[RFC PATCH v1] arm64:mm: An optimization about kernel direct sapce mapping

[RFC PATCH v1] arm64:mm: An optimization about kernel direct sapce mapping

[zhichang.yuan]

From: "zhichang.yuan" <zhichang.yuan@linaro.org>

This patch make the processing of map_mem more common and support more
discrete memory layout cases.

In current map_mem, the processing is based on two hypotheses:
1) no any early page allocations occur before the first PMD or PUD regime
where the kernel image locate is successfully mapped;
2) there are sufficient available pages in the PMD or PUD regime to satisfy
the need of page tables from other memory ranges mapping.

The current SOC or hardware platform designs had not broken this constraint.
But we can make the software more versatile.

In addition, for the 4K page system, to comply with the constraint No.1, the
start address of some memory ranges is forced to align at PMD boundary, it
will make some marginal pages of that ranges are skipped to build the PTE. It
is not reasonable.

This patch will relieve the system from those constraints. You can load the
kernel image in any memory range, the memory range can be small, can start at
non-alignment boundary, and so on.

In this patch, the kernel space mapping will probably scan all memory ranges
twice. In the first scanning, those memory ranges whose size is larger than a
threshold are mapped, then the second scanning will map the smaller memory
ranges. Since the threshold is so small, in most cases, the second scanning is
NULL operation.

The patch is also accessible @
https://git.linaro.org/people/zhichang.yuan/pgalloc.git/shortlog/refs/heads/mapmem_linux_master

Signed-off-by: Zhichang Yuan <zhichang.yuan@linaro.org>
---
 arch/arm64/include/asm/page.h    |   10 ++
 arch/arm64/include/asm/pgtable.h |    3 +
 arch/arm64/kernel/vmlinux.lds.S  |    4 +
 arch/arm64/mm/mmu.c              |  230 ++++++++++++++++++++++++++++++++------
 include/linux/memblock.h         |    5 +
 5 files changed, 217 insertions(+), 35 deletions(-)

diff --git a/arch/arm64/include/asm/page.h b/arch/arm64/include/asm/page.h
index 22b1623..7c55e11 100644
--- a/arch/arm64/include/asm/page.h
+++ b/arch/arm64/include/asm/page.h
@@ -44,6 +44,16 @@
 #define SWAPPER_DIR_SIZE	(SWAPPER_PGTABLE_LEVELS * PAGE_SIZE)
 #define IDMAP_DIR_SIZE		(SWAPPER_DIR_SIZE)
 
+/*This macro has strong dependency with BLOCK_SIZE in head.S...*/
+#ifdef CONFIG_ARM64_64K_PAGES
+#define INIT_MAP_PGSZ	(PAGE_SIZE)
+/*we prepare one more page for probable memblock space extension*/
+#define PGT_BRK_SIZE	((SWAPPER_PGTABLE_LEVELS) << PAGE_SHIFT)
+#else
+#define INIT_MAP_PGSZ	(SECTION_SIZE)
+#define PGT_BRK_SIZE	((SWAPPER_PGTABLE_LEVELS + 1) << PAGE_SHIFT)
+#endif
+
 #ifndef __ASSEMBLY__
 
 #include <asm/pgtable-types.h>
diff --git a/arch/arm64/include/asm/pgtable.h b/arch/arm64/include/asm/pgtable.h
index 41a43bf..9f96c6c 100644
--- a/arch/arm64/include/asm/pgtable.h
+++ b/arch/arm64/include/asm/pgtable.h
@@ -464,6 +464,9 @@ static inline pmd_t pmd_modify(pmd_t pmd, pgprot_t newprot)
 extern pgd_t swapper_pg_dir[PTRS_PER_PGD];
 extern pgd_t idmap_pg_dir[PTRS_PER_PGD];
 
+/*define for kernel direct space mapping*/
+extern char pgtbrk_base[], pgtbrk_end[];
+
 /*
  * Encode and decode a swap entry:
  *	bits 0-1:	present (must be zero)
diff --git a/arch/arm64/kernel/vmlinux.lds.S b/arch/arm64/kernel/vmlinux.lds.S
index edf8715..ca5b69c 100644
--- a/arch/arm64/kernel/vmlinux.lds.S
+++ b/arch/arm64/kernel/vmlinux.lds.S
@@ -113,6 +113,10 @@ SECTIONS
 	swapper_pg_dir = .;
 	. += SWAPPER_DIR_SIZE;
 
+	pgtbrk_base = .;
+	. += PGT_BRK_SIZE;
+	pgtbrk_end = .;
+
 	_end = .;
 
 	STABS_DEBUG
diff --git a/arch/arm64/mm/mmu.c b/arch/arm64/mm/mmu.c
index f4f8b50..e56fbc8 100644
--- a/arch/arm64/mm/mmu.c
+++ b/arch/arm64/mm/mmu.c
@@ -67,6 +67,12 @@ static struct cachepolicy cache_policies[] __initdata = {
 };
 
 /*
+ * points to the specific brk regions. Those pages can be allocated for
+ * page tables usage.
+ */
+static unsigned long pgtbrk_sp = (unsigned long)pgtbrk_base;
+
+/*
  * These are useful for identifying cache coherency problems by allowing the
  * cache or the cache and writebuffer to be turned off. It changes the Normal
  * memory caching attributes in the MAIR_EL1 register.
@@ -131,7 +137,18 @@ EXPORT_SYMBOL(phys_mem_access_prot);
 
 static void __init *early_alloc(unsigned long sz)
 {
-	void *ptr = __va(memblock_alloc(sz, sz));
+	void *ptr;
+
+	if (!(sz & (~PAGE_MASK)) &&
+			pgtbrk_sp + sz <= (unsigned long)pgtbrk_end) {
+		ptr = (void *)pgtbrk_sp;
+		pgtbrk_sp += sz;
+		pr_info("BRK [0x%p, 0x%lx] PGTABLE\n",	ptr, pgtbrk_sp);
+
+	} else {
+		ptr = __va(memblock_alloc(sz, sz));
+	}
+
 	memset(ptr, 0, sz);
 	return ptr;
 }
@@ -287,52 +304,195 @@ void __init create_id_mapping(phys_addr_t addr, phys_addr_t size, int map_io)
 			 addr, addr, size, map_io);
 }
 
