0 which shipped with, and required, Windows Vista Service Pack 1, which was released in February 2008. [37] This release mainly sets a few more image quality standards for graphics vendors, while giving developers more control over image quality. [38] It also adds support for cube map arrays, separate blend modes per-MRT, coverage mask export from a pixel shader, ability to run pixel shader per sample, access to multi-sampled depth buffers [39] and requires that the video card supports Shader Model 4.1 or higher and 32-bit floating-point operations. Direct3D 10.1 still fully supports Direct3D 10 hardware, but in order to utilize all of the new features, updated hardware is required. [40]
Microsoft unveiled DirectX 11 at the Gamefest 08 event in Seattle. The Final Platform Update launched for Windows Vista on October 27, 2009, which was a week after the initial release of Windows 7, which launched with Direct3D 11 as a base standard.
Major scheduled features including GPGPU support (DirectCompute), and Direct3D 11 with tessellation support [41] [42] and improved multi-threading support to assist video game developers in developing games that better utilize multi-core processors. [43] Parts of the new API such as multi-threaded resource handling can be supported on Direct3D 9/10/10.1-class hardware. Hardware tessellation and Shader Model 5.0 require Direct3D 11 supporting hardware. [44] Microsoft has since released the Direct3D 11 Technical Preview. [45] Direct3D 11 is a strict superset of Direct3D 10.1 — all hardware and API features of version 10.1 are retained, and new features are added only when necessary for exposing new functionality. This helps to keep backwards compatibility with previous versions of DirectX.
Four updates for DirectX 11 were released:
DirectX 12 was announced by Microsoft at GDC on March 20, 2014, and was officially launched alongside Windows 10 on July 29, 2015.
The primary feature highlight for the new release of DirectX was the introduction of advanced low-level programming APIs for Direct3D 12 which can reduce driver overhead. Developers are now able to implement their own command lists and buffers to the GPU, allowing for more efficient resource utilization through parallel computation. Lead developer Max McMullen stated that the main goal of Direct3D 12 is to achieve "console-level efficiency on phone, tablet and PC". [55] The release of Direct3D 12 comes alongside other initiatives for low-overhead graphics APIs including AMD's Mantle for AMD graphics cards, Apple's Metal for iOS and macOS and Khronos Group's cross-platform Vulkan.
Multiadapter support will feature in DirectX 12 allowing developers to utilize multiple GPUs on a system simultaneously; multi-GPU support was previously dependent on vendor implementations such as AMD CrossFireX or NVIDIA SLI. [56] [57] [58] [59]
DirectX 12 is supported on all Fermi and later Nvidia GPUs, on AMD's GCN-based chips and on Intel's Haswell and later processors' graphics units. [60]
At SIGGRAPH 2014, Intel released a demo showing a computer generated asteroid field, in which DirectX 12 was claimed to be 50–70% more efficient than DirectX 11 in rendering speed and CPU power consumption. [61] [62]
Ashes of the Singularity was the first publicly available game to utilize DirectX 12. Testing by Ars Technica in August 2015 revealed slight performance regressions in DirectX 12 over DirectX 11 mode for the Nvidia GeForce 980 Ti, whereas the AMD Radeon R9 290x achieved consistent performance improvements of up to 70% under DirectX 12, and in some scenarios the AMD outperformed the more powerful Nvidia under DirectX 12. The performance discrepancies may be due to poor Nvidia driver optimizations for DirectX 12, or even hardware limitations of the card which was optimized for DirectX 11 serial execution; however, the exact cause remains unclear. [63]
The performance improvements of DirectX 12 on the Xbox are not as substantial as on the PC. [64]
In March 2018, DirectX Raytracing (DXR) was announced, capable of real-time ray-tracing on supported hardware, [65] and the DXR API was added in the Windows 10 October 2018 update.
