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235 lines
9.8 KiB
Plaintext
235 lines
9.8 KiB
Plaintext
The new SCSI subsystem
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----------------------
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1. Introduction
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The nscsi subsystem was created to allow an implementation to be
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closer to the physical reality, making it easier (hopefully) to
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implement new controller chips from the documentations.
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2. Global structure
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Parallel SCSI is built around a symmetric bus to which a number of
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devices are connected. The bus is composed of 9 control lines (for
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now, later scsi versions may have more) and up to 32 data lines (but
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currently implemented chips only handle 8). All the lines are open
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collector, which means that either one or multiple chip connect the
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line to ground and the line, of course, goes to ground, or no chip
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drives anything and the line stays at Vcc. Also, the bus uses
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inverted logic, where ground means 1. SCSI chips traditionally work
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in logical and not physical levels, so the nscsi subsystem also works
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in logical levels and does a logical-or of all the outputs of the
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devices.
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Structurally, the implementation is done around two main classes:
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nscsi_bus_devices represents the bus, and nscsi_device represents an
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individual device. A device only communicate with the bus, and the
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bus takes care of transparently handling the device discovery and
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communication. In addition the nscsi_full_device class proposes a
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scsi device with the scsi protocol implemented making building generic
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scsi devices like harddrives or cdrom readers easier.
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3. Plugging in a scsi bus in a driver
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The nscsi subsystem leverages the slot interfaces and the device
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naming to allow for a configurable yet simple bus implementation.
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First you need to create a list of acceptable devices to plug on the
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bus. This usually comprises of cdrom, harddisk and the controller
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chip. For instance:
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static SLOT_INTERFACE_START( next_scsi_devices )
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SLOT_INTERFACE("cdrom", NSCSI_CDROM)
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SLOT_INTERFACE("harddisk", NSCSI_HARDDISK)
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SLOT_INTERFACE_INTERNAL("ncr5390", NCR5390)
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SLOT_INTERFACE_END
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The _INTERNAL interface indicates a device that is not
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user-selectable, which is useful for the controller.
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Then in the machine config (or in a fragment config) you need to first
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add the bus, and then the (potential) devices as subdevices of the bus
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with the scsi id as the name. For instance you can use:
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MCFG_NSCSI_BUS_ADD("scsibus")
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MCFG_NSCSI_ADD("scsibus:0", next_scsi_devices, "cdrom", 0, 0, 0, false)
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MCFG_NSCSI_ADD("scsibus:1", next_scsi_devices, "harddisk", 0, 0, 0, false)
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MCFG_NSCSI_ADD("scsibus:2", next_scsi_devices, 0, 0, 0, 0, false)
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MCFG_NSCSI_ADD("scsibus:3", next_scsi_devices, 0, 0, 0, 0, false)
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MCFG_NSCSI_ADD("scsibus:4", next_scsi_devices, 0, 0, 0, 0, false)
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MCFG_NSCSI_ADD("scsibus:5", next_scsi_devices, 0, 0, 0, 0, false)
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MCFG_NSCSI_ADD("scsibus:6", next_scsi_devices, 0, 0, 0, 0, false)
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MCFG_NSCSI_ADD("scsibus:7", next_scsi_devices, "ncr5390", 0, &next_ncr5390_interface, 10000000, true)
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That configuration puts as default a cdrom reader on scsi id 0 and a
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hard drive on scsi id 1, and forces the controller on id 7. The
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parameters of add are:
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- device tag, comprised of bus-tag:scsi-id
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- the list of acceptable devices
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- the device name as per the list, if one is to be there by default
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- the device input config, if any (and there usually isn't one)
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- the device configuration structure, usually for the controller only
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- the frequency, usually for the controller only
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- "false" for a user-modifyable slot, "true" for a fixed slot
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The full device name, for mapping purposes, will be
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bus-tag:scsi-id:device-type, i.e. "scsibus:7:ncr5390" for our
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controller here.
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4. Creating a new scsi device using nscsi_device
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The base class "nscsi_device" is to be used for down-to-the-metal
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devices, i.e. scsi controller chips. The class provides three
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variables and one method. The first variable, scsi_bus, is a pointer
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to the nscsi_bus_device. The second, scsi_refid, is an opaque
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reference to pass to the bus on some operations. Finally, scsi_id
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gives the scsi id as per the device tag. It's written once at startup
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and never written or read afterwards, the device can do whatever it
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wants with the value or the variable.
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The virtual method scsi_ctrl_changed is called when watched-for
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control lines change. Which lines are watched is defined through the
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bus.
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The bus proposes five methods to access the lines. The read methods
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are ctrl_r() and data_r(). The meaning of the control bits are
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defined in the S_* enum of nscsi_device. The bottom three bits (INP,
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CTL and MSG) are setup so that masking with 7 (S_PHASE_MASK) gives the
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traditional numbers for the phases, which are also available with the
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S_PHASE_* enum.
