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Searched refs:HW (Results 1 – 25 of 245) sorted by relevance

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/Linux-v6.1/Documentation/scsi/
D	scsi-parameters.rst	`19 advansys= [HW,SCSI] 22 aha152x= [HW,SCSI] 25 aha1542= [HW,SCSI] 28 aic7xxx= [HW,SCSI] 31 aic79xx= [HW,SCSI] 34 atascsi= [HW,SCSI] 37 BusLogic= [HW,SCSI] 41 gvp11= [HW,SCSI] 43 ips= [HW,SCSI] Adaptec / IBM ServeRAID controller 46 mac5380= [HW,SCSI] [all …]`
/Linux-v6.1/Documentation/networking/device_drivers/ethernet/huawei/
D	hinic.rst	35 specific HW details about HW data structure formats. 37 hinic_hwdev - Implement the HW details of the device and include the components 43 HW Interface: 49 Configuration Status Registers Area that describes the HW Registers on the 63 card by AEQs. Also set the addresses of the IO CMDQs in HW. 78 used to set the QPs addresses in HW. The commands completion events are 82 Queue Pairs(QPs) - The HW Receive and Send queues for Receiving and Transmitting 87 HW device: 90 HW device - de/constructs the HW Interface, the MGMT components on the 101 Port Commands - Send commands to the HW device for port management [all …]
/Linux-v6.1/Documentation/watchdog/
D	mlx-wdt.rst	13 There are 2 types of HW watchdog implementations. 16 Actual HW timeout can be defined as a power of 2 msec. 22 Actual HW timeout is defined in sec. and it's the same as 31 Type 1 HW watchdog implementation exist in old systems and 32 all new systems have type 2 HW watchdog. 33 Two types of HW implementation have also different register map. 35 Type 3 HW watchdog implementation can exist on all Mellanox systems 54 This mlx-wdt driver supports both HW watchdog implementations. 65 Access to HW registers is performed through a generic regmap interface.
/Linux-v6.1/Documentation/networking/dsa/
D	lan9303.rst	`21 interfaces (which is the default state of a DSA device). Due to HW limitations, 22 no HW MAC learning takes place in this mode. 24 When both user ports are joined to the same bridge, the normal HW MAC learning 25 is enabled. This means that unicast traffic is forwarded in HW. Broadcast and 26 multicast is flooded in HW. STP is also supported in this mode. The driver 37 - The HW does not support VLAN-specific fdb entries`
/Linux-v6.1/Documentation/translations/zh_CN/infiniband/
D	opa_vnic.rst	`117 依赖于HW的VNIC功能是HFI1驱动的一部分。它实现了分配和释放OPA_VNIC RDMA 118 netdev的动作。它涉及VNIC功能的HW资源分配/管理。它与网络堆栈接口并实现所 120 并提供对它们的HW访问。在将数据包向上传递到网络堆栈之前，它把Omni-Path头 126 RDMA netdev设备。它在需要时覆盖由依赖HW的VNIC驱动设置的net_device_ops函数， 129 RDMA netdev控制操作将任何控制信息传递给依赖于HW的驱动程序::`
/Linux-v6.1/Documentation/ABI/testing/
D	sysfs-bus-coresight-devices-etb10	`27 2. The value is read directly from HW register RDP, 0x004. 34 is read directly from HW register STS, 0x00C. 42 interface. The value is read directly from HW register RRP, 52 from HW register RWP, 0x018. 59 read directly from HW register TRG, 0x01C. 66 is read directly from HW register CTL, 0x020. 73 register. The value is read directly from HW register FFSR, 81 register. The value is read directly from HW register FFCR,`
D	sysfs-bus-coresight-devices-tmc	`15 The value is read directly from HW register RSZ, 0x004. 22 is read directly from HW register STS, 0x00C. 30 interface. The value is read directly from HW register RRP, 40 from HW register RWP, 0x018. 47 read directly from HW register TRG, 0x01C. 54 is read directly from HW register CTL, 0x020. 61 register. The value is read directly from HW register FFSR, 69 register. The value is read directly from HW register FFCR,`
D	sysfs-bus-coresight-devices-etm4x	337 The value it taken directly from the HW. 344 (0x310). The value is taken directly from the HW. 351 (0x314). The value is taken directly from the HW. 358 (0xFB4). The value is taken directly from the HW. 365 (0xFB8). The value is taken directly from the HW. 372 (0xFC8). The value is taken directly from the HW. 380 from the HW. 387 (0xFCC). The value is taken directly from the HW. 394 (0xFE0). The value is taken directly from the HW. 401 (0xFE4). The value is taken directly from the HW. [all …]