In 2019 Microsoft announced the arrival of DirectX 12 to Windows 7 but only as a plug-in for certain game titles. [66]
Microsoft revealed DirectX 12 Ultimate in March 2020. DirectX 12 Ultimate will unify to a common library on both Windows 10 computers and the Xbox Series X and other ninth-generation Xbox consoles. Among the new features in Ultimate includes DirectX Raytracing 1.1, Variable Rate Shading, which gives programmers control over the level of detail of shading depending on design choices, Mesh Shaders, and Sampler Feedback. [67] [68]
1995 | DirectX 1 |
---|---|
1996 | DirectX 2 |
DirectX 3 | |
1997 | DirectX 5 |
1998 | DirectX 6 |
1999 | DirectX 7 |
2000 | DirectX 8 |
2001 | |
2002 | DirectX 9 |
2003 | |
2004 | |
2005 | |
2006 | DirectX 10 |
2007 | |
2008 | |
2009 | DirectX 11 |
2010 | |
2011 | |
2012 | |
2013 | |
2014 | |
2015 | DirectX 12 |
Version | Release date | Notes | ||
---|---|---|---|---|
Major | Minor | Number | ||
1 | 1.0 | 4.02.0095 | September 30, 1995 | Initially released as Windows Game SDK, replacing WinG for Windows 95 onward |
2 | 2.0 | 1996 | Was shipped only with a few 3rd party applications | |
2.0a | 4.03.00.1096 | June 5, 1996 | Windows 95 OSR2 and Windows NT 4.0 exclusive | |
3 | 3.0 | 4.04.00.0068 | September 15, 1996 | |
4.04.00.0069 | 1996 | Later package of DirectX 3.0 included Direct3D 4.04.00.0069 | ||
3.0a | 4.04.00.0070 | December 1996 | Windows NT 4.0 SP3 (and above) Last version supporting Windows NT 4.0 | |
3.0b | 4.04.00.0070 | December 1996 | This was a very minor update to 3.0a that fixed a cosmetic problem with the Japanese version of Windows 95 | |
4 | 4.0 | Never released | DirectX 4 was never released. Raymond Chen of Microsoft explained in his book, The Old New Thing, that after DirectX 3 was released, Microsoft began developing versions 4 and 5 at the same time. Version 4 was to be a shorter-term release with small features, whereas version 5 would be a more substantial release. The lack of interest from game developers in the features stated for DirectX 4 resulted in it being shelved, and the large amount of documents that already distinguished the two new versions resulted in Microsoft choosing to not re-use version 4 to describe features intended for version 5. [69] [70] | |
5 | 5.0 | 4.05.00.0155 (RC55) | August 4, 1997 | Available as a beta for Windows 2000 that would install on Windows NT 4.0 |
4.05.00.0155 (RC66) | Installer included on the Windows 95 OSR 2.5 installation media | |||
5.2 | 4.05.01.1600 (RC00) | May 5, 1998 | DirectX 5.2 release for Windows 95 | |
4.05.01.1998 (RC0) | June 25, 1998 | Windows 98 exclusive | ||
6 | 6.0 | 4.06.00.0318 (RC3) | August 7, 1998 [71] | Windows CE as implemented on Dreamcast and other devices |
6.1 | 4.06.02.0436 (RC0) | February 3, 1999 [72] | ||
6.1a | 4.06.03.0518 (RC0) | May 5, 1999 [73] | Windows 98 Second Edition exclusive. This is last version that runs on 486 or older CPU. | |
7 | 7.0 | 4.07.00.0700 (RC1) | September 22, 1999 [74] [75] [76] | |
4.07.00.0700 | February 17, 2000 | Windows 2000 exclusive | ||
7.0a | December 17, 1999 | Released only for Windows 95 to 98 [77] [78] | ||
4.07.00.0716 (RC0) | March 8, 2000 | |||
4.07.00.0716 (RC1) | 2000 | |||
7.1 | 4.07.01.3000 (RC1) | September 14, 2000 [79] | Windows Me exclusive. Last version to have built-in RGB software rendering support | |
8 | 8.0 | 4.08.00.0400 (RC10) | November 10, 2000 [80] | |
8.0a | 4.08.00.0400 (RC14) | January 24, 2001 [81] [82] | Last version supporting Windows 95 and last version to have software rendering support in dxdiag.exe | |
8.1 | 4.08.01.0810 | October 25, 2001 | Windows XP, Windows XP SP1, Windows Server 2003 | |
