forked from KolibriOS/kolibrios
a77e7ee15d
git-svn-id: svn://kolibrios.org@3598 a494cfbc-eb01-0410-851d-a64ba20cac60
1596 lines
66 KiB
PHP
1596 lines
66 KiB
PHP
; Code for OHCI controllers.
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; Note: it should be moved to an external driver,
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; it was convenient to have this code compiled into the kernel during initial
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; development, but there are no reasons to keep it here.
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; =============================================================================
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; ================================= Constants =================================
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; =============================================================================
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; OHCI register declarations
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; All of the registers should be read and written as Dwords.
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; Partition 1. Control and Status registers.
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OhciRevisionReg = 0
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OhciControlReg = 4
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OhciCommandStatusReg = 8
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OhciInterruptStatusReg = 0Ch
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OhciInterruptEnableReg = 10h
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OhciInterruptDisableReg = 14h
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; Partition 2. Memory Pointer registers.
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OhciHCCAReg = 18h
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OhciPeriodCurrentEDReg = 1Ch
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OhciControlHeadEDReg = 20h
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OhciControlCurrentEDReg = 24h
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OhciBulkHeadEDReg = 28h
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OhciBulkCurrentEDReg = 2Ch
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OhciDoneHeadReg = 30h
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; Partition 3. Frame Counter registers.
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OhciFmIntervalReg = 34h
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OhciFmRemainingReg = 38h
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OhciFmNumberReg = 3Ch
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OhciPeriodicStartReg = 40h
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OhciLSThresholdReg = 44h
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; Partition 4. Root Hub registers.
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OhciRhDescriptorAReg = 48h
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OhciRhDescriptorBReg = 4Ch
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OhciRhStatusReg = 50h
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OhciRhPortStatusReg = 54h
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; =============================================================================
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; ================================ Structures =================================
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; =============================================================================
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; OHCI-specific part of a pipe descriptor.
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; * This structure corresponds to the Endpoint Descriptor aka ED from the OHCI
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; specification.
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; * The hardware requires 16-bytes alignment of the hardware part.
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; Since the allocator (usb_allocate_common) allocates memory sequentially
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; from page start (aligned on 0x1000 bytes), size of the structure must be
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; divisible by 16.
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struct ohci_pipe
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; All addresses are physical.
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Flags dd ?
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; 1. Lower 7 bits (bits 0-6) are FunctionAddress. This is the USB address of
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; the function containing the endpoint that this ED controls.
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; 2. Next 4 bits (bits 7-10) are EndpointNumber. This is the USB address of
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; the endpoint within the function.
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; 3. Next 2 bits (bits 11-12) are Direction. This 2-bit field indicates the
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; direction of data flow: 1 = IN, 2 = OUT. If neither IN nor OUT is
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; specified, then the direction is determined from the PID field of the TD.
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; For CONTROL endpoints, the transfer direction is different
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; for different transfers, so the value of this field is 0
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; (3 would have the same effect) and the actual direction
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; of one transfer is encoded in the Transfer Descriptor.
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; 4. Next bit (bit 13) is Speed bit. It indicates the speed of the endpoint:
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; full-speed (S = 0) or low-speed (S = 1).
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; 5. Next bit (bit 14) is sKip bit. When this bit is set, the hardware
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; continues on to the next ED on the list without attempting access
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; to the TD queue or issuing any USB token for the endpoint.
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; Always cleared.
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; 6. Next bit (bit 15) is Format bit. It must be 0 for Control, Bulk and
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; Interrupt endpoints and 1 for Isochronous endpoints.
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; 7. Next 11 bits (bits 16-26) are MaximumPacketSize. This field indicates
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; the maximum number of bytes that can be sent to or received from the
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; endpoint in a single data packet.
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TailP dd ?
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; Physical address of the tail descriptor in the TD queue.
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; The descriptor itself is not in the queue. See also HeadP.
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HeadP dd ?
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; 1. First bit (bit 0) is Halted bit. This bit is set by the hardware to
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; indicate that processing of the TD queue on the endpoint is halted.
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; 2. Second bit (bit 1) is toggleCarry bit. Whenever a TD is retired, this
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; bit is written to contain the last data toggle value from the retired TD.
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; 3. Next two bits (bits 2-3) are reserved and always zero.
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; 4. With masked 4 lower bits, this is HeadP itself: physical address of the
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; head descriptor in the TD queue, that is, next TD to be processed for this
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; endpoint. Note that a TD must be 16-bytes aligned.
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; Empty queue is characterized by the condition HeadP == TailP.
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NextED dd ?
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; If nonzero, then this entry is a physical address of the next ED to be
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; processed. See also the description before NextVirt field of the usb_pipe
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; structure. Additionally to that description, the following is specific for
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; the OHCI controller:
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; * n=5, N=32, there are 32 "leaf" periodic lists.
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; * The 1ms periodic list also serves Isochronous endpoints, which should be
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; in the end of the list.
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; * There is no "next" list for Bulk and Control lists, they are processed
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; separately from others.
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; * There is no "next" list for Periodic list for 1ms interval.
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SoftwarePart rd sizeof.usb_pipe/4
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; Software part, common for all controllers.
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ends
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if sizeof.ohci_pipe mod 16
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.err ohci_pipe must be 16-bytes aligned
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end if
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; This structure describes the static head of every list of pipes.
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; The hardware requires 16-bytes alignment of this structure.
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; All instances of this structure are located sequentially in uhci_controller,
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; uhci_controller is page-aligned, so it is sufficient to make this structure
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; 16-bytes aligned and verify that the first instance is 16-bytes aligned
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; inside uhci_controller.
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struct ohci_static_ep
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Flags dd ?
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; Same as ohci_pipe.Flags.
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; sKip bit is set, so the hardware ignores other fields except NextED.
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dd ?
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; Corresponds to ohci_pipe.TailP. Not used.
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NextList dd ?
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; Virtual address of the next list.
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NextED dd ?
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; Same as ohci_pipe.NextED.
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SoftwarePart rd sizeof.usb_static_ep/4
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; Software part, common for all controllers.
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dd ?
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; Padding for 16-bytes alignment.
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ends
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if sizeof.ohci_static_ep mod 16
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.err ohci_static_ep must be 16-bytes aligned
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end if
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; OHCI-specific part of controller data.
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; * The structure describes the memory area used for controller data,
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; additionally to the registers of the controller.
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; * The structure includes two parts, the hardware part and the software part.
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; * The hardware part consists of first 256 bytes and corresponds to
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; the HCCA from OHCI specification.
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; * The hardware requires 256-bytes alignment of the hardware part, so
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; the entire descriptor must be 256-bytes aligned.
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; This structure is allocated with kernel_alloc (see usb_init_controller),
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; this gives page-aligned data.
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; * The controller is described by both ohci_controller and usb_controller
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; structures, for each controller there is one ohci_controller and one
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; usb_controller structure. These structures are located sequentially
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; in the memory: beginning from some page start, there is ohci_controller
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; structure - this enforces hardware alignment requirements - and then
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; usb_controller structure.
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; * The code keeps pointer to usb_controller structure. The ohci_controller
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; structure is addressed as [ptr + ohci_controller.field - sizeof.ohci_controller].
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struct ohci_controller
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; ------------------------------ hardware fields ------------------------------
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InterruptTable rd 32
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; Pointers to interrupt EDs. The hardware starts processing of periodic lists
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; within the frame N from the ED pointed to by [InterruptTable+(N and 31)*4].
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; See also the description of periodic lists inside ohci_pipe structure.
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FrameNumber dw ?
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; The current frame number. This field is written by hardware only.
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; This field is read by ohci_process_deferred and ohci_irq to
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; communicate when control/bulk processing needs to be temporarily
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; stopped/restarted.
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dw ?
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; Padding. Written as zero at every update of FrameNumber.
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DoneHead dd ?
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; Physical pointer to the start of Done Queue.
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; When the hardware updates this field, it sets bit 0 to one if there is
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; unmasked interrupt pending.
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rb 120
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; Reserved for the hardware.
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; ------------------------------ software fields ------------------------------
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IntEDs ohci_static_ep
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rb 62 * sizeof.ohci_static_ep
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; Heads of 63 Periodic lists, see the description in usb_pipe.
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ControlED ohci_static_ep
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; Head of Control list, see the description in usb_pipe.
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BulkED ohci_static_ep
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; Head of Bulk list, see the description in usb_pipe.
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MMIOBase dd ?
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; Virtual address of memory-mapped area with OHCI registers OhciXxxReg.
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PoweredUp db ?
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; 1 in normal work, 0 during early phases of the initialization.
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; This field is initialized to zero during memory allocation
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; (see usb_init_controller), set to one by ohci_init when ports of the root hub
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; are powered up, so connect/disconnect events can be handled.
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rb 3 ; alignment
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DoneList dd ?
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; List of descriptors which were processed by the controller and now need
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; to be finalized.
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DoneListEndPtr dd ?
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; Pointer to dword which should receive a pointer to the next item in DoneList.
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; If DoneList is empty, this is a pointer to DoneList itself;
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; otherwise, this is a pointer to NextTD field of the last item in DoneList.
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ends
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if ohci_controller.IntEDs mod 16
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.err Static endpoint descriptors must be 16-bytes aligned inside ohci_controller
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end if
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; OHCI general transfer descriptor.
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; * The structure describes transfers to be performed on Control, Bulk or
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; Interrupt endpoints.
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; * The structure includes two parts, the hardware part and the software part.
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; * The hardware part consists of first 16 bytes and corresponds to
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; the General Transfer Descriptor aka general TD from OHCI specification.
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; * The hardware requires 16-bytes alignment of the hardware part, so
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; the entire descriptor must be 16-bytes aligned. Since the allocator
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; (usb_allocate_common) allocates memory sequentially from page start
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; (aligned on 0x1000 bytes), size of the structure must be divisible by 16.
