From: Penny Zheng <penny.zh...@arm.com>
setup_mm is used for Xen to setup memory management subsystem at boot
time, like boot allocator, direct-mapping, xenheap initialization,
frametable and static memory pages.
We could inherit some components seamlessly in later MPU system like
boot allocator, whilst we need to implement some components differently
in MPU, like xenheap, etc. There are some components that is specific
to MMU only, like direct-mapping.
In the commit, we move MMU-specific components into mmu/setup.c, in
preparation of implementing MPU version of setup_mm later in future
commit. Also, make init_pdx(), init_staticmem_pages(), setup_mm(), and
populate_boot_allocator() public for future MPU inplementation.
Signed-off-by: Penny Zheng <penny.zh...@arm.com>
Signed-off-by: Wei Chen <wei.c...@arm.com>
Signed-off-by: Henry Wang <henry.w...@arm.com>
---
v4:
- No change
---
xen/arch/arm/include/asm/setup.h | 5 +
xen/arch/arm/mmu/Makefile | 1 +
xen/arch/arm/mmu/setup.c | 339 +++++++++++++++++++++++++++++++
xen/arch/arm/setup.c | 326 +----------------------------
4 files changed, 349 insertions(+), 322 deletions(-)
create mode 100644 xen/arch/arm/mmu/setup.c
diff --git a/xen/arch/arm/include/asm/setup.h b/xen/arch/arm/include/asm/setup.h
index f0f64d228c..0922549631 100644
--- a/xen/arch/arm/include/asm/setup.h
+++ b/xen/arch/arm/include/asm/setup.h
@@ -156,6 +156,11 @@ struct bootcmdline
*boot_cmdline_find_by_kind(bootmodule_kind kind);
struct bootcmdline * boot_cmdline_find_by_name(const char *name);
const char *boot_module_kind_as_string(bootmodule_kind kind);
+extern void init_pdx(void);
+extern void init_staticmem_pages(void);
+extern void populate_boot_allocator(void);
+extern void setup_mm(void);
+
extern uint32_t hyp_traps_vector[];
void init_traps(void);
diff --git a/xen/arch/arm/mmu/Makefile b/xen/arch/arm/mmu/Makefile
index b18cec4836..4aa1fb466d 100644
--- a/xen/arch/arm/mmu/Makefile
+++ b/xen/arch/arm/mmu/Makefile
@@ -1 +1,2 @@
obj-y += mm.o
+obj-y += setup.o
diff --git a/xen/arch/arm/mmu/setup.c b/xen/arch/arm/mmu/setup.c
new file mode 100644
index 0000000000..e05cca3f86
--- /dev/null
+++ b/xen/arch/arm/mmu/setup.c
@@ -0,0 +1,339 @@
+/* SPDX-License-Identifier: GPL-2.0 */
+/*
+ * xen/arch/arm/mmu/setup.c
+ *
+ * MMU-specific early bringup code for an ARMv7-A with virt extensions.
+ */
+
+#include <xen/init.h>
+#include <xen/serial.h>
+#include <xen/libfdt/libfdt-xen.h>
+#include <xen/mm.h>
+#include <xen/param.h>
+#include <xen/pfn.h>
+#include <asm/fixmap.h>
+#include <asm/page.h>
+#include <asm/setup.h>
+
+#ifdef CONFIG_ARM_32
+static unsigned long opt_xenheap_megabytes __initdata;
+integer_param("xenheap_megabytes", opt_xenheap_megabytes);
+
+/*
+ * Returns the end address of the highest region in the range s..e
+ * with required size and alignment that does not conflict with the
+ * modules from first_mod to nr_modules.
+ *
+ * For non-recursive callers first_mod should normally be 0 (all
+ * modules and Xen itself) or 1 (all modules but not Xen).
