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CBMEM high table memory manager. This code adds a very simple toc based memory manager for the high tables area. The purpose of this code is to make it simpler and more reliable to find certain data structures in memory. This will also make it possible to have ACPI S3 Resume working without an ugly hole at 31MB. Signed-off-by: Stefan Reinauer <stepan@coresystems.de> Acked-by: Peter Stuge <peter@stuge.se> git-svn-id: svn://svn.coreboot.org/coreboot/trunk@4860 2b7e53f0-3cfb-0310-b3e9-8179ed1497e1
2009-10-26 18:04:28 +01:00
/*
* This file is part of the coreboot project.
*
* Copyright (C) 2009 coresystems GmbH
cbmem: dynamic cbmem support This patch adds a parallel implementation of cbmem that supports dynamic sizing. The original implementation relied on reserving a fixed-size block of memory for adding cbmem entries. In order to allow for more flexibility for adding cbmem allocations the dynamic cbmem infrastructure was developed as an alternative to the fixed block approach. Also, the amount of memory to reserve for cbmem allocations does not need to be known prior to the first allocation. The dynamic cbmem code implements the same API as the existing cbmem code except for cbmem_init() and cbmem_reinit(). The add and find routines behave the same way. The dynamic cbmem infrastructure uses a top down allocator that starts allocating from a board/chipset defined function cbmem_top(). A root pointer lives just below cbmem_top(). In turn that pointer points to the root block which contains the entries for all the large alloctations. The corresponding block for each large allocation falls just below the previous entry. It should be noted that this implementation rounds all allocations up to a 4096 byte granularity. Though a packing allocator could be written for small allocations it was deemed OK to just fragment the memory as there shouldn't be that many small allocations. The result is less code with a tradeoff of some wasted memory. +----------------------+ <- cbmem_top() | +----| root pointer | | | +----------------------+ | | | |--------+ | +--->| root block |-----+ | | +----------------------+ | | | | | | | | | | | | | | alloc N |<----+ | | +----------------------+ | | | | | | | | | \|/ | alloc N + 1 |<-------+ v +----------------------+ In addition to preserving the previous cbmem API, the dynamic cbmem API allows for removing blocks from cbmem. This allows for the boot process to allocate memory that can be discarded after it's been used for performing more complex boot tasks in romstage. In order to plumb this support in there were some issues to work around regarding writing of coreboot tables. There were a few assumptions to how cbmem was layed out which dictated some ifdef guarding and other runtime checks so as not to incorrectly tag the e820 and coreboot memory tables. The example shown below is using dynamic cbmem infrastructure. The reserved memory for cbmem is less than 512KiB. coreboot memory table: 0. 0000000000000000-0000000000000fff: CONFIGURATION TABLES 1. 0000000000001000-000000000002ffff: RAM 2. 0000000000030000-000000000003ffff: RESERVED 3. 0000000000040000-000000000009ffff: RAM 4. 00000000000a0000-00000000000fffff: RESERVED 5. 0000000000100000-0000000000efffff: RAM 6. 0000000000f00000-0000000000ffffff: RESERVED 7. 0000000001000000-000000007bf80fff: RAM 8. 000000007bf81000-000000007bffffff: CONFIGURATION TABLES 9. 000000007c000000-000000007e9fffff: RESERVED 10. 00000000f0000000-00000000f3ffffff: RESERVED 11. 00000000fed10000-00000000fed19fff: RESERVED 12. 00000000fed84000-00000000fed84fff: RESERVED 13. 0000000100000000-00000001005fffff: RAM Wrote coreboot table at: 7bf81000, 0x39c bytes, checksum f5bf coreboot table: 948 bytes. CBMEM ROOT 0. 7bfff000 00001000 MRC DATA 1. 7bffe000 00001000 ROMSTAGE 2. 7bffd000 00001000 TIME STAMP 3. 7bffc000 00001000 ROMSTG STCK 4. 7bff7000 00005000 CONSOLE 5. 7bfe7000 00010000 VBOOT 6. 7bfe6000 00001000 RAMSTAGE 7. 7bf98000 0004e000 GDT 8. 7bf97000 00001000 ACPI 9. 7bf8b000 0000c000 ACPI GNVS 10. 7bf8a000 00001000 SMBIOS 11. 7bf89000 00001000 COREBOOT 12. 7bf81000 00008000 And the corresponding e820 entries: BIOS-e820: [mem 0x0000000000000000-0x0000000000000fff] type 16 BIOS-e820: [mem 0x0000000000001000-0x000000000002ffff] usable BIOS-e820: [mem 0x0000000000030000-0x000000000003ffff] reserved BIOS-e820: [mem 0x0000000000040000-0x000000000009ffff] usable BIOS-e820: [mem 0x00000000000a0000-0x00000000000fffff] reserved BIOS-e820: [mem 0x0000000000100000-0x0000000000efffff] usable BIOS-e820: [mem 0x0000000000f00000-0x0000000000ffffff] reserved BIOS-e820: [mem 0x0000000001000000-0x000000007bf80fff] usable BIOS-e820: [mem 0x000000007bf81000-0x000000007bffffff] type 16 BIOS-e820: [mem 0x000000007c000000-0x000000007e9fffff] reserved BIOS-e820: [mem 0x00000000f0000000-0x00000000f3ffffff] reserved BIOS-e820: [mem 0x00000000fed10000-0x00000000fed19fff] reserved BIOS-e820: [mem 0x00000000fed84000-0x00000000fed84fff] reserved BIOS-e820: [mem 0x0000000100000000-0x00000001005fffff] usable Change-Id: Ie3bca52211800a8652a77ca684140cfc9b3b9a6b Signed-off-by: Aaron Durbin <adurbin@chromium.org> Reviewed-on: http://review.coreboot.org/2848 Tested-by: build bot (Jenkins) Reviewed-by: Ronald G. Minnich <rminnich@gmail.com>
2013-03-13 18:41:44 +01:00
* Copyright (C) 2013 Google, Inc.
CBMEM high table memory manager. This code adds a very simple toc based memory manager for the high tables area. The purpose of this code is to make it simpler and more reliable to find certain data structures in memory. This will also make it possible to have ACPI S3 Resume working without an ugly hole at 31MB. Signed-off-by: Stefan Reinauer <stepan@coresystems.de> Acked-by: Peter Stuge <peter@stuge.se> git-svn-id: svn://svn.coreboot.org/coreboot/trunk@4860 2b7e53f0-3cfb-0310-b3e9-8179ed1497e1
2009-10-26 18:04:28 +01:00
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; version 2 of the License.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA, 02110-1301 USA
*/
#ifndef _CBMEM_H_
#define _CBMEM_H_
Increase size of the coreboot table area Packing a device tree into the coreboot table can easily make the table exceed the current limit of 8KB. However, right now there is no error handling in place to catch that case. Increase the maximum memory usable for all tables from 64KB to 128KB and increase the maximum coreboot table size from 8KB to 32KB. Change-Id: I2025bf070d0adb276c1cd610aa8402b50bdf2525 Signed-off-by: Stefan Reinauer <reinauer@google.com> Reviewed-on: http://review.coreboot.org/704 Tested-by: build bot (Jenkins) Reviewed-by: Ronald G. Minnich <rminnich@gmail.com>
2011-08-14 22:52:03 +02:00
/* Reserve 128k for ACPI and other tables */
Increase CBMEM to accommodate larger console. This change adds 128K to the memory amount set aside for CBMEM in case the CBMEM console is enabled (to keep the CBMEM 128K byte aligned). The console buffer size is being set to 64K, which is enough to accommodate the most verbose coreboot console and u-boot console. Change-Id: If583013dfb210de5028d69577675095c6fe2f3ab Signed-off-by: Vadim Bendebury <vbendeb@chromium.org> Reviewed-on: http://review.coreboot.org/725 Tested-by: build bot (Jenkins) Reviewed-by: Ronald G. Minnich <rminnich@gmail.com>
2011-10-04 19:44:16 +02:00
#if CONFIG_CONSOLE_CBMEM
#define HIGH_MEMORY_DEF_SIZE ( 256 * 1024 )
#else
Increase size of the coreboot table area Packing a device tree into the coreboot table can easily make the table exceed the current limit of 8KB. However, right now there is no error handling in place to catch that case. Increase the maximum memory usable for all tables from 64KB to 128KB and increase the maximum coreboot table size from 8KB to 32KB. Change-Id: I2025bf070d0adb276c1cd610aa8402b50bdf2525 Signed-off-by: Stefan Reinauer <reinauer@google.com> Reviewed-on: http://review.coreboot.org/704 Tested-by: build bot (Jenkins) Reviewed-by: Ronald G. Minnich <rminnich@gmail.com>
2011-08-14 22:52:03 +02:00
#define HIGH_MEMORY_DEF_SIZE ( 128 * 1024 )
Increase CBMEM to accommodate larger console. This change adds 128K to the memory amount set aside for CBMEM in case the CBMEM console is enabled (to keep the CBMEM 128K byte aligned). The console buffer size is being set to 64K, which is enough to accommodate the most verbose coreboot console and u-boot console. Change-Id: If583013dfb210de5028d69577675095c6fe2f3ab Signed-off-by: Vadim Bendebury <vbendeb@chromium.org> Reviewed-on: http://review.coreboot.org/725 Tested-by: build bot (Jenkins) Reviewed-by: Ronald G. Minnich <rminnich@gmail.com>
2011-10-04 19:44:16 +02:00
#endif
CBMEM high table memory manager. This code adds a very simple toc based memory manager for the high tables area. The purpose of this code is to make it simpler and more reliable to find certain data structures in memory. This will also make it possible to have ACPI S3 Resume working without an ugly hole at 31MB. Signed-off-by: Stefan Reinauer <stepan@coresystems.de> Acked-by: Peter Stuge <peter@stuge.se> git-svn-id: svn://svn.coreboot.org/coreboot/trunk@4860 2b7e53f0-3cfb-0310-b3e9-8179ed1497e1
2009-10-26 18:04:28 +01:00
#if CONFIG_HAVE_ACPI_RESUME
coreboot: introduce CONFIG_RELOCATABLE_RAMSTAGE This patch adds an option to build the ramstage as a reloctable binary. It uses the rmodule library for the relocation. The main changes consist of the following: 1. The ramstage is loaded just under the cmbem space. 2. Payloads cannot be loaded over where ramstage is loaded. If a payload is attempted to load where the relocatable ramstage resides the load is aborted. 3. The memory occupied by the ramstage is reserved from the OS's usage using the romstage_handoff structure stored in cbmem. This region is communicated to ramstage by an CBMEM_ID_ROMSTAGE_INFO entry in cbmem. 4. There is no need to reserve cbmem space for the OS controlled memory for the resume path because the ramsage region has been reserved in #3. 5. Since no memory needs to be preserved in the wake path, the loading and begin of execution of a elf payload is straight forward. Change-Id: Ia66cf1be65c29fa25ca7bd9ea6c8f11d7eee05f5 Signed-off-by: Aaron Durbin <adurbin@chromium.org> Reviewed-on: http://review.coreboot.org/2792 Reviewed-by: Ronald G. Minnich <rminnich@gmail.com> Tested-by: build bot (Jenkins) Reviewed-by: Aaron Durbin <adurbin@google.com>
2013-02-09 00:28:04 +01:00
#if CONFIG_RELOCATABLE_RAMSTAGE
#define HIGH_MEMORY_SAVE 0
#else
S3 code in coreboot public folder. 1. Move the Stack to high memory. 2. Restore the MTRR before Coreboot jump to the wakeup vector. Change-Id: I9872e02fcd7eed98e7f630aa29ece810ac32d55a Signed-off-by: Zheng Bao <zheng.bao@amd.com> Signed-off-by: zbao <fishbaozi@gmail.com> Reviewed-on: http://review.coreboot.org/623 Tested-by: build bot (Jenkins) Reviewed-by: Marc Jones <marcj303@gmail.com>
2012-04-13 07:42:15 +02:00
#define HIGH_MEMORY_SAVE (CONFIG_RAMTOP - CONFIG_RAMBASE)
coreboot: introduce CONFIG_RELOCATABLE_RAMSTAGE This patch adds an option to build the ramstage as a reloctable binary. It uses the rmodule library for the relocation. The main changes consist of the following: 1. The ramstage is loaded just under the cmbem space. 2. Payloads cannot be loaded over where ramstage is loaded. If a payload is attempted to load where the relocatable ramstage resides the load is aborted. 3. The memory occupied by the ramstage is reserved from the OS's usage using the romstage_handoff structure stored in cbmem. This region is communicated to ramstage by an CBMEM_ID_ROMSTAGE_INFO entry in cbmem. 4. There is no need to reserve cbmem space for the OS controlled memory for the resume path because the ramsage region has been reserved in #3. 5. Since no memory needs to be preserved in the wake path, the loading and begin of execution of a elf payload is straight forward. Change-Id: Ia66cf1be65c29fa25ca7bd9ea6c8f11d7eee05f5 Signed-off-by: Aaron Durbin <adurbin@chromium.org> Reviewed-on: http://review.coreboot.org/2792 Reviewed-by: Ronald G. Minnich <rminnich@gmail.com> Tested-by: build bot (Jenkins) Reviewed-by: Aaron Durbin <adurbin@google.com>
2013-02-09 00:28:04 +01:00
#endif