+/*
+* In the worst case, mapping one memory range or sub-range will comsume
+* MIN_MAP_INCRSZ pages. To garentee there are sufficient mapped pages
+* for the ranges to be mapped, it is priority to map those range that can
+* supply available pages over this macro value.
+* For 64K, one page less than SWAPPER_PGTABLE_LEVELS;
+* For 4K, SWAPPER_PGTABLE_LEVELS pages
+*/
+#ifdef CONFIG_ARM64_64K_PAGES
+#define MIN_MAP_INCRSZ		((SWAPPER_PGTABLE_LEVELS - 1) << PAGE_SHIFT)
+#else
+#define MIN_MAP_INCRSZ		(SWAPPER_PGTABLE_LEVELS << PAGE_SHIFT)
+#endif
+
+static inline void __init map_cont_memseg(phys_addr_t start,
+				phys_addr_t end, phys_addr_t *plimit)
+{
+	create_mapping(start, __phys_to_virt(start), end - start);
+	if (*plimit < end) {
+		*plimit = end;
+		memblock_set_current_limit(end);
+	}
+}
+
+/*
+* This function will map the designated memory range. If successfully do
+* the mapping, will update the current_limit as the maximal mapped address.
+*
+* each mapped memory range should at least supply (SWAPPER_PGTABLE_LEVELS - 1)
+* new mapped pages for the next range. Otherwise, that range should be reserved
+* for delay mapping.
+* The memory range will probably be divided into several sub-ranges.
+* The division will occur at the PMD, PUD boundaries.
+* In the worst case, one sub-range will spend (SWAPPER_PGTABLE_LEVELS - 1)
+* pages as page tables, we firstly map the sub-range that can provide enough
+* pages for the remaining sub-ranges.
+*/
+static size_t __init map_onerng_reverse(phys_addr_t start,
+			phys_addr_t end, phys_addr_t *plimit)
+{
+	phys_addr_t blk_start, blk_end;
+	phys_addr_t delimit = 0;
+
+	blk_start = round_up(start, PMD_SIZE);
+	blk_end = round_down(end, PMD_SIZE);
+
+	/*
+	* first case: start and end are spread in adjacent PMD
+	* second case: start and end are separated by at least one PMD
+	* third case: start and end are in same PMD
+	*/
+	if (blk_start == blk_end &&
+			blk_start != start && blk_end != end) {
+		delimit = blk_start;
+		/*blk_start is the minimum, blk_end is the maximum*/
+		if (end - delimit >= delimit - start) {
+			blk_end = end - delimit;
+			blk_start = delimit - start;
+		} else {
+			blk_end = delimit - start;
+			blk_start = end - delimit;
+		}
+		/*both sub-ranges can supply enough pages*/
+		if (blk_start >= MIN_MAP_INCRSZ) {
+			map_cont_memseg(delimit, end, plimit);
+			map_cont_memseg(start, delimit, plimit);
+		} else if (blk_end >= (MIN_MAP_INCRSZ << 1)) {
+			if (blk_end == end - delimit) {
+				map_cont_memseg(delimit, end, plimit);
+				map_cont_memseg(start, delimit, plimit);
+			} else {
+				map_cont_memseg(start, delimit, plimit);
+				map_cont_memseg(delimit, end, plimit);
+			}
+		} else
+			return 0;
+	} else if (blk_start < blk_end) {
+		/*
+		* In one PUD regime, only can mapping the sub-range that has
+		* one non-PMD alignment edge at most. Otherwise, the mapping
+		* will probably consume over MIN_MAP_INCRSZ space.
+		*/
+		phys_addr_t pud_start, pud_end;
+
+		pud_end = round_down(blk_end, PUD_SIZE);
+		pud_start = round_up(blk_start, PUD_SIZE);
+		/*first case: [blk_start, blk_end) spread in adjacent PUD */
+		if ((pud_start == pud_end) &&
+				pud_start != blk_start && pud_end != blk_end)
+			delimit = (blk_end > pud_end) ?
+					(blk_end = end, pud_end) : blk_start;
+		else if (pud_start < pud_end)
+			/*spread among multiple PUD*/
+			delimit = (blk_end > pud_end) ?
+					(blk_end = end, pud_end) : pud_start;
+		else {
+			/*
+			* spread in same PUD:
+			* if blk_end aligns to PUD boundary, mapping of
+			* [start,blk_end) should has higher priority.
+			*/
+			blk_end = (blk_end & ~PUD_MASK) ? end : blk_end;
+			delimit = ((blk_start & ~PUD_MASK) && !(blk_end & ~PMD_MASK)) ?
+					start : blk_start;
+		}
+		/*adjust the blk_end, try to map a bigger memory range*/
+		if (end - blk_end >= MIN_MAP_INCRSZ)
+			blk_end = end;
+
+		map_cont_memseg(delimit, blk_end, plimit);
+		/*
+		* now, at least one PMD was mapped. sufficient pages is ready
+		* for mapping the remaining sub-ranges.
+		*/
+		if (blk_end < end)
+			map_cont_memseg(blk_end, end, plimit);
+		if (start < delimit)
+			map_cont_memseg(start, delimit, plimit);
+	} else {
+		if (end - start < MIN_MAP_INCRSZ)
+			return 0;
+		map_cont_memseg(start, end, plimit);
+	}
+
+	return end - start;
+}
+
+
 static void __init map_mem(void)
 {
 	struct memblock_region *reg;
-	phys_addr_t limit;
 
-	/*
-	 * Temporarily limit the memblock range. We need to do this as
-	 * create_mapping requires puds, pmds and ptes to be allocated from
-	 * memory addressable from the initial direct kernel mapping.
-	 *
-	 * The initial direct kernel mapping, located at swapper_pg_dir, gives
-	 * us PUD_SIZE (4K pages) or PMD_SIZE (64K pages) memory starting from
-	 * PHYS_OFFSET (which must be aligned to 2MB as per
-	 * Documentation/arm64/booting.txt).
-	 */
-	if (IS_ENABLED(CONFIG_ARM64_64K_PAGES))
-		limit = PHYS_OFFSET + PMD_SIZE;
-	else
-		limit = PHYS_OFFSET + PUD_SIZE;
-	memblock_set_current_limit(limit);
+	size_t incr;
+	size_t mapped_sz = 0;
+	phys_addr_t limit = 0;
 
-	/* map all the memory banks */
-	for_each_memblock(memory, reg) {
-		phys_addr_t start = reg->base;
-		phys_addr_t end = start + reg->size;
+	phys_addr_t start, end;
 
-		if (start >= end)
+	/*set current_limit as the maximum addr mapped in head.S*/
+	limit = round_up(__pa_symbol(_end), INIT_MAP_PGSZ);
+	memblock_set_current_limit(limit);
+
+	for_each_memblock_reverse(memory, reg) {
+		start = reg->base;
+		end = start + reg->size;
+		/*
+		* the range does not cover even one page is invalid.
+		* wrap-wroud is invalid too.
+		*/
+		if (PFN_UP(start) >= PFN_DOWN(end))
 			break;
 
-#ifndef CONFIG_ARM64_64K_PAGES
+		incr = map_onerng_reverse(start, end, &limit);
 		/*
-		 * For the first memory bank align the start address and
-		 * current memblock limit to prevent create_mapping() from
-		 * allocating pte page tables from unmapped memory.
-		 * When 64K pages are enabled, the pte page table for the
-		 * first PGDIR_SIZE is already present in swapper_pg_dir.
-		 */
-		if (start < limit)
-			start = ALIGN(start, PMD_SIZE);
-		if (end < limit) {
-			limit = end & PMD_MASK;
-			memblock_set_current_limit(limit);
+		* if CONFIG_HAVE_MEMBLOCK_NODE_MAP is support in future,need
+		* to change the input parameter of nid.
+		* incr is Zero means the range is too small that can not map
+		* in this scanning. In avoid to be allocated by memblock APIs,
+		* temporarily reserve this range and set the flag in
+		* memblock.memory for the second scanning.
+		*/
+		if (!incr) {
+			memblock_add_range(&memblock.reserved, reg->base,
+				reg->size, NUMA_NO_NODE, reg->flags);
+			memblock_set_region_flags(reg, MEMBLOCK_TMP_UNMAP);
+		} else {
+			mapped_sz += incr;
 		}
-#endif
+	}
+	/*
+	* The second scanning. Supposed there are large memory ranges,
+	* after the first scanning, those large memory ranges were mapped,
+	* and supply sufficient pages to map the remaining small ranges.
+	*/
+	for_each_memblock(memory, reg) {
+		if (!(reg->flags & MEMBLOCK_TMP_UNMAP))
+			continue;
+
+		start = reg->base;
+		end = start + reg->size;
+
+		if (PFN_UP(start) >= PFN_DOWN(end))
+			break;
 
 		create_mapping(start, __phys_to_virt(start), end - start);
+		memblock_clear_region_flags(reg, MEMBLOCK_TMP_UNMAP);
+
+		memblock_remove_range(&memblock.reserved, reg->base,
+			reg->size);
 	}
 