+ */
+static paddr_t __init consider_modules(paddr_t s, paddr_t e,
+ uint32_t size, paddr_t align,
+ int first_mod)
+{
+ const struct bootmodules *mi = &bootinfo.modules;
+ int i;
+ int nr;
+
+ s = (s+align-1) & ~(align-1);
+ e = e & ~(align-1);
+
+ if ( s > e || e - s < size )
+ return 0;
+
+ /* First check the boot modules */
+ for ( i = first_mod; i < mi->nr_mods; i++ )
+ {
+ paddr_t mod_s = mi->module[i].start;
+ paddr_t mod_e = mod_s + mi->module[i].size;
+
+ if ( s < mod_e && mod_s < e )
+ {
+ mod_e = consider_modules(mod_e, e, size, align, i+1);
+ if ( mod_e )
+ return mod_e;
+
+ return consider_modules(s, mod_s, size, align, i+1);
+ }
+ }
+
+ /* Now check any fdt reserved areas. */
+
+ nr = fdt_num_mem_rsv(device_tree_flattened);
+
+ for ( ; i < mi->nr_mods + nr; i++ )
+ {
+ paddr_t mod_s, mod_e;
+
+ if ( fdt_get_mem_rsv_paddr(device_tree_flattened,
+ i - mi->nr_mods,
+ &mod_s, &mod_e ) < 0 )
+ /* If we can't read it, pretend it doesn't exist... */
+ continue;
+
+ /* fdt_get_mem_rsv_paddr returns length */
+ mod_e += mod_s;
+
+ if ( s < mod_e && mod_s < e )
+ {
+ mod_e = consider_modules(mod_e, e, size, align, i+1);
+ if ( mod_e )
+ return mod_e;
+
+ return consider_modules(s, mod_s, size, align, i+1);
+ }
+ }
+
+ /*
+ * i is the current bootmodule we are evaluating, across all
+ * possible kinds of bootmodules.
+ *
+ * When retrieving the corresponding reserved-memory addresses, we
+ * need to index the bootinfo.reserved_mem bank starting from 0, and
+ * only counting the reserved-memory modules. Hence, we need to use
+ * i - nr.
+ */
+ nr += mi->nr_mods;
+ for ( ; i - nr < bootinfo.reserved_mem.nr_banks; i++ )
+ {
+ paddr_t r_s = bootinfo.reserved_mem.bank[i - nr].start;
+ paddr_t r_e = r_s + bootinfo.reserved_mem.bank[i - nr].size;
+
+ if ( s < r_e && r_s < e )
+ {
+ r_e = consider_modules(r_e, e, size, align, i + 1);
+ if ( r_e )
+ return r_e;
+
+ return consider_modules(s, r_s, size, align, i + 1);
+ }
+ }
+ return e;
+}
+
+/*
+ * Find a contiguous region that fits in the static heap region with
+ * required size and alignment, and return the end address of the region
+ * if found otherwise 0.
+ */
+static paddr_t __init fit_xenheap_in_static_heap(uint32_t size, paddr_t align)
+{
+ unsigned int i;
+ paddr_t end = 0, aligned_start, aligned_end;
+ paddr_t bank_start, bank_size, bank_end;
+
+ for ( i = 0 ; i < bootinfo.reserved_mem.nr_banks; i++ )
+ {
+ if ( bootinfo.reserved_mem.bank[i].type != MEMBANK_STATIC_HEAP )
+ continue;
+
+ bank_start = bootinfo.reserved_mem.bank[i].start;
+ bank_size = bootinfo.reserved_mem.bank[i].size;
+ bank_end = bank_start + bank_size;
+
+ if ( bank_size < size )
+ continue;
+
+ aligned_end = bank_end & ~(align - 1);
+ aligned_start = (aligned_end - size) & ~(align - 1);
+
+ if ( aligned_start > bank_start )
+ /*
+ * Allocate the xenheap as high as possible to keep low-memory
+ * available (assuming the admin supplied region below 4GB)
+ * for other use (e.g. domain memory allocation).