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struct ohci_gtd
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; ------------------------------ hardware fields ------------------------------
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; All addresses in this part are physical.
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Flags dd ?
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; 1. Lower 18 bits (bits 0-17) are ignored and not modified by the hardware.
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; 2. Next bit (bit 18) is bufferRounding bit. If this bit is 0, then the last
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; data packet must exactly fill the defined data buffer. If this bit is 1,
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; then the last data packet may be smaller than the defined buffer without
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; causing an error condition on the TD.
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; 3. Next 2 bits (bits 19-20) are Direction field. This field indicates the
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; direction of data flow. If the Direction field in the ED is OUT or IN,
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; this field is ignored and the direction from the ED is used instead.
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; Otherwise, 0 = SETUP, 1 = OUT, 2 = IN, 3 is reserved.
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; 4. Next 3 bits (bits 21-23) are DelayInterrupt field. This field contains
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; the interrupt delay count for this TD. When a TD is complete, the hardware
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; may wait up to DelayInterrupt frames before generating an interrupt.
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; If DelayInterrupt is 7 (maximum possible), then there is no interrupt
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; associated with completion of this TD.
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; 5. Next 2 bits (bits 24-25) are DataToggle field. This field is used to
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; generate/compare the data PID value (DATA0 or DATA1). It is updated after
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; each successful transmission/reception of a data packet. The bit 25
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; is 0 when the data toggle value is acquired from the toggleCarry field in
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; the ED and 1 when the data toggle value is taken from the bit 24.
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; 6. Next 2 bits (bits 26-27) are ErrorCount field. For each transmission
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; error, this value is incremented. If ErrorCount is 2 and another error
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; occurs, the TD is retired with error. When a transaction completes without
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; error, ErrorCount is reset to 0.
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; 7. Upper 4 bits (bits 28-31) are ConditionCode field. This field contains
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; the status of the last attempted transaction, one of USB_STATUS_* values.
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CurBufPtr dd ?
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; Physical address of the next memory location that will be accessed for
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; transfer to/from the endpoint. 0 means zero-length data packet or that all
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; bytes have been transferred.
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NextTD dd ?
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; This field has different meanings depending on the status of the descriptor.
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; When the descriptor is queued for processing, but not yet processed:
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; Physical address of the next TD for the endpoint.
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; When the descriptor is processed by hardware, but not yet by software:
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; Physical address of the previous processed TD.
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; When the descriptor is processed by the IRQ handler, but not yet completed:
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; Virtual pointer to the next processed TD.
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BufEnd dd ?
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; Physical address of the last byte in the buffer for this TD.
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dd ? ; padding for 16-bytes alignment
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SoftwarePart rd sizeof.usb_gtd/4
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; Common part for all controllers.
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ends
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if sizeof.ohci_gtd mod 16
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.err ohci_gtd must be 16-bytes aligned
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end if
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; OHCI isochronous transfer descriptor.
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; * The structure describes transfers to be performed on Isochronous endpoints.
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; * The structure includes two parts, the hardware part and the software part.
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; * The hardware part consists of first 32 bytes and corresponds to
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; the Isochronous Transfer Descriptor aka isochronous TD from OHCI
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; specification.
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; * The hardware requires 32-bytes alignment of the hardware part, so
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; the entire descriptor must be 32-bytes aligned.
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; * The isochronous endpoints are not supported yet, so only hardware part is
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; defined at the moment.
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struct ohci_itd
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StartingFrame dw ?
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; This field contains the low order 16 bits of the frame number in which the
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; first data packet of the Isochronous TD is to be sent.
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Flags dw ?
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; 1. Lower 5 bits (bits 0-4) are ignored and not modified by the hardware.
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; 2. Next 3 bits (bits 5-7) are DelayInterrupt field.
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; 3. Next 3 bits (bits 8-10) are FrameCount field. The TD describes
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; FrameCount+1 data packets.
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; 4. Next bit (bit 11) is ignored and not modified by the hardware.
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; 5. Upper 4 bits (bits 12-15) are ConditionCode field. This field contains
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; the completion code, one of USB_STATUS_* values, when the TD is moved to
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; the Done Queue.
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BufPage0 dd ?
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; Lower 12 bits are ignored and not modified by the hardware.
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; With masked 12 bits this field is the physical page containing all buffers.
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NextTD dd ?
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; Physical address of the next TD in the transfer queue.
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BufEnd dd ?
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; Physical address of the last byte in the buffer.
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OffsetArray rw 8
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; Initialized by software, read by hardware: Offset for packet 0..7.
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; Used to determine size and starting address of an isochronous data packet.
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; Written by hardware, read by software: PacketStatusWord for packet 0..7.
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; Contains completion code and, if applicable, size received for an isochronous
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; data packet.
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ends
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; Description of OHCI-specific data and functions for
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; controller-independent code.
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; Implements the structure usb_hardware_func from hccommon.inc for OHCI.
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iglobal
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align 4
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ohci_hardware_func:
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dd 'OHCI'
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dd sizeof.ohci_controller
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dd ohci_init
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dd ohci_process_deferred
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dd ohci_set_device_address
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dd ohci_get_device_address
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dd ohci_port_disable
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dd ohci_new_port.reset
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dd ohci_set_endpoint_packet_size
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dd usb1_allocate_endpoint
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dd usb1_free_endpoint
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dd ohci_init_pipe
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dd ohci_unlink_pipe
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dd usb1_allocate_general_td
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dd usb1_free_general_td
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dd ohci_alloc_transfer
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dd ohci_insert_transfer
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dd ohci_new_device
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endg
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; =============================================================================
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; =================================== Code ====================================
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; =============================================================================
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; Controller-specific initialization function.
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; Called from usb_init_controller. Initializes the hardware and
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; OHCI-specific parts of software structures.
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; eax = pointer to ohci_controller to be initialized
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; [ebp-4] = pcidevice
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proc ohci_init
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; inherit some variables from the parent (usb_init_controller)
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.devfn equ ebp - 4
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.bus equ ebp - 3
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; 1. Store pointer to ohci_controller for further use.
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push eax
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mov edi, eax
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; 2. Initialize hardware fields of ohci_controller.
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; Namely, InterruptTable needs to be initialized with
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; physical addresses of heads of first 32 Periodic lists.
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; Note that all static heads fit in one page, so one call
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; to get_pg_addr is sufficient.
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if (ohci_controller.IntEDs / 0x1000) <> (ohci_controller.BulkED / 0x1000)
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.err assertion failed
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end if
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if ohci_controller.IntEDs >= 0x1000
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.err assertion failed
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end if
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lea esi, [eax+ohci_controller.IntEDs+32*sizeof.ohci_static_ep]
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call get_pg_addr
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add eax, ohci_controller.IntEDs
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movi ecx, 32
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mov edx, ecx
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@@:
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stosd
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add eax, sizeof.ohci_static_ep
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loop @b
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; 3. Initialize static heads ohci_controller.IntEDs, .ControlED, .BulkED.
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; Use the loop over groups: first group consists of first 32 Periodic
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; descriptors, next group consists of next 16 Periodic descriptors,
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; ..., last group consists of the last Periodic descriptor.
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; 3a. Prepare for the loop.
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; make edi point to start of ohci_controller.IntEDs,
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; other registers are already set.
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; -128 fits in one byte, +128 does not fit.
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sub edi, -128
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; 3b. Loop over groups. On every iteration:
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; edx = size of group, edi = pointer to the current group,
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; esi = pointer to the next group, eax = physical address of the next group.
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.init_static_eds:
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; 3c. Get the size of the next group.
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shr edx, 1
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; 3d. Exit the loop if there is no next group.
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jz .init_static_eds_done
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; 3e. Initialize the first half of the current group.
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; Advance edi to the second half.
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push eax esi
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call ohci_init_static_ep_group
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pop esi eax
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; 3f. Initialize the second half of the current group
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; with the same values.
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; Advance edi to the next group, esi/eax to the next of the next group.
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call ohci_init_static_ep_group
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jmp .init_static_eds
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.init_static_eds_done:
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; 3g. Initialize the head of the last Periodic list.
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xor eax, eax
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xor esi, esi
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call ohci_init_static_endpoint
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; 3i. Initialize the heads of Control and Bulk lists.
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call ohci_init_static_endpoint
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call ohci_init_static_endpoint
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; 4. Create a virtual memory area to talk with the controller.
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; 4a. Enable memory & bus master access.
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mov ch, [.bus]
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mov cl, 0
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mov eax, ecx
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mov bh, [.devfn]
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mov bl, 4
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call pci_read_reg
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or al, 6
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xchg eax, ecx
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call pci_write_reg
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; 4b. Read memory base address.
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mov ah, [.bus]
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mov al, 2
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mov bl, 10h
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call pci_read_reg
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and al, not 0Fh
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; 4c. Create mapping for physical memory. 256 bytes are sufficient.
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stdcall map_io_mem, eax, 100h, PG_SW+PG_NOCACHE
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test eax, eax
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jz .fail
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stosd ; fill ohci_controller.MMIOBase
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xchg eax, edi
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; now edi = MMIOBase
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; 5. Reset the controller if needed.
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; 5a. Check operational state.
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; 0 = reset, 1 = resume, 2 = operational, 3 = suspended
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mov eax, [edi+OhciControlReg]
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and al, 3 shl 6
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cmp al, 2 shl 6
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jz .operational
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; 5b. State is not operational, reset is needed.
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.reset:
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; 5c. Save FmInterval register.
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pushd [edi+OhciFmIntervalReg]
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; 5d. Issue software reset and wait up to 10ms, checking status every 1 ms.
