powerpc/8xx: Implementation of PAGE_EXEC

This patch implements PAGE_EXEC capability on the 8xx.

All pages PP exec bits are set to 000, which means Execute for
Supervisor and no Execute for User.
Then we use the APG to say whether accesses are according to Page
rules, "all Supervisor" rules (Exec for all) and
"all User" rules (Exec for noone)

Therefore, we define 4 APG groups. msb is _PAGE_EXEC,
lsb is _PAGE_USER. MI_AP is initialised as follows:
GP0 (00) => Not User, no exec => 11 (all accesses performed as user)
GP1 (01) => User but no exec => 11 (all accesses performed as user)
GP2 (10) => Not User, exec => 01 (rights according to page definition)
GP3 (11) => User, exec => 00 (all accesses performed as supervisor)

Signed-off-by: Christophe Leroy <christophe.leroy@c-s.fr>
[scottwood: comments: s/exec/data/ on data side, and s/pages/pages'/]
Signed-off-by: Scott Wood <scottwood@freescale.com>
This commit is contained in:
LEROY Christophe 2015-04-22 12:06:45 +02:00 committed by Scott Wood
parent e0a8e0d90a
commit 5b2753fc3e
4 changed files with 38 additions and 5 deletions

View File

@ -366,7 +366,7 @@ enum {
CPU_FTR_USE_TB | CPU_FTR_MAYBE_CAN_NAP | \ CPU_FTR_USE_TB | CPU_FTR_MAYBE_CAN_NAP | \
CPU_FTR_COMMON | CPU_FTR_FPU_UNAVAILABLE) CPU_FTR_COMMON | CPU_FTR_FPU_UNAVAILABLE)
#define CPU_FTRS_CLASSIC32 (CPU_FTR_COMMON | CPU_FTR_USE_TB) #define CPU_FTRS_CLASSIC32 (CPU_FTR_COMMON | CPU_FTR_USE_TB)
#define CPU_FTRS_8XX (CPU_FTR_USE_TB) #define CPU_FTRS_8XX (CPU_FTR_USE_TB | CPU_FTR_NOEXECUTE)
#define CPU_FTRS_40X (CPU_FTR_USE_TB | CPU_FTR_NODSISRALIGN | CPU_FTR_NOEXECUTE) #define CPU_FTRS_40X (CPU_FTR_USE_TB | CPU_FTR_NODSISRALIGN | CPU_FTR_NOEXECUTE)
#define CPU_FTRS_44X (CPU_FTR_USE_TB | CPU_FTR_NODSISRALIGN | CPU_FTR_NOEXECUTE) #define CPU_FTRS_44X (CPU_FTR_USE_TB | CPU_FTR_NODSISRALIGN | CPU_FTR_NOEXECUTE)
#define CPU_FTRS_440x6 (CPU_FTR_USE_TB | CPU_FTR_NODSISRALIGN | CPU_FTR_NOEXECUTE | \ #define CPU_FTRS_440x6 (CPU_FTR_USE_TB | CPU_FTR_NODSISRALIGN | CPU_FTR_NOEXECUTE | \

View File

@ -27,6 +27,19 @@
#define MI_Ks 0x80000000 /* Should not be set */ #define MI_Ks 0x80000000 /* Should not be set */
#define MI_Kp 0x40000000 /* Should always be set */ #define MI_Kp 0x40000000 /* Should always be set */
/*
* All pages' PP exec bits are set to 000, which means Execute for Supervisor
* and no Execute for User.
* Then we use the APG to say whether accesses are according to Page rules,
* "all Supervisor" rules (Exec for all) and "all User" rules (Exec for noone)
* Therefore, we define 4 APG groups. msb is _PAGE_EXEC, lsb is _PAGE_USER
* 0 (00) => Not User, no exec => 11 (all accesses performed as user)
* 1 (01) => User but no exec => 11 (all accesses performed as user)
* 2 (10) => Not User, exec => 01 (rights according to page definition)
* 3 (11) => User, exec => 00 (all accesses performed as supervisor)
*/
#define MI_APG_INIT 0xf4ffffff
/* The effective page number register. When read, contains the information /* The effective page number register. When read, contains the information
* about the last instruction TLB miss. When MI_RPN is written, bits in * about the last instruction TLB miss. When MI_RPN is written, bits in
* this register are used to create the TLB entry. * this register are used to create the TLB entry.
@ -87,6 +100,19 @@
#define MD_Ks 0x80000000 /* Should not be set */ #define MD_Ks 0x80000000 /* Should not be set */
#define MD_Kp 0x40000000 /* Should always be set */ #define MD_Kp 0x40000000 /* Should always be set */
/*
* All pages' PP data bits are set to either 000 or 011, which means
* respectively RW for Supervisor and no access for User, or RO for
* Supervisor and no access for user.
* Then we use the APG to say whether accesses are according to Page rules or
* "all Supervisor" rules (Access to all)
* Therefore, we define 2 APG groups. lsb is _PAGE_USER
* 0 => No user => 01 (all accesses performed according to page definition)
* 1 => User => 00 (all accesses performed as supervisor
* according to page definition)
*/
#define MD_APG_INIT 0x4fffffff
/* The effective page number register. When read, contains the information /* The effective page number register. When read, contains the information
* about the last instruction TLB miss. When MD_RPN is written, bits in * about the last instruction TLB miss. When MD_RPN is written, bits in
* this register are used to create the TLB entry. * this register are used to create the TLB entry.