+ */
+ end = max(end, aligned_end);
+ }
+
+ return end;
+}
+
+void __init setup_mm(void)
+{
+ paddr_t ram_start, ram_end, ram_size, e, bank_start, bank_end, bank_size;
+ paddr_t static_heap_end = 0, static_heap_size = 0;
+ unsigned long heap_pages, xenheap_pages, domheap_pages;
+ unsigned int i;
+ const uint32_t ctr = READ_CP32(CTR);
+
+ if ( !bootinfo.mem.nr_banks )
+ panic("No memory bank\n");
+
+ /* We only supports instruction caches implementing the IVIPT extension. */
+ if ( ((ctr >> CTR_L1IP_SHIFT) & CTR_L1IP_MASK) == ICACHE_POLICY_AIVIVT )
+ panic("AIVIVT instruction cache not supported\n");
+
+ init_pdx();
+
+ ram_start = bootinfo.mem.bank[0].start;
+ ram_size = bootinfo.mem.bank[0].size;
+ ram_end = ram_start + ram_size;
+
+ for ( i = 1; i < bootinfo.mem.nr_banks; i++ )
+ {
+ bank_start = bootinfo.mem.bank[i].start;
+ bank_size = bootinfo.mem.bank[i].size;
+ bank_end = bank_start + bank_size;
+
+ ram_size = ram_size + bank_size;
+ ram_start = min(ram_start,bank_start);
+ ram_end = max(ram_end,bank_end);
+ }
+
+ total_pages = ram_size >> PAGE_SHIFT;
+
+ if ( bootinfo.static_heap )
+ {
+ for ( i = 0 ; i < bootinfo.reserved_mem.nr_banks; i++ )
+ {
+ if ( bootinfo.reserved_mem.bank[i].type != MEMBANK_STATIC_HEAP )
+ continue;
+
+ bank_start = bootinfo.reserved_mem.bank[i].start;
+ bank_size = bootinfo.reserved_mem.bank[i].size;
+ bank_end = bank_start + bank_size;
+
+ static_heap_size += bank_size;
+ static_heap_end = max(static_heap_end, bank_end);
+ }
+
+ heap_pages = static_heap_size >> PAGE_SHIFT;
+ }
+ else
+ heap_pages = total_pages;
+
+ /*
+ * If the user has not requested otherwise via the command line
+ * then locate the xenheap using these constraints:
+ *
+ * - must be contiguous
+ * - must be 32 MiB aligned
+ * - must not include Xen itself or the boot modules
+ * - must be at most 1GB or 1/32 the total RAM in the system (or static
+ heap if enabled) if less
+ * - must be at least 32M
+ *
+ * We try to allocate the largest xenheap possible within these
+ * constraints.
+ */
+ if ( opt_xenheap_megabytes )
+ xenheap_pages = opt_xenheap_megabytes << (20-PAGE_SHIFT);
+ else
+ {
+ xenheap_pages = (heap_pages/32 + 0x1fffUL) & ~0x1fffUL;
+ xenheap_pages = max(xenheap_pages, 32UL<<(20-PAGE_SHIFT));
+ xenheap_pages = min(xenheap_pages, 1UL<<(30-PAGE_SHIFT));
+ }
+
+ do
+ {
+ e = bootinfo.static_heap ?
+ fit_xenheap_in_static_heap(pfn_to_paddr(xenheap_pages), MB(32)) :
+ consider_modules(ram_start, ram_end,
+ pfn_to_paddr(xenheap_pages),
+ 32<<20, 0);
+ if ( e )
+ break;
+
+ xenheap_pages >>= 1;
+ } while ( !opt_xenheap_megabytes && xenheap_pages > 32<<(20-PAGE_SHIFT) );
+
+ if ( ! e )
+ panic("Not enough space for xenheap\n");
+
+ domheap_pages = heap_pages - xenheap_pages;
+
+ printk("Xen heap: %"PRIpaddr"-%"PRIpaddr" (%lu pages%s)\n",
+ e - (pfn_to_paddr(xenheap_pages)), e, xenheap_pages,
+ opt_xenheap_megabytes ? ", from command-line" : "");
+ printk("Dom heap: %lu pages\n", domheap_pages);
+
+ /*
+ * We need some memory to allocate the page-tables used for the
+ * directmap mappings. So populate the boot allocator first.
+ *
+ * This requires us to set directmap_mfn_{start, end} first so the
+ * direct-mapped Xenheap region can be avoided.