S3 code in coreboot public folder. 1. Move the Stack to high memory. 2. Restore the MTRR before Coreboot jump to the wakeup vector. Change-Id: I9872e02fcd7eed98e7f630aa29ece810ac32d55a Signed-off-by: Zheng Bao <zheng.bao@amd.com> Signed-off-by: zbao <fishbaozi@gmail.com> Reviewed-on: http://review.coreboot.org/623 Tested-by: build bot (Jenkins) Reviewed-by: Marc Jones <marcj303@gmail.com>
2012-04-13 07:42:15 +02:00
#define HIGH_MEMORY_SIZE (HIGH_MEMORY_SAVE + CONFIG_HIGH_SCRATCH_MEMORY_SIZE + HIGH_MEMORY_DEF_SIZE)
Add constants for fast path resume copying cache as ram does not usually cache the ram before it is up. Hence, if romstage.c backs up resume memory, the involved memcpy is always uncached. This makes resume very slow. On Sandybridge we copy the memory later, after enabling caching, and that allows us to resume in as little as 250ms. Change-Id: I31a71ad4468679d39880cf9a8c4e497bb7addf8f Signed-off-by: Stefan Reinauer <reinauer@google.com> Reviewed-on: http://review.coreboot.org/872 Reviewed-by: Ronald G. Minnich <rminnich@gmail.com> Tested-by: build bot (Jenkins)
2012-04-04 01:21:04 +02:00
/* Delegation of resume backup memory so we don't have to
* (slowly) handle backing up OS memory in romstage.c
*/
#define CBMEM_BOOT_MODE 0x610
#define CBMEM_RESUME_BACKUP 0x614
S3 code in coreboot public folder. 1. Move the Stack to high memory. 2. Restore the MTRR before Coreboot jump to the wakeup vector. Change-Id: I9872e02fcd7eed98e7f630aa29ece810ac32d55a Signed-off-by: Zheng Bao <zheng.bao@amd.com> Signed-off-by: zbao <fishbaozi@gmail.com> Reviewed-on: http://review.coreboot.org/623 Tested-by: build bot (Jenkins) Reviewed-by: Marc Jones <marcj303@gmail.com>
2012-04-13 07:42:15 +02:00
#else /* CONFIG_HAVE_ACPI_RESUME */
We hardcode highmemory size in every northbridge! This is bad, and especially if suspend to ram is involved. Let the default be taken from cbmem.h which also handles the suspend logic. Abuild tested. Please check all changes if I did not make any wrong while converting this to bytes. Signed-off-by: Rudolf Marek <r.marek@assembler.cz> Acked-by: Peter Stuge <peter@stuge.se> git-svn-id: svn://svn.coreboot.org/coreboot/trunk@6171 2b7e53f0-3cfb-0310-b3e9-8179ed1497e1
2010-12-13 20:50:25 +01:00
#define HIGH_MEMORY_SIZE HIGH_MEMORY_DEF_SIZE
S3 code in coreboot public folder. 1. Move the Stack to high memory. 2. Restore the MTRR before Coreboot jump to the wakeup vector. Change-Id: I9872e02fcd7eed98e7f630aa29ece810ac32d55a Signed-off-by: Zheng Bao <zheng.bao@amd.com> Signed-off-by: zbao <fishbaozi@gmail.com> Reviewed-on: http://review.coreboot.org/623 Tested-by: build bot (Jenkins) Reviewed-by: Marc Jones <marcj303@gmail.com>
2012-04-13 07:42:15 +02:00
#endif /* CONFIG_HAVE_ACPI_RESUME */
CBMEM high table memory manager. This code adds a very simple toc based memory manager for the high tables area. The purpose of this code is to make it simpler and more reliable to find certain data structures in memory. This will also make it possible to have ACPI S3 Resume working without an ugly hole at 31MB. Signed-off-by: Stefan Reinauer <stepan@coresystems.de> Acked-by: Peter Stuge <peter@stuge.se> git-svn-id: svn://svn.coreboot.org/coreboot/trunk@4860 2b7e53f0-3cfb-0310-b3e9-8179ed1497e1
2009-10-26 18:04:28 +01:00
#define CBMEM_ID_FREESPACE 0x46524545
#define CBMEM_ID_GDT 0x4c474454
#define CBMEM_ID_ACPI 0x41435049
SMM: Restore GNVS pointer in the resume path The SMM GNVS pointer is normally updated only when the ACPI tables are created, which does not happen in the resume path. In order to restore this pointer it needs to be available at resume time. The method used to locate it at creation time cannot be used again as that magic signature is overwritten with the address itself. So a new CBMEM ID is added to store the 32bit address so it can be found again easily. A new function is defined to save this pointer in CBMEM which needs to be called when the ACPI tables are created in each mainboard when write_acpi_tables() is called. The cpu_index variable had to be renamed due to a conflict when cpu/cpu.h is added for the smm_setup_structures() prototype. Change-Id: Ic764ff54525e12b617c1dd8d6a3e5c4f547c3e6b Signed-off-by: Duncan Laurie <dlaurie@chromium.org> Reviewed-on: http://review.coreboot.org/1765 Tested-by: build bot (Jenkins) Reviewed-by: Ronald G. Minnich <rminnich@gmail.com>
2012-10-04 04:07:05 +02:00
#define CBMEM_ID_ACPI_GNVS 0x474e5653
lynxpoint: Move ACPI NVS into separate CBMEM table The ACPI NVS region was setup in place and there was a CBMEM table that pointed to it. In order to be able to use NVS earlier the CBMEM region is allocated for NVS itself during the LPC device init and the ACPI tables point to it in CBMEM. The current cbmem region is renamed to ACPI_GNVS_PTR to indicate that it is really a pointer to the GNVS and does not actually contain the GNVS. Change-Id: I31ace432411c7f825d86ca75c63dd79cd658e891 Signed-off-by: Duncan Laurie <dlaurie@chromium.org> Reviewed-on: http://review.coreboot.org/2970 Tested-by: build bot (Jenkins) Reviewed-by: Ronald G. Minnich <rminnich@gmail.com>
2013-03-22 19:08:39 +01:00
#define CBMEM_ID_ACPI_GNVS_PTR 0x474e5650
CBMEM high table memory manager. This code adds a very simple toc based memory manager for the high tables area. The purpose of this code is to make it simpler and more reliable to find certain data structures in memory. This will also make it possible to have ACPI S3 Resume working without an ugly hole at 31MB. Signed-off-by: Stefan Reinauer <stepan@coresystems.de> Acked-by: Peter Stuge <peter@stuge.se> git-svn-id: svn://svn.coreboot.org/coreboot/trunk@4860 2b7e53f0-3cfb-0310-b3e9-8179ed1497e1
2009-10-26 18:04:28 +01:00
#define CBMEM_ID_CBTABLE 0x43425442
#define CBMEM_ID_PIRQ 0x49525154
#define CBMEM_ID_MPTABLE 0x534d5054
#define CBMEM_ID_RESUME 0x5245534d
S3 code in coreboot public folder. 1. Move the Stack to high memory. 2. Restore the MTRR before Coreboot jump to the wakeup vector. Change-Id: I9872e02fcd7eed98e7f630aa29ece810ac32d55a Signed-off-by: Zheng Bao <zheng.bao@amd.com> Signed-off-by: zbao <fishbaozi@gmail.com> Reviewed-on: http://review.coreboot.org/623 Tested-by: build bot (Jenkins) Reviewed-by: Marc Jones <marcj303@gmail.com>
2012-04-13 07:42:15 +02:00
#define CBMEM_ID_RESUME_SCRATCH 0x52455343
Add automatic SMBIOS table generation Change-Id: I0ae16dda8969638a8f70fe1d2e29e992aef3a834 Signed-off-by: Sven Schnelle <svens@stackframe.org> Reviewed-on: http://review.coreboot.org/152 Tested-by: build bot (Jenkins)
2011-08-14 20:56:34 +02:00
#define CBMEM_ID_SMBIOS 0x534d4254
Add timestamp collecting to coreboot. This patch adds code to initialize the time stamp collection facility in coreboot. It adds a table in the CBMEM section, which provides the base timer reading value (all other readings are offsets of this one) and an array of timestamp id/timestamp value pairs. Just two values are being added now, this will have to be used more extensively and also integrated into payloads to provide more comprehensive boot process time measurements. Also, since the CBMEM area could already contain a section (from the previous run, before reset), when processing a section addition request we should check if a section already exists and return its address, if so. Change-Id: I7ed9f5c400bc5432f228348b41fd19a67c36d533 Signed-off-by: Vadim Bendebury <vbendeb@chromium.org> Reviewed-on: http://review.coreboot.org/713 Reviewed-by: Ronald G. Minnich <rminnich@gmail.com> Tested-by: build bot (Jenkins)
2011-09-22 01:12:39 +02:00
#define CBMEM_ID_TIMESTAMP 0x54494d45
Add constants for fast path resume copying cache as ram does not usually cache the ram before it is up. Hence, if romstage.c backs up resume memory, the involved memcpy is always uncached. This makes resume very slow. On Sandybridge we copy the memory later, after enabling caching, and that allows us to resume in as little as 250ms. Change-Id: I31a71ad4468679d39880cf9a8c4e497bb7addf8f Signed-off-by: Stefan Reinauer <reinauer@google.com> Reviewed-on: http://review.coreboot.org/872 Reviewed-by: Ronald G. Minnich <rminnich@gmail.com> Tested-by: build bot (Jenkins)
2012-04-04 01:21:04 +02:00
#define CBMEM_ID_MRCDATA 0x4d524344
CBMEM CONSOLE: Add CBMEM type for console buffer. Add CBMEM type for the console buffer section. Change-Id: I02757c06d71e46af77b02b90b0e6018a37b62406 Signed-off-by: Vadim Bendebury <vbendeb@chromium.org> Reviewed-on: http://review.coreboot.org/720 Tested-by: build bot (Jenkins) Reviewed-by: Ronald G. Minnich <rminnich@gmail.com>
2011-09-30 20:13:06 +02:00
#define CBMEM_ID_CONSOLE 0x434f4e53
ELOG: Support for non-memory mapped flash If the event log is stored in flash that is not memory mapped then it must use the SPI controller to read from the flash device instead of relying on memory accesses. In addition a new CBMEM ID is added to keep an resident copy of the ELOG around if needed. The use of CBMEM for this is guarded by a new CONFIG_ELOG_CBMEM config option. This CBMEM buffer is created and filled late in the process when the SMBIOS table is being created because CBMEM is not functional when ELOG is first initialized. The downside to using CBMEM is that events added via the SMI handler at runtime are not reflected in the CBMEM copy because I don't want to let the SMM handler write to memory outside the TSEG region. In reality the only time we add runtime events is at kernel shutdown so the impact is limited. Test: 1) Test with CONFIG_ELOG_CBMEM enabled to ensure the event log is operational and SMBIOS points to address in CBMEM. The test should involve at least on reboot to ensure that the kernel is able to write events as well. > mosys -l smbios info log | grep ^address address | 0xacedd000 > mosys eventlog list 0 | 2012-10-10 14:02:46 | Log area cleared | 4096 1 | 2012-10-10 14:02:46 | System boot | 478 2 | 2012-10-10 14:02:46 | System Reset 3 | 2012-10-10 14:03:33 | Kernel Event | Clean Shutdown 4 | 2012-10-10 14:03:34 | System boot | 479 5 | 2012-10-10 14:03:34 | System Reset 2) Test with CONFIG_ELOG_CBMEM disabled to ensure the event log is operational and SMBIOS points to memory mapped flash. The test should involve at least on reboot to ensure that the kernel is able to write events as well. > mosys -l smbios info log | grep ^address address | 0xffbf0000 > mosys eventlog list 0 | 2012-10-10 14:33:17 | Log area cleared | 4096 1 | 2012-10-10 14:33:18 | System boot | 480 2 | 2012-10-10 14:33:18 | System Reset 3 | 2012-10-10 14:33:35 | Kernel Event | Clean Shutdown 4 | 2012-10-10 14:33:36 | System boot | 481 5 | 2012-10-10 14:33:36 | System Reset Change-Id: I87755d5291ce209c1e647792227c433dc966615d Signed-off-by: Duncan Laurie <dlaurie@chromium.org> Reviewed-on: http://review.coreboot.org/1776 Tested-by: build bot (Jenkins) Reviewed-by: Ronald G. Minnich <rminnich@gmail.com>
2012-10-10 23:34:49 +02:00
#define CBMEM_ID_ELOG 0x454c4f47
Implement GCC code coverage analysis In order to provide some insight on what code is executed during coreboot's run time and how well our test scenarios work, this adds code coverage support to coreboot's ram stage. This should be easily adaptable for payloads, and maybe even romstage. See http://gcc.gnu.org/onlinedocs/gcc/Gcov.html for more information. To instrument coreboot, select CONFIG_COVERAGE ("Code coverage support") in Kconfig, and recompile coreboot. coreboot will then store its code coverage information into CBMEM, if possible. Then, run "cbmem -CV" as root on the target system running the instrumented coreboot binary. This will create a whole bunch of .gcda files that contain coverage information. Tar them up, copy them to your build system machine, and untar them. Then you can use your favorite coverage utility (gcov, lcov, ...) to visualize code coverage. For a sneak peak of what will expect you, please take a look at http://www.coreboot.org/~stepan/coreboot-coverage/ Change-Id: Ib287d8309878a1f5c4be770c38b1bc0bb3aa6ec7 Signed-off-by: Stefan Reinauer <reinauer@google.com> Reviewed-on: http://review.coreboot.org/2052 Tested-by: build bot (Jenkins) Reviewed-by: David Hendricks <dhendrix@chromium.org> Reviewed-by: Martin Roth <martin@se-eng.com> Reviewed-by: Ronald G. Minnich <rminnich@gmail.com>