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movi ecx, 1
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movi edx, 10
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mov [edi+OhciCommandStatusReg], ecx
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@@:
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mov esi, ecx
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call delay_ms
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test [edi+OhciCommandStatusReg], ecx
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jz .resetdone
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dec edx
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jnz @b
|
|
pop eax
|
|
dbgstr 'controller reset timeout'
|
|
jmp .fail_unmap
|
|
.resetdone:
|
|
; 5e. Restore FmInterval register.
|
|
pop eax
|
|
mov edx, eax
|
|
and edx, 3FFFh
|
|
jz .setfminterval
|
|
cmp dx, 2EDFh ; default value?
|
|
jnz @f ; assume that BIOS has configured the value
|
|
.setfminterval:
|
|
mov eax, 27792EDFh ; default value
|
|
@@:
|
|
mov [edi+OhciFmIntervalReg], eax
|
|
; 5f. Set PeriodicStart to 90% of FmInterval.
|
|
movzx eax, ax
|
|
; Two following lines are equivalent to eax = floor(eax * 0.9)
|
|
; for any 0 <= eax < 1C71C71Dh, which of course is far from maximum 0FFFFh.
|
|
mov edx, 0E6666667h
|
|
mul edx
|
|
mov [edi+OhciPeriodicStartReg], edx
|
|
.operational:
|
|
; 6. Setup controller registers.
|
|
pop esi ; restore pointer to ohci_controller saved in step 1
|
|
; 6a. Physical address of HCCA.
|
|
mov eax, esi
|
|
call get_pg_addr
|
|
mov [edi+OhciHCCAReg], eax
|
|
; 6b. Transition to operational state and clear all Enable bits.
|
|
mov cl, 2 shl 6
|
|
mov [edi+OhciControlReg], ecx
|
|
; 6c. Physical addresses of head of Control and Bulk lists.
|
|
if ohci_controller.BulkED >= 0x1000
|
|
.err assertion failed
|
|
end if
|
|
add eax, ohci_controller.ControlED
|
|
mov [edi+OhciControlHeadEDReg], eax
|
|
add eax, ohci_controller.BulkED - ohci_controller.ControlED
|
|
mov [edi+OhciBulkHeadEDReg], eax
|
|
; 6d. Zero Head registers: there are no active Control and Bulk descriptors yet.
|
|
xor eax, eax
|
|
; mov [edi+OhciPeriodCurrentEDReg], eax
|
|
mov [edi+OhciControlCurrentEDReg], eax
|
|
mov [edi+OhciBulkCurrentEDReg], eax
|
|
; mov [edi+OhciDoneHeadReg], eax
|
|
; 6e. Enable processing of all lists with control:bulk ratio = 1:1.
|
|
mov dword [edi+OhciControlReg], 10111100b
|
|
; 7. Get number of ports.
|
|
add esi, sizeof.ohci_controller
|
|
mov eax, [edi+OhciRhDescriptorAReg]
|
|
and eax, 0xF
|
|
mov [esi+usb_controller.NumPorts], eax
|
|
; 8. Initialize DoneListEndPtr to point to DoneList.
|
|
lea eax, [esi+ohci_controller.DoneList-sizeof.ohci_controller]
|
|
mov [esi+ohci_controller.DoneListEndPtr-sizeof.ohci_controller], eax
|
|
; 9. Hook interrupt.
|
|
mov ah, [.bus]
|
|
mov al, 0
|
|
mov bh, [.devfn]
|
|
mov bl, 3Ch
|
|
call pci_read_reg
|
|
; al = IRQ
|
|
movzx eax, al
|
|
stdcall attach_int_handler, eax, ohci_irq, esi
|
|
; 10. Enable controller interrupt on HcDoneHead writeback and RootHubStatusChange.
|
|
mov dword [edi+OhciInterruptEnableReg], 80000042h
|
|
DEBUGF 1,'K : OHCI controller at %x:%x with %d ports initialized\n',[.bus]:2,[.devfn]:2,[esi+usb_controller.NumPorts]
|
|
; 11. Initialize ports of the controller.
|
|
; 11a. Initiate power up, disable all ports, clear all "changed" bits.
|
|
mov dword [edi+OhciRhStatusReg], 10000h ; SetGlobalPower
|
|
xor ecx, ecx
|
|
@@:
|
|
mov dword [edi+OhciRhPortStatusReg+ecx*4], 1F0101h ; SetPortPower+ClearPortEnable+clear "changed" bits
|
|
inc ecx
|
|
cmp ecx, [esi+usb_controller.NumPorts]
|
|
jb @b
|
|
; 11b. Wait for power up.
|
|
; VirtualBox has AReg == 0, delay_ms doesn't like zero value; ignore zero delay
|
|
push esi
|
|
mov esi, [edi+OhciRhDescriptorAReg]
|
|
shr esi, 24
|
|
add esi, esi
|
|
jz @f
|
|
call delay_ms
|
|
@@:
|
|
pop esi
|
|
; 11c. Ports are powered up; now it is ok to process connect/disconnect events.
|
|
mov [esi+ohci_controller.PoweredUp-sizeof.ohci_controller], 1
|
|
; IRQ handler doesn't accept connect/disconnect events before this point
|
|
; 11d. We could miss some events while waiting for powering up;
|
|
; scan all ports manually and check for connected devices.
|
|
xor ecx, ecx
|
|
.port_loop:
|
|
test dword [edi+OhciRhPortStatusReg+ecx*4], 1
|
|
jz .next_port
|
|
; There is a connected device; mark the port as 'connected'
|
|
; and save the connected time.
|
|
; Note that ConnectedTime must be set before 'connected' mark,
|
|
; otherwise the code in ohci_process_deferred could use incorrect time.
|
|
mov eax, [timer_ticks]
|
|
mov [esi+usb_controller.ConnectedTime+ecx*4], eax
|
|
lock bts [esi+usb_controller.NewConnected], ecx
|
|
.next_port:
|
|
inc ecx
|
|
cmp ecx, [esi+usb_controller.NumPorts]
|
|
jb .port_loop
|
|
; 12. Return pointer to usb_controller.
|
|
xchg eax, esi
|
|
ret
|
|
.fail_unmap:
|
|
; On error after step 4, release the virtual memory area.
|
|
stdcall free_kernel_space, edi
|
|
.fail:
|
|
; On error, free the ohci_controller structure and return zero.
|
|
; Note that the pointer was placed in the stack at step 1.
|
|
; Note also that there can be no errors after step 8,
|
|
; where that pointer is popped from the stack.
|
|
pop ecx
|
|
.nothing:
|
|
xor eax, eax
|
|
ret
|
|
endp
|
|
|
|
; Helper procedure for step 3 of ohci_init.
|
|
; Initializes the static head of one list.
|
|
; eax = physical address of the "next" list, esi = pointer to the "next" list,
|
|
; edi = pointer to head to initialize.
|
|
; Advances edi to the next head, keeps eax/esi.
|
|
proc ohci_init_static_endpoint
|
|
mov byte [edi+ohci_static_ep.Flags+1], 1 shl (14 - 8) ; sKip this endpoint
|
|
mov [edi+ohci_static_ep.NextED], eax
|
|
mov [edi+ohci_static_ep.NextList], esi
|
|
add edi, ohci_static_ep.SoftwarePart
|
|
call usb_init_static_endpoint
|
|
add edi, sizeof.ohci_static_ep - ohci_static_ep.SoftwarePart
|
|
ret
|
|
endp
|
|
|
|
; Helper procedure for step 3 of ohci_init.
|
|
; Initializes one half of group of static heads.
|
|
; edx = size of the next group = half of size of the group,
|
|
; edi = pointer to the group, eax = physical address of the next group,
|
|
; esi = pointer to the next group.
|
|
; Advances eax, esi, edi to next group, keeps edx.
|
|
proc ohci_init_static_ep_group
|
|
push edx
|
|
@@:
|
|
call ohci_init_static_endpoint
|
|
add eax, sizeof.ohci_static_ep
|
|
add esi, sizeof.ohci_static_ep
|
|
dec edx
|
|
jnz @b
|
|
pop edx
|
|
ret
|
|
endp
|
|
|
|
; Controller-specific pre-initialization function: take ownership from BIOS.
|
|
; Some BIOSes, although not all of them, provide legacy emulation
|
|
; for USB keyboard and/or mice as PS/2-devices. In this case,
|
|
; we must notify the BIOS that we don't need that emulation and know how to
|
|
; deal with USB devices.
|
|
proc ohci_kickoff_bios
|
|
; 1. Get the physical address of MMIO registers.
|
|
mov ah, [esi+PCIDEV.bus]
|
|
mov bh, [esi+PCIDEV.devfn]
|
|
mov al, 2
|
|
mov bl, 10h
|
|
call pci_read_reg
|
|
and al, not 0Fh
|
|
; 2. Create mapping for physical memory. 256 bytes are sufficient.
|
|
stdcall map_io_mem, eax, 100h, PG_SW+PG_NOCACHE
|
|
test eax, eax
|
|
jz .nothing
|
|
; 3. Some BIOSes enable controller interrupts as a result of giving
|
|
; controller away. At this point the system knows nothing about how to serve
|
|
; OHCI interrupts, so such an interrupt will send the system into an infinite
|
|
; loop handling the same IRQ again and again. Thus, we need to block OHCI
|
|
; interrupts. We can't do this at the controller level until step 5,
|
|
; because the controller is currently owned by BIOS, so we block all hardware
|
|
; interrupts on this processor until step 5.
|
|
pushf
|
|
cli
|
|
; 4. Take the ownership over the controller.
|
|
; 4a. Check whether BIOS handles this controller at all.
|
|
mov edx, 100h
|
|
test dword [eax+OhciControlReg], edx
|
|
jz .has_ownership
|
|
; 4b. Send "take ownership" command to the BIOS.
