Fix typos involving "the the"
Change-Id: I179264ee6681a7ba4488b9f1c6bce1a19b4e1772 Signed-off-by: Jonathan Neuschäfer <j.neuschaefer@gmx.net> Reviewed-on: https://review.coreboot.org/c/30160 Tested-by: build bot (Jenkins) <no-reply@coreboot.org> Reviewed-by: Angel Pons <th3fanbus@gmail.com>
This commit is contained in:
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45e6c82e68
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@ -264,7 +264,7 @@
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<ul>
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<li>MemoryInit UPD values are correct</li>
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<li>MemoryInit returns 0 (success) and</li>
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<li>The the message "ERROR - coreboot's requirements not met by FSP binary!"
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<li>The message "ERROR - coreboot's requirements not met by FSP binary!"
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is not displayed
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</li>
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</ul>
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@ -324,7 +324,7 @@
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<ul>
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<li>MemoryInit UPD values are correct</li>
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<li>MemoryInit returns 0 (success) and</li>
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<li>The the message "ERROR - coreboot's requirements not met by FSP binary!"
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<li>The message "ERROR - coreboot's requirements not met by FSP binary!"
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is not displayed
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</li>
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</ul>
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@ -174,7 +174,7 @@ with
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regards to the erase block sizes on the ROM - allowing one to replace a
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component at runtime without disturbing the others.
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'offset' is the offset of the the first CBFS component (from the start of
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'offset' is the offset of the first CBFS component (from the start of
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the ROM). This is to allow for arbitrary space to be left at the beginning
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of the ROM for things like embedded controller firmware.
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@ -150,7 +150,7 @@ together so people can easily see the connection at the top level of
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gerrit. Topics can be set for individual patches in gerrit by going into
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the patch and clicking on the icon next to the topic line. Topics can also
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be set when you push the patches into gerrit. For example, to push a set of
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commits with the the i915-kernel-x60 set, use the command:
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commits with the i915-kernel-x60 set, use the command:
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git push origin HEAD:refs/for/master/i915-kernel-x60
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* If one of your patches isn't ready to be merged, make sure it's obvious
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@ -120,7 +120,7 @@ $(foreach supported_arch,$(ARCH_SUPPORTED), \
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# values are space separated if using more than one value
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#
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# int-add: adds an arbitrary length list of integers
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# int-subtract: subtracts the the second of two integers from the first
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# int-subtract: subtracts the second of two integers from the first
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# int-multiply: multiplies an arbitrary length list of integers
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# int-divide: divides the first integer by the second
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# int-remainder: arithmetic remainder of the first number divided by the second
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@ -23,7 +23,7 @@ RCSID("$Id: clear.c,v 1.35 2008/07/13 16:08:18 wmcbrine Exp $")
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every cell of the window.
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clear() and wclear() are similar to erase() and werase(), but
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they also call clearok() to ensure that the the window is
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they also call clearok() to ensure that the window is
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cleared on the next wrefresh().
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clrtobot() and wclrtobot() clear the window from the current
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@ -58,7 +58,7 @@
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* modularize it, was basically: 1) no unnecessary subroutine calls,
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* 2) no routines more than about 200 lines in size, and 3) modularize
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* any code that I might not get right the first time. The fetch_*
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* subroutines fall into the latter category. The The decode_* fall
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* subroutines fall into the latter category. The decode_* fall
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* into the second category. The coding of the "switch(mod){ .... }"
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* in many of the subroutines below falls into the first category.
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* Especially, the coding of {add,and,or,sub,...}_{byte,word}
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@ -37,7 +37,7 @@ void fsp_verify_memory_init_hobs(void)
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if (fsp_find_reserved_memory(&fsp_mem))
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die("9.1: FSP_RESERVED_MEMORY_RESOURCE_HOB missing!\n");
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/* Verify the the bootloader tolum is above the FSP reserved area */
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/* Verify the bootloader tolum is above the FSP reserved area */
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if (range_entry_end(&tolum) <= range_entry_base(&fsp_mem)) {
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printk(BIOS_CRIT,
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"TOLUM end: 0x%08llx != 0x%08llx: FSP rsvd base\n",
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@ -31,7 +31,7 @@ void intel_microcode_load_unlocked(const void *microcode_patch);
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* required, will skip microcode update if true. */
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int soc_skip_ucode_update(u32 currrent_patch_id, u32 new_patch_id);
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/* return the the version of the currently running microcode */
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/* return the version of the currently running microcode */
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uint32_t get_current_microcode_rev(void);
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/* extract microcode revision from the given patch */
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@ -235,7 +235,7 @@ static void power_well_enable(void)
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gtt_poll(HSW_PWR_WELL_CTL1, HSW_PWR_WELL_STATE, HSW_PWR_WELL_STATE);
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/* In the native graphics case, we've got about 20 ms.