2012-12-19 01:23:28 +01:00
#define CBMEM_ID_COVERAGE 0x47434f56
cbmem: add CBMEM_ID_ROMSTAGE_INFO id Introduce a new cbmem id to indicate romstage information. Proper coordination with ramstage and romstage can use this cbmem entity to communicate between one another. Change-Id: Id785f429eeff5b015188c36eb932e6a6ce122da8 Signed-off-by: Aaron Durbin <adurbin@chromium.org> Reviewed-on: http://review.coreboot.org/2790 Tested-by: build bot (Jenkins) Reviewed-by: Marc Jones <marc.jones@se-eng.com>
2013-02-09 00:11:28 +01:00
#define CBMEM_ID_ROMSTAGE_INFO 0x47545352
cbmem: dynamic cbmem support This patch adds a parallel implementation of cbmem that supports dynamic sizing. The original implementation relied on reserving a fixed-size block of memory for adding cbmem entries. In order to allow for more flexibility for adding cbmem allocations the dynamic cbmem infrastructure was developed as an alternative to the fixed block approach. Also, the amount of memory to reserve for cbmem allocations does not need to be known prior to the first allocation. The dynamic cbmem code implements the same API as the existing cbmem code except for cbmem_init() and cbmem_reinit(). The add and find routines behave the same way. The dynamic cbmem infrastructure uses a top down allocator that starts allocating from a board/chipset defined function cbmem_top(). A root pointer lives just below cbmem_top(). In turn that pointer points to the root block which contains the entries for all the large alloctations. The corresponding block for each large allocation falls just below the previous entry. It should be noted that this implementation rounds all allocations up to a 4096 byte granularity. Though a packing allocator could be written for small allocations it was deemed OK to just fragment the memory as there shouldn't be that many small allocations. The result is less code with a tradeoff of some wasted memory. +----------------------+ <- cbmem_top() | +----| root pointer | | | +----------------------+ | | | |--------+ | +--->| root block |-----+ | | +----------------------+ | | | | | | | | | | | | | | alloc N |<----+ | | +----------------------+ | | | | | | | | | \|/ | alloc N + 1 |<-------+ v +----------------------+ In addition to preserving the previous cbmem API, the dynamic cbmem API allows for removing blocks from cbmem. This allows for the boot process to allocate memory that can be discarded after it's been used for performing more complex boot tasks in romstage. In order to plumb this support in there were some issues to work around regarding writing of coreboot tables. There were a few assumptions to how cbmem was layed out which dictated some ifdef guarding and other runtime checks so as not to incorrectly tag the e820 and coreboot memory tables. The example shown below is using dynamic cbmem infrastructure. The reserved memory for cbmem is less than 512KiB. coreboot memory table: 0. 0000000000000000-0000000000000fff: CONFIGURATION TABLES 1. 0000000000001000-000000000002ffff: RAM 2. 0000000000030000-000000000003ffff: RESERVED 3. 0000000000040000-000000000009ffff: RAM 4. 00000000000a0000-00000000000fffff: RESERVED 5. 0000000000100000-0000000000efffff: RAM 6. 0000000000f00000-0000000000ffffff: RESERVED 7. 0000000001000000-000000007bf80fff: RAM 8. 000000007bf81000-000000007bffffff: CONFIGURATION TABLES 9. 000000007c000000-000000007e9fffff: RESERVED 10. 00000000f0000000-00000000f3ffffff: RESERVED 11. 00000000fed10000-00000000fed19fff: RESERVED 12. 00000000fed84000-00000000fed84fff: RESERVED 13. 0000000100000000-00000001005fffff: RAM Wrote coreboot table at: 7bf81000, 0x39c bytes, checksum f5bf coreboot table: 948 bytes. CBMEM ROOT 0. 7bfff000 00001000 MRC DATA 1. 7bffe000 00001000 ROMSTAGE 2. 7bffd000 00001000 TIME STAMP 3. 7bffc000 00001000 ROMSTG STCK 4. 7bff7000 00005000 CONSOLE 5. 7bfe7000 00010000 VBOOT 6. 7bfe6000 00001000 RAMSTAGE 7. 7bf98000 0004e000 GDT 8. 7bf97000 00001000 ACPI 9. 7bf8b000 0000c000 ACPI GNVS 10. 7bf8a000 00001000 SMBIOS 11. 7bf89000 00001000 COREBOOT 12. 7bf81000 00008000 And the corresponding e820 entries: BIOS-e820: [mem 0x0000000000000000-0x0000000000000fff] type 16 BIOS-e820: [mem 0x0000000000001000-0x000000000002ffff] usable BIOS-e820: [mem 0x0000000000030000-0x000000000003ffff] reserved BIOS-e820: [mem 0x0000000000040000-0x000000000009ffff] usable BIOS-e820: [mem 0x00000000000a0000-0x00000000000fffff] reserved BIOS-e820: [mem 0x0000000000100000-0x0000000000efffff] usable BIOS-e820: [mem 0x0000000000f00000-0x0000000000ffffff] reserved BIOS-e820: [mem 0x0000000001000000-0x000000007bf80fff] usable BIOS-e820: [mem 0x000000007bf81000-0x000000007bffffff] type 16 BIOS-e820: [mem 0x000000007c000000-0x000000007e9fffff] reserved BIOS-e820: [mem 0x00000000f0000000-0x00000000f3ffffff] reserved BIOS-e820: [mem 0x00000000fed10000-0x00000000fed19fff] reserved BIOS-e820: [mem 0x00000000fed84000-0x00000000fed84fff] reserved BIOS-e820: [mem 0x0000000100000000-0x00000001005fffff] usable Change-Id: Ie3bca52211800a8652a77ca684140cfc9b3b9a6b Signed-off-by: Aaron Durbin <adurbin@chromium.org> Reviewed-on: http://review.coreboot.org/2848 Tested-by: build bot (Jenkins) Reviewed-by: Ronald G. Minnich <rminnich@gmail.com>
2013-03-13 18:41:44 +01:00
#define CBMEM_ID_ROMSTAGE_RAM_STACK 0x90357ac4
#define CBMEM_ID_RAMSTAGE 0x9a357a9e
#define CBMEM_ID_RAMSTAGE_CACHE 0x9a3ca54e
#define CBMEM_ID_ROOT 0xff4007ff
cbmem: add vboot cmbem id The vboot firmware selection from romstage will need to pass the resulting vboot data to other consumers. This will be done using a cbmem entry. Change-Id: I497caba53f9f3944513382f3929d21b04bf3ba9e Signed-off-by: Aaron Durbin <adurbin@chromium.org> Reviewed-on: http://review.coreboot.org/2851 Tested-by: build bot (Jenkins) Reviewed-by: Ronald G. Minnich <rminnich@gmail.com>
2013-03-13 18:48:33 +01:00
#define CBMEM_ID_VBOOT_HANDOFF 0x780074f0
x86: add cache-as-ram migration option There are some boards that do a significant amount of work after cache-as-ram is torn down but before ramstage is loaded. For example, using vboot to verify the ramstage is one such operation. However, there are pieces of code that are executed that reference global variables that are linked in the cache-as-ram region. If those variables are referenced after cache-as-ram is torn down then the values observed will most likely be incorrect. Therefore provide a Kconfig option to select cache-as-ram migration to memory using cbmem. This option is named CAR_MIGRATION. When enabled, the address of cache-as-ram variables may be obtained dynamically. Additionally, when cache-as-ram migration occurs the cache-as-ram data region for global variables is copied into cbmem. There are also automatic callbacks for other modules to perform their own migration, if necessary. Change-Id: I2e77219647c2bd2b1aa845b262be3b2543f1fcb7 Signed-off-by: Aaron Durbin <adurbin@chromium.org> Reviewed-on: http://review.coreboot.org/3232 Reviewed-by: Paul Menzel <paulepanter@users.sourceforge.net> Tested-by: build bot (Jenkins) Reviewed-by: Stefan Reinauer <stefan.reinauer@coreboot.org>
2013-05-10 07:33:32 +02:00
#define CBMEM_ID_CAR_GLOBALS 0xcac4e6a3
usbdebug: Use CAR migration If we already initialized EHCI controller and USB device in romstage, locate active configuration from salvaged CAR_GLOBAL and avoid doing the hardware initialisation again. Change-Id: I7cb3a359488b25abc9de49c96c0197f6563a4a2c Signed-off-by: Kyösti Mälkki <kyosti.malkki@gmail.com> Reviewed-on: http://review.coreboot.org/3476 Tested-by: build bot (Jenkins) Reviewed-by: Aaron Durbin <adurbin@google.com>
2013-07-06 10:41:21 +02:00
#define CBMEM_ID_EHCI_DEBUG 0xe4c1deb9
CBMEM high table memory manager. This code adds a very simple toc based memory manager for the high tables area. The purpose of this code is to make it simpler and more reliable to find certain data structures in memory. This will also make it possible to have ACPI S3 Resume working without an ugly hole at 31MB. Signed-off-by: Stefan Reinauer <stepan@coresystems.de> Acked-by: Peter Stuge <peter@stuge.se> git-svn-id: svn://svn.coreboot.org/coreboot/trunk@4860 2b7e53f0-3cfb-0310-b3e9-8179ed1497e1
2009-10-26 18:04:28 +01:00
#define CBMEM_ID_NONE 0x00000000
AMD Fam15tn: Add support for AGESA runtime allocation in CBMEM The IOMMU AGESA needs a reserved scratch space and it wants to allocate the stuff for runtime. So provide a simple allocator for 4 KB CBMEM page. Change-Id: I53bdfcd2cd69f84fbfbc6edea53a051f516c05cc Signed-off-by: Rudolf Marek <r.marek@assembler.cz> Reviewed-on: http://review.coreboot.org/3315 Tested-by: build bot (Jenkins) Reviewed-by: Paul Menzel <paulepanter@users.sourceforge.net> Reviewed-by: Ronald G. Minnich <rminnich@gmail.com>
2013-05-27 16:09:44 +02:00
#define CBMEM_ID_AGESA_RUNTIME 0x41474553
CBMEM high table memory manager. This code adds a very simple toc based memory manager for the high tables area. The purpose of this code is to make it simpler and more reliable to find certain data structures in memory. This will also make it possible to have ACPI S3 Resume working without an ugly hole at 31MB. Signed-off-by: Stefan Reinauer <stepan@coresystems.de> Acked-by: Peter Stuge <peter@stuge.se> git-svn-id: svn://svn.coreboot.org/coreboot/trunk@4860 2b7e53f0-3cfb-0310-b3e9-8179ed1497e1
2009-10-26 18:04:28 +01:00
Add constants for fast path resume copying cache as ram does not usually cache the ram before it is up. Hence, if romstage.c backs up resume memory, the involved memcpy is always uncached. This makes resume very slow. On Sandybridge we copy the memory later, after enabling caching, and that allows us to resume in as little as 250ms. Change-Id: I31a71ad4468679d39880cf9a8c4e497bb7addf8f Signed-off-by: Stefan Reinauer <reinauer@google.com> Reviewed-on: http://review.coreboot.org/872 Reviewed-by: Ronald G. Minnich <rminnich@gmail.com> Tested-by: build bot (Jenkins)
2012-04-04 01:21:04 +02:00
#ifndef __ASSEMBLER__
cbmem: dynamic cbmem support This patch adds a parallel implementation of cbmem that supports dynamic sizing. The original implementation relied on reserving a fixed-size block of memory for adding cbmem entries. In order to allow for more flexibility for adding cbmem allocations the dynamic cbmem infrastructure was developed as an alternative to the fixed block approach. Also, the amount of memory to reserve for cbmem allocations does not need to be known prior to the first allocation. The dynamic cbmem code implements the same API as the existing cbmem code except for cbmem_init() and cbmem_reinit(). The add and find routines behave the same way. The dynamic cbmem infrastructure uses a top down allocator that starts allocating from a board/chipset defined function cbmem_top(). A root pointer lives just below cbmem_top(). In turn that pointer points to the root block which contains the entries for all the large alloctations. The corresponding block for each large allocation falls just below the previous entry. It should be noted that this implementation rounds all allocations up to a 4096 byte granularity. Though a packing allocator could be written for small allocations it was deemed OK to just fragment the memory as there shouldn't be that many small allocations. The result is less code with a tradeoff of some wasted memory. +----------------------+ <- cbmem_top() | +----| root pointer | | | +----------------------+ | | | |--------+ | +--->| root block |-----+ | | +----------------------+ | | | | | | | | | | | | | | alloc N |<----+ | | +----------------------+ | | | | | | | | | \|/ | alloc N + 1 |<-------+ v +----------------------+ In addition to preserving the previous cbmem API, the dynamic cbmem API allows for removing blocks from cbmem. This allows for the boot process to allocate memory that can be discarded after it's been used for performing more complex boot tasks in romstage. In order to plumb this support in there were some issues to work around regarding writing of coreboot tables. There were a few assumptions to how cbmem was layed out which dictated some ifdef guarding and other runtime checks so as not to incorrectly tag the e820 and coreboot memory tables. The example shown below is using dynamic cbmem infrastructure. The reserved memory for cbmem is less than 512KiB. coreboot memory table: 0. 