+ */
+ directmap_mfn_start = _mfn((e >> PAGE_SHIFT) - xenheap_pages);
+ directmap_mfn_end = mfn_add(directmap_mfn_start, xenheap_pages);
+
+ populate_boot_allocator();
+
+ setup_directmap_mappings(mfn_x(directmap_mfn_start), xenheap_pages);
+
+ /* Frame table covers all of RAM region, including holes */
+ setup_frametable_mappings(ram_start, ram_end);
+ max_page = PFN_DOWN(ram_end);
+
+ /*
+ * The allocators may need to use map_domain_page() (such as for
+ * scrubbing pages). So we need to prepare the domheap area first.
+ */
+ if ( !init_domheap_mappings(smp_processor_id()) )
+ panic("CPU%u: Unable to prepare the domheap page-tables\n",
+ smp_processor_id());
+
+ /* Add xenheap memory that was not already added to the boot allocator. */
+ init_xenheap_pages(mfn_to_maddr(directmap_mfn_start),
+ mfn_to_maddr(directmap_mfn_end));
+
+ init_staticmem_pages();
+}
+#else /* CONFIG_ARM_64 */
+void __init setup_mm(void)
+{
+ const struct meminfo *banks = &bootinfo.mem;
+ paddr_t ram_start = INVALID_PADDR;
+ paddr_t ram_end = 0;
+ paddr_t ram_size = 0;
+ unsigned int i;
+
+ init_pdx();
+
+ /*
+ * We need some memory to allocate the page-tables used for the directmap
+ * mappings. But some regions may contain memory already allocated
+ * for other uses (e.g. modules, reserved-memory...).
+ *
+ * For simplicity, add all the free regions in the boot allocator.
+ */
+ populate_boot_allocator();
+
+ total_pages = 0;
+
+ for ( i = 0; i < banks->nr_banks; i++ )
+ {
+ const struct membank *bank = &banks->bank[i];
+ paddr_t bank_end = bank->start + bank->size;
+
+ ram_size = ram_size + bank->size;
+ ram_start = min(ram_start, bank->start);
+ ram_end = max(ram_end, bank_end);
+
+ setup_directmap_mappings(PFN_DOWN(bank->start),
+ PFN_DOWN(bank->size));
+ }
+
+ total_pages += ram_size >> PAGE_SHIFT;
+
+ directmap_virt_end = XENHEAP_VIRT_START + ram_end - ram_start;
+ directmap_mfn_start = maddr_to_mfn(ram_start);
+ directmap_mfn_end = maddr_to_mfn(ram_end);
+
+ setup_frametable_mappings(ram_start, ram_end);
+ max_page = PFN_DOWN(ram_end);
+
+ init_staticmem_pages();
+}
+#endif
+
+/*
+ * Local variables:
+ * mode: C
+ * c-file-style: "BSD"
+ * c-basic-offset: 4
+ * indent-tabs-mode: nil
+ * End:
+ */
diff --git a/xen/arch/arm/setup.c b/xen/arch/arm/setup.c
index bbf72b69aa..50259552a0 100644
--- a/xen/arch/arm/setup.c
+++ b/xen/arch/arm/setup.c
@@ -2,7 +2,7 @@
/*
* xen/arch/arm/setup.c
*
- * Early bringup code for an ARMv7-A with virt extensions.
+ * Early bringup code for an ARMv7-A/ARM64v8R with virt extensions.
*
* Tim Deegan <t...@xen.org>
* Copyright (c) 2011 Citrix Systems.
@@ -57,11 +57,6 @@ struct cpuinfo_arm __read_mostly system_cpuinfo;
bool __read_mostly acpi_disabled;
#endif
-#ifdef CONFIG_ARM_32
-static unsigned long opt_xenheap_megabytes __initdata;
-integer_param("xenheap_megabytes", opt_xenheap_megabytes);
-#endif
-
domid_t __read_mostly max_init_domid;
static __used void init_done(void)
@@ -546,138 +541,6 @@ static void * __init relocate_fdt(paddr_t dtb_paddr,
size_t dtb_size)
return fdt;
}
-#ifdef CONFIG_ARM_32
-/*
- * Returns the end address of the highest region in the range s..e
- * with required size and alignment that does not conflict with the
- * modules from first_mod to nr_modules.