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* after we power up the the AUX channel until we can talk to it.
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* after we power up the AUX channel until we can talk to it.
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* So get that going right now. We can't turn on the panel, yet, just VDD.
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*/
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if (IS_ENABLED(CONFIG_MAINBOARD_DO_NATIVE_VGA_INIT)) {
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@ -22,7 +22,7 @@
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/*
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* Fill the buf and returns 0 on success.
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* Return -1 on failure and the the caller tries sb_read_spd()
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* Return -1 on failure and the caller tries sb_read_spd()
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* to get the SPD from I2C.
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*/
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int mainboard_read_spd(uint8_t spdAddress, char *buf, size_t len);
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@ -158,7 +158,7 @@ config STONEYRIDGE_XHCI_ENABLE
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The XHCI controller must be enabled and the XHCI firmware
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must be added in order to have USB 3.0 support configured
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by coreboot. The OS will be responsible for enabling the XHCI
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controller if the the XHCI firmware is available but the
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controller if the XHCI firmware is available but the
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XHCI controller is not enabled by coreboot.
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config STONEYRIDGE_XHCI_FWM
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@ -46,7 +46,7 @@ config HUDSON_XHCI_ENABLE
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The XHCI controller must be enabled and the XHCI firmware
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must be added in order to have USB 3.0 support configured
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by coreboot. The OS will be responsible for enabling the XHCI
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controller if the the XHCI firmware is available but the
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controller if the XHCI firmware is available but the
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XHCI controller is not enabled by coreboot.
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config HUDSON_XHCI_FWM
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@ -49,7 +49,7 @@ config HUDSON_XHCI_ENABLE
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The XHCI controller must be enabled and the XHCI firmware
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must be added in order to have USB 3.0 support configured
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by coreboot. The OS will be responsible for enabling the XHCI
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controller if the the XHCI firmware is available but the
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controller if the XHCI firmware is available but the
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XHCI controller is not enabled by coreboot.
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config HUDSON_XHCI_FWM
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@ -103,7 +103,7 @@ typedef struct _S3_MEM_NB_BLOCK {
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/// Header for heap space to store the special case register.
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typedef struct _S3_SPECIAL_CASE_HEAP_HEADER {
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UINT8 Node; ///< Node ID for the the header
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UINT8 Node; ///< Node ID for the header
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UINT8 Offset; ///< Offset for the target node
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} S3_SPECIAL_CASE_HEAP_HEADER;
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/*----------------------------------------------------------------------------
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@ -105,7 +105,7 @@ typedef struct _S3_MEM_NB_BLOCK {
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/// Header for heap space to store the special case register.
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typedef struct _S3_SPECIAL_CASE_HEAP_HEADER {
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UINT8 Node; ///< Node ID for the the header
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UINT8 Node; ///< Node ID for the header
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UINT8 Offset; ///< Offset for the target node
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} S3_SPECIAL_CASE_HEAP_HEADER;
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/*----------------------------------------------------------------------------
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@ -103,7 +103,7 @@ typedef struct _S3_MEM_NB_BLOCK {
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/// Header for heap space to store the special case register.
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typedef struct _S3_SPECIAL_CASE_HEAP_HEADER {
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UINT8 Node; ///< Node ID for the the header
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UINT8 Node; ///< Node ID for the header
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UINT8 Offset; ///< Offset for the target node
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} S3_SPECIAL_CASE_HEAP_HEADER;
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/*----------------------------------------------------------------------------
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@ -106,7 +106,7 @@ typedef struct _S3_MEM_NB_BLOCK {
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/// Header for heap space to store the special case register.