/Linux-v6.1/Documentation/devicetree/bindings/clock/ti/
D	interface.txt	`19 "ti,omap3-hsotgusb-interface-clock" - interface clock with USB specific HW 21 "ti,omap3-dss-interface-clock" - interface clock with DSS specific HW handling 22 "ti,omap3-ssi-interface-clock" - interface clock with SSI specific HW handling 23 "ti,am35xx-interface-clock" - interface clock with AM35xx specific HW handling 24 "ti,omap2430-interface-clock" - interface clock with OMAP2430 specific HW`
/Linux-v6.1/Documentation/driver-api/iio/
D	hw-consumer.rst	`2 HW consumer 6 The Industrial I/O HW consumer offers a way to bond these IIO devices without 18 HW consumer setup 22 A typical IIO HW consumer setup looks like this::`
/Linux-v6.1/drivers/crypto/keembay/
D	Kconfig	`2 tristate "Support for Intel Keem Bay OCS AES/SM4 HW acceleration" 12 Provides HW acceleration for the following transformations: 20 bool "Support for Intel Keem Bay OCS AES/SM4 ECB HW acceleration" 31 bool "Support for Intel Keem Bay OCS AES/SM4 CTS HW acceleration" 43 tristate "Support for Intel Keem Bay OCS ECC HW acceleration" 62 tristate "Support for Intel Keem Bay OCS HCU HW acceleration"`
/Linux-v6.1/Documentation/infiniband/
D	opa_vnic.rst	104 OPA VNIC functionality has a HW dependent component and a HW 112 The HW dependent VNIC functionality is part of the HFI1 driver. It 114 It involves HW resource allocation/management for VNIC functionality. 117 packets in the transmit path and provides HW access to them. It strips 121 The OPA VNIC module implements the HW independent VNIC functionality. 127 set by HW dependent VNIC driver where required to accommodate any control 131 interface. It also passes any control information to the HW dependent driver
/Linux-v6.1/net/tls/
D	Kconfig	`21 bool "Transport Layer Security HW offload" 27 Enable kernel support for HW offload of the TLS protocol. 36 Enable kernel support for legacy HW offload of the TLS protocol,`
/Linux-v6.1/drivers/net/ethernet/mellanox/mlx5/core/en/
D	port_buffer.c	68 mlx5e_dbg(HW, priv, "buffer %d: size=%d, xon=%d, xoff=%d, epsb=%d, lossy=%d\n", i, in mlx5e_port_query_buffer() 81 mlx5e_dbg(HW, priv, "total buffer size=%d, spare buffer size=%d\n", in mlx5e_port_query_buffer() 144 mlx5e_dbg(HW, priv, "%s: xoff=%d\n", __func__, xoff); in calculate_xoff() 281 mlx5e_dbg(HW, priv, "%s: change=%x\n", __func__, change); in mlx5e_port_manual_buffer_config() 320 mlx5e_dbg(HW, priv, "%s: buffer[%d]=%d\n", __func__, i, buffer_size[i]); in mlx5e_port_manual_buffer_config() 322 mlx5e_dbg(HW, priv, "%s: lossless buffer[%d] size cannot be zero\n", in mlx5e_port_manual_buffer_config() 331 mlx5e_dbg(HW, priv, "%s: total buffer requested=%d\n", __func__, total_used); in mlx5e_port_manual_buffer_config()
/Linux-v6.1/Documentation/devicetree/bindings/dma/
D	qcom_hidma_mgmt.txt	`7 Each HIDMA HW instance consists of multiple DMA channels. These channels 37 Once a reset is applied to the HW, HW starts a timer for reset operation 38 to confirm. If reset is not completed within this time, HW reports reset 50 - compatible: must contain "qcom,hidma-1.0" for initial HW or 51 "qcom,hidma-1.1"/"qcom,hidma-1.2" for MSI capable HW.`
/Linux-v6.1/drivers/gpu/drm/sti/
D	NOTES	`3 The STMicroelectronics stiH SoCs use a common chain of HW display IP blocks: 19 - The VTG (Video Timing Generators) build Vsync signals used by the other HW IP 20 Note that some stiH drivers support only a subset of thee HW IP. 37 2. DRM / HW mapping`
/Linux-v6.1/Documentation/powerpc/
D	cpu_families.rst	`173 - e6500 adds HW loaded indirect TLB entries. 206 \| e6500 (HW TLB) (Multithreaded) \| 213 - Book3E, software loaded TLB + HW loaded indirect TLB entries.`
/Linux-v6.1/Documentation/networking/device_drivers/ethernet/stmicro/