- *
- * For non-recursive callers first_mod should normally be 0 (all
- * modules and Xen itself) or 1 (all modules but not Xen).
- */
-static paddr_t __init consider_modules(paddr_t s, paddr_t e,
- uint32_t size, paddr_t align,
- int first_mod)
-{
- const struct bootmodules *mi = &bootinfo.modules;
- int i;
- int nr;
-
- s = (s+align-1) & ~(align-1);
- e = e & ~(align-1);
-
- if ( s > e || e - s < size )
- return 0;
-
- /* First check the boot modules */
- for ( i = first_mod; i < mi->nr_mods; i++ )
- {
- paddr_t mod_s = mi->module[i].start;
- paddr_t mod_e = mod_s + mi->module[i].size;
-
- if ( s < mod_e && mod_s < e )
- {
- mod_e = consider_modules(mod_e, e, size, align, i+1);
- if ( mod_e )
- return mod_e;
-
- return consider_modules(s, mod_s, size, align, i+1);
- }
- }
-
- /* Now check any fdt reserved areas. */
-
- nr = fdt_num_mem_rsv(device_tree_flattened);
-
- for ( ; i < mi->nr_mods + nr; i++ )
- {
- paddr_t mod_s, mod_e;
-
- if ( fdt_get_mem_rsv_paddr(device_tree_flattened,
- i - mi->nr_mods,
- &mod_s, &mod_e ) < 0 )
- /* If we can't read it, pretend it doesn't exist... */
- continue;
-
- /* fdt_get_mem_rsv_paddr returns length */
- mod_e += mod_s;
-
- if ( s < mod_e && mod_s < e )
- {
- mod_e = consider_modules(mod_e, e, size, align, i+1);
- if ( mod_e )
- return mod_e;
-
- return consider_modules(s, mod_s, size, align, i+1);
- }
- }
-
- /*
- * i is the current bootmodule we are evaluating, across all
- * possible kinds of bootmodules.
- *
- * When retrieving the corresponding reserved-memory addresses, we
- * need to index the bootinfo.reserved_mem bank starting from 0, and
- * only counting the reserved-memory modules. Hence, we need to use
- * i - nr.
- */
- nr += mi->nr_mods;
- for ( ; i - nr < bootinfo.reserved_mem.nr_banks; i++ )
- {
- paddr_t r_s = bootinfo.reserved_mem.bank[i - nr].start;
- paddr_t r_e = r_s + bootinfo.reserved_mem.bank[i - nr].size;
-
- if ( s < r_e && r_s < e )
- {
- r_e = consider_modules(r_e, e, size, align, i + 1);
- if ( r_e )
- return r_e;
-
- return consider_modules(s, r_s, size, align, i + 1);
- }
- }
- return e;
-}
-
-/*
- * Find a contiguous region that fits in the static heap region with
- * required size and alignment, and return the end address of the region
- * if found otherwise 0.
- */
-static paddr_t __init fit_xenheap_in_static_heap(uint32_t size, paddr_t align)
-{
- unsigned int i;
- paddr_t end = 0, aligned_start, aligned_end;
- paddr_t bank_start, bank_size, bank_end;
-
- for ( i = 0 ; i < bootinfo.reserved_mem.nr_banks; i++ )
- {
- if ( bootinfo.reserved_mem.bank[i].type != MEMBANK_STATIC_HEAP )
- continue;
-
- bank_start = bootinfo.reserved_mem.bank[i].start;
- bank_size = bootinfo.reserved_mem.bank[i].size;
- bank_end = bank_start + bank_size;
-
- if ( bank_size < size )
- continue;
-
- aligned_end = bank_end & ~(align - 1);
- aligned_start = (aligned_end - size) & ~(align - 1);
-
- if ( aligned_start > bank_start )
- /*
- * Allocate the xenheap as high as possible to keep low-memory
- * available (assuming the admin supplied region below 4GB)
- * for other use (e.g. domain memory allocation).