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typedef struct _S3_SPECIAL_CASE_HEAP_HEADER {
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UINT8 Node; ///< Node ID for the the header
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UINT8 Node; ///< Node ID for the header
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UINT8 Offset; ///< Offset for the target node
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} S3_SPECIAL_CASE_HEAP_HEADER;
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@ -150,7 +150,7 @@ static bdk_dram_test_flags_t dram_test_flags; // FIXME: Don't use global
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* variables at the beginning of this file.
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*
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* @param arg Number of the region we should check
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* @param arg1 Pointer the the test_info structure
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* @param arg1 Pointer to the test_info structure
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*/
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static void dram_test_thread(int arg, void *arg1)
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{
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@ -11862,7 +11862,7 @@ union bdk_gsernx_lanex_rx_idle_cal_cfg
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FIXME no such field RECALIBRATION_OOB_COUNT_ADDER then remove above exempt attribute. */
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uint64_t reserved_40_60 : 21;
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uint64_t max_oob_adder_count : 8; /**< [ 39: 32](R/W) Maximum number of OOB forced pushouts of the idle recalibrations allowed. If the
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number of pushouts matches this number, the the idle offset is forced to recalibrate
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number of pushouts matches this number, the idle offset is forced to recalibrate
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regardless of the state of the link. */
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uint64_t oob_delay_adder_count : 32; /**< [ 31: 0](R/W) Number of svc_clk ticks allowed to delay the idle recalibration. Default is equal to
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1 second based on a 10 ns service clock cycle time. */
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@ -11870,7 +11870,7 @@ union bdk_gsernx_lanex_rx_idle_cal_cfg
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uint64_t oob_delay_adder_count : 32; /**< [ 31: 0](R/W) Number of svc_clk ticks allowed to delay the idle recalibration. Default is equal to
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1 second based on a 10 ns service clock cycle time. */
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uint64_t max_oob_adder_count : 8; /**< [ 39: 32](R/W) Maximum number of OOB forced pushouts of the idle recalibrations allowed. If the
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number of pushouts matches this number, the the idle offset is forced to recalibrate
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number of pushouts matches this number, the idle offset is forced to recalibrate
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regardless of the state of the link. */
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uint64_t reserved_40_60 : 21;
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uint64_t idle_oob_adder_counter_clear : 1;/**< [ 61: 61](R/W) This bit one set to high, forces the counter counting the number of OOB caused
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@ -1616,13 +1616,13 @@ union bdk_rvu_pf_block_addrx_disc
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uint64_t reserved_9_10 : 2;
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uint64_t num_lfs : 9; /**< [ 8: 0](RO/H) Number of local functions from the block that are provisioned to the VF/PF.
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When non-zero, the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in
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the the block.
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the block.
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Returns 0 for block types that do not have local functions, 0 or 1 for
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single-slot blocks; see RVU_BLOCK_TYPE_E. */
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#else /* Word 0 - Little Endian */
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uint64_t num_lfs : 9; /**< [ 8: 0](RO/H) Number of local functions from the block that are provisioned to the VF/PF.
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When non-zero, the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in
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the the block.
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the block.