4.08.01.0881 (RC7) | November 8, 2001 | This version is for the down level operating systems (Windows 98, Windows Me and Windows 2000) | ||
8.1a | 4.08.01.0901 (RC?) | 2002 | This release includes an update to Direct3D (D3d8.dll) | |
8.1b | 4.08.01.0901 (RC7) | June 25, 2002 | This update includes a fix to DirectShow on Windows 2000 (Quartz.dll) | |
8.2 | 4.08.02.0134 (RC0) | 2002 | Same as the DirectX 8.1b but includes DirectPlay 8.2 | |
9 | 9.0 | 4.09.00.0900 (RC4) | December 19, 2002 | |
9.0a | 4.09.00.0901 (RC6) | March 26, 2003 | ||
9.0b | 4.09.00.0902 (RC2) | August 13, 2003 | ||
9.0c [83] | 4.09.00.0904 (RC0) | July 22, 2004 | First 9.0c version Periodic hybrid 32-bit/64-bit updates, starting from October 2004, were released bimonthly until August 2007, and quarterly thereafter. The last update was released in June 2010 [84] | |
4.09.00.0904 | August 6, 2004 / April 21, 2008* | Windows XP SP2 and SP3*, Windows Server 2003 SP1 and Windows Server 2003 R2 | ||
December 8, 2006 | Last version supporting Windows 98, 98 SE and Me [a] | |||
February 5, 2010 | Last version supporting Windows 2000, XP and XP SP1 | |||
June 7, 2010 | Final 9.0c version Last version supporting Windows XP SP2 and SP3 [85] | |||
10 | 10 | 6.00.6000.16386 | November 30, 2006 | Windows Vista exclusive |
10.1 | 6.00.6001.18000 | February 4, 2008 | Windows Vista SP1, Windows Server 2008 Includes Direct3D 10.1 | |
6.00.6002.18005 | April 28, 2009 | Windows Vista SP2, Windows Server 2008 SP2 Includes Direct3D 10.1 | ||
11 | 11 | 6.01.7600.16385 | October 22, 2009 | Windows 7, Windows Server 2008 R2 |
6.00.6002.18107 | October 27, 2009 | Windows Vista SP2 and Windows Server 2008 SP2, through the Platform Update for Windows Vista and Windows Server 2008 [86] | ||
6.01.7601.17514 | February 16, 2011 | Windows 7 SP1, Windows Server 2008 R2 SP1 | ||
11.1 | 6.02.9200.16384 | August 1, 2012 | Windows 8, Windows RT, Windows Server 2012 | |
6.02.9200.16492 | February 11, 2013 | Windows 7 SP1 and Windows Server 2008 R2 SP1, through the Platform Update for Windows 7 and Windows Server 2008 R2 [87] | ||
11.2 | 6.03.9600.16384 | October 18, 2013 | Windows 8.1, Windows RT, Windows Server 2012 R2 | |
12 | 12 | 10.00.10240.16384 | July 29, 2015 | Windows 10 |
10.00.15063.0000 | March 20, 2017 | Windows 10, Depth Bounds Testing and Programmable MSAA added [88] [89] | ||
10.00.17763.0000 | November 20, 2019 | Direct3D 12 only for Windows 7 SP1, via a dedicated source code package for app developers [90] [91] | ||
12.1 | 10.00.17763.0001 | October 2, 2018 | Windows 10, DirectX Raytracing support added [92] | |
10.00.18362.0116 | May 19, 2019 | Windows 10, Variable Rate Shading (VRS) support added [93] | ||
12.2 | 10.00.19041.0928 | November 10, 2020 | Windows 10, Ultimate | |
10.00.22000.1000 | October 5, 2021 | Windows 11, Added native refresh rate switching [94] and improved graphics capabilities to Windows Subsystem for Linux [95] |
The version number as reported by Microsoft's DxDiag tool (version 4.09.0000.0900 and higher) use the x.xx.xxxx.xxxx format for version numbers. However, the DirectX and Windows XP MSDN page claims that the registry always has been in the x.xx.xx.xxxx format. Therefore, when the above table lists a version as '4.09.00.0904' Microsoft's DxDiag tool may have it as '4.09.0000.0904'. [96]
Various releases of Windows have included and supported various versions of DirectX, allowing newer versions of the operating system to continue running applications designed for earlier versions of DirectX until those versions can be gradually phased out in favor of newer APIs, drivers, and hardware. [97]