View File

@ -39,8 +39,9 @@
*/ */
#define _PAGE_GUARDED 0x0010 /* Copied to L1 G entry in DTLB */ #define _PAGE_GUARDED 0x0010 /* Copied to L1 G entry in DTLB */
#define _PAGE_USER 0x0020 /* Copied to L1 APG lsb */ #define _PAGE_USER 0x0020 /* Copied to L1 APG lsb */
#define _PAGE_ACCESSED 0x0040 /* software: page referenced */ #define _PAGE_EXEC 0x0040 /* Copied to L1 APG */
#define _PAGE_WRITETHRU 0x0080 /* software: caching is write through */ #define _PAGE_WRITETHRU 0x0080 /* software: caching is write through */
#define _PAGE_ACCESSED 0x0800 /* software: page referenced */
#define _PAGE_RO 0x0600 /* Supervisor RO, User no access */ #define _PAGE_RO 0x0600 /* Supervisor RO, User no access */

View File

@ -357,7 +357,7 @@ InstructionTLBMiss:
lwz r10, 0(r10) /* Get the pte */ lwz r10, 0(r10) /* Get the pte */
/* Insert the APG into the TWC from the Linux PTE. */ /* Insert the APG into the TWC from the Linux PTE. */
rlwimi r11, r10, 0, 26, 26 rlwimi r11, r10, 0, 25, 26
/* Load the MI_TWC with the attributes for this "segment." */ /* Load the MI_TWC with the attributes for this "segment." */
MTSPR_CPU6(SPRN_MI_TWC, r11, r3) /* Set segment attributes */ MTSPR_CPU6(SPRN_MI_TWC, r11, r3) /* Set segment attributes */
@ -449,6 +449,7 @@ DataStoreTLBMiss:
*/ */
li r11, RPN_PATTERN li r11, RPN_PATTERN
rlwimi r10, r11, 0, 24, 28 /* Set 24-27, clear 28 */ rlwimi r10, r11, 0, 24, 28 /* Set 24-27, clear 28 */
rlwimi r10, r11, 0, 20, 20 /* clear 20 */
MTSPR_CPU6(SPRN_MD_RPN, r10, r3) /* Update TLB entry */ MTSPR_CPU6(SPRN_MD_RPN, r10, r3) /* Update TLB entry */
/* Restore registers */ /* Restore registers */
@ -769,15 +770,20 @@ initial_mmu:
ori r8, r8, MI_EVALID /* Mark it valid */ ori r8, r8, MI_EVALID /* Mark it valid */
mtspr SPRN_MI_EPN, r8 mtspr SPRN_MI_EPN, r8
mtspr SPRN_MD_EPN, r8 mtspr SPRN_MD_EPN, r8
li r8, MI_PS8MEG /* Set 8M byte page */ li r8, MI_PS8MEG | (2 << 5) /* Set 8M byte page, APG 2 */
ori r8, r8, MI_SVALID /* Make it valid */ ori r8, r8, MI_SVALID /* Make it valid */
mtspr SPRN_MI_TWC, r8 mtspr SPRN_MI_TWC, r8
li r8, MI_PS8MEG /* Set 8M byte page, APG 0 */
ori r8, r8, MI_SVALID /* Make it valid */
mtspr SPRN_MD_TWC, r8 mtspr SPRN_MD_TWC, r8
li r8, MI_BOOTINIT /* Create RPN for address 0 */ li r8, MI_BOOTINIT /* Create RPN for address 0 */
mtspr SPRN_MI_RPN, r8 /* Store TLB entry */ mtspr SPRN_MI_RPN, r8 /* Store TLB entry */
mtspr SPRN_MD_RPN, r8 mtspr SPRN_MD_RPN, r8
lis r8, MI_Kp@h /* Set the protection mode */ lis r8, MI_APG_INIT@h /* Set protection modes */
ori r8, r8, MI_APG_INIT@l
mtspr SPRN_MI_AP, r8 mtspr SPRN_MI_AP, r8
lis r8, MD_APG_INIT@h
ori r8, r8, MD_APG_INIT@l
mtspr SPRN_MD_AP, r8 mtspr SPRN_MD_AP, r8
/* Map another 8 MByte at the IMMR to get the processor /* Map another 8 MByte at the IMMR to get the processor