 	/* Limit no longer required. */
diff --git a/include/linux/memblock.h b/include/linux/memblock.h
index e8cc453..4c09f7c 100644
--- a/include/linux/memblock.h
+++ b/include/linux/memblock.h
@@ -22,6 +22,7 @@
 
 /* Definition of memblock flags. */
 #define MEMBLOCK_HOTPLUG	0x1	/* hotpluggable region */
+#define MEMBLOCK_TMP_UNMAP	0x2	/* can not be mapped in first scan*/
 
 struct memblock_region {
 	phys_addr_t base;
@@ -356,6 +357,10 @@ static inline unsigned long memblock_region_reserved_end_pfn(const struct memblo
 	     region < (memblock.memblock_type.regions + memblock.memblock_type.cnt);	\
 	     region++)
 
+#define for_each_memblock_reverse(memblock_type, region)					\
+		for (region = memblock.memblock_type.regions + memblock.memblock_type.cnt - 1;	\
+		     region >= memblock.memblock_type.regions;	\
+		     region--)
 
 #ifdef CONFIG_ARCH_DISCARD_MEMBLOCK
 #define __init_memblock __meminit
-- 
1.7.9.5

[RFC PATCH v1] arm64:mm: An optimization about kernel direct sapce mapping

[zhichang.yuan at linaro.org]

From: "zhichang.yuan" <zhichang.yuan@linaro.org>

This patch make the processing of map_mem more common and support more
discrete memory layout cases.

In current map_mem, the processing is based on two hypotheses:
1) no any early page allocations occur before the first PMD or PUD regime
where the kernel image locate is successfully mapped;
2) there are sufficient available pages in the PMD or PUD regime to satisfy
the need of page tables from other memory ranges mapping.

The current SOC or hardware platform designs had not broken this constraint.
But we can make the software more versatile.

In addition, for the 4K page system, to comply with the constraint No.1, the
start address of some memory ranges is forced to align at PMD boundary, it
will make some marginal pages of that ranges are skipped to build the PTE. It
is not reasonable.

This patch will relieve the system from those constraints. You can load the
kernel image in any memory range, the memory range can be small, can start at
non-alignment boundary, and so on.

In this patch, the kernel space mapping will probably scan all memory ranges
twice. In the first scanning, those memory ranges whose size is larger than a
threshold are mapped, then the second scanning will map the smaller memory
ranges. Since the threshold is so small, in most cases, the second scanning is
NULL operation.

The patch is also accessible @
https://git.linaro.org/people/zhichang.yuan/pgalloc.git/shortlog/refs/heads/mapmem_linux_master

Signed-off-by: Zhichang Yuan <zhichang.yuan@linaro.org>
---
 arch/arm64/include/asm/page.h    |   10 ++
 arch/arm64/include/asm/pgtable.h |    3 +
 arch/arm64/kernel/vmlinux.lds.S  |    4 +
 arch/arm64/mm/mmu.c              |  230 ++++++++++++++++++++++++++++++++------
 include/linux/memblock.h         |    5 +
 5 files changed, 217 insertions(+), 35 deletions(-)

diff --git a/arch/arm64/include/asm/page.h b/arch/arm64/include/asm/page.h
index 22b1623..7c55e11 100644
--- a/arch/arm64/include/asm/page.h
+++ b/arch/arm64/include/asm/page.h
@@ -44,6 +44,16 @@
 #define SWAPPER_DIR_SIZE	(SWAPPER_PGTABLE_LEVELS * PAGE_SIZE)
 #define IDMAP_DIR_SIZE		(SWAPPER_DIR_SIZE)
 
+/*This macro has strong dependency with BLOCK_SIZE in head.S...*/
+#ifdef CONFIG_ARM64_64K_PAGES
+#define INIT_MAP_PGSZ	(PAGE_SIZE)
+/*we prepare one more page for probable memblock space extension*/
+#define PGT_BRK_SIZE	((SWAPPER_PGTABLE_LEVELS) << PAGE_SHIFT)
+#else
+#define INIT_MAP_PGSZ	(SECTION_SIZE)
+#define PGT_BRK_SIZE	((SWAPPER_PGTABLE_LEVELS + 1) << PAGE_SHIFT)
+#endif
+
 #ifndef __ASSEMBLY__
 
 #include <asm/pgtable-types.h>
diff --git a/arch/arm64/include/asm/pgtable.h b/arch/arm64/include/asm/pgtable.h
index 41a43bf..9f96c6c 100644
--- a/arch/arm64/include/asm/pgtable.h
+++ b/arch/arm64/include/asm/pgtable.h
@@ -464,6 +464,9 @@ static inline pmd_t pmd_modify(pmd_t pmd, pgprot_t newprot)
 extern pgd_t swapper_pg_dir[PTRS_PER_PGD];
 extern pgd_t idmap_pg_dir[PTRS_PER_PGD];
 
+/*define for kernel direct space mapping*/
+extern char pgtbrk_base[], pgtbrk_end[];
+
 /*
  * Encode and decode a swap entry:
  *	bits 0-1:	present (must be zero)
diff --git a/arch/arm64/kernel/vmlinux.lds.S b/arch/arm64/kernel/vmlinux.lds.S
index edf8715..ca5b69c 100644
--- a/arch/arm64/kernel/vmlinux.lds.S
+++ b/arch/arm64/kernel/vmlinux.lds.S
@@ -113,6 +113,10 @@ SECTIONS
 	swapper_pg_dir = .;
 	. += SWAPPER_DIR_SIZE;
 
+	pgtbrk_base = .;
+	. += PGT_BRK_SIZE;
+	pgtbrk_end = .;
+
 	_end = .;
 
 	STABS_DEBUG
diff --git a/arch/arm64/mm/mmu.c b/arch/arm64/mm/mmu.c
index f4f8b50..e56fbc8 100644
--- a/arch/arm64/mm/mmu.c
+++ b/arch/arm64/mm/mmu.c
@@ -67,6 +67,12 @@ static struct cachepolicy cache_policies[] __initdata = {
 };
 