APIs such as Direct3D and DirectSound need to interact with hardware, and they do this through a device driver. Hardware manufacturers have to write these drivers for a particular DirectX version's device driver interface (or DDI), and test each individual piece of hardware to make them DirectX compatible. Some hardware devices have only DirectX compatible drivers (in other words, one must install DirectX in order to use that hardware). Early versions of DirectX included an up-to-date library of all of the DirectX compatible drivers currently available. This practice was stopped however, in favor of the web-based Windows Update driver-update system, which allowed users to download only the drivers relevant to their hardware, rather than the entire library.
Prior to DirectX 10, DirectX runtime was designed to be backward compatible with older drivers, meaning that newer versions of the APIs were designed to interoperate with older drivers written against a previous version's DDI. The application programmer had to query the available hardware capabilities using a complex system of "cap bits" each tied to a particular hardware feature. Direct3D 7 and earlier would work on any version of the DDI, Direct3D 8 requires a minimum DDI level of 6 and Direct3D 9 requires a minimum DDI level of 7. [98] However, the Direct3D 10 runtime in Windows Vista cannot run on older hardware drivers due to the significantly updated DDI, which requires a unified feature set and abandons the use of "cap bits".
Direct3D 10.1 introduces "feature levels" 10_0 and 10_1, which allow use of only the hardware features defined in the specified version of Direct3D API. Direct3D 11 adds level 11_0 and "10 Level 9" - a subset of the Direct3D 10 API designed to run on Direct3D 9 hardware, which has three feature levels (9_1, 9_2 and 9_3) grouped by common capabilities of "low", "med" and "high-end" video cards; the runtime directly uses Direct3D 9 DDI provided in all WDDM drivers. Feature level 11_1 has been introduced with Direct3D 11.1.
In 2002, Microsoft released a version of DirectX compatible with the Microsoft .NET Framework, thus allowing programmers to take advantage of DirectX functionality from within .NET applications using compatible languages such as managed C++ or the use of the C# programming language. This API was known as "Managed DirectX" (or MDX for short), and claimed to operate at 98% of performance of the underlying native DirectX APIs. In December 2005, February 2006, April 2006, and August 2006, Microsoft released successive updates to this library, culminating in a beta version called Managed DirectX 2.0. While Managed DirectX 2.0 consolidated functionality that had previously been scattered over multiple assemblies into a single assembly, thus simplifying dependencies on it for software developers, development on this version has subsequently been discontinued, and it is no longer supported. The Managed DirectX 2.0 library expired on October 5, 2006.
During the GDC 2006, Microsoft presented the XNA Framework, a new managed version of DirectX (similar but not identical to Managed DirectX) that is intended to assist development of games by making it easier to integrate DirectX, HLSL and other tools in one package. It also supports the execution of managed code on the Xbox 360. The XNA Game Studio Express RTM was made available on December 11, 2006, as a free download for Windows XP. Unlike the DirectX runtime, Managed DirectX, XNA Framework or the Xbox 360 APIs (XInput, XACT etc.) have not shipped as part of Windows. Developers are expected to redistribute the runtime components along with their games or applications.
