SHD-CacheAttackLab/Part1-Timing/utility.h

#include <stdint.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <unistd.h>
#include <signal.h>
#include <assert.h>

#ifndef __UTILITY_H__
#define __UTILITY_H__

#define SAMPLES 10


// Function to read the time stamp counter, which is called tsc for short
// "rdtscpp" returns a 32bit unsigned integer
// "rdtscpp64" return a 64 bit unsigned integer
// Details in https://www.felixcloutier.com/x86/rdtscp
static inline uint32_t rdtscpp() {
    uint32_t rv;
    asm volatile ("rdtscpp": "=a" (rv) :: "edx", "ecx");
    return rv;
}

static inline uint64_t rdtscpp64() {
    uint32_t low, high;
    asm volatile ("rdtscpp": "=a" (low), "=d" (high) :: "ecx");
    return (((uint64_t)high) << 32) | low;
}

// Function "lfence" wrap the assembly instruction lfence
// This function performs a serializing operation which ensures that
// the instructions after "lfence" start execution after
// all the instructions before "lfence" complete
// Details in https://www.felixcloutier.com/x86/lfence
static inline void lfence() {
    asm volatile("lfence");
}

// Here is an example of using "rdtscp" and "mfence" to
// measure the time it takes to access a block specified by its virtual address
// The corresponding pseudo code is
// =========
// t1 = rdtscp
// load addr
// t2 = rdtscp
// cycles = t2 - t1
// return cycles
// =========
static inline uint64_t measure_one_block_access_time(uint64_t addr)
{
    uint64_t cycles;

    asm volatile("mov %1, %%r8\n\t"
    "mfence\n\t"
    "lfence\n\t"
    "rdtscp\n\t"
    "mov %%eax, %%edi\n\t"
    "mov (%%r8), %%r8\n\t"
    "rdtscp\n\t"
    "sub %%edi, %%eax\n\t"
    : "=a"(cycles) /*output*/
    : "r"(addr)    /*input*/
    : "r8", "edi"); /*reserved register*/

    return cycles;
}

static inline uint64_t one_block_access(uint64_t addr)
{
    asm volatile("mov (%0), %%r8\n\t"
    : /*output*/
    : "r"(addr)    /*input*/
    : "r8");    /*reserved register*/

}


// A wrapper function of the clflush instruction
// The instruction evict the given address from the cache to DRAM
// so that the next time the line is accessed, it will be fetched from DRAM
// Details in https://www.felixcloutier.com/x86/clflush
static inline void clflush(void *v) {
    asm volatile ("clflush 0(%0)": : "r" (v):);
}


// Supporting functions for printing results in different formats
// Function "compare" is used in the priting functions and you do not need it
int compare(const void *p1, const void *p2) {
    uint64_t u1 = *(uint64_t *)p1;
    uint64_t u2 = *(uint64_t *)p2;

    return (int)u1 - (int)u2;
}


// Print out the latencies you measured
void print_results_plaintext(uint64_t* dram, uint64_t* l1, uint64_t* l2, uint64_t* l3) {
    qsort(dram, SAMPLES, sizeof(uint64_t), compare);
    qsort(l1, SAMPLES, sizeof(uint64_t), compare);
    qsort(l2, SAMPLES, sizeof(uint64_t), compare);
    qsort(l3, SAMPLES, sizeof(uint64_t), compare);
    printf("             :  L1   L2   L3   Mem   \n");
    printf("Minimum      : %5ld %5ld %5ld %5ld\n", l1[0], l2[0], l3[0], dram[0]);

    printf("Bottom decile: %5ld %5ld %5ld %5ld\n", l1[SAMPLES/10], l2[SAMPLES/10],
                                                l3[SAMPLES/10], dram[SAMPLES/10]);

    printf("Median       : %5ld %5ld %5ld %5ld\n", l1[SAMPLES/2], l2[SAMPLES/2],
                                                l3[SAMPLES/2], dram[SAMPLES/2]);

    printf("Top decile   : %5ld %5ld %5ld %5ld\n", l1[(SAMPLES * 9)/10], l2[(SAMPLES * 9)/10],
                                                   l3[(SAMPLES * 9)/10], dram[(SAMPLES * 9)/10]);

    printf("Maximum      : %5ld %5ld %5ld %5ld\n", l1[SAMPLES-1], l2[SAMPLES-1],
                                                    l3[SAMPLES-1], dram[SAMPLES-1]);
}