 /*
+ * points to the specific brk regions. Those pages can be allocated for
+ * page tables usage.
+ */
+static unsigned long pgtbrk_sp = (unsigned long)pgtbrk_base;
+
+/*
  * These are useful for identifying cache coherency problems by allowing the
  * cache or the cache and writebuffer to be turned off. It changes the Normal
  * memory caching attributes in the MAIR_EL1 register.
@@ -131,7 +137,18 @@ EXPORT_SYMBOL(phys_mem_access_prot);
 
 static void __init *early_alloc(unsigned long sz)
 {
-	void *ptr = __va(memblock_alloc(sz, sz));
+	void *ptr;
+
+	if (!(sz & (~PAGE_MASK)) &&
+			pgtbrk_sp + sz <= (unsigned long)pgtbrk_end) {
+		ptr = (void *)pgtbrk_sp;
+		pgtbrk_sp += sz;
+		pr_info("BRK [0x%p, 0x%lx] PGTABLE\n",	ptr, pgtbrk_sp);
+
+	} else {
+		ptr = __va(memblock_alloc(sz, sz));
+	}
+
 	memset(ptr, 0, sz);
 	return ptr;
 }
@@ -287,52 +304,195 @@ void __init create_id_mapping(phys_addr_t addr, phys_addr_t size, int map_io)
 			 addr, addr, size, map_io);
 }
 
+/*
+* In the worst case, mapping one memory range or sub-range will comsume
+* MIN_MAP_INCRSZ pages. To garentee there are sufficient mapped pages
+* for the ranges to be mapped, it is priority to map those range that can
+* supply available pages over this macro value.
+* For 64K, one page less than SWAPPER_PGTABLE_LEVELS;
+* For 4K, SWAPPER_PGTABLE_LEVELS pages
+*/
+#ifdef CONFIG_ARM64_64K_PAGES
+#define MIN_MAP_INCRSZ		((SWAPPER_PGTABLE_LEVELS - 1) << PAGE_SHIFT)
+#else
+#define MIN_MAP_INCRSZ		(SWAPPER_PGTABLE_LEVELS << PAGE_SHIFT)
+#endif
+
+static inline void __init map_cont_memseg(phys_addr_t start,
+				phys_addr_t end, phys_addr_t *plimit)
+{
+	create_mapping(start, __phys_to_virt(start), end - start);
+	if (*plimit < end) {
+		*plimit = end;
+		memblock_set_current_limit(end);
+	}
+}
+
+/*
+* This function will map the designated memory range. If successfully do
+* the mapping, will update the current_limit as the maximal mapped address.
+*
+* each mapped memory range should at least supply (SWAPPER_PGTABLE_LEVELS - 1)
+* new mapped pages for the next range. Otherwise, that range should be reserved
+* for delay mapping.
+* The memory range will probably be divided into several sub-ranges.
+* The division will occur at the PMD, PUD boundaries.
+* In the worst case, one sub-range will spend (SWAPPER_PGTABLE_LEVELS - 1)
+* pages as page tables, we firstly map the sub-range that can provide enough
+* pages for the remaining sub-ranges.
+*/
+static size_t __init map_onerng_reverse(phys_addr_t start,
+			phys_addr_t end, phys_addr_t *plimit)
+{
+	phys_addr_t blk_start, blk_end;
+	phys_addr_t delimit = 0;
+
+	blk_start = round_up(start, PMD_SIZE);
+	blk_end = round_down(end, PMD_SIZE);
+
+	/*
+	* first case: start and end are spread in adjacent PMD
+	* second case: start and end are separated by@least one PMD
+	* third case: start and end are in same PMD
+	*/
+	if (blk_start == blk_end &&
+			blk_start != start && blk_end != end) {
+		delimit = blk_start;
+		/*blk_start is the minimum, blk_end is the maximum*/
+		if (end - delimit >= delimit - start) {
+			blk_end = end - delimit;
+			blk_start = delimit - start;
+		} else {
+			blk_end = delimit - start;
+			blk_start = end - delimit;
+		}
+		/*both sub-ranges can supply enough pages*/
+		if (blk_start >= MIN_MAP_INCRSZ) {
+			map_cont_memseg(delimit, end, plimit);
+			map_cont_memseg(start, delimit, plimit);
+		} else if (blk_end >= (MIN_MAP_INCRSZ << 1)) {
+			if (blk_end == end - delimit) {
+				map_cont_memseg(delimit, end, plimit);
+				map_cont_memseg(start, delimit, plimit);
+			} else {
+				map_cont_memseg(start, delimit, plimit);
+				map_cont_memseg(delimit, end, plimit);
+			}
+		} else
+			return 0;
+	} else if (blk_start < blk_end) {
+		/*
+		* In one PUD regime, only can mapping the sub-range that has
+		* one non-PMD alignment edge@most. Otherwise, the mapping
+		* will probably consume over MIN_MAP_INCRSZ space.
+		*/
+		phys_addr_t pud_start, pud_end;
+
+		pud_end = round_down(blk_end, PUD_SIZE);
+		pud_start = round_up(blk_start, PUD_SIZE);
+		/*first case: [blk_start, blk_end) spread in adjacent PUD */
+		if ((pud_start == pud_end) &&
+				pud_start != blk_start && pud_end != blk_end)
+			delimit = (blk_end > pud_end) ?
+					(blk_end = end, pud_end) : blk_start;
+		else if (pud_start < pud_end)
+			/*spread among multiple PUD*/
+			delimit = (blk_end > pud_end) ?
+					(blk_end = end, pud_end) : pud_start;
+		else {
+			/*
+			* spread in same PUD:
+			* if blk_end aligns to PUD boundary, mapping of
+			* [start,blk_end) should has higher priority.
+			*/
+			blk_end = (blk_end & ~PUD_MASK) ? end : blk_end;
+			delimit = ((blk_start & ~PUD_MASK) && !(blk_end & ~PMD_MASK)) ?
+					start : blk_start;
+		}
+		/*adjust the blk_end, try to map a bigger memory range*/
+		if (end - blk_end >= MIN_MAP_INCRSZ)
+			blk_end = end;
+
+		map_cont_memseg(delimit, blk_end, plimit);
+		/*
+		* now, at least one PMD was mapped. sufficient pages is ready
+		* for mapping the remaining sub-ranges.
+		*/
+		if (blk_end < end)
+			map_cont_memseg(blk_end, end, plimit);
+		if (start < delimit)
+			map_cont_memseg(start, delimit, plimit);
+	} else {
+		if (end - start < MIN_MAP_INCRSZ)
+			return 0;
+		map_cont_memseg(start, end, plimit);
+	}
+
+	return end - start;
+}
+
+
 static void __init map_mem(void)
 {
 	struct memblock_region *reg;
-	phys_addr_t limit;
 
-	/*
-	 * Temporarily limit the memblock range. We need to do this as
-	 * create_mapping requires puds, pmds and ptes to be allocated from
-	 * memory addressable from the initial direct kernel mapping.
-	 *
-	 * The initial direct kernel mapping, located@swapper_pg_dir, gives
-	 * us PUD_SIZE (4K pages) or PMD_SIZE (64K pages) memory starting from
-	 * PHYS_OFFSET (which must be aligned to 2MB as per
-	 * Documentation/arm64/booting.txt).
-	 */
-	if (IS_ENABLED(CONFIG_ARM64_64K_PAGES))
-		limit = PHYS_OFFSET + PMD_SIZE;
-	else
-		limit = PHYS_OFFSET + PUD_SIZE;
-	memblock_set_current_limit(limit);
+	size_t incr;
+	size_t mapped_sz = 0;
+	phys_addr_t limit = 0;
 