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Returns 0 for block types that do not have local functions, 0 or 1 for
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single-slot blocks; see RVU_BLOCK_TYPE_E. */
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uint64_t reserved_9_10 : 2;
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@ -2972,10 +2972,10 @@ union bdk_rvu_priv_hwvfx_cptx_cfg
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#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
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uint64_t reserved_9_63 : 55;
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uint64_t num_lfs : 9; /**< [ 8: 0](R/W) Number of LFs from the block that are provisioned to the PF/VF. When non-zero,
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the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in the the block. */
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the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in the block. */
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#else /* Word 0 - Little Endian */
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uint64_t num_lfs : 9; /**< [ 8: 0](R/W) Number of LFs from the block that are provisioned to the PF/VF. When non-zero,
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the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in the the block. */
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the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in the block. */
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uint64_t reserved_9_63 : 55;
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#endif /* Word 0 - End */
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} s;
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@ -3140,10 +3140,10 @@ union bdk_rvu_priv_hwvfx_sso_cfg
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#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
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uint64_t reserved_9_63 : 55;
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uint64_t num_lfs : 9; /**< [ 8: 0](R/W) Number of LFs from the block that are provisioned to the PF/VF. When non-zero,
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the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in the the block. */
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the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in the block. */
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#else /* Word 0 - Little Endian */
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uint64_t num_lfs : 9; /**< [ 8: 0](R/W) Number of LFs from the block that are provisioned to the PF/VF. When non-zero,
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the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in the the block. */
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the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in the block. */
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uint64_t reserved_9_63 : 55;
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#endif /* Word 0 - End */
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} s;
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@ -3180,10 +3180,10 @@ union bdk_rvu_priv_hwvfx_ssow_cfg
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#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
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uint64_t reserved_9_63 : 55;
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uint64_t num_lfs : 9; /**< [ 8: 0](R/W) Number of LFs from the block that are provisioned to the PF/VF. When non-zero,
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the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in the the block. */
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the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in the block. */
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#else /* Word 0 - Little Endian */
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uint64_t num_lfs : 9; /**< [ 8: 0](R/W) Number of LFs from the block that are provisioned to the PF/VF. When non-zero,
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the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in the the block. */
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the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in the block. */
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uint64_t reserved_9_63 : 55;
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#endif /* Word 0 - End */
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} s;
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@ -3220,10 +3220,10 @@ union bdk_rvu_priv_hwvfx_tim_cfg
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#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
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uint64_t reserved_9_63 : 55;
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uint64_t num_lfs : 9; /**< [ 8: 0](R/W) Number of LFs from the block that are provisioned to the PF/VF. When non-zero,
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the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in the the block. */
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the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in the block. */
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#else /* Word 0 - Little Endian */
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uint64_t num_lfs : 9; /**< [ 8: 0](R/W) Number of LFs from the block that are provisioned to the PF/VF. When non-zero,
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the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in the the block. */
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the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in the block. */
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uint64_t reserved_9_63 : 55;
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#endif /* Word 0 - End */
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} s;
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@ -3357,10 +3357,10 @@ union bdk_rvu_priv_pfx_cptx_cfg
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#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
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uint64_t reserved_9_63 : 55;
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uint64_t num_lfs : 9; /**< [ 8: 0](R/W) Number of LFs from the block that are provisioned to the PF/VF. When non-zero,
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the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in the the block. */
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the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in the block. */
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#else /* Word 0 - Little Endian */
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uint64_t num_lfs : 9; /**< [ 8: 0](R/W) Number of LFs from the block that are provisioned to the PF/VF. When non-zero,
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the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in the the block. */
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the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in the block. */
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uint64_t reserved_9_63 : 55;
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#endif /* Word 0 - End */
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} s;
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@ -3660,10 +3660,10 @@ union bdk_rvu_priv_pfx_sso_cfg
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#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
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uint64_t reserved_9_63 : 55;
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uint64_t num_lfs : 9; /**< [ 8: 0](R/W) Number of LFs from the block that are provisioned to the PF/VF. When non-zero,
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the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in the the block. */
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the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in the block. */
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#else /* Word 0 - Little Endian */
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uint64_t num_lfs : 9; /**< [ 8: 0](R/W) Number of LFs from the block that are provisioned to the PF/VF. When non-zero,
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the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in the the block. */
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the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in the block. */
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uint64_t reserved_9_63 : 55;
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#endif /* Word 0 - End */
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} s;
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@ -3700,10 +3700,10 @@ union bdk_rvu_priv_pfx_ssow_cfg
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#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
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uint64_t reserved_9_63 : 55;
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uint64_t num_lfs : 9; /**< [ 8: 0](R/W) Number of LFs from the block that are provisioned to the PF/VF. When non-zero,
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the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in the the block. */
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the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in the block. */
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#else /* Word 0 - Little Endian */
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uint64_t num_lfs : 9; /**< [ 8: 0](R/W) Number of LFs from the block that are provisioned to the PF/VF. When non-zero,
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the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in the the block. */
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the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in the block. */
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uint64_t reserved_9_63 : 55;
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#endif /* Word 0 - End */
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} s;
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@ -3740,10 +3740,10 @@ union bdk_rvu_priv_pfx_tim_cfg
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#if __BYTE_ORDER == __BIG_ENDIAN /* Word 0 - Big Endian */
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uint64_t reserved_9_63 : 55;
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uint64_t num_lfs : 9; /**< [ 8: 0](R/W) Number of LFs from the block that are provisioned to the PF/VF. When non-zero,
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the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in the the block. */
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the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in the block. */
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#else /* Word 0 - Little Endian */
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uint64_t num_lfs : 9; /**< [ 8: 0](R/W) Number of LFs from the block that are provisioned to the PF/VF. When non-zero,
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the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in the the block. */
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the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in the block. */
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uint64_t reserved_9_63 : 55;
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#endif /* Word 0 - End */
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} s;
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|
@ -3792,13 +3792,13 @@ union bdk_rvu_vf_block_addrx_disc
|
|||
uint64_t reserved_9_10 : 2;
|
||||
uint64_t num_lfs : 9; /**< [ 8: 0](RO/H) Number of local functions from the block that are provisioned to the VF/PF.