|
|
; (This should generate SMI, BIOS should release its ownership in SMI handler.)
|
|
mov dword [eax+OhciCommandStatusReg], 8
|
|
; 4c. Wait for result no more than 50 ms, checking for status every 1 ms.
|
|
movi ecx, 50
|
|
@@:
|
|
test dword [eax+OhciControlReg], edx
|
|
jz .has_ownership
|
|
push esi
|
|
movi esi, 1
|
|
call delay_ms
|
|
pop esi
|
|
loop @b
|
|
dbgstr 'warning: taking OHCI ownership from BIOS timeout'
|
|
.has_ownership:
|
|
; 5. Disable all controller interrupts until the system will be ready to
|
|
; process them.
|
|
mov dword [eax+OhciInterruptDisableReg], 0C000007Fh
|
|
; 6. Now we can unblock interrupts in the processor.
|
|
popf
|
|
; 7. Release memory mapping created in step 2 and return.
|
|
stdcall free_kernel_space, eax
|
|
.nothing:
|
|
ret
|
|
endp
|
|
|
|
; IRQ handler for OHCI controllers.
|
|
ohci_irq.noint:
|
|
; Not our interrupt: restore registers and return zero.
|
|
xor eax, eax
|
|
pop edi esi ebx
|
|
ret
|
|
|
|
proc ohci_irq
|
|
push ebx esi edi ; save used registers to be cdecl
|
|
virtual at esp
|
|
rd 3 ; saved registers
|
|
dd ? ; return address
|
|
.controller dd ?
|
|
end virtual
|
|
; 1. ebx will hold whether some deferred processing is needed,
|
|
; that cannot be done from the interrupt handler. Initialize to zero.
|
|
xor ebx, ebx
|
|
; 2. Get the mask of events which should be processed.
|
|
mov esi, [.controller]
|
|
mov edi, [esi+ohci_controller.MMIOBase-sizeof.ohci_controller]
|
|
mov eax, [edi+OhciInterruptStatusReg]
|
|
; 3. Check whether that interrupt has been generated by our controller.
|
|
; (One IRQ can be shared by several devices.)
|
|
and eax, [edi+OhciInterruptEnableReg]
|
|
jz .noint
|
|
; 4. Get the physical pointer to the last processed descriptor.
|
|
; All processed descriptors form single-linked list from last to first
|
|
; with the help of NextTD field. The list is restarted every time when
|
|
; the controller writes to DoneHead, so grab the pointer now (before the next
|
|
; step) or it could be lost (the controller could write new value to DoneHead
|
|
; any time after WorkDone bit is cleared in OhciInterruptStatusReg).
|
|
mov ecx, [esi+ohci_controller.DoneHead-sizeof.ohci_controller]
|
|
and ecx, not 1
|
|
; 5. Clear the events we know of.
|
|
; Note that this should be done before processing of events:
|
|
; new events could arise while we are processing those, this way we won't lose
|
|
; them (the controller would generate another interrupt
|
|
; after completion of this one).
|
|
mov [edi+OhciInterruptStatusReg], eax
|
|
; 6. Save the mask of events for further reference.
|
|
push eax
|
|
; 7. Handle 'transfer is done' events.
|
|
; 7a. Test whether there are such events.
|
|
test al, 2
|
|
jz .skip_donehead
|
|
; There are some 'transfer is done' events, processed descriptors are linked
|
|
; through physical addresses in the reverse order.
|
|
; We can't do much in an interrupt handler, since callbacks could require
|
|
; waiting for locks and that can't be done in an interrupt handler.
|
|
; However, we can't also just defer all work to the USB thread, since
|
|
; it is possible that previous lists are not yet processed and it is hard
|
|
; to store unlimited number of list heads. Thus, we reverse the current list,
|
|
; append it to end of the previous list (if there is one) and defer other
|
|
; processing to the USB thread; this way there always is no more than one list
|
|
; (possibly joined from several controller-reported lists).
|
|
; The list traversal requires converting physical addresses to virtual pointers,
|
|
; so we may as well store pointers instead of physical addresses.
|
|
; 7b. Prepare for the reversing loop.
|
|
push ebx
|
|
xor ebx, ebx
|
|
test ecx, ecx
|
|
jz .tddone
|
|
call usb_td_to_virt
|
|
test eax, eax
|
|
jz .tddone
|
|
lea edx, [eax+ohci_gtd.NextTD]
|
|
; 7c. Reverse the list, converting physical to virtual. On every iteration:
|
|
; ecx = physical address of the current item
|
|
; eax = virtual pointer to the current item
|
|
; edx = virtual pointer to the last item.NextTD (first in the reverse list)
|
|
; ebx = virtual pointer to the next item (previous in the reverse list)
|
|
.tdloop:
|
|
mov ecx, [eax+ohci_gtd.NextTD]
|
|
mov [eax+ohci_gtd.NextTD], ebx
|
|
lea ebx, [eax+ohci_gtd.SoftwarePart]
|
|
test ecx, ecx
|
|
jz .tddone
|
|
call usb_td_to_virt
|
|
test eax, eax
|
|
jnz .tdloop
|
|
.tddone:
|
|
mov ecx, ebx
|
|
pop ebx
|
|
; 7d. The list is reversed,
|
|
; ecx = pointer to the first item, edx = pointer to the last item.NextTD.
|
|
; If the list is empty (unusual case), step 7 is done.
|
|
test ecx, ecx
|
|
jz .skip_donehead
|
|
; 7e. Otherwise, append this list to the end of previous one.
|
|
; Note that in theory the interrupt handler and the USB thread
|
|
; could execute in parallel.
|
|
.append_restart:
|
|
; Atomically get DoneListEndPtr in eax and set it to edx.
|
|
mov eax, [esi+ohci_controller.DoneListEndPtr-sizeof.ohci_controller]
|
|
lock cmpxchg [esi+ohci_controller.DoneListEndPtr-sizeof.ohci_controller], edx
|
|
jnz .append_restart
|
|
; Store pointer to the new list.
|
|
; Note: we cannot perform any operations with [DoneListEndPtr]
|
|
; until we switch DoneListEndPtr to a new descriptor:
|
|
; it is possible that after first line of .append_restart loop
|
|
; ohci_process_deferred obtains the control, finishes processing
|
|
; of the old list, sets DoneListEndPtr to address of DoneList,
|
|
; frees all old descriptors, so eax would point to invalid location.
|
|
; This way, .append_restart loop would detect that DoneListEndPtr
|
|
; has changed, so eax needs to be re-read.
|
|
mov [eax], ecx
|
|
; 7f. Notify the USB thread that there is new work.
|
|
inc ebx
|
|
.skip_donehead:
|
|
; 8. Handle start-of-frame events.
|
|
; 8a. Test whether there are such events.
|
|
test byte [esp], 4
|
|
jz .skip_sof
|
|
; We enable SOF interrupt only when some pipes are waiting after changes.
|
|
spin_lock_irqsave [esi+usb_controller.WaitSpinlock]
|
|
; 8b. Make sure that there was at least one frame update
|
|
; since the request. If not, wait for the next SOF.
|
|
movzx eax, [esi+ohci_controller.FrameNumber-sizeof.ohci_controller]
|
|
cmp eax, [esi+usb_controller.StartWaitFrame]
|
|
jz .sof_unlock
|
|
; 8c. Copy WaitPipeRequest* to ReadyPipeHead*.
|
|
mov eax, [esi+usb_controller.WaitPipeRequestAsync]
|
|
mov [esi+usb_controller.ReadyPipeHeadAsync], eax
|
|
mov eax, [esi+usb_controller.WaitPipeRequestPeriodic]
|
|
mov [esi+usb_controller.ReadyPipeHeadPeriodic], eax
|
|
; 8d. It is possible that pipe change is due to removal and
|
|
; Control/BulkCurrentED registers still point to one of pipes to be removed.
|
|
; The code responsible for disconnect events has temporarily stopped
|
|
; Control/Bulk processing, so it is safe to clear Control/BulkCurrentED.
|
|
; After that, restart processing.
|
|
xor edx, edx
|
|
mov [edi+OhciControlCurrentEDReg], edx
|
|
mov [edi+OhciBulkCurrentEDReg], edx
|
|
mov dword [edi+OhciCommandStatusReg], 6
|
|
or dword [edi+OhciControlReg], 30h
|
|
; 8e. Disable further interrupts on SOF.
|
|
; Note: OhciInterruptEnableReg/OhciInterruptDisableReg have unusual semantics.
|
|
mov dword [edi+OhciInterruptDisableReg], 4
|
|
; Notify the USB thread that there is new work (with pipes from ReadyPipeHead*).
|
|
inc ebx
|
|
.sof_unlock:
|
|
spin_unlock_irqrestore [esi+usb_controller.RemoveSpinlock]
|
|
.skip_sof:
|
|
; Handle roothub events.
|
|
; 9. Test whether there are such events.
|
|
test byte [esp], 40h
|
|
jz .skip_roothub
|
|
; 10. Check the status of the roothub itself.
|
|
; 10a. Global overcurrent?
|
|
test dword [edi+OhciRhStatusReg], 2
|
|
jz @f
|
|
; Note: this needs work.
|
|
dbgstr 'global overcurrent'
|
|
@@:
|
|
; 10b. Clear roothub events.
|
|
mov dword [edi+OhciRhStatusReg], 80020000h
|
|
; 11. Check the status of individual ports.
|
|
; Look for connect/disconnect and reset events.
|
|
; 11a. Prepare for the loop: start from port 0.
|
|
xor ecx, ecx
|
|
.portloop:
|
|
; 11b. Get the port status and changes of it.
|
|
; Accumulate change information.