-	/* map all the memory banks */
-	for_each_memblock(memory, reg) {
-		phys_addr_t start = reg->base;
-		phys_addr_t end = start + reg->size;
+	phys_addr_t start, end;
 
-		if (start >= end)
+	/*set current_limit as the maximum addr mapped in head.S*/
+	limit = round_up(__pa_symbol(_end), INIT_MAP_PGSZ);
+	memblock_set_current_limit(limit);
+
+	for_each_memblock_reverse(memory, reg) {
+		start = reg->base;
+		end = start + reg->size;
+		/*
+		* the range does not cover even one page is invalid.
+		* wrap-wroud is invalid too.
+		*/
+		if (PFN_UP(start) >= PFN_DOWN(end))
 			break;
 
-#ifndef CONFIG_ARM64_64K_PAGES
+		incr = map_onerng_reverse(start, end, &limit);
 		/*
-		 * For the first memory bank align the start address and
-		 * current memblock limit to prevent create_mapping() from
-		 * allocating pte page tables from unmapped memory.
-		 * When 64K pages are enabled, the pte page table for the
-		 * first PGDIR_SIZE is already present in swapper_pg_dir.
-		 */
-		if (start < limit)
-			start = ALIGN(start, PMD_SIZE);
-		if (end < limit) {
-			limit = end & PMD_MASK;
-			memblock_set_current_limit(limit);
+		* if CONFIG_HAVE_MEMBLOCK_NODE_MAP is support in future,need
+		* to change the input parameter of nid.
+		* incr is Zero means the range is too small that can not map
+		* in this scanning. In avoid to be allocated by memblock APIs,
+		* temporarily reserve this range and set the flag in
+		* memblock.memory for the second scanning.
+		*/
+		if (!incr) {
+			memblock_add_range(&memblock.reserved, reg->base,
+				reg->size, NUMA_NO_NODE, reg->flags);
+			memblock_set_region_flags(reg, MEMBLOCK_TMP_UNMAP);
+		} else {
+			mapped_sz += incr;
 		}
-#endif
+	}
+	/*
+	* The second scanning. Supposed there are large memory ranges,
+	* after the first scanning, those large memory ranges were mapped,
+	* and supply sufficient pages to map the remaining small ranges.
+	*/
+	for_each_memblock(memory, reg) {
+		if (!(reg->flags & MEMBLOCK_TMP_UNMAP))
+			continue;
+
+		start = reg->base;
+		end = start + reg->size;
+
+		if (PFN_UP(start) >= PFN_DOWN(end))
+			break;
 
 		create_mapping(start, __phys_to_virt(start), end - start);
+		memblock_clear_region_flags(reg, MEMBLOCK_TMP_UNMAP);
+
+		memblock_remove_range(&memblock.reserved, reg->base,
+			reg->size);
 	}
 
 	/* Limit no longer required. */
diff --git a/include/linux/memblock.h b/include/linux/memblock.h
index e8cc453..4c09f7c 100644
--- a/include/linux/memblock.h
+++ b/include/linux/memblock.h
@@ -22,6 +22,7 @@
 
 /* Definition of memblock flags. */
 #define MEMBLOCK_HOTPLUG	0x1	/* hotpluggable region */
+#define MEMBLOCK_TMP_UNMAP	0x2	/* can not be mapped in first scan*/
 
 struct memblock_region {
 	phys_addr_t base;
@@ -356,6 +357,10 @@ static inline unsigned long memblock_region_reserved_end_pfn(const struct memblo
 	     region < (memblock.memblock_type.regions + memblock.memblock_type.cnt);	\
 	     region++)
 
+#define for_each_memblock_reverse(memblock_type, region)					\
+		for (region = memblock.memblock_type.regions + memblock.memblock_type.cnt - 1;	\
+		     region >= memblock.memblock_type.regions;	\
+		     region--)
 
 #ifdef CONFIG_ARCH_DISCARD_MEMBLOCK
 #define __init_memblock __meminit
-- 
1.7.9.5

Re: [RFC PATCH v1] arm64:mm: An optimization about kernel direct sapce mapping

[Catalin Marinas]

Hi,

I'm trying to make some sense of this patch, so questions below:

On Wed, Nov 19, 2014 at 02:21:55PM +0000, zhichang.yuan@linaro.org wrote:
> From: "zhichang.yuan" <zhichang.yuan@linaro.org>
> 
> This patch make the processing of map_mem more common and support more
> discrete memory layout cases.
> 
> In current map_mem, the processing is based on two hypotheses:
> 1) no any early page allocations occur before the first PMD or PUD regime
> where the kernel image locate is successfully mapped;

No because we use the kernel load offset to infer the start of RAM
(PHYS_OFFSET). This would define which memory you can allocate.

> 2) there are sufficient available pages in the PMD or PUD regime to satisfy
> the need of page tables from other memory ranges mapping.

I don't fully understand this. Can you be more specific?

> The current SOC or hardware platform designs had not broken this constraint.
> But we can make the software more versatile.

We need to have code readability in mind ;).

> In addition, for the 4K page system, to comply with the constraint No.1, the
> start address of some memory ranges is forced to align at PMD boundary, it
> will make some marginal pages of that ranges are skipped to build the PTE. It
> is not reasonable.

It is reasonable to ask for the start of RAM to be on a PMD (2MB)
boundary.

> This patch will relieve the system from those constraints. You can load the
> kernel image in any memory range, the memory range can be small, can start at
> non-alignment boundary, and so on.

I guess you still depend on the PAGE_OFFSET, TEXT_OFFSET, so it's not
random.

I'm not sure what the end goal is with this patch but my plan is to
entirely decouple TEXT_OFFSET from PAGE_OFFSET (with a duplicate mapping
for the memory covering the kernel text). This would allow us to load
the kernel anywhere in RAM (well, with some sane alignment to benefit
from section mapping) and the PHYS_OFFSET detected from DT at run-time.
Once that's done, I don't think your patch is necessary.

Thanks.

-- 
Catalin

[RFC PATCH v1] arm64:mm: An optimization about kernel direct sapce mapping

[Catalin Marinas]

Hi,

I'm trying to make some sense of this patch, so questions below:

On Wed, Nov 19, 2014 at 02:21:55PM +0000, zhichang.yuan at linaro.org wrote:
> From: "zhichang.yuan" <zhichang.yuan@linaro.org>
> 
> This patch make the processing of map_mem more common and support more
> discrete memory layout cases.
> 
> In current map_mem, the processing is based on two hypotheses:
> 1) no any early page allocations occur before the first PMD or PUD regime
> where the kernel image locate is successfully mapped;

No because we use the kernel load offset to infer the start of RAM
(PHYS_OFFSET). This would define which memory you can allocate.

> 2) there are sufficient available pages in the PMD or PUD regime to satisfy
> the need of page tables from other memory ranges mapping.

I don't fully understand this. Can you be more specific?

> The current SOC or hardware platform designs had not broken this constraint.
> But we can make the software more versatile.

We need to have code readability in mind ;).

> In addition, for the 4K page system, to comply with the constraint No.1, the
> start address of some memory ranges is forced to align at PMD boundary, it
> will make some marginal pages of that ranges are skipped to build the PTE. It
> is not reasonable.

It is reasonable to ask for the start of RAM to be on a PMD (2MB)
boundary.

