diff --git a/Documentation/hid/hid-alps.rst b/Documentation/hid/hid-alps.rst index 767c96bcbb7cdfdbcbea2bd795b9943d3f7c5b5c..94382bb0ada4d87a63b2dbaf2b242fb344732cde 100644 --- a/Documentation/hid/hid-alps.rst +++ b/Documentation/hid/hid-alps.rst @@ -9,7 +9,7 @@ Currently ALPS HID driver supports U1 Touchpad device. U1 device basic information. ========== ====== -Vender ID 0x044E +Vendor ID 0x044E Product ID 0x120B Version ID 0x0121 ========== ====== diff --git a/Documentation/hid/hid-bpf.rst b/Documentation/hid/hid-bpf.rst index c205f92b7bcc43cce95fc04f0ff0fde1ca36bc7b..4fad83a6ebc309ff87df420efa3a633d5a9011ad 100644 --- a/Documentation/hid/hid-bpf.rst +++ b/Documentation/hid/hid-bpf.rst @@ -307,7 +307,7 @@ sysfs path: ``/sys/bus/hid/devices/xxxx:yyyy:zzzz:0000``) We can not rely on hidraw to bind a BPF program to a HID device. hidraw is an artefact of the processing of the HID device, and is not stable. Some drivers -even disable it, so that removes the tracing capabilies on those devices +even disable it, so that removes the tracing capabilities on those devices (where it is interesting to get the non-hidraw traces). On the other hand, the ``hid_id`` is stable for the entire life of the HID device, diff --git a/Documentation/hid/hiddev.rst b/Documentation/hid/hiddev.rst index caebc6266603c1a27b217471e07fcdf8ef1c0b8f..9b82c7f896aada6305c61a49d4f9641cfe05716e 100644 --- a/Documentation/hid/hiddev.rst +++ b/Documentation/hid/hiddev.rst @@ -8,7 +8,7 @@ Introduction In addition to the normal input type HID devices, USB also uses the human interface device protocols for things that are not really human interfaces, but have similar sorts of communication needs. The two big -examples for this are power devices (especially uninterruptable power +examples for this are power devices (especially uninterruptible power supplies) and monitor control on higher end monitors. To support these disparate requirements, the Linux USB system provides diff --git a/Documentation/hid/hidraw.rst b/Documentation/hid/hidraw.rst index b717ee5cdaef7cbba515d604e4f34eb532b8736a..14d076753b8531b279ae9e02067c8d9c90455734 100644 --- a/Documentation/hid/hidraw.rst +++ b/Documentation/hid/hidraw.rst @@ -163,7 +163,7 @@ HIDIOCGOUTPUT(len): Get an Output Report This ioctl will request an output report from the device using the control -endpoint. Typically, this is used to retrive the initial state of +endpoint. Typically, this is used to retrieve the initial state of an output report of a device, before an application updates it as necessary either via a HIDIOCSOUTPUT request, or the regular device write() interface. The format of the buffer issued with this report is identical to that of HIDIOCGFEATURE. diff --git a/Documentation/hid/intel-ish-hid.rst b/Documentation/hid/intel-ish-hid.rst index 7a851252267ae75f252c166fe2c27ab7dfb565fb..91b5c52b37081d31453a681e81588257529ce724 100644 --- a/Documentation/hid/intel-ish-hid.rst +++ b/Documentation/hid/intel-ish-hid.rst @@ -199,7 +199,7 @@ the sender that the memory region for that message may be reused. DMA initialization is started with host sending DMA_ALLOC_NOTIFY bus message (that includes RX buffer) and FW responds with DMA_ALLOC_NOTIFY_ACK. Additionally to DMA address communication, this sequence checks capabilities: -if thw host doesn't support DMA, then it won't send DMA allocation, so FW can't +if the host doesn't support DMA, then it won't send DMA allocation, so FW can't send DMA; if FW doesn't support DMA then it won't respond with DMA_ALLOC_NOTIFY_ACK, in which case host will not use DMA transfers. Here ISH acts as busmaster DMA controller. Hence when host sends DMA_XFER,