|
|
; Look to "11.12.3 Port Change Information Processing" of the USB2 spec.
|
|
xor eax, eax
|
|
.accloop:
|
|
mov edx, [edi+OhciRhPortStatusReg+ecx*4]
|
|
xor ax, ax
|
|
or eax, edx
|
|
test edx, 1F0000h
|
|
jz .accdone
|
|
mov dword [edi+OhciRhPortStatusReg+ecx*4], 1F0000h
|
|
jmp .accloop
|
|
.accdone:
|
|
; debugging output, not needed for work
|
|
; test eax, 1F0000h
|
|
; jz @f
|
|
; DEBUGF 1,'K : ohci irq [%d] status of port %d is %x\n',[timer_ticks],ecx,eax
|
|
;@@:
|
|
; 11c. Ignore any events until all ports are powered up.
|
|
; They will be processed by ohci_init.
|
|
cmp [esi+ohci_controller.PoweredUp-sizeof.ohci_controller], 0
|
|
jz .nextport
|
|
; Handle changing of connection status.
|
|
test eax, 10000h
|
|
jz .nocsc
|
|
; There was a connect or disconnect event at this port.
|
|
; 11d. Disconnect the old device on this port, if any.
|
|
; if the port was resetting, indicate fail and signal
|
|
cmp cl, [esi+usb_controller.ResettingPort]
|
|
jnz @f
|
|
mov [esi+usb_controller.ResettingStatus], -1
|
|
inc ebx
|
|
@@:
|
|
lock bts [esi+usb_controller.NewDisconnected], ecx
|
|
; notify the USB thread that new work is waiting
|
|
inc ebx
|
|
; 11e. Change connected status. For the connection event, also
|
|
; store the connection time; any further processing is permitted only
|
|
; after USB_CONNECT_DELAY ticks.
|
|
test al, 1
|
|
jz .disconnect
|
|
; Note: ConnectedTime must be stored before setting the 'connected' bit,
|
|
; otherwise ohci_process_deferred could use an old time.
|
|
mov eax, [timer_ticks]
|
|
mov [esi+usb_controller.ConnectedTime+ecx*4], eax
|
|
lock bts [esi+usb_controller.NewConnected], ecx
|
|
jmp .nextport
|
|
.disconnect:
|
|
lock btr [esi+usb_controller.NewConnected], ecx
|
|
jmp .nextport
|
|
.nocsc:
|
|
; 11f. Process 'reset done' events.
|
|
test eax, 100000h
|
|
jz .nextport
|
|
test al, 10h
|
|
jnz .nextport
|
|
mov edx, [timer_ticks]
|
|
mov [esi+usb_controller.ResetTime], edx
|
|
mov [esi+usb_controller.ResettingStatus], 2
|
|
inc ebx
|
|
.nextport:
|
|
; 11g. Continue the loop for the next port.
|
|
inc ecx
|
|
cmp ecx, [esi+usb_controller.NumPorts]
|
|
jb .portloop
|
|
.skip_roothub:
|
|
; 12. Restore the stack after step 6.
|
|
pop eax
|
|
; 13. Notify the USB thread if some deferred processing is required.
|
|
call usb_wakeup_if_needed
|
|
; 14. Interrupt processed; return something non-zero.
|
|
mov al, 1
|
|
pop edi esi ebx ; restore used registers to be stdcall
|
|
ret
|
|
endp
|
|
|
|
; This procedure is called from usb_set_address_callback
|
|
; and stores USB device address in the ohci_pipe structure.
|
|
; in: esi -> usb_controller, ebx -> usb_pipe, cl = address
|
|
proc ohci_set_device_address
|
|
mov byte [ebx+ohci_pipe.Flags-ohci_pipe.SoftwarePart], cl
|
|
; Wait until the hardware will forget the old value.
|
|
call usb_subscribe_control
|
|
ret
|
|
endp
|
|
|
|
; This procedure returns USB device address from the usb_pipe structure.
|
|
; in: esi -> usb_controller, ebx -> usb_pipe
|
|
; out: eax = endpoint address
|
|
proc ohci_get_device_address
|
|
mov eax, [ebx+ohci_pipe.Flags-ohci_pipe.SoftwarePart]
|
|
and eax, 7Fh
|
|
ret
|
|
endp
|
|
|
|
; This procedure is called from usb_set_address_callback
|
|
; if the device does not accept SET_ADDRESS command and needs
|
|
; to be disabled at the port level.
|
|
; in: esi -> usb_controller, ecx = port
|
|
proc ohci_port_disable
|
|
mov edx, [esi+ohci_controller.MMIOBase-sizeof.ohci_controller]
|
|
mov dword [edx+OhciRhPortStatusReg+ecx*4], 1
|
|
ret
|
|
endp
|
|
|
|
; This procedure is called from usb_get_descr8_callback when
|
|
; the packet size for zero endpoint becomes known and
|
|
; stores the packet size in ohci_pipe structure.
|
|
; in: esi -> usb_controller, ebx -> usb_pipe, ecx = packet size
|
|
proc ohci_set_endpoint_packet_size
|
|
mov byte [ebx+ohci_pipe.Flags+2-ohci_pipe.SoftwarePart], cl
|
|
; Wait until the hardware will forget the old value.
|
|
call usb_subscribe_control
|
|
ret
|
|
endp
|
|
|
|
; This procedure is called from API usb_open_pipe and processes
|
|
; the controller-specific part of this API. See docs.
|
|
; in: edi -> usb_pipe for target, ecx -> usb_pipe for config pipe,
|
|
; esi -> usb_controller, eax -> usb_gtd for the first TD,
|
|
; [ebp+12] = endpoint, [ebp+16] = maxpacket, [ebp+20] = type
|
|
proc ohci_init_pipe
|
|
virtual at ebp+8
|
|
.config_pipe dd ?
|
|
.endpoint dd ?
|
|
.maxpacket dd ?
|
|
.type dd ?
|
|
.interval dd ?
|
|
end virtual
|
|
; 1. Initialize the queue of transfer descriptors: empty.
|
|
sub eax, ohci_gtd.SoftwarePart
|
|
call get_phys_addr
|
|
mov [edi+ohci_pipe.TailP-ohci_pipe.SoftwarePart], eax
|
|
mov [edi+ohci_pipe.HeadP-ohci_pipe.SoftwarePart], eax
|
|
; 2. Generate ohci_pipe.Flags, see the description in ohci_pipe.
|
|
mov eax, [ecx+ohci_pipe.Flags-ohci_pipe.SoftwarePart]
|
|
and eax, 0x207F ; keep Speed bit and FunctionAddress
|
|
mov edx, [.endpoint]
|
|
and edx, 15
|
|
shl edx, 7
|
|
or eax, edx
|
|
mov [edi+ohci_pipe.Flags-ohci_pipe.SoftwarePart], eax
|
|
mov eax, [.maxpacket]
|
|
mov word [edi+ohci_pipe.Flags+2-ohci_pipe.SoftwarePart], ax
|
|
cmp [.type], CONTROL_PIPE
|
|
jz @f
|
|
test byte [.endpoint], 80h
|
|
setnz al
|
|
inc eax
|
|
shl al, 3
|
|
or byte [edi+ohci_pipe.Flags+1-ohci_pipe.SoftwarePart], al
|
|
@@:
|
|
; 3. Insert the new pipe to the corresponding list of endpoints.
|
|
; 3a. Use Control list for control pipes, Bulk list for bulk pipes.
|
|
lea edx, [esi+ohci_controller.ControlED.SoftwarePart-sizeof.ohci_controller]
|
|
cmp [.type], BULK_PIPE
|
|
jb .insert ; control pipe
|
|
lea edx, [esi+ohci_controller.BulkED.SoftwarePart-sizeof.ohci_controller]
|
|
jz .insert ; bulk pipe
|
|
.interrupt_pipe:
|
|
; 3b. For interrupt pipes, let the scheduler select the appropriate list
|
|
; based on the current bandwidth distribution and the requested bandwidth.
|
|
; This could fail if the requested bandwidth is not available;
|
|
; if so, return an error.
|
|
lea edx, [esi + ohci_controller.IntEDs - sizeof.ohci_controller]
|
|
lea eax, [esi + ohci_controller.IntEDs + 32*sizeof.ohci_static_ep - sizeof.ohci_controller]
|
|
movi ecx, 64
|
|
call usb1_select_interrupt_list
|
|
test edx, edx
|
|
jz .return0
|
|
; 3c. Insert endpoint at edi to the head of list in edx.
|
|
; Inserting to tail would work as well,
|
|
; but let's be consistent with other controllers.
|
|
.insert:
|
|
mov ecx, [edx+usb_pipe.NextVirt]
|
|
mov [edi+usb_pipe.NextVirt], ecx
|
|
mov [edi+usb_pipe.PrevVirt], edx
|
|
mov [ecx+usb_pipe.PrevVirt], edi
|
|
mov [edx+usb_pipe.NextVirt], edi
|
|
mov ecx, [edx+ohci_pipe.NextED-ohci_pipe.SoftwarePart]
|
|
mov [edi+ohci_pipe.NextED-ohci_pipe.SoftwarePart], ecx
|
|
lea eax, [edi-ohci_pipe.SoftwarePart]
|
|
call get_phys_addr
|
|
mov [edx+ohci_pipe.NextED-ohci_pipe.SoftwarePart], eax
|
|
; 4. Return something non-zero.
|
|
ret
|
|
.return0:
|
|
xor eax, eax
|
|
ret
|
|
endp
|
|
|
|
; This function is called from ohci_process_deferred when
|
|
; a new device was connected at least USB_CONNECT_DELAY ticks
|
|
; and therefore is ready to be configured.
