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Writing Device Drivers     Oracle Solaris 11.1 Information Library
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Part I Designing Device Drivers for the Oracle Solaris Platform

1.  Overview of Oracle Solaris Device Drivers

2.  Oracle Solaris Kernel and Device Tree

3.  Multithreading

4.  Properties

5.  Managing Events and Queueing Tasks

6.  Driver Autoconfiguration

7.  Device Access: Programmed I/O

Device Memory

Managing Differences in Device and Host Endianness

Managing Data Ordering Requirements

ddi_device_acc_attr Structure

Mapping Device Memory

Mapping Setup Example

Device Access Functions

Alternate Device Access Interfaces

Memory Space Access

I/O Space Access

PCI Configuration Space Access

8.  Interrupt Handlers

9.  Direct Memory Access (DMA)

10.  Mapping Device and Kernel Memory

11.  Device Context Management

12.  Power Management

13.  Hardening Oracle Solaris Drivers

14.  Layered Driver Interface (LDI)

Part II Designing Specific Kinds of Device Drivers

15.  Drivers for Character Devices

16.  Drivers for Block Devices

17.  SCSI Target Drivers

18.  SCSI Host Bus Adapter Drivers

19.  Drivers for Network Devices

20.  USB Drivers

21.  SR-IOV Drivers

Part III Building a Device Driver

22.  Compiling, Loading, Packaging, and Testing Drivers

23.  Debugging, Testing, and Tuning Device Drivers

24.  Recommended Coding Practices

Part IV Appendixes

A.  Hardware Overview

B.  Summary of Oracle Solaris DDI/DKI Services

C.  Making a Device Driver 64-Bit Ready

D.  Console Frame Buffer Drivers

E.  pci.conf File


Device Access Functions

Drivers use the ddi_get8(9F) and ddi_put8(9F) family of routines in conjunction with the handle returned by ddi_regs_map_setup(9F) to transfer data to and from a device. The DDI framework automatically handles any byte-swapping that is required to meet the endian format for the host or device, and enforces any store-ordering constraints the device might have.

The DDI provides interfaces for transferring data in 8-bit, 16-bit, 32-bit, and 64-bit quantities, as well as interfaces for transferring multiple values repeatedly. See the man pages for the ddi_get8(9F), ddi_put8(9F), ddi_rep_get8(9F) and ddi_rep_put8(9F) families of routines for a complete listing and description of these interfaces.

The following example builds on Example 7-1 where the driver mapped the device's CSR and data registers. Here, the driver's write(9E) entry point, when called, writes a buffer of data to the device one byte at a time.

Example 7-2 Mapping Setup: Buffer

static  int
pio_write(dev_t dev, struct uio *uiop, cred_t *credp)
    int  retval;
    int  error = OK;
    Pio *pio_p = ddi_get_soft_state(pio_softstate, getminor(dev));

    if (pio_p == NULL)
        return (ENXIO);
     * enable interrupts from the device by setting the Interrupt
     * Enable bit in the devices CSR register
    ddi_put8(pio_p->csr_handle, pio_p->csr,
      (ddi_get8(pio_p->csr_handle, pio_p->csr) | PIO_INTR_ENABLE));

    while (uiop->uio_resid > 0) {
     * This device issues an IDLE interrupt when it is ready
     * to accept a character; the interrupt can be cleared
     * by setting PIO_INTR_CLEAR.  The interrupt is reasserted
     * after the next character is written or the next time
     * PIO_INTR_ENABLE is toggled on.
     * wait for interrupt (see pio_intr)
        cv_wait(&pio_p->cv, &pio_p->mutex);

     * get a character from the user's write request
     * fail the write request if any errors are encountered
        if ((retval = uwritec(uiop)) == -1) {
            error = retval;

     * pass the character to the device by writing it to
     * the device's data register
        ddi_put8(pio_p->data_handle, pio_p->data, (uchar_t)retval);

     * disable interrupts by clearing the Interrupt Enable bit
     * in the CSR
    ddi_put8(pio_p->csr_handle, pio_p->csr,
      (ddi_get8(pio_p->csr_handle, pio_p->csr) & ~PIO_INTR_ENABLE));

    return (error);

Alternate Device Access Interfaces

In addition to implementing all device accesses through the ddi_get8(9F) and ddi_put8(9F) families of interfaces, the Oracle Solaris OS provides interfaces that are specific to particular bus implementations. While these functions can be more efficient on some platforms, use of these routines can limit the ability of the driver to remain portable across different bus versions of the device.

Memory Space Access

With memory mapped access, device registers appear in memory address space. The ddi_getX family of routines and the ddi_putX family are available for use by drivers as an alternative to the standard device access interfaces.

I/O Space Access

With I/O space access, the device registers appear in I/O space, where each addressable element is called an I/O port. The ddi_io_get8(9F) and ddi_io_put8(9F) routines are available for use by drivers as an alternative to the standard device access interfaces.

PCI Configuration Space Access

To access PCI configuration space without using the normal device access interfaces, a driver is required to map PCI configuration space by calling pci_config_setup(9F) in place of ddi_regs_map_setup(9F). The driver can then call the pci_config_get8(9F) and pci_config_put8(9F) families of interfaces to access PCI configuration space.