0000000000000000-0000000000000fff: CONFIGURATION TABLES 1. 0000000000001000-000000000002ffff: RAM 2. 0000000000030000-000000000003ffff: RESERVED 3. 0000000000040000-000000000009ffff: RAM 4. 00000000000a0000-00000000000fffff: RESERVED 5. 0000000000100000-0000000000efffff: RAM 6. 0000000000f00000-0000000000ffffff: RESERVED 7. 0000000001000000-000000007bf80fff: RAM 8. 000000007bf81000-000000007bffffff: CONFIGURATION TABLES 9. 000000007c000000-000000007e9fffff: RESERVED 10. 00000000f0000000-00000000f3ffffff: RESERVED 11. 00000000fed10000-00000000fed19fff: RESERVED 12. 00000000fed84000-00000000fed84fff: RESERVED 13. 0000000100000000-00000001005fffff: RAM Wrote coreboot table at: 7bf81000, 0x39c bytes, checksum f5bf coreboot table: 948 bytes. CBMEM ROOT 0. 7bfff000 00001000 MRC DATA 1. 7bffe000 00001000 ROMSTAGE 2. 7bffd000 00001000 TIME STAMP 3. 7bffc000 00001000 ROMSTG STCK 4. 7bff7000 00005000 CONSOLE 5. 7bfe7000 00010000 VBOOT 6. 7bfe6000 00001000 RAMSTAGE 7. 7bf98000 0004e000 GDT 8. 7bf97000 00001000 ACPI 9. 7bf8b000 0000c000 ACPI GNVS 10. 7bf8a000 00001000 SMBIOS 11. 7bf89000 00001000 COREBOOT 12. 7bf81000 00008000 And the corresponding e820 entries: BIOS-e820: [mem 0x0000000000000000-0x0000000000000fff] type 16 BIOS-e820: [mem 0x0000000000001000-0x000000000002ffff] usable BIOS-e820: [mem 0x0000000000030000-0x000000000003ffff] reserved BIOS-e820: [mem 0x0000000000040000-0x000000000009ffff] usable BIOS-e820: [mem 0x00000000000a0000-0x00000000000fffff] reserved BIOS-e820: [mem 0x0000000000100000-0x0000000000efffff] usable BIOS-e820: [mem 0x0000000000f00000-0x0000000000ffffff] reserved BIOS-e820: [mem 0x0000000001000000-0x000000007bf80fff] usable BIOS-e820: [mem 0x000000007bf81000-0x000000007bffffff] type 16 BIOS-e820: [mem 0x000000007c000000-0x000000007e9fffff] reserved BIOS-e820: [mem 0x00000000f0000000-0x00000000f3ffffff] reserved BIOS-e820: [mem 0x00000000fed10000-0x00000000fed19fff] reserved BIOS-e820: [mem 0x00000000fed84000-0x00000000fed84fff] reserved BIOS-e820: [mem 0x0000000100000000-0x00000001005fffff] usable Change-Id: Ie3bca52211800a8652a77ca684140cfc9b3b9a6b Signed-off-by: Aaron Durbin <adurbin@chromium.org> Reviewed-on: http://review.coreboot.org/2848 Tested-by: build bot (Jenkins) Reviewed-by: Ronald G. Minnich <rminnich@gmail.com>
2013-03-13 18:41:44 +01:00
#include <stdint.h>
struct cbmem_entry;
#if CONFIG_DYNAMIC_CBMEM
/*
* The dynamic cbmem infrastructure allows for growing cbmem dynamically as
* things are added. It requires an external function, cbmem_top(), to be
* implemented by the board or chipset to define the upper address where
* cbmem lives. This address is required to be a 32-bit address. Additionally,
* the address needs to be consistent in both romstage and ramstage. The
include: Fix spelling Change-Id: Iadc813bc8208278996b2b1aa20cfb156ec06fac9 Signed-off-by: Martin Roth <martin.roth@se-eng.com> Reviewed-on: http://review.coreboot.org/3755 Tested-by: build bot (Jenkins) Reviewed-by: Stefan Reinauer <stefan.reinauer@coreboot.org>
2013-07-10 05:46:01 +02:00
* dynamic cbmem infrastructure allocates new regions below the last allocated
cbmem: dynamic cbmem support This patch adds a parallel implementation of cbmem that supports dynamic sizing. The original implementation relied on reserving a fixed-size block of memory for adding cbmem entries. In order to allow for more flexibility for adding cbmem allocations the dynamic cbmem infrastructure was developed as an alternative to the fixed block approach. Also, the amount of memory to reserve for cbmem allocations does not need to be known prior to the first allocation. The dynamic cbmem code implements the same API as the existing cbmem code except for cbmem_init() and cbmem_reinit(). The add and find routines behave the same way. The dynamic cbmem infrastructure uses a top down allocator that starts allocating from a board/chipset defined function cbmem_top(). A root pointer lives just below cbmem_top(). In turn that pointer points to the root block which contains the entries for all the large alloctations. The corresponding block for each large allocation falls just below the previous entry. It should be noted that this implementation rounds all allocations up to a 4096 byte granularity. Though a packing allocator could be written for small allocations it was deemed OK to just fragment the memory as there shouldn't be that many small allocations. The result is less code with a tradeoff of some wasted memory. +----------------------+ <- cbmem_top() | +----| root pointer | | | +----------------------+ | | | |--------+ | +--->| root block |-----+ | | +----------------------+ | | | | | | | | | | | | | | alloc N |<----+ | | +----------------------+ | | | | | | | | | \|/ | alloc N + 1 |<-------+ v +----------------------+ In addition to preserving the previous cbmem API, the dynamic cbmem API allows for removing blocks from cbmem. This allows for the boot process to allocate memory that can be discarded after it's been used for performing more complex boot tasks in romstage. In order to plumb this support in there were some issues to work around regarding writing of coreboot tables. There were a few assumptions to how cbmem was layed out which dictated some ifdef guarding and other runtime checks so as not to incorrectly tag the e820 and coreboot memory tables. The example shown below is using dynamic cbmem infrastructure. The reserved memory for cbmem is less than 512KiB. coreboot memory table: 0. 0000000000000000-0000000000000fff: CONFIGURATION TABLES 1. 0000000000001000-000000000002ffff: RAM 2. 0000000000030000-000000000003ffff: RESERVED 3. 0000000000040000-000000000009ffff: RAM 4. 00000000000a0000-00000000000fffff: RESERVED 5. 0000000000100000-0000000000efffff: RAM 6. 0000000000f00000-0000000000ffffff: RESERVED 7. 0000000001000000-000000007bf80fff: RAM 8. 000000007bf81000-000000007bffffff: CONFIGURATION TABLES 9. 000000007c000000-000000007e9fffff: RESERVED 10. 00000000f0000000-00000000f3ffffff: RESERVED 11. 00000000fed10000-00000000fed19fff: RESERVED 12. 00000000fed84000-00000000fed84fff: RESERVED 13. 0000000100000000-00000001005fffff: RAM Wrote coreboot table at: 7bf81000, 0x39c bytes, checksum f5bf coreboot table: 948 bytes. CBMEM ROOT 0. 7bfff000 00001000 MRC DATA 1. 7bffe000 00001000 ROMSTAGE 2. 7bffd000 00001000 TIME STAMP 3. 7bffc000 00001000 ROMSTG STCK 4. 7bff7000 00005000 CONSOLE 5. 7bfe7000 00010000 VBOOT 6. 7bfe6000 00001000 RAMSTAGE 7. 7bf98000 0004e000 GDT 8. 7bf97000 00001000 ACPI 9. 7bf8b000 0000c000 ACPI GNVS 10. 7bf8a000 00001000 SMBIOS 11. 7bf89000 00001000 COREBOOT 12. 7bf81000 00008000 And the corresponding e820 entries: BIOS-e820: [mem 0x0000000000000000-0x0000000000000fff] type 16 BIOS-e820: [mem 0x0000000000001000-0x000000000002ffff] usable BIOS-e820: [mem 0x0000000000030000-0x000000000003ffff] reserved BIOS-e820: [mem 0x0000000000040000-0x000000000009ffff] usable BIOS-e820: [mem 0x00000000000a0000-0x00000000000fffff] reserved BIOS-e820: [mem 0x0000000000100000-0x0000000000efffff] usable BIOS-e820: [mem 0x0000000000f00000-0x0000000000ffffff] reserved BIOS-e820: [mem 0x0000000001000000-0x000000007bf80fff] usable BIOS-e820: [mem 0x000000007bf81000-0x000000007bffffff] type 16 BIOS-e820: [mem 0x000000007c000000-0x000000007e9fffff] reserved BIOS-e820: [mem 0x00000000f0000000-0x00000000f3ffffff] reserved BIOS-e820: [mem 0x00000000fed10000-0x00000000fed19fff] reserved BIOS-e820: [mem 0x00000000fed84000-0x00000000fed84fff] reserved BIOS-e820: [mem 0x0000000100000000-0x00000001005fffff] usable Change-Id: Ie3bca52211800a8652a77ca684140cfc9b3b9a6b Signed-off-by: Aaron Durbin <adurbin@chromium.org> Reviewed-on: http://review.coreboot.org/2848 Tested-by: build bot (Jenkins) Reviewed-by: Ronald G. Minnich <rminnich@gmail.com>
2013-03-13 18:41:44 +01:00
* region. Regions are defined by a cbmem_entry struct that is opaque. Regions
* may be removed, but the last one added is the only that can be removed.
*
* Dynamic cbmem has two allocators within it. All allocators use a top down
* allocation scheme. However, there are 2 modes for each allocation depending
* on the requested size. There are large allocations and small allocations.
* An allocation is considered to be small when it is less than or equal to
* DYN_CBMEM_ALIGN_SIZE / 2. The smaller allocations are fit into a larger
* allocation region.
*/
#define DYN_CBMEM_ALIGN_SIZE (4096)
include: Fix spelling Change-Id: Iadc813bc8208278996b2b1aa20cfb156ec06fac9 Signed-off-by: Martin Roth <martin.roth@se-eng.com> Reviewed-on: http://review.coreboot.org/3755 Tested-by: build bot (Jenkins) Reviewed-by: Stefan Reinauer <stefan.reinauer@coreboot.org>
2013-07-10 05:46:01 +02:00
/* Initialize cbmem to be empty. */
cbmem: dynamic cbmem support This patch adds a parallel implementation of cbmem that supports dynamic sizing. The original implementation relied on reserving a fixed-size block of memory for adding cbmem entries. In order to allow for more flexibility for adding cbmem allocations the dynamic cbmem infrastructure was developed as an alternative to the fixed block approach. Also, the amount of memory to reserve for cbmem allocations does not need to be known prior to the first allocation. The dynamic cbmem code implements the same API as the existing cbmem code except for cbmem_init() and cbmem_reinit(). The add and find routines behave the same way. The dynamic cbmem infrastructure uses a top down allocator that starts allocating from a board/chipset defined function cbmem_top(). A root pointer lives just below cbmem_top(). In turn that pointer points to the root block which contains the entries for all the large alloctations. The corresponding block for each large allocation falls just below the previous entry. It should be noted that this implementation rounds all allocations up to a 4096 byte granularity. Though a packing allocator could be written for small allocations it was deemed OK to just fragment the memory as there shouldn't be that many small allocations. The result is less code with a tradeoff of some wasted memory. +----------------------+ <- cbmem_top() | +----| root pointer | | | +----------------------+ | | | |--------+ | +--->| root block |-----+ | | +----------------------+ | | | | | | | | | | | | | | alloc N |<----+ | | +----------------------+ | | | | | | | | | \|/ | alloc N + 1 |<-------+ v +----------------------+ In addition to preserving the previous cbmem API, the dynamic cbmem API allows for removing blocks from cbmem. This allows for the boot process to allocate memory that can be discarded after it's been used for performing more complex boot tasks in romstage. In order to plumb this support in there were some issues to work around regarding writing of coreboot tables. There were a few assumptions to how cbmem was layed out which dictated some ifdef guarding and other runtime checks so as not to incorrectly tag the e820 and coreboot memory tables. The example shown below is using dynamic cbmem infrastructure. The reserved memory for cbmem is less than 512KiB. coreboot memory table: 0. 0000000000000000-0000000000000fff: CONFIGURATION TABLES 1. 0000000000001000-000000000002ffff: RAM 2. 0000000000030000-000000000003ffff: RESERVED 3. 0000000000040000-000000000009ffff: RAM 4. 00000000000a0000-00000000000fffff: RESERVED 5. 0000000000100000-0000000000efffff: RAM 6. 0000000000f00000-0000000000ffffff: RESERVED 7. 0000000001000000-000000007bf80fff: RAM 8. 000000007bf81000-000000007bffffff: CONFIGURATION TABLES 9. 000000007c000000-000000007e9fffff: RESERVED 10. 00000000f0000000-00000000f3ffffff: RESERVED 11. 00000000fed10000-00000000fed19fff: RESERVED 12. 00000000fed84000-00000000fed84fff: RESERVED 13. 0000000100000000-00000001005fffff: RAM Wrote coreboot table at: 7bf81000, 0x39c bytes, checksum f5bf coreboot table: 948 bytes. CBMEM ROOT 0. 7bfff000 00001000 MRC DATA 1. 7bffe000 00001000 ROMSTAGE 2. 7bffd000 00001000 TIME STAMP 3. 7bffc000 00001000 ROMSTG STCK 4. 7bff7000 00005000 CONSOLE 5. 7bfe7000 00010000 VBOOT 6. 7bfe6000 00001000 RAMSTAGE 7. 7bf98000 0004e000 GDT 8. 7bf97000 00001000 ACPI 9. 7bf8b000 0000c000 ACPI GNVS 10. 7bf8a000 00001000 SMBIOS 11. 7bf89000 00001000 COREBOOT 12. 7bf81000 00008000 And the corresponding e820 entries: BIOS-e820: [mem 0x0000000000000000-0x0000000000000fff] type 16 BIOS-e820: [mem 0x0000000000001000-0x000000000002ffff] usable BIOS-e820: [mem 0x0000000000030000-0x000000000003ffff] reserved BIOS-e820: [mem 0x0000000000040000-0x000000000009ffff] usable BIOS-e820: [mem 0x00000000000a0000-0x00000000000fffff] reserved BIOS-e820: [mem 0x0000000000100000-0x0000000000efffff] usable BIOS-e820: [mem 0x0000000000f00000-0x0000000000ffffff] reserved BIOS-e820: [mem 0x0000000001000000-0x000000007bf80fff] usable BIOS-e820: [mem 0x000000007bf81000-0x000000007bffffff] type 16 BIOS-e820: [mem 0x000000007c000000-0x000000007e9fffff] reserved BIOS-e820: [mem 0x00000000f0000000-0x00000000f3ffffff] reserved BIOS-e820: [mem 0x00000000fed10000-0x00000000fed19fff] reserved BIOS-e820: [mem 0x00000000fed84000-0x00000000fed84fff] reserved BIOS-e820: [mem 0x0000000100000000-0x00000001005fffff] usable Change-Id: Ie3bca52211800a8652a77ca684140cfc9b3b9a6b Signed-off-by: Aaron Durbin <adurbin@chromium.org> Reviewed-on: http://review.coreboot.org/2848 Tested-by: build bot (Jenkins) Reviewed-by: Ronald G. Minnich <rminnich@gmail.com>