No Microsoft product including the latest XNA releases provides DirectX 10 support for the .NET Framework.
The other approach for DirectX in managed languages is to use third-party libraries like:
There are alternatives to the DirectX family of APIs, with OpenGL, its successor Vulkan, Metal and Mantle having the most features comparable to Direct3D. Examples of other APIs include SDL, Allegro, OpenMAX, OpenML, OpenAL, OpenCL, FMOD, SFML etc. Many of these libraries are cross-platform or have open codebases. There are also alternative implementations that aim to provide the same API, such as the one in Wine. Furthermore, the developers of ReactOS are trying to reimplement DirectX under the name "ReactX".
OpenGL is a cross-language, cross-platform application programming interface (API) for rendering 2D and 3D vector graphics. The API is typically used to interact with a graphics processing unit (GPU), to achieve hardware-accelerated rendering.
DirectDraw (ddraw.dll) is an API that used to be a part of Microsoft's DirectX API. DirectDraw is used to accelerate rendering of 2D graphics in applications. DirectDraw also allows applications to run fullscreen or embedded in a window such as most other MS Windows applications. DirectDraw uses hardware acceleration if it is available on the client's computer. DirectDraw allows direct access to video memory, hardware overlays, hardware blitters, and page flipping. Its video memory manager can manipulate video memory with ease, taking full advantage of the blitting and color decompression capabilities of different types of display adapters.
Direct3D is a graphics application programming interface (API) for Microsoft Windows. Part of DirectX, Direct3D is used to render three-dimensional graphics in applications where performance is important, such as games. Direct3D uses hardware acceleration if available on the graphics card, allowing for hardware acceleration of the entire 3D rendering pipeline or even only partial acceleration. Direct3D exposes the advanced graphics capabilities of 3D graphics hardware, including Z-buffering, W-buffering, stencil buffering, spatial anti-aliasing, alpha blending, color blending, mipmapping, texture blending, clipping, culling, atmospheric effects, perspective-correct texture mapping, programmable HLSL shaders and effects. Integration with other DirectX technologies enables Direct3D to deliver such features as video mapping, hardware 3D rendering in 2D overlay planes, and even sprites, providing the use of 2D and 3D graphics in interactive media ties.
The Graphics Device Interface (GDI) is a legacy component of Microsoft Windows responsible for representing graphical objects and transmitting them to output devices such as monitors and printers. It was superseded by DirectDraw API and later Direct2D API. Windows apps use Windows API to interact with GDI, for such tasks as drawing lines and curves, rendering fonts, and handling palettes. The Windows USER subsystem uses GDI to render such UI elements as window frames and menus. Other systems have components that are similar to GDI; for example: Mac OS has QuickDraw, and Linux and Unix have X Window System core protocol.
In computing, D3DX is a high level API library which is written to supplement Microsoft's Direct3D graphics API. The D3DX library was introduced in Direct3D 7, and subsequently was improved in Direct3D 9. It provides classes for common calculations on vectors, matrices and colors, calculating look-at and projection matrices, spline interpolations, and several more complicated tasks, such as compiling or assembling shaders used for 3D graphic programming, compressed skeletal animation storage and matrix stacks. There are several functions that provide complex operations over 3D meshes like tangent-space computation, mesh simplification, precomputed radiance transfer, optimizing for vertex cache friendliness and strip reordering, and generators for 3D text meshes. 2D features include classes for drawing screen-space lines, text and sprite based particle systems. Spatial functions include various intersection routines, conversion from/to barycentric coordinates and bounding box and sphere generators.
In computer graphics, a shader is a computer program that calculates the appropriate levels of light, darkness, and color during the rendering of a 3D scene—a process known as shading. Shaders have evolved to perform a variety of specialized functions in computer graphics special effects and video post-processing, as well as general-purpose computing on graphics processing units.