> This patch will relieve the system from those constraints. You can load the
> kernel image in any memory range, the memory range can be small, can start at
> non-alignment boundary, and so on.

I guess you still depend on the PAGE_OFFSET, TEXT_OFFSET, so it's not
random.

I'm not sure what the end goal is with this patch but my plan is to
entirely decouple TEXT_OFFSET from PAGE_OFFSET (with a duplicate mapping
for the memory covering the kernel text). This would allow us to load
the kernel anywhere in RAM (well, with some sane alignment to benefit
from section mapping) and the PHYS_OFFSET detected from DT at run-time.
Once that's done, I don't think your patch is necessary.

Thanks.

-- 
Catalin

Re: [RFC PATCH v1] arm64:mm: An optimization about kernel direct sapce mapping

[zhichang.yuan]

On 2014年11月25日 01:17, Catalin Marinas wrote:
> Hi,
>
> I'm trying to make some sense of this patch, so questions below:
>
> On Wed, Nov 19, 2014 at 02:21:55PM +0000, zhichang.yuan@linaro.org wrote:
>> From: "zhichang.yuan" <zhichang.yuan@linaro.org>
>>
>> This patch make the processing of map_mem more common and support more
>> discrete memory layout cases.
>>
>> In current map_mem, the processing is based on two hypotheses:
>> 1) no any early page allocations occur before the first PMD or PUD regime
>> where the kernel image locate is successfully mapped;
> No because we use the kernel load offset to infer the start of RAM
> (PHYS_OFFSET). This would define which memory you can allocate.
I note that the current PHYS_OFFSET is 0x8000,0000 in JUNO, 0x4000,0000 in QEMU.  I think the current
processing like that:
the booloader load the kernel image at (PHYS_OFFSET + TEXT_OFFSET), and vmlinux.lds.S define the VMA of image
as (. = PAGE_OFFSET + TEXT_OFFSET). So, the starting RAM physical address, PHYS_OFFSET, correspond to
PAGE_OFFSET now.( this is my inference, have not investigate the UEFI)


But is it possible in the future the kernel image is loaded to a memory range that is not the first memblock,
such as :

block 0: 0x100000, 0x20100000
block 1: 0x40000000, 0x40000000

Supposed the block 1 is where the kernel image locate.


Actually, if bootloader put the kernel image at a configurable physical address named as PA, and VMA of text
section is defined as PAGE_OFFSET + 0x100000 + PA, then PAGE_OFFSET will correspond to 0x100000.

In x86, the VMA of text section is as below:

#ifdef CONFIG_X86_32
        . = LOAD_OFFSET + LOAD_PHYSICAL_ADDR;
#else
        . = __START_KERNEL;
#endif

LOAD_PHYSICAL_ADD is configurable. I think it can support different hardware design.


I am not sure whether this case will happen.

>> 2) there are sufficient available pages in the PMD or PUD regime to satisfy
>> the need of page tables from other memory ranges mapping.
> I don't fully understand this. Can you be more specific?
>
Supposed this memory layout:

block 0: 0x40000000, 0xc00000
block 1: 0x60000000, 0x1f000000
block 2: 0x80000000, 0x40000000

if the end of kernel image is near to 0xc00000, it is possible no available mapped pages for other blocks
mapping.

Of-course, this is a very special case, not practical, since the memblock where the kernel image locate should
be big enough.

>> The current SOC or hardware platform designs had not broken this constraint.
>> But we can make the software more versatile.
> We need to have code readability in mind ;).
>
>> In addition, for the 4K page system, to comply with the constraint No.1, the
>> start address of some memory ranges is forced to align at PMD boundary, it
>> will make some marginal pages of that ranges are skipped to build the PTE. It
>> is not reasonable.
> It is reasonable to ask for the start of RAM to be on a PMD (2MB)
> boundary.
I think the physical address where the kernel image locate can be limited on PMD boundary. But the start of
RAM is decided by Soc or hardware platform. For example, the start of RAM only align to MB boundary.
>> This patch will relieve the system from those constraints. You can load the
>> kernel image in any memory range, the memory range can be small, can start at
>> non-alignment boundary, and so on.
> I guess you still depend on the PAGE_OFFSET, TEXT_OFFSET, so it's not
> random.
>
> I'm not sure what the end goal is with this patch but my plan is to
> entirely decouple TEXT_OFFSET from PAGE_OFFSET (with a duplicate mapping
> for the memory covering the kernel text). This would allow us to load
> the kernel anywhere in RAM (well, with some sane alignment to benefit
> from section mapping) and the PHYS_OFFSET detected from DT at run-time.
> Once that's done, I don't think your patch is necessary.
>
> Thanks.


I am not so clear what is the coupling between TEXT_OFFSET and PAGE_OFFSET. It seems the VMA and LMA have some
coupling.

PHYS_OFFSET + TEXT_OFFSET <------------> PAGE_OFFSET + TEXT_OFFSET.

I am not sure what situation will be happened on the SOC design or application, that is the reason why i
submit as RFC.
If the cases i described do not need to think about or can not exist, this RFC can be skipped.


Thanks,
-Zhichang

[RFC PATCH v1] arm64:mm: An optimization about kernel direct sapce mapping

[zhichang.yuan]

On 2014?11?25? 01:17, Catalin Marinas wrote:
> Hi,
>
> I'm trying to make some sense of this patch, so questions below:
>
> On Wed, Nov 19, 2014 at 02:21:55PM +0000, zhichang.yuan at linaro.org wrote:
>> From: "zhichang.yuan" <zhichang.yuan@linaro.org>
>>
>> This patch make the processing of map_mem more common and support more
>> discrete memory layout cases.
>>
>> In current map_mem, the processing is based on two hypotheses:
>> 1) no any early page allocations occur before the first PMD or PUD regime
>> where the kernel image locate is successfully mapped;
> No because we use the kernel load offset to infer the start of RAM
> (PHYS_OFFSET). This would define which memory you can allocate.
I note that the current PHYS_OFFSET is 0x8000,0000 in JUNO, 0x4000,0000 in QEMU.  I think the current
processing like that:
the booloader load the kernel image at (PHYS_OFFSET + TEXT_OFFSET), and vmlinux.lds.S define the VMA of image
as (. = PAGE_OFFSET + TEXT_OFFSET). So, the starting RAM physical address, PHYS_OFFSET, correspond to
PAGE_OFFSET now.( this is my inference, have not investigate the UEFI)


But is it possible in the future the kernel image is loaded to a memory range that is not the first memblock,
such as :

block 0: 0x100000, 0x20100000
block 1: 0x40000000, 0x40000000

Supposed the block 1 is where the kernel image locate.


Actually, if bootloader put the kernel image at a configurable physical address named as PA, and VMA of text
section is defined as PAGE_OFFSET + 0x100000 + PA, then PAGE_OFFSET will correspond to 0x100000.

In x86, the VMA of text section is as below:

#ifdef CONFIG_X86_32
        . = LOAD_OFFSET + LOAD_PHYSICAL_ADDR;
#else
        . = __START_KERNEL;
#endif

LOAD_PHYSICAL_ADD is configurable. I think it can support different hardware design.


I am not sure whether this case will happen.