2013-03-13 18:41:44 +01:00
void cbmem_initialize_empty(void);
/* Return the top address for dynamic cbmem. The address returned needs to
* be consistent across romstage and ramstage, and it is required to be
* below 4GiB. */
void *cbmem_top(void);
/* Add a cbmem entry of a given size and id. These return NULL on failure. The
* add function performs a find first and do not check against the original
* size. */
const struct cbmem_entry *cbmem_entry_add(u32 id, u64 size);
/* Find a cbmem entry of a given id. These return NULL on failure. */
const struct cbmem_entry *cbmem_entry_find(u32 id);
/* Remove a region defined by a cbmem_entry. Returns 0 on success, < 0 on
* error. Note: A cbmem_entry cannot be removed unless it was the last one
* added. */
int cbmem_entry_remove(const struct cbmem_entry *entry);
/* cbmem_entry accessors to get pointer and size of a cbmem_entry. */
void *cbmem_entry_start(const struct cbmem_entry *entry);
u64 cbmem_entry_size(const struct cbmem_entry *entry);
#else /* !CONFIG_DYNAMIC_CBMEM */
Add constants for fast path resume copying cache as ram does not usually cache the ram before it is up. Hence, if romstage.c backs up resume memory, the involved memcpy is always uncached. This makes resume very slow. On Sandybridge we copy the memory later, after enabling caching, and that allows us to resume in as little as 250ms. Change-Id: I31a71ad4468679d39880cf9a8c4e497bb7addf8f Signed-off-by: Stefan Reinauer <reinauer@google.com> Reviewed-on: http://review.coreboot.org/872 Reviewed-by: Ronald G. Minnich <rminnich@gmail.com> Tested-by: build bot (Jenkins)
2012-04-04 01:21:04 +02:00
#ifndef __PRE_RAM__
extern uint64_t high_tables_base, high_tables_size;
CBMEM AMD: Fix calls to set_top_of_ram_once() We can postpone the call to set_top_of_ram_once() outside the loops and make just one call instead. As set_top_of_ram() is now only called once, it is no longer necessary to check if high_tables_base was already set. Change-Id: I302d9af52ac40c7fa8c7c7e65f82e00b031cd397 Signed-off-by: Kyösti Mälkki <kyosti.malkki@gmail.com> Reviewed-on: http://review.coreboot.org/3895 Tested-by: build bot (Jenkins) Reviewed-by: Stefan Reinauer <stefan.reinauer@coreboot.org>
2013-09-03 04:25:57 +02:00
void set_top_of_ram(uint64_t ramtop);
CBMEM: Backup top_of_ram instead of cbmem_toc AMD northbridges have a complex way to resolve top_of_ram. Once it is resolved, it is stored in NVRAM to be used on resume. TODO: Redesign these get_top_of_ram() functions from scratch. Change-Id: I3cceb7e9b8b07620dacf138e99f98dc818c65341 Signed-off-by: Kyösti Mälkki <kyosti.malkki@gmail.com> Reviewed-on: http://review.coreboot.org/3557 Tested-by: build bot (Jenkins) Reviewed-by: Aaron Durbin <adurbin@google.com>
2013-09-04 12:26:11 +02:00
void backup_top_of_ram(uint64_t ramtop);
CBMEM: Add cbmem_late_set_table() and drop references to high_tables_base This helper function is for compatibility only for chipsets that do not implement get_top_of_ram() to support early CBMEM. Also remove references to globals high_tables_base and _size under arch/ and from two ARMv7 boards. Change-Id: I17eee30635a0368b2ada06e0698425c5ef0ecc53 Signed-off-by: Kyösti Mälkki <kyosti.malkki@gmail.com> Reviewed-on: http://review.coreboot.org/3902 Tested-by: build bot (Jenkins) Reviewed-by: Stefan Reinauer <stefan.reinauer@coreboot.org> Reviewed-by: Aaron Durbin <adurbin@google.com>
2013-09-04 12:05:01 +02:00
void cbmem_late_set_table(uint64_t base, uint64_t size);
CBMEM tables: Remove references to global high_tables_base Unify checks and writing of CBMEM tables for x86 and ARMv7. Change-Id: I89c012bce1b86d0710748719a8840ec532ce6939 Signed-off-by: Kyösti Mälkki <kyosti.malkki@gmail.com> Reviewed-on: http://review.coreboot.org/3559 Tested-by: build bot (Jenkins) Reviewed-by: Stefan Reinauer <stefan.reinauer@coreboot.org> Reviewed-by: Aaron Durbin <adurbin@google.com>
2013-09-04 13:11:08 +02:00
int cbmem_base_check(void);
Add constants for fast path resume copying cache as ram does not usually cache the ram before it is up. Hence, if romstage.c backs up resume memory, the involved memcpy is always uncached. This makes resume very slow. On Sandybridge we copy the memory later, after enabling caching, and that allows us to resume in as little as 250ms. Change-Id: I31a71ad4468679d39880cf9a8c4e497bb7addf8f Signed-off-by: Stefan Reinauer <reinauer@google.com> Reviewed-on: http://review.coreboot.org/872 Reviewed-by: Ronald G. Minnich <rminnich@gmail.com> Tested-by: build bot (Jenkins)
2012-04-04 01:21:04 +02:00
#endif
CBMEM high table memory manager. This code adds a very simple toc based memory manager for the high tables area. The purpose of this code is to make it simpler and more reliable to find certain data structures in memory. This will also make it possible to have ACPI S3 Resume working without an ugly hole at 31MB. Signed-off-by: Stefan Reinauer <stepan@coresystems.de> Acked-by: Peter Stuge <peter@stuge.se> git-svn-id: svn://svn.coreboot.org/coreboot/trunk@4860 2b7e53f0-3cfb-0310-b3e9-8179ed1497e1
2009-10-26 18:04:28 +01:00
void cbmem_init(u64 baseaddr, u64 size);
int cbmem_reinit(u64 baseaddr);
cbmem: dynamic cbmem support This patch adds a parallel implementation of cbmem that supports dynamic sizing. The original implementation relied on reserving a fixed-size block of memory for adding cbmem entries. In order to allow for more flexibility for adding cbmem allocations the dynamic cbmem infrastructure was developed as an alternative to the fixed block approach. Also, the amount of memory to reserve for cbmem allocations does not need to be known prior to the first allocation. The dynamic cbmem code implements the same API as the existing cbmem code except for cbmem_init() and cbmem_reinit(). The add and find routines behave the same way. The dynamic cbmem infrastructure uses a top down allocator that starts allocating from a board/chipset defined function cbmem_top(). A root pointer lives just below cbmem_top(). In turn that pointer points to the root block which contains the entries for all the large alloctations. The corresponding block for each large allocation falls just below the previous entry. It should be noted that this implementation rounds all allocations up to a 4096 byte granularity. Though a packing allocator could be written for small allocations it was deemed OK to just fragment the memory as there shouldn't be that many small allocations. The result is less code with a tradeoff of some wasted memory. +----------------------+ <- cbmem_top() | +----| root pointer | | | +----------------------+ | | | |--------+ | +--->| root block |-----+ | | +----------------------+ | | | | | | | | | | | | | | alloc N |<----+ | | +----------------------+ | | | | | | | | | \|/ | alloc N + 1 |<-------+ v +----------------------+ In addition to preserving the previous cbmem API, the dynamic cbmem API allows for removing blocks from cbmem. This allows for the boot process to allocate memory that can be discarded after it's been used for performing more complex boot tasks in romstage. In order to plumb this support in there were some issues to work around regarding writing of coreboot tables. There were a few assumptions to how cbmem was layed out which dictated some ifdef guarding and other runtime checks so as not to incorrectly tag the e820 and coreboot memory tables. The example shown below is using dynamic cbmem infrastructure. The reserved memory for cbmem is less than 512KiB. coreboot memory table: 0. 0000000000000000-0000000000000fff: CONFIGURATION TABLES 1. 0000000000001000-000000000002ffff: RAM 2. 0000000000030000-000000000003ffff: RESERVED 3. 0000000000040000-000000000009ffff: RAM 4. 00000000000a0000-00000000000fffff: RESERVED 5. 0000000000100000-0000000000efffff: RAM 6. 0000000000f00000-0000000000ffffff: RESERVED 7. 0000000001000000-000000007bf80fff: RAM 8. 000000007bf81000-000000007bffffff: CONFIGURATION TABLES 9. 000000007c000000-000000007e9fffff: RESERVED 10. 00000000f0000000-00000000f3ffffff: RESERVED 11. 00000000fed10000-00000000fed19fff: RESERVED 12. 00000000fed84000-00000000fed84fff: RESERVED 13. 0000000100000000-00000001005fffff: RAM Wrote coreboot table at: 7bf81000, 0x39c bytes, checksum f5bf coreboot table: 948 bytes. CBMEM ROOT 0. 7bfff000 00001000 MRC DATA 1. 7bffe000 00001000 ROMSTAGE 2. 7bffd000 00001000 TIME STAMP 3. 7bffc000 00001000 ROMSTG STCK 4. 7bff7000 00005000 CONSOLE 5. 7bfe7000 00010000 VBOOT 6. 7bfe6000 00001000 RAMSTAGE 7. 7bf98000 0004e000 GDT 8. 7bf97000 00001000 ACPI 9. 7bf8b000 0000c000 ACPI GNVS 10. 7bf8a000 00001000 SMBIOS 11. 7bf89000 00001000 COREBOOT 12. 7bf81000 00008000 And the corresponding e820 entries: BIOS-e820: [mem 0x0000000000000000-0x0000000000000fff] type 16 BIOS-e820: [mem 0x0000000000001000-0x000000000002ffff] usable BIOS-e820: [mem 0x0000000000030000-0x000000000003ffff] reserved BIOS-e820: [mem 0x0000000000040000-0x000000000009ffff] usable BIOS-e820: [mem 0x00000000000a0000-0x00000000000fffff] reserved BIOS-e820: [mem 0x0000000000100000-0x0000000000efffff] usable BIOS-e820: [mem 0x0000000000f00000-0x0000000000ffffff] reserved BIOS-e820: [mem 0x0000000001000000-0x000000007bf80fff] usable BIOS-e820: [mem 0x000000007bf81000-0x000000007bffffff] type 16 BIOS-e820: [mem 0x000000007c000000-0x000000007e9fffff] reserved BIOS-e820: [mem 0x00000000f0000000-0x00000000f3ffffff] reserved BIOS-e820: [mem 0x00000000fed10000-0x00000000fed19fff] reserved BIOS-e820: [mem 0x00000000fed84000-0x00000000fed84fff] reserved BIOS-e820: [mem 0x0000000100000000-0x00000001005fffff] usable Change-Id: Ie3bca52211800a8652a77ca684140cfc9b3b9a6b Signed-off-by: Aaron Durbin <adurbin@chromium.org> Reviewed-on: http://review.coreboot.org/2848 Tested-by: build bot (Jenkins) Reviewed-by: Ronald G. Minnich <rminnich@gmail.com>
2013-03-13 18:41:44 +01:00
CBMEM: Add cbmem_locate_table() For both romstage and ramstage, this calls an arch-specific function get_cbmem_table() to resolve the base and size of CBMEM region. In ramstage, the result is cached as the query may be relatively slow involving multiple PCI configuration reads. For x86 CBMEM tables are located right below top of low ram and have fixed size of HIGH_MEMORY_SIZE in EARLY_CBMEM_INIT implementation. Change-Id: Ie8d16eb30cd5c3860fff243f36bd4e7d8827a782 Signed-off-by: Kyösti Mälkki <kyosti.malkki@gmail.com> Reviewed-on: http://review.coreboot.org/3558 Tested-by: build bot (Jenkins) Reviewed-by: Aaron Durbin <adurbin@google.com>
2013-09-04 12:31:39 +02:00
void get_cbmem_table(uint64_t *base, uint64_t *size);
