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Writing Device Drivers Oracle Solaris 11 Express 11/10 |
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Writing Device Drivers Oracle Solaris 11 Express 11/10 |
Part I Designing Device Drivers for the Oracle Solaris Platform
1. Overview of Oracle Solaris Device Drivers
2. Oracle Solaris Kernel and Device Tree
5. Managing Events and Queueing Tasks
7. Device Access: Programmed I/O
Performing Bus-Master DMA Transfers
Performing First-Party DMA Transfers
Performing Third-Party DMA Transfers
Determining Maximum Burst Sizes
Allocating Private DMA Buffers
Handling Resource Allocation Failures
10. Mapping Device and Kernel Memory
13. Hardening Oracle Solaris Drivers
14. Layered Driver Interface (LDI)
Part II Designing Specific Kinds of Device Drivers
15. Drivers for Character Devices
18. SCSI Host Bus Adapter Drivers
19. Drivers for Network Devices
Part III Building a Device Driver
21. Compiling, Loading, Packaging, and Testing Drivers
22. Debugging, Testing, and Tuning Device Drivers
23. Recommended Coding Practices
B. Summary of Oracle Solaris DDI/DKI Services
C. Making a Device Driver 64-Bit Ready
A DMA handle is an opaque pointer that represents an object, usually a memory buffer or address. A DMA handle enables a device to perform DMA transfers. Several different calls to DMA routines use the handle to identify the DMA resources that are allocated for the object.
An object represented by a DMA handle is completely covered by one or more DMA cookies. A DMA cookie represents a contiguous piece of memory that is used in data transfers by the DMA engine. The system divides objects into multiple cookies based on the following information:
The ddi_dma_attr(9S) attribute structure provided by the driver
Memory location of the target object
Alignment of the target object
If an object does not fit within the limitations of the DMA engine, that object must be broken into multiple DMA windows. You can only activate and allocate resources for one window at a time. Use the ddi_dma_getwin(9F) function to position between windows within an object. Each DMA window consists of one or more DMA cookies. For more information, see DMA Windows.
Some DMA engines can accept more than one cookie. Such engines perform scatter-gather I/O without the help of the system. If multiple cookies are returned from a bind, the driver should call ddi_dma_nextcookie(9F) repeatedly to retrieve each cookie. These cookies must then be programmed into the engine. The device can then be programmed to transfer the total number of bytes covered by the aggregate of these DMA cookies.
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