>> 2) there are sufficient available pages in the PMD or PUD regime to satisfy
>> the need of page tables from other memory ranges mapping.
> I don't fully understand this. Can you be more specific?
>
Supposed this memory layout:

block 0: 0x40000000, 0xc00000
block 1: 0x60000000, 0x1f000000
block 2: 0x80000000, 0x40000000

if the end of kernel image is near to 0xc00000, it is possible no available mapped pages for other blocks
mapping.

Of-course, this is a very special case, not practical, since the memblock where the kernel image locate should
be big enough.

>> The current SOC or hardware platform designs had not broken this constraint.
>> But we can make the software more versatile.
> We need to have code readability in mind ;).
>
>> In addition, for the 4K page system, to comply with the constraint No.1, the
>> start address of some memory ranges is forced to align at PMD boundary, it
>> will make some marginal pages of that ranges are skipped to build the PTE. It
>> is not reasonable.
> It is reasonable to ask for the start of RAM to be on a PMD (2MB)
> boundary.
I think the physical address where the kernel image locate can be limited on PMD boundary. But the start of
RAM is decided by Soc or hardware platform. For example, the start of RAM only align to MB boundary.
>> This patch will relieve the system from those constraints. You can load the
>> kernel image in any memory range, the memory range can be small, can start at
>> non-alignment boundary, and so on.
> I guess you still depend on the PAGE_OFFSET, TEXT_OFFSET, so it's not
> random.
>
> I'm not sure what the end goal is with this patch but my plan is to
> entirely decouple TEXT_OFFSET from PAGE_OFFSET (with a duplicate mapping
> for the memory covering the kernel text). This would allow us to load
> the kernel anywhere in RAM (well, with some sane alignment to benefit
> from section mapping) and the PHYS_OFFSET detected from DT at run-time.
> Once that's done, I don't think your patch is necessary.
>
> Thanks.


I am not so clear what is the coupling between TEXT_OFFSET and PAGE_OFFSET. It seems the VMA and LMA have some
coupling.

PHYS_OFFSET + TEXT_OFFSET <------------> PAGE_OFFSET + TEXT_OFFSET.

I am not sure what situation will be happened on the SOC design or application, that is the reason why i
submit as RFC.
If the cases i described do not need to think about or can not exist, this RFC can be skipped.


Thanks,
-Zhichang

Re: [RFC PATCH v1] arm64:mm: An optimization about kernel direct sapce mapping

[Catalin Marinas]

On Tue, Nov 25, 2014 at 02:16:07PM +0000, zhichang.yuan wrote:
> On 2014年11月25日 01:17, Catalin Marinas wrote:
> > I'm trying to make some sense of this patch, so questions below:
> >
> > On Wed, Nov 19, 2014 at 02:21:55PM +0000, zhichang.yuan@linaro.org wrote:
> >> From: "zhichang.yuan" <zhichang.yuan@linaro.org>
> >>
> >> This patch make the processing of map_mem more common and support more
> >> discrete memory layout cases.
> >>
> >> In current map_mem, the processing is based on two hypotheses:
> >> 1) no any early page allocations occur before the first PMD or PUD regime
> >> where the kernel image locate is successfully mapped;
> > No because we use the kernel load offset to infer the start of RAM
> > (PHYS_OFFSET). This would define which memory you can allocate.
> 
> I note that the current PHYS_OFFSET is 0x8000,0000 in JUNO,
> 0x4000,0000 in QEMU.  I think the current processing like that: the
> booloader load the kernel image at (PHYS_OFFSET + TEXT_OFFSET), and
> vmlinux.lds.S define the VMA of image as (. = PAGE_OFFSET +
> TEXT_OFFSET). So, the starting RAM physical address, PHYS_OFFSET,
> correspond to PAGE_OFFSET now.( this is my inference, have not
> investigate the UEFI)

Yes, but the PAGE_OFFSET / PHYS_OFFSET relation is true on any
architecture. The linear kernel mapping translates virtual address at
PAGE_OFFSET to physical address PHYS_OFFSET.

Also note that PHYS_OFFSET is not known at build time. The kernel entry
code calculates it by subtracting TEXT_OFFSET from its load address.
TEXT_OFFSET is known at build time.

> But is it possible in the future the kernel image is loaded to a
> memory range that is not the first memblock, such as :
> 
> block 0: 0x100000, 0x20100000
> block 1: 0x40000000, 0x40000000
> 
> Supposed the block 1 is where the kernel image locate.
> 
> Actually, if bootloader put the kernel image at a configurable
> physical address named as PA, and VMA of text section is defined as
> PAGE_OFFSET + 0x100000 + PA, then PAGE_OFFSET will correspond to
> 0x100000.

Basically what you want is configurable TEXT_OFFSET based on your
configurable physical address PA. For single kernel Image running on
multiple platforms, we don't want this. PA in this case would be
platform specific.

> In x86, the VMA of text section is as below:
> 
> #ifdef CONFIG_X86_32
>         . = LOAD_OFFSET + LOAD_PHYSICAL_ADDR;
> #else
>         . = __START_KERNEL;
> #endif
> 
> LOAD_PHYSICAL_ADD is configurable. I think it can support different
> hardware design.

One x86, this LOAD_PHYSICAL_ADDR is defined to CONFIG_PHYSICAL_START
which is only enabled if EXPERT || CRASH_DUMP. It's not a general user
config option for exactly the same reasons as stated above - single
kernel Image.

> >> 2) there are sufficient available pages in the PMD or PUD regime to satisfy
> >> the need of page tables from other memory ranges mapping.
> >
> > I don't fully understand this. Can you be more specific?
> 
> Supposed this memory layout:
> 
> block 0: 0x40000000, 0xc00000
> block 1: 0x60000000, 0x1f000000
> block 2: 0x80000000, 0x40000000
> 
> if the end of kernel image is near to 0xc00000, it is possible no
> available mapped pages for other blocks mapping.
> 
> Of-course, this is a very special case, not practical, since the
> memblock where the kernel image locate should be big enough.

So is this a real use-case?

> >> In addition, for the 4K page system, to comply with the constraint No.1, the
> >> start address of some memory ranges is forced to align at PMD boundary, it
> >> will make some marginal pages of that ranges are skipped to build the PTE. It
> >> is not reasonable.
> >
> > It is reasonable to ask for the start of RAM to be on a PMD (2MB)
> > boundary.
>
> I think the physical address where the kernel image locate can be
> limited on PMD boundary. But the start of RAM is decided by Soc or
> hardware platform. For example, the start of RAM only align to MB
> boundary.

But, again, do you have a real use-case in mind or just theoretical? For
arm64, we expect at least a bit of alignment with the SBSA where the
memory starts on a GB boundary.

> >> This patch will relieve the system from those constraints. You can load the
> >> kernel image in any memory range, the memory range can be small, can start at
> >> non-alignment boundary, and so on.
> >
> > I guess you still depend on the PAGE_OFFSET, TEXT_OFFSET, so it's not
> > random.
> >
> > I'm not sure what the end goal is with this patch but my plan is to
> > entirely decouple TEXT_OFFSET from PAGE_OFFSET (with a duplicate mapping
> > for the memory covering the kernel text). This would allow us to load
> > the kernel anywhere in RAM (well, with some sane alignment to benefit
> > from section mapping) and the PHYS_OFFSET detected from DT at run-time.
> > Once that's done, I don't think your patch is necessary.
> 
> I am not so clear what is the coupling between TEXT_OFFSET and
> PAGE_OFFSET. It seems the VMA and LMA have some coupling.