cbmem: dynamic cbmem support This patch adds a parallel implementation of cbmem that supports dynamic sizing. The original implementation relied on reserving a fixed-size block of memory for adding cbmem entries. In order to allow for more flexibility for adding cbmem allocations the dynamic cbmem infrastructure was developed as an alternative to the fixed block approach. Also, the amount of memory to reserve for cbmem allocations does not need to be known prior to the first allocation. The dynamic cbmem code implements the same API as the existing cbmem code except for cbmem_init() and cbmem_reinit(). The add and find routines behave the same way. The dynamic cbmem infrastructure uses a top down allocator that starts allocating from a board/chipset defined function cbmem_top(). A root pointer lives just below cbmem_top(). In turn that pointer points to the root block which contains the entries for all the large alloctations. The corresponding block for each large allocation falls just below the previous entry. It should be noted that this implementation rounds all allocations up to a 4096 byte granularity. Though a packing allocator could be written for small allocations it was deemed OK to just fragment the memory as there shouldn't be that many small allocations. The result is less code with a tradeoff of some wasted memory. +----------------------+ <- cbmem_top() | +----| root pointer | | | +----------------------+ | | | |--------+ | +--->| root block |-----+ | | +----------------------+ | | | | | | | | | | | | | | alloc N |<----+ | | +----------------------+ | | | | | | | | | \|/ | alloc N + 1 |<-------+ v +----------------------+ In addition to preserving the previous cbmem API, the dynamic cbmem API allows for removing blocks from cbmem. This allows for the boot process to allocate memory that can be discarded after it's been used for performing more complex boot tasks in romstage. In order to plumb this support in there were some issues to work around regarding writing of coreboot tables. There were a few assumptions to how cbmem was layed out which dictated some ifdef guarding and other runtime checks so as not to incorrectly tag the e820 and coreboot memory tables. The example shown below is using dynamic cbmem infrastructure. The reserved memory for cbmem is less than 512KiB. coreboot memory table: 0. 0000000000000000-0000000000000fff: CONFIGURATION TABLES 1. 0000000000001000-000000000002ffff: RAM 2. 0000000000030000-000000000003ffff: RESERVED 3. 0000000000040000-000000000009ffff: RAM 4. 00000000000a0000-00000000000fffff: RESERVED 5. 0000000000100000-0000000000efffff: RAM 6. 0000000000f00000-0000000000ffffff: RESERVED 7. 0000000001000000-000000007bf80fff: RAM 8. 000000007bf81000-000000007bffffff: CONFIGURATION TABLES 9. 000000007c000000-000000007e9fffff: RESERVED 10. 00000000f0000000-00000000f3ffffff: RESERVED 11. 00000000fed10000-00000000fed19fff: RESERVED 12. 00000000fed84000-00000000fed84fff: RESERVED 13. 0000000100000000-00000001005fffff: RAM Wrote coreboot table at: 7bf81000, 0x39c bytes, checksum f5bf coreboot table: 948 bytes. CBMEM ROOT 0. 7bfff000 00001000 MRC DATA 1. 7bffe000 00001000 ROMSTAGE 2. 7bffd000 00001000 TIME STAMP 3. 7bffc000 00001000 ROMSTG STCK 4. 7bff7000 00005000 CONSOLE 5. 7bfe7000 00010000 VBOOT 6. 7bfe6000 00001000 RAMSTAGE 7. 7bf98000 0004e000 GDT 8. 7bf97000 00001000 ACPI 9. 7bf8b000 0000c000 ACPI GNVS 10. 7bf8a000 00001000 SMBIOS 11. 7bf89000 00001000 COREBOOT 12. 7bf81000 00008000 And the corresponding e820 entries: BIOS-e820: [mem 0x0000000000000000-0x0000000000000fff] type 16 BIOS-e820: [mem 0x0000000000001000-0x000000000002ffff] usable BIOS-e820: [mem 0x0000000000030000-0x000000000003ffff] reserved BIOS-e820: [mem 0x0000000000040000-0x000000000009ffff] usable BIOS-e820: [mem 0x00000000000a0000-0x00000000000fffff] reserved BIOS-e820: [mem 0x0000000000100000-0x0000000000efffff] usable BIOS-e820: [mem 0x0000000000f00000-0x0000000000ffffff] reserved BIOS-e820: [mem 0x0000000001000000-0x000000007bf80fff] usable BIOS-e820: [mem 0x000000007bf81000-0x000000007bffffff] type 16 BIOS-e820: [mem 0x000000007c000000-0x000000007e9fffff] reserved BIOS-e820: [mem 0x00000000f0000000-0x00000000f3ffffff] reserved BIOS-e820: [mem 0x00000000fed10000-0x00000000fed19fff] reserved BIOS-e820: [mem 0x00000000fed84000-0x00000000fed84fff] reserved BIOS-e820: [mem 0x0000000100000000-0x00000001005fffff] usable Change-Id: Ie3bca52211800a8652a77ca684140cfc9b3b9a6b Signed-off-by: Aaron Durbin <adurbin@chromium.org> Reviewed-on: http://review.coreboot.org/2848 Tested-by: build bot (Jenkins) Reviewed-by: Ronald G. Minnich <rminnich@gmail.com>
2013-03-13 18:41:44 +01:00
extern struct cbmem_entry *get_cbmem_toc(void);
#endif /* CONFIG_DYNAMIC_CBMEM */
/* Common API between cbmem and dynamic cbmem. */
CBMEM: Unify get_top_of_ram() Change-Id: Ic40a51638873642f33c74d80ac41cf082b2fb177 Signed-off-by: Kyösti Mälkki <kyosti.malkki@gmail.com> Reviewed-on: http://review.coreboot.org/3904 Tested-by: build bot (Jenkins) Reviewed-by: Stefan Reinauer <stefan.reinauer@coreboot.org> Reviewed-by: Aaron Durbin <adurbin@google.com>
2013-09-04 00:11:16 +02:00
unsigned long get_top_of_ram(void);
cbmem: dynamic cbmem support This patch adds a parallel implementation of cbmem that supports dynamic sizing. The original implementation relied on reserving a fixed-size block of memory for adding cbmem entries. In order to allow for more flexibility for adding cbmem allocations the dynamic cbmem infrastructure was developed as an alternative to the fixed block approach. Also, the amount of memory to reserve for cbmem allocations does not need to be known prior to the first allocation. The dynamic cbmem code implements the same API as the existing cbmem code except for cbmem_init() and cbmem_reinit(). The add and find routines behave the same way. The dynamic cbmem infrastructure uses a top down allocator that starts allocating from a board/chipset defined function cbmem_top(). A root pointer lives just below cbmem_top(). In turn that pointer points to the root block which contains the entries for all the large alloctations. The corresponding block for each large allocation falls just below the previous entry. It should be noted that this implementation rounds all allocations up to a 4096 byte granularity. Though a packing allocator could be written for small allocations it was deemed OK to just fragment the memory as there shouldn't be that many small allocations. The result is less code with a tradeoff of some wasted memory. +----------------------+ <- cbmem_top() | +----| root pointer | | | +----------------------+ | | | |--------+ | +--->| root block |-----+ | | +----------------------+ | | | | | | | | | | | | | | alloc N |<----+ | | +----------------------+ | | | | | | | | | \|/ | alloc N + 1 |<-------+ v +----------------------+ In addition to preserving the previous cbmem API, the dynamic cbmem API allows for removing blocks from cbmem. This allows for the boot process to allocate memory that can be discarded after it's been used for performing more complex boot tasks in romstage. In order to plumb this support in there were some issues to work around regarding writing of coreboot tables. There were a few assumptions to how cbmem was layed out which dictated some ifdef guarding and other runtime checks so as not to incorrectly tag the e820 and coreboot memory tables. The example shown below is using dynamic cbmem infrastructure. The reserved memory for cbmem is less than 512KiB. coreboot memory table: 0. 0000000000000000-0000000000000fff: CONFIGURATION TABLES 1. 0000000000001000-000000000002ffff: RAM 2. 0000000000030000-000000000003ffff: RESERVED 3. 0000000000040000-000000000009ffff: RAM 4. 00000000000a0000-00000000000fffff: RESERVED 5. 0000000000100000-0000000000efffff: RAM 6. 0000000000f00000-0000000000ffffff: RESERVED 7. 0000000001000000-000000007bf80fff: RAM 8. 000000007bf81000-000000007bffffff: CONFIGURATION TABLES 9. 000000007c000000-000000007e9fffff: RESERVED 10. 00000000f0000000-00000000f3ffffff: RESERVED 11. 00000000fed10000-00000000fed19fff: RESERVED 12. 00000000fed84000-00000000fed84fff: RESERVED 13. 0000000100000000-00000001005fffff: RAM Wrote coreboot table at: 7bf81000, 0x39c bytes, checksum f5bf coreboot table: 948 bytes. CBMEM ROOT 0. 7bfff000 00001000 MRC DATA 1. 7bffe000 00001000 ROMSTAGE 2. 7bffd000 00001000 TIME STAMP 3. 7bffc000 00001000 ROMSTG STCK 4. 7bff7000 00005000 CONSOLE 5. 7bfe7000 00010000 VBOOT 6. 7bfe6000 00001000 RAMSTAGE 7. 7bf98000 0004e000 GDT 8. 7bf97000 00001000 ACPI 9. 7bf8b000 0000c000 ACPI GNVS 10. 7bf8a000 00001000 SMBIOS 11. 7bf89000 00001000 COREBOOT 12. 7bf81000 00008000 And the corresponding e820 entries: BIOS-e820: [mem 0x0000000000000000-0x0000000000000fff] type 16 BIOS-e820: [mem 0x0000000000001000-0x000000000002ffff] usable BIOS-e820: [mem 0x0000000000030000-0x000000000003ffff] reserved BIOS-e820: [mem 0x0000000000040000-0x000000000009ffff] usable BIOS-e820: [mem 0x00000000000a0000-0x00000000000fffff] reserved BIOS-e820: [mem 0x0000000000100000-0x0000000000efffff] usable BIOS-e820: [mem 0x0000000000f00000-0x0000000000ffffff] reserved BIOS-e820: [mem 0x0000000001000000-0x000000007bf80fff] usable BIOS-e820: [mem 0x000000007bf81000-0x000000007bffffff] type 16 BIOS-e820: [mem 0x000000007c000000-0x000000007e9fffff] reserved BIOS-e820: [mem 0x00000000f0000000-0x00000000f3ffffff] reserved BIOS-e820: [mem 0x00000000fed10000-0x00000000fed19fff] reserved BIOS-e820: [mem 0x00000000fed84000-0x00000000fed84fff] reserved BIOS-e820: [mem 0x0000000100000000-0x00000001005fffff] usable Change-Id: Ie3bca52211800a8652a77ca684140cfc9b3b9a6b Signed-off-by: Aaron Durbin <adurbin@chromium.org> Reviewed-on: http://review.coreboot.org/2848 Tested-by: build bot (Jenkins) Reviewed-by: Ronald G. Minnich <rminnich@gmail.com>
2013-03-13 18:41:44 +01:00
/* By default cbmem is attempted to be recovered. Returns 0 if cbmem was
* recovered or 1 if cbmem had to be reinitialized. */
int cbmem_initialize(void);
/* Add a cbmem entry of a given size and id. These return NULL on failure. The
* add function performs a find first and do not check against the original
* size. */
CBMEM high table memory manager. This code adds a very simple toc based memory manager for the high tables area. The purpose of this code is to make it simpler and more reliable to find certain data structures in memory. This will also make it possible to have ACPI S3 Resume working without an ugly hole at 31MB. Signed-off-by: Stefan Reinauer <stepan@coresystems.de> Acked-by: Peter Stuge <peter@stuge.se> git-svn-id: svn://svn.coreboot.org/coreboot/trunk@4860 2b7e53f0-3cfb-0310-b3e9-8179ed1497e1
2009-10-26 18:04:28 +01:00
void *cbmem_add(u32 id, u64 size);
cbmem: dynamic cbmem support This patch adds a parallel implementation of cbmem that supports dynamic sizing. The original implementation relied on reserving a fixed-size block of memory for adding cbmem entries. In order to allow for more flexibility for adding cbmem allocations the dynamic cbmem infrastructure was developed as an alternative to the fixed block approach. Also, the amount of memory to reserve for cbmem allocations does not need to be known prior to the first allocation. The dynamic cbmem code implements the same API as the existing cbmem code except for cbmem_init() and cbmem_reinit(). The add and find routines behave the same way. The dynamic cbmem infrastructure uses a top down allocator that starts allocating from a board/chipset defined function cbmem_top(). A root pointer lives just below cbmem_top(). In turn that pointer points to the root block which contains the entries for all the large alloctations. The corresponding block for each large allocation falls just below the previous entry. It should be noted that this implementation rounds all allocations up to a 4096 byte granularity. Though a packing allocator could be written for small allocations it was deemed OK to just fragment the memory as there shouldn't be that many small allocations. The result is less code with a tradeoff of some wasted memory. +----------------------+ <- cbmem_top() | +----| root pointer | | | +----------------------+ | | | |--------+ | +--->| root block |-----+ | | +----------------------+ | | | | | | | | | | | | | | alloc N |<----+ | | +----------------------+ | | | | | | | | | \|/ | alloc N + 1 |<-------+ v +----------------------+ In addition to preserving the previous cbmem API, the dynamic cbmem API allows for removing blocks from cbmem. This allows for the boot process to allocate memory that can be discarded after it's been used for performing more complex boot tasks in romstage. In order to plumb this support in there were some issues to work around regarding writing of coreboot tables. There were a few assumptions to how cbmem was layed out which dictated some ifdef guarding and other runtime checks so as not to incorrectly tag the e820 and coreboot memory tables. The example shown below is using dynamic cbmem infrastructure. The reserved memory for cbmem is less than 512KiB. coreboot memory table: 0. 