// Format the latencies for part 1.5
void print_results_for_visualization(uint64_t* dram, uint64_t* l1, uint64_t* l2, uint64_t* l3)
{
    qsort(dram, SAMPLES, sizeof(uint64_t), compare);
    qsort(l1,   SAMPLES, sizeof(uint64_t), compare);
    qsort(l2,   SAMPLES, sizeof(uint64_t), compare);
    qsort(l3,   SAMPLES, sizeof(uint64_t), compare);

    for (int i = 0; i < SAMPLES; i++) {
        printf("%ld ", l1[i]);
    }
    printf("\n");
    for (int i = 0; i < SAMPLES; i++) {
        printf("%ld ", l2[i]);
    }
    printf("\n");
    for (int i = 0; i < SAMPLES; i++) {
        printf("%ld ", l3[i]);
    }
    printf("\n");
    for (int i = 0; i < SAMPLES; i++) {
        printf("%ld ", dram[i]);
    }
    printf("\n");
}

#endif // _UTILITY_H__
Initial cache attack lab commit 2023-01-31 20:19:02 +00:00			`#include <stdint.h>`
			`#include <stdio.h>`
			`#include <stdlib.h>`
			`#include <string.h>`
			`#include <unistd.h>`
			`#include <signal.h>`
			`#include <assert.h>`

			`#ifndef __UTILITY_H__`
			`#define __UTILITY_H__`

			`#define SAMPLES 10`


			`// Function to read the time stamp counter, which is called tsc for short`
			`// "rdtscpp" returns a 32bit unsigned integer`
			`// "rdtscpp64" return a 64 bit unsigned integer`
2024 release 2024-02-07 14:23:56 +00:00			`// Details in https://www.felixcloutier.com/x86/rdtscp`
Initial cache attack lab commit 2023-01-31 20:19:02 +00:00			`static inline uint32_t rdtscpp() {`
			`uint32_t rv;`
			`asm volatile ("rdtscpp": "=a" (rv) :: "edx", "ecx");`
			`return rv;`
			`}`

			`static inline uint64_t rdtscpp64() {`
			`uint32_t low, high;`
			`asm volatile ("rdtscpp": "=a" (low), "=d" (high) :: "ecx");`
			`return (((uint64_t)high) << 32) \| low;`
			`}`

			`// Function "lfence" wrap the assembly instruction lfence`
			`// This function performs a serializing operation which ensures that`
			`// the instructions after "lfence" start execution after`
			`// all the instructions before "lfence" complete`
			`// Details in https://www.felixcloutier.com/x86/lfence`
			`static inline void lfence() {`
			`asm volatile("lfence");`
			`}`

			`// Here is an example of using "rdtscp" and "mfence" to`
			`// measure the time it takes to access a block specified by its virtual address`
			`// The corresponding pseudo code is`
			`// =========`
			`// t1 = rdtscp`
			`// load addr`
			`// t2 = rdtscp`
			`// cycles = t2 - t1`
			`// return cycles`
			`// =========`
			`static inline uint64_t measure_one_block_access_time(uint64_t addr)`
			`{`
			`uint64_t cycles;`

			`asm volatile("mov %1, %%r8\n\t"`
			`"mfence\n\t"`
			`"lfence\n\t"`
			`"rdtscp\n\t"`
			`"mov %%eax, %%edi\n\t"`
			`"mov (%%r8), %%r8\n\t"`
			`"rdtscp\n\t"`
			`"sub %%edi, %%eax\n\t"`
			`: "=a"(cycles) /output/`
			`: "r"(addr) /input/`
			`: "r8", "edi"); /reserved register/`