|
||||
When non-zero, the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in
|
||||
the the block.
|
||||
the block.
|
||||
Returns 0 for block types that do not have local functions, 0 or 1 for
|
||||
single-slot blocks; see RVU_BLOCK_TYPE_E. */
|
||||
#else /* Word 0 - Little Endian */
|
||||
uint64_t num_lfs : 9; /**< [ 8: 0](RO/H) Number of local functions from the block that are provisioned to the VF/PF.
|
||||
When non-zero, the provisioned LFs are mapped to slots 0 to [NUM_LFS]-1 in
|
||||
the the block.
|
||||
the block.
|
||||
Returns 0 for block types that do not have local functions, 0 or 1 for
|
||||
single-slot blocks; see RVU_BLOCK_TYPE_E. */
|
||||
uint64_t reserved_9_10 : 2;
|
||||
|
|
|
@ -180,7 +180,7 @@ typedef struct {
|
|||
/// EFI_CERT_TYPE_RSA2048_SHA256_GUID. If the attribute specifies
|
||||
/// authenticated access, then the Data buffer should begin with an
|
||||
/// authentication descriptor prior to the data payload and DataSize
|
||||
/// should reflect the the data.and descriptor size. The caller
|
||||
/// should reflect the data.and descriptor size. The caller
|
||||
/// shall digest the Monotonic Count value and the associated data
|
||||
/// for the variable update using the SHA-256 1-way hash algorithm.
|
||||
/// The ensuing the 32-byte digest will be signed using the private
|
||||
|
|
|
@ -177,7 +177,7 @@ GetSectionFromFv (
|
|||
|
||||
|
||||
/**
|
||||
Searches the FFS file the the currently executing module was loaded from and returns the first matching FFS section.
|
||||
Searches the FFS file the currently executing module was loaded from and returns the first matching FFS section.
|
||||
|
||||
This function searches the FFS file that the currently executing module was loaded from for a FFS sections of type SectionType.
|
||||
If the FFS file contains at least SectionInstance instances of the FFS section specified by SectionType,
|
||||
|
|
|
@ -119,7 +119,7 @@ RETURN_STATUS
|
|||
If GetInfoHandler is NULL, then ASSERT().
|
||||
If DecodeHandler is NULL, then ASSERT().
|
||||
|
||||
@param[in] SectionGuid A pointer to the GUID associated with the the handlers
|
||||
@param[in] SectionGuid A pointer to the GUID associated with the handlers
|
||||
of the GUIDed section type being registered.
|
||||
@param[in] GetInfoHandler Pointer to a function that examines a GUIDed section and returns the
|
||||
size of the decoded buffer and the size of an optional scratch buffer
|
||||
|
@ -168,7 +168,7 @@ ExtractGuidedSectionGetGuidList (
|
|||
Examines a GUIDed section specified by InputSection.
|
||||
If GUID for InputSection does not match any of the GUIDs registered through ExtractGuidedSectionRegisterHandlers(),
|
||||
then RETURN_UNSUPPORTED is returned.