|
|
; ecx = port, esi -> usb_controller
|
|
proc ohci_new_port
|
|
; test whether we are configuring another port
|
|
; if so, postpone configuring and return
|
|
bts [esi+usb_controller.PendingPorts], ecx
|
|
cmp [esi+usb_controller.ResettingPort], -1
|
|
jnz .nothing
|
|
btr [esi+usb_controller.PendingPorts], ecx
|
|
; fall through to ohci_new_port.reset
|
|
|
|
; This function is called from usb_test_pending_port.
|
|
; It starts reset signalling for the port. Note that in USB first stages
|
|
; of configuration can not be done for several ports in parallel.
|
|
.reset:
|
|
; reset port
|
|
and [esi+usb_controller.ResettingHub], 0
|
|
mov [esi+usb_controller.ResettingPort], cl
|
|
; Note: setting status must be the last action:
|
|
; it is possible that the device has been disconnected
|
|
; after timeout of USB_CONNECT_DELAY but before call to ohci_new_port.
|
|
; In this case, ohci_irq would not set reset status to 'failed',
|
|
; because ohci_irq would not know that this port is to be reset.
|
|
; However, the hardware would generate another interrupt
|
|
; in a response to reset a disconnected port, and this time
|
|
; ohci_irq knows that it needs to generate 'reset failed' event
|
|
; (because ResettingPort is now filled).
|
|
push edi
|
|
mov edi, [esi+ohci_controller.MMIOBase-sizeof.ohci_controller]
|
|
mov dword [edi+OhciRhPortStatusReg+ecx*4], 10h
|
|
pop edi
|
|
.nothing:
|
|
ret
|
|
endp
|
|
|
|
; This procedure is called from the several places in main USB code
|
|
; and allocates required packets for the given transfer.
|
|
; ebx = pipe, other parameters are passed through the stack:
|
|
; buffer,size = data to transfer
|
|
; flags = same as in usb_open_pipe: bit 0 = allow short transfer, other bits reserved
|
|
; td = pointer to the current end-of-queue descriptor
|
|
; direction =
|
|
; 0000b for normal transfers,
|
|
; 1000b for control SETUP transfer,
|
|
; 1101b for control OUT transfer,
|
|
; 1110b for control IN transfer
|
|
; returns eax = pointer to the new end-of-queue descriptor
|
|
; (not included in the queue itself) or 0 on error
|
|
proc ohci_alloc_transfer stdcall uses edi, \
|
|
buffer:dword, size:dword, flags:dword, td:dword, direction:dword
|
|
locals
|
|
origTD dd ?
|
|
packetSize dd ? ; must be the last variable, see usb_init_transfer
|
|
endl
|
|
; 1. Save original value of td:
|
|
; it will be useful for rollback if something would fail.
|
|
mov eax, [td]
|
|
mov [origTD], eax
|
|
; One transfer descriptor can describe up to two pages.
|
|
; In the worst case (when the buffer is something*1000h+0FFFh)
|
|
; this corresponds to 1001h bytes. If the requested size is
|
|
; greater, we should split the transfer into several descriptors.
|
|
; Boundaries to split must be multiples of endpoint transfer size
|
|
; to avoid short packets except in the end of the transfer,
|
|
; 1000h is always a good value.
|
|
; 2. While the remaining data cannot fit in one packet,
|
|
; allocate page-sized descriptors.
|
|
mov edi, 1000h
|
|
mov [packetSize], edi
|
|
.fullpackets:
|
|
cmp [size], edi
|
|
jbe .lastpacket
|
|
call ohci_alloc_packet
|
|
test eax, eax
|
|
jz .fail
|
|
mov [td], eax
|
|
add [buffer], edi
|
|
sub [size], edi
|
|
jmp .fullpackets
|
|
; 3. The remaining data can fit in one descriptor;
|
|
; allocate the last descriptor with size = size of remaining data.
|
|
.lastpacket:
|
|
mov eax, [size]
|
|
mov [packetSize], eax
|
|
call ohci_alloc_packet
|
|
test eax, eax
|
|
jz .fail
|
|
; 4. Enable an immediate interrupt on completion of the last packet.
|
|
and byte [ecx+ohci_gtd.Flags+2-ohci_gtd.SoftwarePart], not (7 shl (21-16))
|
|
; 5. If a short transfer is ok for a caller, set the corresponding bit in
|
|
; the last descriptor, but not in others.
|
|
; Note: even if the caller says that short transfers are ok,
|
|
; all packets except the last one are marked as 'must be complete':
|
|
; if one of them will be short, the software intervention is needed
|
|
; to skip remaining packets; ohci_process_finalized_td will handle this
|
|
; transparently to the caller.
|
|
test [flags], 1
|
|
jz @f
|
|
or byte [ecx+ohci_gtd.Flags+2-ohci_gtd.SoftwarePart], 1 shl (18-16)
|
|
@@:
|
|
ret
|
|
.fail:
|
|
mov edi, ohci_hardware_func
|
|
mov eax, [td]
|
|
stdcall usb_undo_tds, [origTD]
|
|
xor eax, eax
|
|
ret
|
|
endp
|
|
|
|
; Helper procedure for ohci_alloc_transfer.
|
|
; Allocates and initializes one transfer descriptor.
|
|
; ebx = pipe, other parameters are passed through the stack;
|
|
; fills the current last descriptor and
|
|
; returns eax = next descriptor (not filled).
|
|
proc ohci_alloc_packet
|
|
; inherit some variables from the parent ohci_alloc_transfer
|
|
virtual at ebp-8
|
|
.origTD dd ?
|
|
.packetSize dd ?
|
|
rd 2
|
|
.buffer dd ?
|
|
.transferSize dd ?
|
|
.Flags dd ?
|
|
.td dd ?
|
|
.direction dd ?
|
|
end virtual
|
|
; 1. Allocate the next TD.
|
|
call usb1_allocate_general_td
|
|
test eax, eax
|
|
jz .nothing
|
|
; 2. Initialize controller-independent parts of both TDs.
|
|
push eax
|
|
call usb_init_transfer
|
|
pop eax
|
|
; 3. Save the returned value (next descriptor).
|
|
push eax
|
|
; 4. Store the physical address of the next descriptor.
|
|
sub eax, ohci_gtd.SoftwarePart
|
|
call get_phys_addr
|
|
mov [ecx+ohci_gtd.NextTD-ohci_gtd.SoftwarePart], eax
|
|
; 5. For zero-length transfers, store zero in both fields for buffer addresses.
|
|
; Otherwise, fill them with real values.
|
|
xor eax, eax
|
|
mov [ecx+ohci_gtd.CurBufPtr-ohci_gtd.SoftwarePart], eax
|
|
mov [ecx+ohci_gtd.BufEnd-ohci_gtd.SoftwarePart], eax
|
|
cmp [.packetSize], eax
|
|
jz @f
|
|
mov eax, [.buffer]
|
|
call get_phys_addr
|
|
mov [ecx+ohci_gtd.CurBufPtr-ohci_gtd.SoftwarePart], eax
|
|
mov eax, [.buffer]
|
|
add eax, [.packetSize]
|
|
dec eax
|
|
call get_phys_addr
|
|
mov [ecx+ohci_gtd.BufEnd-ohci_gtd.SoftwarePart], eax
|
|
@@:
|
|
; 6. Generate Flags field:
|
|
; - set bufferRounding (bit 18) to zero = disallow short transfers;
|
|
; for the last transfer in a row, ohci_alloc_transfer would set the real value;
|
|
; - set Direction (bits 19-20) to lower 2 bits of [.direction];
|
|
; - set DelayInterrupt (bits 21-23) to 7 = do not generate interrupt;
|
|
; for the last transfer in a row, ohci_alloc_transfer would set the real value;
|
|
; - set DataToggle (bits 24-25) to next 2 bits of [.direction];
|
|
; - set ConditionCode (bits 28-31) to 1111b as a indicator that there was no
|
|
; attempts to perform this transfer yet;
|
|
; - zero all other bits.
|
|
mov eax, [.direction]
|
|
mov edx, eax
|
|
and eax, 3
|
|
shl eax, 19
|
|
and edx, (3 shl 2)
|
|
shl edx, 24 - 2
|
|
lea eax, [eax + edx + (7 shl 21) + (15 shl 28)]
|
|
mov [ecx+ohci_gtd.Flags-ohci_gtd.SoftwarePart], eax
|
|
; 7. Restore the returned value saved in step 3.
|
|
pop eax
|
|
.nothing:
|
|
ret
|
|
endp
|
|
|
|
; This procedure is called from the several places in main USB code
|
|
; and activates the transfer which was previously allocated by
|
|
; ohci_alloc_transfer.
|
|
; ecx -> last descriptor for the transfer, ebx -> usb_pipe
|
|
proc ohci_insert_transfer
|
|
; 1. Advance the queue of transfer descriptors.
|
|
mov eax, [ecx+ohci_gtd.NextTD-ohci_gtd.SoftwarePart]
|
|
mov [ebx+ohci_pipe.TailP-ohci_pipe.SoftwarePart], eax
|
|
; 2. For control and bulk pipes, notify the controller that
|
|
; there is new work in control/bulk queue respectively.
|
|
ohci_notify_new_work:
|
|
mov edx, [ebx+usb_pipe.Controller]
|
|
mov edx, [edx+ohci_controller.MMIOBase-sizeof.ohci_controller]
|
|
cmp [ebx+usb_pipe.Type], CONTROL_PIPE
|
|
jz .control
|
|
cmp [ebx+usb_pipe.Type], BULK_PIPE
|
|
jnz .nothing
|
|
.bulk:
|
|
mov dword [edx+OhciCommandStatusReg], 4
|
|
jmp .nothing
|
|
.control:
|
|
mov dword [edx+OhciCommandStatusReg], 2
|
|
.nothing:
|
|
ret
|
|
endp
|
|
|
|
; This function is called from ohci_process_deferred when
|
|
; a new device has been reset and needs to be configured.
