There have been quite a few questions in this (and other) news groups concerning the built-in video capabilities of the new Macintosh Quadra 700 and 900. In response to these questions, here is the first of three articles which provide an in-depth (and accurate!) description of the Quadra video capabilities. This first article discusses a number of general Quadra video topics, the second details how to wire the video connector sense pins to access all the Quadra's supported video modes, and the third describes the memory configurations necessary to support each of the video modes at specific pixel depths. And by the way, I am the designer of the video hardware for both Mac Quadras, so this information is accurate. The Quadras were designed with a flexible video hardware section in order to support a wide variety of displays. Since the purchaser of one of these CPUs is paying for a frame buffer on the motherboard (whether (s)he wants it or not), and since the Quadras were designed to be high performance machines, the frame buffer was designed to be both very flexible (to support most displays a user may want to use) and to be relatively high performance (to match the computer's capabilities).
Obviously every display made by every 3rd party monitor vendor can't be supported by the onboard video, but the Quadras do support a much wider range of displays at a higher level of performance than any previous Macintosh. The Quadra 700 and 900 support pixel depths ranging from 1 to 32 bits per pixel (bpp), Apple displays ranging from the 512 x 384 12-inch color monitor through the 1152 x 870 21-inch color monitor, pixel clocks ranging from 12 to 100 MHz, and a variety of industry standards such as VGA, SVGA, NTSC, and PAL. The Mac Quadra video port produces RS-343 RGB, and also provides horizontal, vertical and composite sync outputs. Composite or S-video output is not provided, but can be accomplished by use of an external RGB-to-composite encoder. The Quadra 700 and 900 also support Apple convolution for flicker-reduction on interlaced displays (i.e., NTSC and PAL) at up to 8 bpp. The Mac Quadras automatically detect the type of display attached to the video connector via 3 'sense' pins on the video connector. Depending on the wiring of these 3 pins, software in ROM configures the video hardware for one the supported display types. (A full description of sense pin wiring and supported display types is in the 2nd article.)
The Quadra 700/900 provide the highest built-in video performance of any Macintosh CPU to date. In a (very) simplified graphics model, we could say that performance depends on two main factors: processor horsepower and the bandwidth the processor has into frame buffer memory. These machines already have a fast processor - the 68040 - which runs standard 32-bit QuickDraw. To provide high bandwidth into frame buffer memory, dedicated video RAM (VRAM) was used for the frame buffer, and that VRAM was placed directly on the 68040 processor's local bus. This provides the 68040 the same access time into frame buffer memory that it has into main system RAM. (Transfer rates can exceed 40 MBytes/sec.) In addition, memory options such as fast page mode are supported, which can improve graphics performance for operations such as scrolling, offscreen-to-onscreen pixmap transfers, etc.
In a number of cases the design was optimized for high performance over low cost. A good example of this is 32 bpp operation on Apple's standard 13-inch RGB monitor at 640 x 480 resolution (and this also applies to VGA and NTSC), which is probably the most common color monitor in use on the Macintosh. The actual number of memory bytes needed to support 24 bpp is 640 x 480 x 3 = 921,600. This would seem to fit within 1 MByte of memory (as is the case with the Apple 8*24 video card), but the Quadras actually require 2 MBytes of VRAM for this mode. The 8*24 card supports 24 bpp at 640 x 480 by using a storage mode called 'chunky planar' to fully utilize all its 1 MByte of VRAM. However, this results in having to perform 3 separate memory accesses for each 24-bit pixel read from or written to the frame buffer. (This is done in hardware so software only performs a single read or write.) On a NuBus video card, this inefficiency is partially masked by the synchronization delays which occur at the processor-bus/NuBus interface. However, when frame buffer memory is placed directly on the processor bus, this approach results in a nearly 3X performance degradation. This was judged unacceptable for the Quadras. Each 24-bit pixel occupies one longword (4-bytes) in VRAM, so the Quadras actually provide 32 bpp for the 640 x 480 resolution. This pushes the memory requirement for this mode over the 1 MByte boundary (640 x 480 x 4 = 1,228,800 bytes). Performance is improved still more by another frame buffer architectural feature. Frame buffer memory in the Quadras is organized into 4 'banks' of 512 KBytes per bank. As mentioned earlier, Quadra VRAM can operate in fast page mode. In addition, each bank of VRAM operates in fast page mode independently of the other 3 banks. This causes the number of in-page 'hits' to increase, and thus improves the effective bandwidth into the frame buffer. Also, at 32 bpp, 640 x 480 resolution, each row is set to 4096 bytes, or 1024 32-bit pixels. Each successive row is assigned to a different VRAM bank (modulo 4, of course). This memory organization improves performance during certain commonly performed graphics operations such as vertical scrolling.
In any design there are a number of tradeoffs to be made, and this is certainly true for the frame buffer in the Mac Quadra machines. While the video does operate at 32 bpp on up to 16-inch displays, it does not support 21-inch displays at this pixel depth since this would have significantly raised the cost of the motherboard. (Memory capacity and bus bandwidths would essentially have to double, and this would be expensive.) It does support NTSC and PAL timing, but does not provide a composite video output. While it is much faster than any non-accelerated video card, there are accelerated video cards that are faster (and much more expensive, too, by the way). A separate graphics processor was not added primarily for cost reasons. However, a graphics processor such as the 29000 RISC chip on the 8*24GC card can only speed up the graphics operations that it was designed to know about. If an application program bypasses QuickDraw (which is what most Mac graphics accelerators are designed to speed up), a graphics accelerator will not improve performance, and can actually cause a performance degradation.
Overall, the Macintosh Quadra video provides a reasonable compromise of cost, performance, and features, which provides the video needed by the majority of Macintosh users at a reasonable price.
This is the second in a series of articles which describes the capabilities of the built-in video of the Macintosh Quadra 700 and 900. The Quadra frame buffer determines what type of display is attached to the video connector by examining the state of 3 sense line pins. The following chart details how these three pins must be wired for each of the supported display types. For each supported display, the screen resolution (horiz. pixels X vertical pixels), dot clock frequency, and the vertical and horizontal scan rates are listed.
Basically, the Quadra 700 & 900 support any display, whether from Apple or from another vendor, that meets one of the following specifications:
STANDARD SENSE CODES:
|Display||Sense Pins||Pixels||Dot Clock||V refresh||H Refresh|
NOTE 1 on above monitors: A sense pin value of 0 means that the pin should be grounded to the C&V SYNC.GND signal; a value of 1 means do not connect the pin. NOTE 2 on above monitors: sense pins 4, 7, and 10 are referred to as SENSE0, SENSE1, and SENSE2 in pinout tables for the video connectors.
NOTE 3: The terms 'underscan' and 'overscan' are used to describe the active video resolution for NTSC and PAL modes. Underscan means that the active video area appears in a rectangle centered on the screen with a black surrounding area. This ensures that the entire active video area always is displayed on all monitors. Overscan utilizes the entire possible video area for NTSC or PAL. However, most monitors or televisions will cause some of this video to be lost beyond the edges of the display, so the entire image will not be seen.
EXTENDED SENSE CODES:
NOTE for extended sense codes: A sense pin pair value of 0 means those pins should be tied together (as opposed to grounding the pins to pin 11); a value of 1 means do not connect the pins. Do _not_ wire any of these pins to ground.