(I don't entirely follow the VMA and LMA acronyms, something to do with
virtual address and load address?)

> PHYS_OFFSET + TEXT_OFFSET <------------> PAGE_OFFSET + TEXT_OFFSET.

What I meant is that we should no longer mandate that the kernel Image
is loaded at PHYS_OFFSET + TEXT_OFFSET.

With additional kernel changes it could be loaded at (TEXT_OFFSET +
random-2MB-aligned-address) which gets mapped during boot to a
KERNEL_PAGE_OFFSET, different from PAGE_OFFSET. We still have the
PAGE_OFFSET -> PHYS_OFFSET correspondence but not with
KERNEL_PAGE_OFFSET. TEXT_OFFSET, PAGE_OFFSET and KERNEL_PAGE_OFFSET
would be build-time configurations while PHYS_OFFSET would be computed
at run-time based on the memory blocks described in DT (rather than
kernel-load-addr - TEXT_OFFSET).

-- 
Catalin

[RFC PATCH v1] arm64:mm: An optimization about kernel direct sapce mapping

[Catalin Marinas]

On Tue, Nov 25, 2014 at 02:16:07PM +0000, zhichang.yuan wrote:
> On 2014?11?25? 01:17, Catalin Marinas wrote:
> > I'm trying to make some sense of this patch, so questions below:
> >
> > On Wed, Nov 19, 2014 at 02:21:55PM +0000, zhichang.yuan at linaro.org wrote:
> >> From: "zhichang.yuan" <zhichang.yuan@linaro.org>
> >>
> >> This patch make the processing of map_mem more common and support more
> >> discrete memory layout cases.
> >>
> >> In current map_mem, the processing is based on two hypotheses:
> >> 1) no any early page allocations occur before the first PMD or PUD regime
> >> where the kernel image locate is successfully mapped;
> > No because we use the kernel load offset to infer the start of RAM
> > (PHYS_OFFSET). This would define which memory you can allocate.
> 
> I note that the current PHYS_OFFSET is 0x8000,0000 in JUNO,
> 0x4000,0000 in QEMU.  I think the current processing like that: the
> booloader load the kernel image at (PHYS_OFFSET + TEXT_OFFSET), and
> vmlinux.lds.S define the VMA of image as (. = PAGE_OFFSET +
> TEXT_OFFSET). So, the starting RAM physical address, PHYS_OFFSET,
> correspond to PAGE_OFFSET now.( this is my inference, have not
> investigate the UEFI)

Yes, but the PAGE_OFFSET / PHYS_OFFSET relation is true on any
architecture. The linear kernel mapping translates virtual address at
PAGE_OFFSET to physical address PHYS_OFFSET.

Also note that PHYS_OFFSET is not known at build time. The kernel entry
code calculates it by subtracting TEXT_OFFSET from its load address.
TEXT_OFFSET is known at build time.

> But is it possible in the future the kernel image is loaded to a
> memory range that is not the first memblock, such as :
> 
> block 0: 0x100000, 0x20100000
> block 1: 0x40000000, 0x40000000
> 
> Supposed the block 1 is where the kernel image locate.
> 
> Actually, if bootloader put the kernel image at a configurable
> physical address named as PA, and VMA of text section is defined as
> PAGE_OFFSET + 0x100000 + PA, then PAGE_OFFSET will correspond to
> 0x100000.

Basically what you want is configurable TEXT_OFFSET based on your
configurable physical address PA. For single kernel Image running on
multiple platforms, we don't want this. PA in this case would be
platform specific.

> In x86, the VMA of text section is as below:
> 
> #ifdef CONFIG_X86_32
>         . = LOAD_OFFSET + LOAD_PHYSICAL_ADDR;
> #else
>         . = __START_KERNEL;
> #endif
> 
> LOAD_PHYSICAL_ADD is configurable. I think it can support different
> hardware design.

One x86, this LOAD_PHYSICAL_ADDR is defined to CONFIG_PHYSICAL_START
which is only enabled if EXPERT || CRASH_DUMP. It's not a general user
config option for exactly the same reasons as stated above - single
kernel Image.

> >> 2) there are sufficient available pages in the PMD or PUD regime to satisfy
> >> the need of page tables from other memory ranges mapping.
> >
> > I don't fully understand this. Can you be more specific?
> 
> Supposed this memory layout:
> 
> block 0: 0x40000000, 0xc00000
> block 1: 0x60000000, 0x1f000000
> block 2: 0x80000000, 0x40000000
> 
> if the end of kernel image is near to 0xc00000, it is possible no
> available mapped pages for other blocks mapping.
> 
> Of-course, this is a very special case, not practical, since the
> memblock where the kernel image locate should be big enough.

So is this a real use-case?

> >> In addition, for the 4K page system, to comply with the constraint No.1, the
> >> start address of some memory ranges is forced to align at PMD boundary, it
> >> will make some marginal pages of that ranges are skipped to build the PTE. It
> >> is not reasonable.
> >
> > It is reasonable to ask for the start of RAM to be on a PMD (2MB)
> > boundary.
>
> I think the physical address where the kernel image locate can be
> limited on PMD boundary. But the start of RAM is decided by Soc or
> hardware platform. For example, the start of RAM only align to MB
> boundary.

But, again, do you have a real use-case in mind or just theoretical? For
arm64, we expect at least a bit of alignment with the SBSA where the
memory starts on a GB boundary.

> >> This patch will relieve the system from those constraints. You can load the
> >> kernel image in any memory range, the memory range can be small, can start at
> >> non-alignment boundary, and so on.
> >
> > I guess you still depend on the PAGE_OFFSET, TEXT_OFFSET, so it's not
> > random.
> >
> > I'm not sure what the end goal is with this patch but my plan is to
> > entirely decouple TEXT_OFFSET from PAGE_OFFSET (with a duplicate mapping
> > for the memory covering the kernel text). This would allow us to load
> > the kernel anywhere in RAM (well, with some sane alignment to benefit
> > from section mapping) and the PHYS_OFFSET detected from DT at run-time.
> > Once that's done, I don't think your patch is necessary.
> 
> I am not so clear what is the coupling between TEXT_OFFSET and
> PAGE_OFFSET. It seems the VMA and LMA have some coupling.

(I don't entirely follow the VMA and LMA acronyms, something to do with
virtual address and load address?)

> PHYS_OFFSET + TEXT_OFFSET <------------> PAGE_OFFSET + TEXT_OFFSET.

What I meant is that we should no longer mandate that the kernel Image
is loaded at PHYS_OFFSET + TEXT_OFFSET.

With additional kernel changes it could be loaded at (TEXT_OFFSET +
random-2MB-aligned-address) which gets mapped during boot to a
KERNEL_PAGE_OFFSET, different from PAGE_OFFSET. We still have the
PAGE_OFFSET -> PHYS_OFFSET correspondence but not with
KERNEL_PAGE_OFFSET. TEXT_OFFSET, PAGE_OFFSET and KERNEL_PAGE_OFFSET
would be build-time configurations while PHYS_OFFSET would be computed
at run-time based on the memory blocks described in DT (rather than
kernel-load-addr - TEXT_OFFSET).

-- 
Catalin