|
|
proc ohci_port_after_reset
|
|
; 1. Get the status.
|
|
; If reset has been failed (device disconnected during reset),
|
|
; continue to next device (if there is one).
|
|
xor eax, eax
|
|
xchg al, [esi+usb_controller.ResettingStatus]
|
|
test al, al
|
|
js usb_test_pending_port
|
|
; If the controller has disabled the port (e.g. overcurrent),
|
|
; continue to next device (if there is one).
|
|
movzx ecx, [esi+usb_controller.ResettingPort]
|
|
mov eax, [edi+OhciRhPortStatusReg+ecx*4]
|
|
test al, 2
|
|
jnz @f
|
|
DEBUGF 1,'K : USB port disabled after reset, status=%x\n',eax
|
|
jmp usb_test_pending_port
|
|
@@:
|
|
push ecx
|
|
; 2. Get LowSpeed bit to bit 0 of eax and call the worker procedure
|
|
; to notify the protocol layer about new OHCI device.
|
|
mov eax, [edi+OhciRhPortStatusReg+ecx*4]
|
|
DEBUGF 1,'K : port_after_reset [%d] status of port %d is %x\n',[timer_ticks],ecx,eax
|
|
shr eax, 9
|
|
call ohci_new_device
|
|
pop ecx
|
|
; 3. If something at the protocol layer has failed
|
|
; (no memory, no bus address), disable the port and stop the initialization.
|
|
test eax, eax
|
|
jnz .nothing
|
|
.disable_exit:
|
|
mov dword [edi+OhciRhPortStatusReg+ecx*4], 1
|
|
jmp usb_test_pending_port
|
|
.nothing:
|
|
ret
|
|
endp
|
|
|
|
; This procedure is called from uhci_port_init and from hub support code
|
|
; when a new device is connected and has been reset.
|
|
; It calls usb_new_device at the protocol layer with correct parameters.
|
|
; in: esi -> usb_controller, eax = speed;
|
|
; OHCI is USB1 device, so only low bit of eax (LowSpeed) is used.
|
|
proc ohci_new_device
|
|
; 1. Clear all bits of speed except bit 0.
|
|
and eax, 1
|
|
; 2. Store the speed for the protocol layer.
|
|
mov [esi+usb_controller.ResettingSpeed], al
|
|
; 3. Create pseudo-pipe in the stack.
|
|
; See ohci_init_pipe: only .Controller and .Flags fields are used.
|
|
shl eax, 13
|
|
push esi ; .Controller
|
|
mov ecx, esp
|
|
sub esp, 12 ; ignored fields
|
|
push eax ; .Flags
|
|
; 4. Notify the protocol layer.
|
|
call usb_new_device
|
|
; 5. Cleanup the stack after step 3 and return.
|
|
add esp, 20
|
|
ret
|
|
endp
|
|
|
|
; This procedure is called in the USB thread from usb_thread_proc,
|
|
; processes regular actions and those actions which can't be safely done
|
|
; from interrupt handler.
|
|
; Returns maximal time delta before the next call.
|
|
proc ohci_process_deferred
|
|
push ebx edi ; save used registers to be stdcall
|
|
; 1. Initialize the return value.
|
|
push -1
|
|
; 2. Process disconnect events.
|
|
call usb_disconnect_stage2
|
|
; 3. Check for connected devices.
|
|
; If there is a connected device which was connected less than
|
|
; USB_CONNECT_DELAY ticks ago, plan to wake up when the delay will be over.
|
|
; Otherwise, call ohci_new_port.
|
|
mov edi, [esi+ohci_controller.MMIOBase-sizeof.ohci_controller]
|
|
xor ecx, ecx
|
|
cmp [esi+usb_controller.NewConnected], ecx
|
|
jz .skip_newconnected
|
|
.portloop:
|
|
bt [esi+usb_controller.NewConnected], ecx
|
|
jnc .noconnect
|
|
mov eax, [timer_ticks]
|
|
sub eax, [esi+usb_controller.ConnectedTime+ecx*4]
|
|
sub eax, USB_CONNECT_DELAY
|
|
jge .connected
|
|
neg eax
|
|
cmp [esp], eax
|
|
jb .nextport
|
|
mov [esp], eax
|
|
jmp .nextport
|
|
.connected:
|
|
lock btr [esi+usb_controller.NewConnected], ecx
|
|
jnc .nextport
|
|
call ohci_new_port
|
|
.noconnect:
|
|
.nextport:
|
|
inc ecx
|
|
cmp ecx, [esi+usb_controller.NumPorts]
|
|
jb .portloop
|
|
.skip_newconnected:
|
|
; 4. Check for end of reset signalling. If so, call ohci_port_after_reset.
|
|
cmp [esi+usb_controller.ResettingStatus], 2
|
|
jnz .no_reset_recovery
|
|
mov eax, [timer_ticks]
|
|
sub eax, [esi+usb_controller.ResetTime]
|
|
sub eax, USB_RESET_RECOVERY_TIME
|
|
jge .reset_done
|
|
neg eax
|
|
cmp [esp], eax
|
|
jb .skip_roothub
|
|
mov [esp], eax
|
|
jmp .skip_roothub
|
|
.no_reset_recovery:
|
|
cmp [esi+usb_controller.ResettingStatus], 0
|
|
jz .skip_roothub
|
|
.reset_done:
|
|
call ohci_port_after_reset
|
|
.skip_roothub:
|
|
; 5. Finalize transfers processed by hardware.
|
|
; It is better to perform this step after processing disconnect events,
|
|
; although not strictly obligatory. This way, an active transfer aborted
|
|
; due to disconnect would be handled with more specific USB_STATUS_CLOSED,
|
|
; not USB_STATUS_NORESPONSE.
|
|
; Loop over all items in DoneList, call ohci_process_finalized_td for each.
|
|
xor ebx, ebx
|
|
xchg ebx, [esi+ohci_controller.DoneList-sizeof.ohci_controller]
|
|
.tdloop:
|
|
test ebx, ebx
|
|
jz .tddone
|
|
call ohci_process_finalized_td
|
|
jmp .tdloop
|
|
.tddone:
|
|
; 6. Process wait-done notifications, test for new wait requests.
|
|
; Note: that must be done after steps 2 and 5 which could create new requests.
|
|
; 6a. Call the worker function from main USB code.
|
|
call usb_process_wait_lists
|
|
; 6b. If no new requests, skip the rest of this step.
|
|
test eax, eax
|
|
jz @f
|
|
; 6c. OHCI is not allowed to cache anything; we don't know what is
|
|
; processed right now, but we can be sure that the controller will not
|
|
; use any removed structure starting from the next frame.
|
|
; Schedule SOF event.
|
|
spin_lock_irq [esi+usb_controller.RemoveSpinlock]
|
|
mov eax, [esi+usb_controller.WaitPipeListAsync]
|
|
mov [esi+usb_controller.WaitPipeRequestAsync], eax
|
|
mov eax, [esi+usb_controller.WaitPipeListPeriodic]
|
|
mov [esi+usb_controller.WaitPipeRequestPeriodic], eax
|
|
; temporarily stop bulk and interrupt processing;
|
|
; this is required for handler of SOF event
|
|
and dword [edi+OhciControlReg], not 30h
|
|
; remember the frame number when processing has been stopped
|
|
; (needs to be done after stopping)
|
|
movzx eax, [esi+ohci_controller.FrameNumber-sizeof.ohci_controller]
|
|
mov [esi+usb_controller.StartWaitFrame], eax
|
|
; make sure that the next SOF will happen after the request
|
|
mov dword [edi+OhciInterruptStatusReg], 4
|
|
; enable interrupt on SOF
|
|
; Note: OhciInterruptEnableReg/OhciInterruptDisableReg have unusual semantics,
|
|
; so there should be 'mov' here, not 'or'
|
|
mov dword [edi+OhciInterruptEnableReg], 4
|
|
spin_unlock_irq [esi+usb_controller.RemoveSpinlock]
|
|
@@:
|
|
; 7. Restore the return value and return.
|
|
pop eax
|
|
pop edi ebx ; restore used registers to be stdcall
|
|
ret
|
|
endp
|
|
|
|
; Helper procedure for ohci_process_deferred. Processes one completed TD.
|
|
; in: esi -> usb_controller, ebx -> usb_gtd, out: ebx -> next usb_gtd.
|
|
proc ohci_process_finalized_td
|
|
; DEBUGF 1,'K : processing %x\n',ebx
|
|
; 1. Check whether the pipe has been closed, either due to API call or due to
|
|
; disconnect; if so, the callback will be called by usb_pipe_closed with
|
|
; correct status, so go to step 6 with ebx = 0 (do not free the TD).
|
|
mov edx, [ebx+usb_gtd.Pipe]
|
|
test [edx+usb_pipe.Flags], USB_FLAG_CLOSED
|
|
jz @f
|
|
lea eax, [ebx+ohci_gtd.NextTD-ohci_gtd.SoftwarePart]
|
|
xor ebx, ebx
|
|
jmp .next_td2
|
|
@@:
|
|
; 2. Remove the descriptor from the descriptors queue.
|
|
call usb_unlink_td
|
|
; 3. Get number of bytes that remain to be transferred.
|
|
; If CurBufPtr is zero, everything was transferred.
|
|
xor edx, edx
|
|
cmp [ebx+ohci_gtd.CurBufPtr-ohci_gtd.SoftwarePart], edx
|
|
jz .gotlen
|
|
; Otherwise, the remaining length is
|
|
; (BufEnd and 0xFFF) - (CurBufPtr and 0xFFF) + 1,
|
|
; plus 0x1000 if BufEnd and CurBufPtr are in different pages.