- */
- end = max(end, aligned_end);
- }
-
- return end;
-}
-#endif
-
/*
* Return the end of the non-module region starting at s. In other
* words return s the start of the next modules after s.
@@ -712,7 +575,7 @@ static paddr_t __init next_module(paddr_t s, paddr_t *end)
return lowest;
}
-static void __init init_pdx(void)
+void __init init_pdx(void)
{
paddr_t bank_start, bank_size, bank_end;
@@ -757,7 +620,7 @@ static void __init init_pdx(void)
}
/* Static memory initialization */
-static void __init init_staticmem_pages(void)
+void __init init_staticmem_pages(void)
{
#ifdef CONFIG_STATIC_MEMORY
unsigned int bank;
@@ -791,7 +654,7 @@ static void __init init_staticmem_pages(void)
* allocator with the corresponding regions only, but with Xenheap excluded
* on arm32.
*/
-static void __init populate_boot_allocator(void)
+void __init populate_boot_allocator(void)
{
unsigned int i;
const struct meminfo *banks = &bootinfo.mem;
@@ -860,187 +723,6 @@ static void __init populate_boot_allocator(void)
}
}
-#ifdef CONFIG_ARM_32
-static void __init setup_mm(void)
-{
- paddr_t ram_start, ram_end, ram_size, e, bank_start, bank_end, bank_size;
- paddr_t static_heap_end = 0, static_heap_size = 0;
- unsigned long heap_pages, xenheap_pages, domheap_pages;
- unsigned int i;
- const uint32_t ctr = READ_CP32(CTR);
-
- if ( !bootinfo.mem.nr_banks )
- panic("No memory bank\n");
-
- /* We only supports instruction caches implementing the IVIPT extension. */
- if ( ((ctr >> CTR_L1IP_SHIFT) & CTR_L1IP_MASK) == ICACHE_POLICY_AIVIVT )
- panic("AIVIVT instruction cache not supported\n");
-
- init_pdx();
-
- ram_start = bootinfo.mem.bank[0].start;
- ram_size = bootinfo.mem.bank[0].size;
- ram_end = ram_start + ram_size;
-
- for ( i = 1; i < bootinfo.mem.nr_banks; i++ )
- {
- bank_start = bootinfo.mem.bank[i].start;
- bank_size = bootinfo.mem.bank[i].size;
- bank_end = bank_start + bank_size;
-
- ram_size = ram_size + bank_size;
- ram_start = min(ram_start,bank_start);
- ram_end = max(ram_end,bank_end);
- }
-
- total_pages = ram_size >> PAGE_SHIFT;
-
- if ( bootinfo.static_heap )
- {
- for ( i = 0 ; i < bootinfo.reserved_mem.nr_banks; i++ )
- {
- if ( bootinfo.reserved_mem.bank[i].type != MEMBANK_STATIC_HEAP )
- continue;
-
- bank_start = bootinfo.reserved_mem.bank[i].start;
- bank_size = bootinfo.reserved_mem.bank[i].size;
- bank_end = bank_start + bank_size;
-
- static_heap_size += bank_size;
- static_heap_end = max(static_heap_end, bank_end);
- }
-
- heap_pages = static_heap_size >> PAGE_SHIFT;
- }
- else
- heap_pages = total_pages;
-
- /*
- * If the user has not requested otherwise via the command line
- * then locate the xenheap using these constraints:
- *
- * - must be contiguous
- * - must be 32 MiB aligned
- * - must not include Xen itself or the boot modules
- * - must be at most 1GB or 1/32 the total RAM in the system (or static
- heap if enabled) if less
- * - must be at least 32M
- *
- * We try to allocate the largest xenheap possible within these
- * constraints.
- */
- if ( opt_xenheap_megabytes )
- xenheap_pages = opt_xenheap_megabytes << (20-PAGE_SHIFT);
- else
- {
- xenheap_pages = (heap_pages/32 + 0x1fffUL) & ~0x1fffUL;
- xenheap_pages = max(xenheap_pages, 32UL<<(20-PAGE_SHIFT));
- xenheap_pages = min(xenheap_pages, 1UL<<(30-PAGE_SHIFT));
- }
-
- do
- {
- e = bootinfo.static_heap ?