|
||||
If the GUID of InputSection does match the GUID that this handler supports, then the the associated handler
|
||||
If the GUID of InputSection does match the GUID that this handler supports, then the associated handler
|
||||
of type EXTRACT_GUIDED_SECTION_GET_INFO_HANDLER that was registered with ExtractGuidedSectionRegisterHandlers()
|
||||
is used to retrieve the OututBufferSize, ScratchSize, and Attributes values. The return status from the handler of
|
||||
type EXTRACT_GUIDED_SECTION_GET_INFO_HANDLER is returned.
|
||||
|
@ -211,7 +211,7 @@ ExtractGuidedSectionGetInfo (
|
|||
Decodes the GUIDed section specified by InputSection.
|
||||
If GUID for InputSection does not match any of the GUIDs registered through ExtractGuidedSectionRegisterHandlers(),
|
||||
then RETURN_UNSUPPORTED is returned.
|
||||
If the GUID of InputSection does match the GUID that this handler supports, then the the associated handler
|
||||
If the GUID of InputSection does match the GUID that this handler supports, then the associated handler
|
||||
of type EXTRACT_GUIDED_SECTION_DECODE_HANDLER that was registered with ExtractGuidedSectionRegisterHandlers()
|
||||
is used to decode InputSection into the buffer specified by OutputBuffer and the authentication status of this
|
||||
decode operation is returned in AuthenticationStatus. If the decoded buffer is identical to the data in InputSection,
|
||||
|
|
|
@ -409,7 +409,7 @@ EfiReleaseLock (
|
|||
|
||||
This function tests whether the driver specified by DriverBindingHandle is
|
||||
currently managing the controller specified by ControllerHandle. This test
|
||||
is performed by evaluating if the the protocol specified by ProtocolGuid is
|
||||
is performed by evaluating if the protocol specified by ProtocolGuid is
|
||||
present on ControllerHandle and is was opened by DriverBindingHandle with an
|
||||
attribute of EFI_OPEN_PROTOCOL_BY_DRIVER.
|
||||
If ProtocolGuid is NULL, then ASSERT().
|
||||
|
|
|
@ -180,7 +180,7 @@ EFI_STATUS
|
|||
@param[in] Type On entry, it points to the type of the next SMBIOS record to return. If NULL, it
|
||||
indicates that the next record of any type will be returned. Type is not
|
||||
modified by the this function.
|
||||
@param[out] Record On exit, points to a pointer to the the SMBIOS Record consisting of the formatted area
|
||||
@param[out] Record On exit, points to a pointer to the SMBIOS Record consisting of the formatted area
|
||||
followed by the unformatted area. The unformatted area optionally contains text strings.
|
||||
@param[out] ProducerHandle On exit, points to the ProducerHandle registered by Add(). If no
|
||||
ProducerHandle was passed into Add() NULL is returned. If a NULL pointer is
|
||||
|
|
|
@ -182,7 +182,7 @@ typedef struct {
|
|||
/// EFI_CERT_TYPE_RSA2048_SHA256_GUID. If the attribute specifies
|
||||
/// authenticated access, then the Data buffer should begin with an
|
||||
/// authentication descriptor prior to the data payload and DataSize
|
||||
/// should reflect the the data.and descriptor size. The caller
|
||||
/// should reflect the data.and descriptor size. The caller
|
||||
/// shall digest the Monotonic Count value and the associated data
|
||||
/// for the variable update using the SHA-256 1-way hash algorithm.
|
||||
/// The ensuing the 32-byte digest will be signed using the private
|
||||
|
|
|
@ -142,7 +142,7 @@ typedef struct {
|
|||
/// EFI_CERT_TYPE_RSA2048_SHA256_GUID. If the attribute specifies
|
||||
/// authenticated access, then the Data buffer should begin with an
|
||||
/// authentication descriptor prior to the data payload and DataSize
|
||||
/// should reflect the the data.and descriptor size. The caller
|
||||
/// should reflect the data.and descriptor size. The caller
|
||||
/// shall digest the Monotonic Count value and the associated data
|
||||
/// for the variable update using the SHA-256 1-way hash algorithm.
|
||||
/// The ensuing the 32-byte digest will be signed using the private
|
||||
|
|
Loading…
Reference in New Issue