Mesa, also called Mesa3D and The Mesa 3D Graphics Library, is an open source implementation of OpenGL, Vulkan, and other graphics API specifications. Mesa translates these specifications to vendor-specific graphics hardware drivers.
Desktop Window Manager is the compositing window manager in Microsoft Windows since Windows Vista that enables the use of hardware acceleration to render the graphical user interface of Windows.
Windows Display Driver Model is the graphic driver architecture for video card drivers running Microsoft Windows versions beginning with Windows Vista.
Managed DirectX (MDX) is Microsoft's deprecated API for DirectX programming on .NET Framework. MDX can be used from any language on .NET Framework. MDX can be used to develop multimedia and interactive applications, enabling high performance graphical representation and enabling the programmer to make use of modern graphical hardware while working inside the .NET Framework.
Adreno is a series of graphics processing unit (GPU) semiconductor intellectual property cores developed by Qualcomm and used in many of their SoCs.
AMD FireStream was AMD's brand name for their Radeon-based product line targeting stream processing and/or GPGPU in supercomputers. Originally developed by ATI Technologies around the Radeon X1900 XTX in 2006, the product line was previously branded as both ATI FireSTREAM and AMD Stream Processor. The AMD FireStream can also be used as a floating-point co-processor for offloading CPU calculations, which is part of the Torrenza initiative. The FireStream line has been discontinued since 2012, when GPGPU workloads were entirely folded into the AMD FirePro line.
DirectX Graphics Infrastructure (DXGI) is a user-mode component of Microsoft Windows which provides a mapping between particular graphics APIs such as Direct3D 10.0 and above and the graphics kernel, which in turn interfaces with the user-mode Windows Display Driver Model driver. DXGI provides objects to handle tasks such as enumerating graphics adapters and monitors, enumerating display modes, choosing buffer formats, sharing resources between processes, and presenting rendered frames to a window or monitor for display.
Direct2D is a 2D vector graphics application programming interface (API) designed by Microsoft and implemented in Windows 10, Windows 8, Windows 7 and Windows Server 2008 R2, and also Windows Vista and Windows Server 2008.
Windows Advanced Rasterization Platform (WARP) is a software rasterizer and a component of DirectX graphics runtime in Windows 7 and later. It is available for Windows Vista and Windows Server 2008 through platform update for Windows Vista.
Mantle was a low-overhead rendering API targeted at 3D video games. AMD originally developed Mantle in cooperation with DICE, starting in 2013. Mantle was designed as an alternative to Direct3D and OpenGL, primarily for use on personal computers. In 2015, Mantle's public development was suspended and in 2019 completely discontinued, as DirectX 12 and the Mantle-derived Vulkan rose in popularity.
CodeXL was an open-source software development tool suite which included a GPU debugger, a GPU profiler, a CPU profiler, a graphics frame analyzer and a static shader/kernel analyzer.
Vulkan is a low-level, low-overhead cross-platform API and open standard for 3D graphics and computing. It was intended to address the shortcomings of OpenGL, and allow developers more control over the GPU. It is designed to support a wide variety of GPUs, CPUs and operating systems, and it is also designed to work with modern multi-core CPUs.
Feature levels in Direct3D define strict sets of features required by certain versions of the Direct3D API and runtime, as well as additional optional feature levels available within the same API version.
Cg and High-Level Shader Language (HLSL) are two names given to a high-level shading language developed by Nvidia and Microsoft for programming shaders. Cg/HLSL is based on the C programming language and although they share the same core syntax, some features of C were modified and new data types were added to make Cg/HLSL more suitable for programming graphics processing units.
Windows needs to support; ... – Page flipping – Vertical blank synchronization – Tight sound mixing – Tight synchronization of sound and video events – Raw blting performance – Ability to set graphic mode ...
Lion King software, for example, is a WinToon app. ... Like WinToon, this example uses WinG for drawing on the DIB.
DMOs have been superseded by Media Foundation Transforms (MFTs).