|
|
mov edx, [ebx+ohci_gtd.BufEnd-ohci_gtd.SoftwarePart]
|
|
mov eax, [ebx+ohci_gtd.CurBufPtr-ohci_gtd.SoftwarePart]
|
|
mov ecx, edx
|
|
and edx, 0xFFF
|
|
inc edx
|
|
xor ecx, eax
|
|
and ecx, -0x1000
|
|
jz @f
|
|
add edx, 0x1000
|
|
@@:
|
|
and eax, 0xFFF
|
|
sub edx, eax
|
|
.gotlen:
|
|
; The actual length is Length - (remaining length).
|
|
sub edx, [ebx+usb_gtd.Length]
|
|
neg edx
|
|
; 4. Check for error. If so, go to 7.
|
|
push ebx
|
|
mov eax, [ebx+ohci_gtd.Flags-ohci_gtd.SoftwarePart]
|
|
shr eax, 28
|
|
jnz .error
|
|
.notify:
|
|
; 5. Successful completion.
|
|
; 5a. Check whether this descriptor has an associated callback.
|
|
mov ecx, [ebx+usb_gtd.Callback]
|
|
test ecx, ecx
|
|
jz .ok_nocallback
|
|
; 5b. If so, call the callback.
|
|
stdcall_verify ecx, [ebx+usb_gtd.Pipe], eax, \
|
|
[ebx+usb_gtd.Buffer], edx, [ebx+usb_gtd.UserData]
|
|
jmp .next_td
|
|
.ok_nocallback:
|
|
; 5c. Otherwise, add length of the current descriptor to the next descriptor.
|
|
mov eax, [ebx+usb_gtd.NextVirt]
|
|
add [eax+usb_gtd.Length], edx
|
|
.next_td:
|
|
; 6. Free the current descriptor and advance to the next item.
|
|
; If the current item is the last in the list,
|
|
; set DoneListEndPtr to pointer to DoneList.
|
|
cmp ebx, [esp]
|
|
jz @f
|
|
stdcall usb1_free_general_td, ebx
|
|
@@:
|
|
pop ebx
|
|
lea eax, [ebx+ohci_gtd.NextTD-ohci_gtd.SoftwarePart]
|
|
.next_td2:
|
|
push ebx
|
|
mov ebx, eax
|
|
lea edx, [esi+ohci_controller.DoneList-sizeof.ohci_controller]
|
|
xor ecx, ecx ; no next item
|
|
lock cmpxchg [esi+ohci_controller.DoneListEndPtr-sizeof.ohci_controller], edx
|
|
jz .last
|
|
; The current item is not the last.
|
|
; It is possible, although very rare, that ohci_irq has already advanced
|
|
; DoneListEndPtr, but not yet written NextTD. Wait until NextTD is nonzero.
|
|
@@:
|
|
mov ecx, [ebx]
|
|
test ecx, ecx
|
|
jz @b
|
|
.last:
|
|
pop ebx
|
|
; ecx = the next item
|
|
push ecx
|
|
; Free the current item, set ebx to the next item, continue to 5a.
|
|
test ebx, ebx
|
|
jz @f
|
|
stdcall usb1_free_general_td, ebx
|
|
@@:
|
|
pop ebx
|
|
ret
|
|
.error:
|
|
; 7. There was an error while processing this descriptor.
|
|
; The hardware has stopped processing the queue.
|
|
; 7a. Save status and length.
|
|
push eax
|
|
push edx
|
|
; DEBUGF 1,'K : TD failed:\n'
|
|
; DEBUGF 1,'K : %x %x %x %x\n',[ebx-ohci_gtd.SoftwarePart],[ebx-ohci_gtd.SoftwarePart+4],[ebx-ohci_gtd.SoftwarePart+8],[ebx-ohci_gtd.SoftwarePart+12]
|
|
; DEBUGF 1,'K : %x %x %x %x\n',[ebx-ohci_gtd.SoftwarePart+16],[ebx-ohci_gtd.SoftwarePart+20],[ebx-ohci_gtd.SoftwarePart+24],[ebx-ohci_gtd.SoftwarePart+28]
|
|
; mov eax, [ebx+usb_gtd.Pipe]
|
|
; DEBUGF 1,'K : pipe: %x %x %x %x\n',[eax-ohci_pipe.SoftwarePart],[eax-ohci_pipe.SoftwarePart+4],[eax-ohci_pipe.SoftwarePart+8],[eax-ohci_pipe.SoftwarePart+12]
|
|
; 7b. Traverse the list of descriptors looking for the final packet
|
|
; for this transfer.
|
|
; Free and unlink non-final descriptors, except the current one.
|
|
; Final descriptor will be freed in step 6.
|
|
call usb_is_final_packet
|
|
jnc .found_final
|
|
mov ebx, [ebx+usb_gtd.NextVirt]
|
|
virtual at esp
|
|
.length dd ?
|
|
.error_code dd ?
|
|
.current_item dd ?
|
|
end virtual
|
|
.look_final:
|
|
call usb_unlink_td
|
|
call usb_is_final_packet
|
|
jnc .found_final
|
|
push [ebx+usb_gtd.NextVirt]
|
|
stdcall usb1_free_general_td, ebx
|
|
pop ebx
|
|
jmp .look_final
|
|
.found_final:
|
|
; 7c. If error code is USB_STATUS_UNDERRUN and the last TD allows short packets,
|
|
; it is not an error.
|
|
; Note: all TDs except the last one in any transfer stage are marked
|
|
; as short-packet-is-error to stop controller from further processing
|
|
; of that stage; we need to restart processing from a TD following the last.
|
|
; After that, go to step 5 with eax = 0 (no error).
|
|
cmp dword [.error_code], USB_STATUS_UNDERRUN
|
|
jnz .no_underrun
|
|
test byte [ebx+ohci_gtd.Flags+2-ohci_gtd.SoftwarePart], 1 shl (18-16)
|
|
jz .no_underrun
|
|
and dword [.error_code], 0
|
|
mov ecx, [ebx+usb_gtd.Pipe]
|
|
mov edx, [ecx+ohci_pipe.HeadP-ohci_pipe.SoftwarePart]
|
|
and edx, 2
|
|
.advance_queue:
|
|
mov eax, [ebx+usb_gtd.NextVirt]
|
|
sub eax, ohci_gtd.SoftwarePart
|
|
call get_phys_addr
|
|
or eax, edx
|
|
mov [ecx+ohci_pipe.HeadP-ohci_pipe.SoftwarePart], eax
|
|
push ebx
|
|
mov ebx, ecx
|
|
call ohci_notify_new_work
|
|
pop ebx
|
|
pop edx eax
|
|
jmp .notify
|
|
; 7d. Abort the entire transfer.
|
|
; There are two cases: either there is only one transfer stage
|
|
; (everything except control transfers), then ebx points to the last TD and
|
|
; all previous TD were unlinked and dismissed (if possible),
|
|
; or there are several stages (a control transfer) and ebx points to the last
|
|
; TD of Data or Status stage (usb_is_final_packet does not stop in Setup stage,
|
|
; because Setup stage can not produce short packets); for Data stage, we need
|
|
; to unlink and free (if possible) one more TD and advance ebx to the next one.
|
|
.no_underrun:
|
|
cmp [ebx+usb_gtd.Callback], 0
|
|
jnz .halted
|
|
cmp ebx, [.current_item]
|
|
push [ebx+usb_gtd.NextVirt]
|
|
jz @f
|
|
stdcall usb1_free_general_td, ebx
|
|
@@:
|
|
pop ebx
|
|
call usb_unlink_td
|
|
.halted:
|
|
; 7e. For bulk/interrupt transfers we have no choice but halt the queue,
|
|
; the driver should intercede (through some API which is not written yet).
|
|
; Control pipes normally recover at the next SETUP transaction (first stage
|
|
; of any control transfer), so we hope on the best and just advance the queue
|
|
; to the next transfer. (According to the standard, "A control pipe may also
|
|
; support functional stall as well, but this is not recommended.").
|
|
; Advance the transfer queue to the next descriptor.
|
|
mov ecx, [ebx+usb_gtd.Pipe]
|
|
mov edx, [ecx+ohci_pipe.HeadP-ohci_pipe.SoftwarePart]
|
|
and edx, 2 ; keep toggleCarry bit
|
|
cmp [ecx+usb_pipe.Type], CONTROL_PIPE
|
|
jnz @f
|
|
inc edx ; set Halted bit
|
|
@@:
|
|
jmp .advance_queue
|
|
endp
|
|
|
|
; This procedure is called when a pipe is closing (either due to API call
|
|
; or due to disconnect); it unlinks the pipe from the corresponding list.
|
|
; esi -> usb_controller, ebx -> usb_pipe
|
|
proc ohci_unlink_pipe
|
|
cmp [ebx+usb_pipe.Type], INTERRUPT_PIPE
|
|
jnz @f
|
|
mov eax, [ebx+ohci_pipe.Flags-ohci_pipe.SoftwarePart]
|
|
bt eax, 13
|
|
setc cl
|
|
bt eax, 11
|
|
setc ch
|
|
shr eax, 16
|
|
stdcall usb1_interrupt_list_unlink, eax, ecx
|
|
@@:
|
|
mov edx, [ebx+usb_pipe.NextVirt]
|
|
mov eax, [ebx+usb_pipe.PrevVirt]
|
|
mov [edx+usb_pipe.PrevVirt], eax
|
|
mov [eax+usb_pipe.NextVirt], edx
|
|
mov edx, [ebx+ohci_pipe.NextED-ohci_pipe.SoftwarePart]
|
|
mov [eax+ohci_pipe.NextED-ohci_pipe.SoftwarePart], edx
|
|
ret
|
|
endp
|