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Writing the data lines is done with data_w(scsi_refid, value).
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Writing the control lines is done with ctrl_w(scsi_refid, value,
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mask-of-lines-to-change). To change all control lines in one call use
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S_ALL as the mask.
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Of course, what is read is the logical-or of all of what is driven by
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all devices.
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Finally, the method ctrl_wait_w(scsi_id, value,
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mask-of-wait-lines-to-change) allows to select which control lines are
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watched. The watch mask is per-device, and the device method
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scsi_ctrl_changed is called whenever a control line in the mask
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changes due to an action of another device (not itself, to avoid an
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annoying and somewhat useless recursion).
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Implementing the controller is then just a matter of following the
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state machines descriptions, at least if they're available. The only
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part often not described is the arbitration/selection, which is
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documented in the scsi standard though. For an initiator (which is
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what the controller essentially always is), it goes like this:
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- wait for the bus to be idle
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- assert the data line which number is your scsi_id (1 << scsi_id)
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- assert the busy line
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- wait the arbitration time
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- check that the of the active data lines the one with the highest number is yours
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- if no, the arbitration was lost, stop driving anything and restart at the beginning
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- assert the select line (at that point, the bus is yours)
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- wait a short while
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- keep your data line asserted, assert the data line which number is the scsi id of the target
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- wait a short while
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- assert the atn line if needed, deassert busy
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- wait for busy to be asserted or timeout
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- timeout means nobody is answering at that id, deassert everything and stop
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- wait a short while for deskewing
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- deassert the data bus and the select line
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- wait a short while
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and then you're done, you're connected with the target until the
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target deasserts the busy line, either because you asked it to or just
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to annoy you. The deassert is called a disconnect.
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The ncr5390 is an example of how to use a two-level state machine to
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handle all the events.
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5. Creating a new scsi device using nscsi_full_device
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The base class "nscsi_full_device" is used to create HLE-d scsi
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devices intended for generic uses, like hard drives, cdroms, perhaps
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scanners, etc. The class provides the scsi protocol handling, leaving
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only the command handling and (optionally) the message handling to the
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implementation.
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The class currently only support target devices.
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The first method to implement is scsi_command(). That method is
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called when a command has fully arrived. The command is available in
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scsi_cmdbuf[], and its length is in scsi_cmdsize (but the length is
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generally useless, the command first byte giving it). The 4096-bytes
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scsi_cmdbuf array is then freely modifiable.
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In scsi_command(), the device can either handle the command or pass it
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up with nscsi_full_device::scsi_command().
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To handle the command, a number of methods are available:
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- get_lun(lua-set-in-command) will give you the lun to work on (the
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in-command one can be overriden by a message-level one).
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- bad_lun() replies to the host that the specific lun is unsupported.
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- scsi_data_in(buffer-id, size) sends size bytes from buffer buffer-id
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- scsi_data_out(buffer-id, size) recieves size bytes into buffer buffer-id
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- scsi_status_complete(status) ends the command with a given status.
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- sense(deferred, key) prepares the sense buffer for a subsequent
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request-sense command, which is useful when returning a
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check-condition status.
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The scsi_data_* and scsi_status_complete commands are queued, the
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command handler should call them all without waiting.
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buffer-id identifies a buffer. 0, aka SBUF_MAIN, targets the
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scsi_cmdbuf buffer. Other acceptable values are 2 or more. 2+ ids
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are handled through the scsi_get_data method for read and
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scsi_put_data for write.
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UINT8 device::scsi_get_data(int id, int pos) must return byte pos of
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buffer id, upcalling in nscsi_full_device for id < 2.
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void device::scsi_put_data(int id, int pos, UINT8 data) must write
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byte pos in buffer id, upcalling in nscsi_full_device for id < 2.
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scsi_get_data and scsi_put_data should do the external reads/writes
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when needed.
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The device can also override scsi_message to handle scsi messages
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other than the ones generically handled, and it can also override some
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of the timings (but a lot of them aren't used, beware).
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A number of enums are defined to make things easier. The SS_* enum
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gives status returns (with SS_GOOD for all's well). The SC_* enum
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gives the scsi commands. The SM_* enum gives the scsi messages, with
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the exception of identify (which is 80-ff, doesn't really fit in an
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enum).
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6. What's missing
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6.1. What's missing in scsi_full_device
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Initiator support - we have no initiator device to HLE at that point.
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Delays - a scsi_delay command would help giving more realistic timings
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to the cdrom reader in particular.
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Disconnected operation - would first require delays and in addition an
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emulated OS that can handle it.
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16-bits wide operation - needs an OS and an initiator that can handle
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it.
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6.2. What's missing in the ncr5390 (and probably future other controllers)
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Bus free detection. Right now the bus is considered free if the
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controllers isn't using it, which is true. This may change once
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disconnected operation is in.
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Target commands, we don't emulate (vs. HLE) any target yet.
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