- fit_xenheap_in_static_heap(pfn_to_paddr(xenheap_pages), MB(32)) :
- consider_modules(ram_start, ram_end,
- pfn_to_paddr(xenheap_pages),
- 32<<20, 0);
- if ( e )
- break;
-
- xenheap_pages >>= 1;
- } while ( !opt_xenheap_megabytes && xenheap_pages > 32<<(20-PAGE_SHIFT) );
-
- if ( ! e )
- panic("Not enough space for xenheap\n");
-
- domheap_pages = heap_pages - xenheap_pages;
-
- printk("Xen heap: %"PRIpaddr"-%"PRIpaddr" (%lu pages%s)\n",
- e - (pfn_to_paddr(xenheap_pages)), e, xenheap_pages,
- opt_xenheap_megabytes ? ", from command-line" : "");
- printk("Dom heap: %lu pages\n", domheap_pages);
-
- /*
- * We need some memory to allocate the page-tables used for the
- * directmap mappings. So populate the boot allocator first.
- *
- * This requires us to set directmap_mfn_{start, end} first so the
- * direct-mapped Xenheap region can be avoided.
- */
- directmap_mfn_start = _mfn((e >> PAGE_SHIFT) - xenheap_pages);
- directmap_mfn_end = mfn_add(directmap_mfn_start, xenheap_pages);
-
- populate_boot_allocator();
-
- setup_directmap_mappings(mfn_x(directmap_mfn_start), xenheap_pages);
-
- /* Frame table covers all of RAM region, including holes */
- setup_frametable_mappings(ram_start, ram_end);
- max_page = PFN_DOWN(ram_end);
-
- /*
- * The allocators may need to use map_domain_page() (such as for
- * scrubbing pages). So we need to prepare the domheap area first.
- */
- if ( !init_domheap_mappings(smp_processor_id()) )
- panic("CPU%u: Unable to prepare the domheap page-tables\n",
- smp_processor_id());
-
- /* Add xenheap memory that was not already added to the boot allocator. */
- init_xenheap_pages(mfn_to_maddr(directmap_mfn_start),
- mfn_to_maddr(directmap_mfn_end));
-
- init_staticmem_pages();
-}
-#else /* CONFIG_ARM_64 */
-static void __init setup_mm(void)
-{
- const struct meminfo *banks = &bootinfo.mem;
- paddr_t ram_start = INVALID_PADDR;
- paddr_t ram_end = 0;
- paddr_t ram_size = 0;
- unsigned int i;
-
- init_pdx();
-
- /*
- * We need some memory to allocate the page-tables used for the directmap
- * mappings. But some regions may contain memory already allocated
- * for other uses (e.g. modules, reserved-memory...).
- *
- * For simplicity, add all the free regions in the boot allocator.
- */
- populate_boot_allocator();
-
- total_pages = 0;
-
- for ( i = 0; i < banks->nr_banks; i++ )
- {
- const struct membank *bank = &banks->bank[i];
- paddr_t bank_end = bank->start + bank->size;
-
- ram_size = ram_size + bank->size;
- ram_start = min(ram_start, bank->start);
- ram_end = max(ram_end, bank_end);
-
- setup_directmap_mappings(PFN_DOWN(bank->start),
- PFN_DOWN(bank->size));
- }
-
- total_pages += ram_size >> PAGE_SHIFT;
-
- directmap_virt_end = XENHEAP_VIRT_START + ram_end - ram_start;
- directmap_mfn_start = maddr_to_mfn(ram_start);
- directmap_mfn_end = maddr_to_mfn(ram_end);
-
- setup_frametable_mappings(ram_start, ram_end);
- max_page = PFN_DOWN(ram_end);
-
- init_staticmem_pages();
-}
-#endif
-
static bool __init is_dom0less_mode(void)
{
struct bootmodules *mods = &bootinfo.modules;
--
2.25.1