0000000000000000-0000000000000fff: CONFIGURATION TABLES 1. 0000000000001000-000000000002ffff: RAM 2. 0000000000030000-000000000003ffff: RESERVED 3. 0000000000040000-000000000009ffff: RAM 4. 00000000000a0000-00000000000fffff: RESERVED 5. 0000000000100000-0000000000efffff: RAM 6. 0000000000f00000-0000000000ffffff: RESERVED 7. 0000000001000000-000000007bf80fff: RAM 8. 000000007bf81000-000000007bffffff: CONFIGURATION TABLES 9. 000000007c000000-000000007e9fffff: RESERVED 10. 00000000f0000000-00000000f3ffffff: RESERVED 11. 00000000fed10000-00000000fed19fff: RESERVED 12. 00000000fed84000-00000000fed84fff: RESERVED 13. 0000000100000000-00000001005fffff: RAM Wrote coreboot table at: 7bf81000, 0x39c bytes, checksum f5bf coreboot table: 948 bytes. CBMEM ROOT 0. 7bfff000 00001000 MRC DATA 1. 7bffe000 00001000 ROMSTAGE 2. 7bffd000 00001000 TIME STAMP 3. 7bffc000 00001000 ROMSTG STCK 4. 7bff7000 00005000 CONSOLE 5. 7bfe7000 00010000 VBOOT 6. 7bfe6000 00001000 RAMSTAGE 7. 7bf98000 0004e000 GDT 8. 7bf97000 00001000 ACPI 9. 7bf8b000 0000c000 ACPI GNVS 10. 7bf8a000 00001000 SMBIOS 11. 7bf89000 00001000 COREBOOT 12. 7bf81000 00008000 And the corresponding e820 entries: BIOS-e820: [mem 0x0000000000000000-0x0000000000000fff] type 16 BIOS-e820: [mem 0x0000000000001000-0x000000000002ffff] usable BIOS-e820: [mem 0x0000000000030000-0x000000000003ffff] reserved BIOS-e820: [mem 0x0000000000040000-0x000000000009ffff] usable BIOS-e820: [mem 0x00000000000a0000-0x00000000000fffff] reserved BIOS-e820: [mem 0x0000000000100000-0x0000000000efffff] usable BIOS-e820: [mem 0x0000000000f00000-0x0000000000ffffff] reserved BIOS-e820: [mem 0x0000000001000000-0x000000007bf80fff] usable BIOS-e820: [mem 0x000000007bf81000-0x000000007bffffff] type 16 BIOS-e820: [mem 0x000000007c000000-0x000000007e9fffff] reserved BIOS-e820: [mem 0x00000000f0000000-0x00000000f3ffffff] reserved BIOS-e820: [mem 0x00000000fed10000-0x00000000fed19fff] reserved BIOS-e820: [mem 0x00000000fed84000-0x00000000fed84fff] reserved BIOS-e820: [mem 0x0000000100000000-0x00000001005fffff] usable Change-Id: Ie3bca52211800a8652a77ca684140cfc9b3b9a6b Signed-off-by: Aaron Durbin <adurbin@chromium.org> Reviewed-on: http://review.coreboot.org/2848 Tested-by: build bot (Jenkins) Reviewed-by: Ronald G. Minnich <rminnich@gmail.com>
2013-03-13 18:41:44 +01:00
/* Find a cbmem entry of a given id. These return NULL on failure. */
CBMEM high table memory manager. This code adds a very simple toc based memory manager for the high tables area. The purpose of this code is to make it simpler and more reliable to find certain data structures in memory. This will also make it possible to have ACPI S3 Resume working without an ugly hole at 31MB. Signed-off-by: Stefan Reinauer <stepan@coresystems.de> Acked-by: Peter Stuge <peter@stuge.se> git-svn-id: svn://svn.coreboot.org/coreboot/trunk@4860 2b7e53f0-3cfb-0310-b3e9-8179ed1497e1
2009-10-26 18:04:28 +01:00
void *cbmem_find(u32 id);
cbmem: dynamic cbmem support This patch adds a parallel implementation of cbmem that supports dynamic sizing. The original implementation relied on reserving a fixed-size block of memory for adding cbmem entries. In order to allow for more flexibility for adding cbmem allocations the dynamic cbmem infrastructure was developed as an alternative to the fixed block approach. Also, the amount of memory to reserve for cbmem allocations does not need to be known prior to the first allocation. The dynamic cbmem code implements the same API as the existing cbmem code except for cbmem_init() and cbmem_reinit(). The add and find routines behave the same way. The dynamic cbmem infrastructure uses a top down allocator that starts allocating from a board/chipset defined function cbmem_top(). A root pointer lives just below cbmem_top(). In turn that pointer points to the root block which contains the entries for all the large alloctations. The corresponding block for each large allocation falls just below the previous entry. It should be noted that this implementation rounds all allocations up to a 4096 byte granularity. Though a packing allocator could be written for small allocations it was deemed OK to just fragment the memory as there shouldn't be that many small allocations. The result is less code with a tradeoff of some wasted memory. +----------------------+ <- cbmem_top() | +----| root pointer | | | +----------------------+ | | | |--------+ | +--->| root block |-----+ | | +----------------------+ | | | | | | | | | | | | | | alloc N |<----+ | | +----------------------+ | | | | | | | | | \|/ | alloc N + 1 |<-------+ v +----------------------+ In addition to preserving the previous cbmem API, the dynamic cbmem API allows for removing blocks from cbmem. This allows for the boot process to allocate memory that can be discarded after it's been used for performing more complex boot tasks in romstage. In order to plumb this support in there were some issues to work around regarding writing of coreboot tables. There were a few assumptions to how cbmem was layed out which dictated some ifdef guarding and other runtime checks so as not to incorrectly tag the e820 and coreboot memory tables. The example shown below is using dynamic cbmem infrastructure. The reserved memory for cbmem is less than 512KiB. coreboot memory table: 0. 0000000000000000-0000000000000fff: CONFIGURATION TABLES 1. 0000000000001000-000000000002ffff: RAM 2. 0000000000030000-000000000003ffff: RESERVED 3. 0000000000040000-000000000009ffff: RAM 4. 00000000000a0000-00000000000fffff: RESERVED 5. 0000000000100000-0000000000efffff: RAM 6. 0000000000f00000-0000000000ffffff: RESERVED 7. 0000000001000000-000000007bf80fff: RAM 8. 000000007bf81000-000000007bffffff: CONFIGURATION TABLES 9. 000000007c000000-000000007e9fffff: RESERVED 10. 00000000f0000000-00000000f3ffffff: RESERVED 11. 00000000fed10000-00000000fed19fff: RESERVED 12. 00000000fed84000-00000000fed84fff: RESERVED 13. 0000000100000000-00000001005fffff: RAM Wrote coreboot table at: 7bf81000, 0x39c bytes, checksum f5bf coreboot table: 948 bytes. CBMEM ROOT 0. 7bfff000 00001000 MRC DATA 1. 7bffe000 00001000 ROMSTAGE 2. 7bffd000 00001000 TIME STAMP 3. 7bffc000 00001000 ROMSTG STCK 4. 7bff7000 00005000 CONSOLE 5. 7bfe7000 00010000 VBOOT 6. 7bfe6000 00001000 RAMSTAGE 7. 7bf98000 0004e000 GDT 8. 7bf97000 00001000 ACPI 9. 7bf8b000 0000c000 ACPI GNVS 10. 7bf8a000 00001000 SMBIOS 11. 7bf89000 00001000 COREBOOT 12. 7bf81000 00008000 And the corresponding e820 entries: BIOS-e820: [mem 0x0000000000000000-0x0000000000000fff] type 16 BIOS-e820: [mem 0x0000000000001000-0x000000000002ffff] usable BIOS-e820: [mem 0x0000000000030000-0x000000000003ffff] reserved BIOS-e820: [mem 0x0000000000040000-0x000000000009ffff] usable BIOS-e820: [mem 0x00000000000a0000-0x00000000000fffff] reserved BIOS-e820: [mem 0x0000000000100000-0x0000000000efffff] usable BIOS-e820: [mem 0x0000000000f00000-0x0000000000ffffff] reserved BIOS-e820: [mem 0x0000000001000000-0x000000007bf80fff] usable BIOS-e820: [mem 0x000000007bf81000-0x000000007bffffff] type 16 BIOS-e820: [mem 0x000000007c000000-0x000000007e9fffff] reserved BIOS-e820: [mem 0x00000000f0000000-0x00000000f3ffffff] reserved BIOS-e820: [mem 0x00000000fed10000-0x00000000fed19fff] reserved BIOS-e820: [mem 0x00000000fed84000-0x00000000fed84fff] reserved BIOS-e820: [mem 0x0000000100000000-0x00000001005fffff] usable Change-Id: Ie3bca52211800a8652a77ca684140cfc9b3b9a6b Signed-off-by: Aaron Durbin <adurbin@chromium.org> Reviewed-on: http://review.coreboot.org/2848 Tested-by: build bot (Jenkins) Reviewed-by: Ronald G. Minnich <rminnich@gmail.com>
2013-03-13 18:41:44 +01:00
#ifndef __PRE_RAM__
/* Ramstage only functions. */
CBMEM tables: Remove references to global high_tables_base Unify checks and writing of CBMEM tables for x86 and ARMv7. Change-Id: I89c012bce1b86d0710748719a8840ec532ce6939 Signed-off-by: Kyösti Mälkki <kyosti.malkki@gmail.com> Reviewed-on: http://review.coreboot.org/3559 Tested-by: build bot (Jenkins) Reviewed-by: Stefan Reinauer <stefan.reinauer@coreboot.org> Reviewed-by: Aaron Durbin <adurbin@google.com>
2013-09-04 13:11:08 +02:00
/* Add the cbmem memory used to the memory tables. */
struct lb_memory;
void cbmem_add_lb_mem(struct lb_memory *mem);
Add few missing prototypes, and remove few unused (thus lonelly) variables. TODO - x86emu need (imo) some common header with prototypes at least - clog2, ulzma, hardwaremain prototypes added by this patch probably should be moved to some header too. - in src/devices/device_util.c prototype is before function because seems, it is used only within same file, if not it should be moved to debug section of prototypes in include/device/device.h Signed-off-by: Maciej Pijanka <maciej.pijanka@gmail.com> Acked-by: Myles Watson <mylesgw@gmail.com> git-svn-id: svn://svn.coreboot.org/coreboot/trunk@4871 2b7e53f0-3cfb-0310-b3e9-8179ed1497e1
2009-10-27 15:29:29 +01:00
void cbmem_list(void);
void cbmem_arch_init(void);
cbmem: dynamic cbmem support This patch adds a parallel implementation of cbmem that supports dynamic sizing. The original implementation relied on reserving a fixed-size block of memory for adding cbmem entries. In order to allow for more flexibility for adding cbmem allocations the dynamic cbmem infrastructure was developed as an alternative to the fixed block approach. Also, the amount of memory to reserve for cbmem allocations does not need to be known prior to the first allocation. The dynamic cbmem code implements the same API as the existing cbmem code except for cbmem_init() and cbmem_reinit(). The add and find routines behave the same way. The dynamic cbmem infrastructure uses a top down allocator that starts allocating from a board/chipset defined function cbmem_top(). A root pointer lives just below cbmem_top(). In turn that pointer points to the root block which contains the entries for all the large alloctations. The corresponding block for each large allocation falls just below the previous entry. It should be noted that this implementation rounds all allocations up to a 4096 byte granularity. Though a packing allocator could be written for small allocations it was deemed OK to just fragment the memory as there shouldn't be that many small allocations. The result is less code with a tradeoff of some wasted memory. +----------------------+ <- cbmem_top() | +----| root pointer | | | +----------------------+ | | | |--------+ | +--->| root block |-----+ | | +----------------------+ | | | | | | | | | | | | | | alloc N |<----+ | | +----------------------+ | | | | | | | | | \|/ | alloc N + 1 |<-------+ v +----------------------+ In addition to preserving the previous cbmem API, the dynamic cbmem API allows for removing blocks from cbmem. This allows for the boot process to allocate memory that can be discarded after it's been used for performing more complex boot tasks in romstage. In order to plumb this support in there were some issues to work around regarding writing of coreboot tables. There were a few assumptions to how cbmem was layed out which dictated some ifdef guarding and other runtime checks so as not to incorrectly tag the e820 and coreboot memory tables. The example shown below is using dynamic cbmem infrastructure. The reserved memory for cbmem is less than 512KiB. coreboot memory table: 0. 0000000000000000-0000000000000fff: CONFIGURATION TABLES 1. 0000000000001000-000000000002ffff: RAM 2. 0000000000030000-000000000003ffff: RESERVED 3. 0000000000040000-000000000009ffff: RAM 4. 00000000000a0000-00000000000fffff: RESERVED 5. 0000000000100000-0000000000efffff: RAM 6. 0000000000f00000-0000000000ffffff: RESERVED 7. 0000000001000000-000000007bf80fff: RAM 8. 000000007bf81000-000000007bffffff: CONFIGURATION TABLES 9. 000000007c000000-000000007e9fffff: RESERVED 10. 00000000f0000000-00000000f3ffffff: RESERVED 11. 00000000fed10000-00000000fed19fff: RESERVED 12. 00000000fed84000-00000000fed84fff: RESERVED 13. 0000000100000000-00000001005fffff: RAM Wrote coreboot table at: 7bf81000, 0x39c bytes, checksum f5bf coreboot table: 948 bytes. CBMEM ROOT 0. 7bfff000 00001000 MRC DATA 1. 7bffe000 00001000 ROMSTAGE 2. 7bffd000 00001000 TIME STAMP 3. 7bffc000 00001000 ROMSTG STCK 4. 7bff7000 00005000 CONSOLE 5. 7bfe7000 00010000 VBOOT 6. 7bfe6000 00001000 RAMSTAGE 7. 7bf98000 0004e000 GDT 8. 7bf97000 00001000 ACPI 9. 7bf8b000 0000c000 ACPI GNVS 10. 7bf8a000 00001000 SMBIOS 11. 7bf89000 00001000 COREBOOT 12. 7bf81000 00008000 And the corresponding e820 entries: BIOS-e820: [mem 0x0000000000000000-0x0000000000000fff] type 16 BIOS-e820: [mem 0x0000000000001000-0x000000000002ffff] usable BIOS-e820: [mem 0x0000000000030000-0x000000000003ffff] reserved BIOS-e820: [mem 0x0000000000040000-0x000000000009ffff] usable BIOS-e820: [mem 0x00000000000a0000-0x00000000000fffff] reserved BIOS-e820: [mem 0x0000000000100000-0x0000000000efffff] usable BIOS-e820: [mem 0x0000000000f00000-0x0000000000ffffff] reserved BIOS-e820: [mem 0x0000000001000000-0x000000007bf80fff] usable BIOS-e820: [mem 0x000000007bf81000-0x000000007bffffff] type 16 BIOS-e820: [mem 0x000000007c000000-0x000000007e9fffff] reserved BIOS-e820: [mem 0x00000000f0000000-0x00000000f3ffffff] reserved BIOS-e820: [mem 0x00000000fed10000-0x00000000fed19fff] reserved BIOS-e820: [mem 0x00000000fed84000-0x00000000fed84fff] reserved BIOS-e820: [mem 0x0000000100000000-0x00000001005fffff] usable Change-Id: Ie3bca52211800a8652a77ca684140cfc9b3b9a6b Signed-off-by: Aaron Durbin <adurbin@chromium.org> Reviewed-on: http://review.coreboot.org/2848 Tested-by: build bot (Jenkins) Reviewed-by: Ronald G. Minnich <rminnich@gmail.com>