			`return cycles;`
			`}`

			`static inline uint64_t one_block_access(uint64_t addr)`
			`{`
			`asm volatile("mov (%0), %%r8\n\t"`
			`: /output/`
			`: "r"(addr) /input/`
			`: "r8"); /reserved register/`

			`}`


			`// A wrapper function of the clflush instruction`
			`// The instruction evict the given address from the cache to DRAM`
			`// so that the next time the line is accessed, it will be fetched from DRAM`
			`// Details in https://www.felixcloutier.com/x86/clflush`
			`static inline void clflush(void *v) {`
			`asm volatile ("clflush 0(%0)": : "r" (v):);`
			`}`




			`// Supporting functions for printing results in different formats`
			`// Function "compare" is used in the priting functions and you do not need it`
			`int compare(const void p1, const void p2) {`
			`uint64_t u1 = (uint64_t )p1;`
			`uint64_t u2 = (uint64_t )p2;`

			`return (int)u1 - (int)u2;`
			`}`


			`// Print out the latencies you measured`
2024 release 2024-02-07 14:23:56 +00:00			`void print_results_plaintext(uint64_t* dram, uint64_t* l1, uint64_t* l2, uint64_t* l3) {`
Initial cache attack lab commit 2023-01-31 20:19:02 +00:00			`qsort(dram, SAMPLES, sizeof(uint64_t), compare);`
			`qsort(l1, SAMPLES, sizeof(uint64_t), compare);`
			`qsort(l2, SAMPLES, sizeof(uint64_t), compare);`
			`qsort(l3, SAMPLES, sizeof(uint64_t), compare);`
			`printf(" : L1 L2 L3 Mem \n");`
			`printf("Minimum : %5ld %5ld %5ld %5ld\n", l1[0], l2[0], l3[0], dram[0]);`

			`printf("Bottom decile: %5ld %5ld %5ld %5ld\n", l1[SAMPLES/10], l2[SAMPLES/10],`
			`l3[SAMPLES/10], dram[SAMPLES/10]);`

			`printf("Median : %5ld %5ld %5ld %5ld\n", l1[SAMPLES/2], l2[SAMPLES/2],`
			`l3[SAMPLES/2], dram[SAMPLES/2]);`

			`printf("Top decile : %5ld %5ld %5ld %5ld\n", l1[(SAMPLES * 9)/10], l2[(SAMPLES * 9)/10],`
			`l3[(SAMPLES * 9)/10], dram[(SAMPLES * 9)/10]);`

			`printf("Maximum : %5ld %5ld %5ld %5ld\n", l1[SAMPLES-1], l2[SAMPLES-1],`
			`l3[SAMPLES-1], dram[SAMPLES-1]);`
			`}`

			`// Format the latencies for part 1.5`
2024 release 2024-02-07 14:23:56 +00:00			`void print_results_for_visualization(uint64_t* dram, uint64_t* l1, uint64_t* l2, uint64_t* l3)`
Initial cache attack lab commit 2023-01-31 20:19:02 +00:00			`{`
			`qsort(dram, SAMPLES, sizeof(uint64_t), compare);`
			`qsort(l1, SAMPLES, sizeof(uint64_t), compare);`
			`qsort(l2, SAMPLES, sizeof(uint64_t), compare);`
			`qsort(l3, SAMPLES, sizeof(uint64_t), compare);`

			`for (int i = 0; i < SAMPLES; i++) {`
			`printf("%ld ", l1[i]);`
			`}`
			`printf("\n");`
			`for (int i = 0; i < SAMPLES; i++) {`
			`printf("%ld ", l2[i]);`
			`}`
			`printf("\n");`
			`for (int i = 0; i < SAMPLES; i++) {`
			`printf("%ld ", l3[i]);`
			`}`
			`printf("\n");`
			`for (int i = 0; i < SAMPLES; i++) {`
			`printf("%ld ", dram[i]);`
			`}`
			`printf("\n");`
			`}`

			`#endif // _UTILITY_H__`