D	stmmac.rst	159 This parameter changes the default HW FIFO Threshold control value. 218 the reception on chips older than the 3.50. New chips have an HW RX Watchdog 263 checks to the HW using MAC and PHY loopback mechanisms:: 305 supported. This is done by looking at both the DMA HW capability register and 326 available at run-time by looking at the HW capability register. This means 328 PHYLIB stuff. In fact, the HW provides a subset of extended registers to 372 7) HW uses the GMAC core:: 380 9) Core is able to perform TX Checksum and/or RX Checksum in HW:: 385 11) Some HWs are not able to perform the csum in HW for over-sized frames due 440 necessary on some platforms (e.g. ST boxes) where the HW needs to have set [all …]
/Linux-v6.1/Documentation/virt/kvm/devices/
D	xive.rst	21 The KVM device exposes different MMIO ranges of the XIVE HW which 52 interrupts are from a different HW controller (PHB4) and the ESB 56 kvmppc_xive_clr_mapped() are called when the device HW irqs are 60 The handler will insert the ESB page corresponding to the HW 119 -ENXIO Could not allocate underlying HW interrupt 147 underlying HW interrupt failed 192 -EIO Configuration of the underlying HW failed 211 called the NVT. When a VP is not dispatched on a HW processor 212 thread, this structure can be updated by HW if the VP is the target
/Linux-v6.1/Documentation/x86/
D	tsx_async_abort.rst	`69 …0 0 0 HW default Yes Same as MDS Same as MDS 71 …0 1 0 HW default No Need ucode update Need ucode up… 84 … 0 0 0 HW default Yes Same as MDS Same as MDS 86 …0 1 0 HW default No Need ucode update Need ucode up… 99 …0 0 0 HW default Yes Same as MDS Same as MDS 101 …0 1 0 HW default No Need ucode update Need ucode up…`
/Linux-v6.1/Documentation/devicetree/bindings/reset/
D	reset.txt	`21 in hardware for a reset signal to affect multiple logically separate HW blocks 23 the DT node of each affected HW block, since if activated, an unrelated block 26 children of the bus are affected by the reset signal, or an individual HW 28 appropriate software access to the reset signals in order to manage the HW, 29 rather than to slavishly enumerate the reset signal that affects each HW`
/Linux-v6.1/Documentation/devicetree/bindings/arc/
D	pct.txt	`8 * The ARC 700 PCT does not support interrupts; although HW events may be 9 counted, the HW events themselves cannot serve as a trigger for a sample.`
/Linux-v6.1/drivers/cpufreq/
D	Kconfig.arm	137 tristate "MediaTek CPUFreq HW driver" 141 Support for the CPUFreq HW driver. 142 Some MediaTek chipsets have a HW engine to offload the steps 145 The driver implements the cpufreq interface for this HW engine. 146 Say Y if you want to support CPUFreq HW. 165 tristate "QCOM CPUFreq HW driver" 168 Support for the CPUFreq HW driver. 169 Some QCOM chipsets have a HW engine to offload the steps 172 The driver implements the cpufreq interface for this HW engine. 173 Say Y if you want to support CPUFreq HW.
/Linux-v6.1/drivers/net/ethernet/aquantia/atlantic/hw_atl2/
D	hw_atl2_utils_fw.c	`18 #define hw_atl2_shared_buffer_write(HW, ITEM, VARIABLE) \ argument 25 hw_atl2_mif_shared_buf_write(HW,\ 30 #define hw_atl2_shared_buffer_get(HW, ITEM, VARIABLE) \ argument 37 hw_atl2_mif_shared_buf_get(HW, \ 46 #define hw_atl2_shared_buffer_read(HW, ITEM, VARIABLE) \ argument 55 hw_atl2_mif_shared_buf_read(HW, \ 60 #define hw_atl2_shared_buffer_read_safe(HW, ITEM, DATA) \ argument 68 hw_atl2_shared_buffer_read_block((HW), \`
/Linux-v6.1/Documentation/devicetree/bindings/thermal/
D	nvidia,tegra124-soctherm.txt	`40 SW need to set priorities for various throttle, the HW arbiter can select 100 than it, it will trigger the HW throttle event. 124 * the HW will skip cpu clock's pulse in 85% depth, 137 * the HW will skip cpu clock's pulse in 50% depth, 149 * If these two devices are triggered in same time, the HW throttle 178 * the HW will skip cpu clock's pulse in HIGH level 189 * the HW will skip cpu clock's pulse in MED level 199 * If these two devices are triggered in same time, the HW throttle`

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