2013-03-13 18:41:44 +01:00
void cbmem_print_entry(int n, u32 id, u64 start, u64 size);
#else
static inline void cbmem_arch_init(void) {}
#endif /* __PRE_RAM__ */
CBMEM high table memory manager. This code adds a very simple toc based memory manager for the high tables area. The purpose of this code is to make it simpler and more reliable to find certain data structures in memory. This will also make it possible to have ACPI S3 Resume working without an ugly hole at 31MB. Signed-off-by: Stefan Reinauer <stepan@coresystems.de> Acked-by: Peter Stuge <peter@stuge.se> git-svn-id: svn://svn.coreboot.org/coreboot/trunk@4860 2b7e53f0-3cfb-0310-b3e9-8179ed1497e1
2009-10-26 18:04:28 +01:00
cbmem: dynamic cbmem support This patch adds a parallel implementation of cbmem that supports dynamic sizing. The original implementation relied on reserving a fixed-size block of memory for adding cbmem entries. In order to allow for more flexibility for adding cbmem allocations the dynamic cbmem infrastructure was developed as an alternative to the fixed block approach. Also, the amount of memory to reserve for cbmem allocations does not need to be known prior to the first allocation. The dynamic cbmem code implements the same API as the existing cbmem code except for cbmem_init() and cbmem_reinit(). The add and find routines behave the same way. The dynamic cbmem infrastructure uses a top down allocator that starts allocating from a board/chipset defined function cbmem_top(). A root pointer lives just below cbmem_top(). In turn that pointer points to the root block which contains the entries for all the large alloctations. The corresponding block for each large allocation falls just below the previous entry. It should be noted that this implementation rounds all allocations up to a 4096 byte granularity. Though a packing allocator could be written for small allocations it was deemed OK to just fragment the memory as there shouldn't be that many small allocations. The result is less code with a tradeoff of some wasted memory. +----------------------+ <- cbmem_top() | +----| root pointer | | | +----------------------+ | | | |--------+ | +--->| root block |-----+ | | +----------------------+ | | | | | | | | | | | | | | alloc N |<----+ | | +----------------------+ | | | | | | | | | \|/ | alloc N + 1 |<-------+ v +----------------------+ In addition to preserving the previous cbmem API, the dynamic cbmem API allows for removing blocks from cbmem. This allows for the boot process to allocate memory that can be discarded after it's been used for performing more complex boot tasks in romstage. In order to plumb this support in there were some issues to work around regarding writing of coreboot tables. There were a few assumptions to how cbmem was layed out which dictated some ifdef guarding and other runtime checks so as not to incorrectly tag the e820 and coreboot memory tables. The example shown below is using dynamic cbmem infrastructure. The reserved memory for cbmem is less than 512KiB. coreboot memory table: 0. 0000000000000000-0000000000000fff: CONFIGURATION TABLES 1. 0000000000001000-000000000002ffff: RAM 2. 0000000000030000-000000000003ffff: RESERVED 3. 0000000000040000-000000000009ffff: RAM 4. 00000000000a0000-00000000000fffff: RESERVED 5. 0000000000100000-0000000000efffff: RAM 6. 0000000000f00000-0000000000ffffff: RESERVED 7. 0000000001000000-000000007bf80fff: RAM 8. 000000007bf81000-000000007bffffff: CONFIGURATION TABLES 9. 000000007c000000-000000007e9fffff: RESERVED 10. 00000000f0000000-00000000f3ffffff: RESERVED 11. 00000000fed10000-00000000fed19fff: RESERVED 12. 00000000fed84000-00000000fed84fff: RESERVED 13. 0000000100000000-00000001005fffff: RAM Wrote coreboot table at: 7bf81000, 0x39c bytes, checksum f5bf coreboot table: 948 bytes. CBMEM ROOT 0. 7bfff000 00001000 MRC DATA 1. 7bffe000 00001000 ROMSTAGE 2. 7bffd000 00001000 TIME STAMP 3. 7bffc000 00001000 ROMSTG STCK 4. 7bff7000 00005000 CONSOLE 5. 7bfe7000 00010000 VBOOT 6. 7bfe6000 00001000 RAMSTAGE 7. 7bf98000 0004e000 GDT 8. 7bf97000 00001000 ACPI 9. 7bf8b000 0000c000 ACPI GNVS 10. 7bf8a000 00001000 SMBIOS 11. 7bf89000 00001000 COREBOOT 12. 7bf81000 00008000 And the corresponding e820 entries: BIOS-e820: [mem 0x0000000000000000-0x0000000000000fff] type 16 BIOS-e820: [mem 0x0000000000001000-0x000000000002ffff] usable BIOS-e820: [mem 0x0000000000030000-0x000000000003ffff] reserved BIOS-e820: [mem 0x0000000000040000-0x000000000009ffff] usable BIOS-e820: [mem 0x00000000000a0000-0x00000000000fffff] reserved BIOS-e820: [mem 0x0000000000100000-0x0000000000efffff] usable BIOS-e820: [mem 0x0000000000f00000-0x0000000000ffffff] reserved BIOS-e820: [mem 0x0000000001000000-0x000000007bf80fff] usable BIOS-e820: [mem 0x000000007bf81000-0x000000007bffffff] type 16 BIOS-e820: [mem 0x000000007c000000-0x000000007e9fffff] reserved BIOS-e820: [mem 0x00000000f0000000-0x00000000f3ffffff] reserved BIOS-e820: [mem 0x00000000fed10000-0x00000000fed19fff] reserved BIOS-e820: [mem 0x00000000fed84000-0x00000000fed84fff] reserved BIOS-e820: [mem 0x0000000100000000-0x00000001005fffff] usable Change-Id: Ie3bca52211800a8652a77ca684140cfc9b3b9a6b Signed-off-by: Aaron Durbin <adurbin@chromium.org> Reviewed-on: http://review.coreboot.org/2848 Tested-by: build bot (Jenkins) Reviewed-by: Ronald G. Minnich <rminnich@gmail.com>
2013-03-13 18:41:44 +01:00
#endif /* __ASSEMBLER__ */
Compile cbmem.c instead of including it in romstage, and do that only if resume is done. Signed-off-by: Rudolf Marek <r.marek@assembler.cz> Acked-by: Patrick Georgi <patrick@georgi-clan.de> git-svn-id: svn://svn.coreboot.org/coreboot/trunk@6174 2b7e53f0-3cfb-0310-b3e9-8179ed1497e1
2010-12-13 21:02:23 +01:00
cbmem: dynamic cbmem support This patch adds a parallel implementation of cbmem that supports dynamic sizing. The original implementation relied on reserving a fixed-size block of memory for adding cbmem entries. In order to allow for more flexibility for adding cbmem allocations the dynamic cbmem infrastructure was developed as an alternative to the fixed block approach. Also, the amount of memory to reserve for cbmem allocations does not need to be known prior to the first allocation. The dynamic cbmem code implements the same API as the existing cbmem code except for cbmem_init() and cbmem_reinit(). The add and find routines behave the same way. The dynamic cbmem infrastructure uses a top down allocator that starts allocating from a board/chipset defined function cbmem_top(). A root pointer lives just below cbmem_top(). In turn that pointer points to the root block which contains the entries for all the large alloctations. The corresponding block for each large allocation falls just below the previous entry. It should be noted that this implementation rounds all allocations up to a 4096 byte granularity. Though a packing allocator could be written for small allocations it was deemed OK to just fragment the memory as there shouldn't be that many small allocations. The result is less code with a tradeoff of some wasted memory. +----------------------+ <- cbmem_top() | +----| root pointer | | | +----------------------+ | | | |--------+ | +--->| root block |-----+ | | +----------------------+ | | | | | | | | | | | | | | alloc N |<----+ | | +----------------------+ | | | | | | | | | \|/ | alloc N + 1 |<-------+ v +----------------------+ In addition to preserving the previous cbmem API, the dynamic cbmem API allows for removing blocks from cbmem. This allows for the boot process to allocate memory that can be discarded after it's been used for performing more complex boot tasks in romstage. In order to plumb this support in there were some issues to work around regarding writing of coreboot tables. There were a few assumptions to how cbmem was layed out which dictated some ifdef guarding and other runtime checks so as not to incorrectly tag the e820 and coreboot memory tables. The example shown below is using dynamic cbmem infrastructure. The reserved memory for cbmem is less than 512KiB. coreboot memory table: 0. 0000000000000000-0000000000000fff: CONFIGURATION TABLES 1. 0000000000001000-000000000002ffff: RAM 2. 0000000000030000-000000000003ffff: RESERVED 3. 0000000000040000-000000000009ffff: RAM 4. 00000000000a0000-00000000000fffff: RESERVED 5. 0000000000100000-0000000000efffff: RAM 6. 0000000000f00000-0000000000ffffff: RESERVED 7. 0000000001000000-000000007bf80fff: RAM 8. 000000007bf81000-000000007bffffff: CONFIGURATION TABLES 9. 000000007c000000-000000007e9fffff: RESERVED 10. 00000000f0000000-00000000f3ffffff: RESERVED 11. 00000000fed10000-00000000fed19fff: RESERVED 12. 00000000fed84000-00000000fed84fff: RESERVED 13. 0000000100000000-00000001005fffff: RAM Wrote coreboot table at: 7bf81000, 0x39c bytes, checksum f5bf coreboot table: 948 bytes. CBMEM ROOT 0. 7bfff000 00001000 MRC DATA 1. 7bffe000 00001000 ROMSTAGE 2. 7bffd000 00001000 TIME STAMP 3. 7bffc000 00001000 ROMSTG STCK 4. 7bff7000 00005000 CONSOLE 5. 7bfe7000 00010000 VBOOT 6. 7bfe6000 00001000 RAMSTAGE 7. 7bf98000 0004e000 GDT 8. 7bf97000 00001000 ACPI 9. 7bf8b000 0000c000 ACPI GNVS 10. 7bf8a000 00001000 SMBIOS 11. 7bf89000 00001000 COREBOOT 12. 7bf81000 00008000 And the corresponding e820 entries: BIOS-e820: [mem 0x0000000000000000-0x0000000000000fff] type 16 BIOS-e820: [mem 0x0000000000001000-0x000000000002ffff] usable BIOS-e820: [mem 0x0000000000030000-0x000000000003ffff] reserved BIOS-e820: [mem 0x0000000000040000-0x000000000009ffff] usable BIOS-e820: [mem 0x00000000000a0000-0x00000000000fffff] reserved BIOS-e820: [mem 0x0000000000100000-0x0000000000efffff] usable BIOS-e820: [mem 0x0000000000f00000-0x0000000000ffffff] reserved BIOS-e820: [mem 0x0000000001000000-0x000000007bf80fff] usable BIOS-e820: [mem 0x000000007bf81000-0x000000007bffffff] type 16 BIOS-e820: [mem 0x000000007c000000-0x000000007e9fffff] reserved BIOS-e820: [mem 0x00000000f0000000-0x00000000f3ffffff] reserved BIOS-e820: [mem 0x00000000fed10000-0x00000000fed19fff] reserved BIOS-e820: [mem 0x00000000fed84000-0x00000000fed84fff] reserved BIOS-e820: [mem 0x0000000100000000-0x00000001005fffff] usable Change-Id: Ie3bca52211800a8652a77ca684140cfc9b3b9a6b Signed-off-by: Aaron Durbin <adurbin@chromium.org> Reviewed-on: http://review.coreboot.org/2848 Tested-by: build bot (Jenkins) Reviewed-by: Ronald G. Minnich <rminnich@gmail.com>
2013-03-13 18:41:44 +01:00
#endif /* _CBMEM_H_ */