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/* mc_dram.c - Memory Controller testbench dram test
         Copyright (C) 2001 by Ivan Guzvinec, ivang@opencores.org
 
         This file is part of OpenRISC 1000 Architectural Simulator.
 
         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; either version 2 of the License, or
         (at your option) any later version.
 
         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., 675 Mass Ave, Cambridge, MA 02139, USA.
*/
 
#include "support.h"
 
#include "mc_common.h"
#include "mc_dram.h"
#include "../peripheral/mc.h"
#include "../peripheral/gpio.h"
#include "../peripheral/fields.h"
 
#define T_ROW_SIZE      8
#define T_ROW_OFF       5
#define T_ROWS          25
#define T_GROUPS        3
 
typedef volatile unsigned long *REGISTER;
 
/*
unsigned long nRowSize = 0;
unsigned long nColumns = 0;
*/
REGISTER mc_poc        = (unsigned long*)(MC_BASE + MC_POC);
REGISTER mc_csr        = (unsigned long*)(MC_BASE + MC_CSR);
REGISTER mc_ba_mask    = (unsigned long*)(MC_BASE + MC_BA_MASK);
 
REGISTER rgpio_out     = (unsigned long*)(GPIO_BASE + RGPIO_OUT);
REGISTER rgpio_in      = (unsigned long*)(GPIO_BASE + RGPIO_IN);
 
unsigned long lpoc;
unsigned char mc_cs;
 
unsigned long set_config()
{
    REGISTER mc_csc;
    unsigned char ch;
 
    for (ch=0; ch<8; ch++) {
        if (MC_SDRAM_CSMASK & (0x01 << ch) ) {
            mc_csc = (unsigned long*)(MC_BASE + MC_CSC(ch));
            SET_FIELD(*mc_csc, MC_CSC, MS,  mc_sdram_cs[ch].MS);
            SET_FIELD(*mc_csc, MC_CSC, BW,  mc_sdram_cs[ch].BW);
            SET_FIELD(*mc_csc, MC_CSC, SEL, mc_sdram_cs[ch].M);
            SET_FLAG(*mc_csc, MC_CSC, EN);
            printf ("Channel Config %d - CSC = 0x%08lX\n", ch, *mc_csc);
        }
    }
 
    return 0;
}
 
unsigned long get_config()
{
  REGISTER mc_csc;
  REGISTER mc_tms;
  unsigned char ch;
 
  mc_cs = 0;
  for (ch=0; ch<8; ch++) {
    mc_csc = (unsigned long*)(MC_BASE + MC_CSC(ch));
    mc_tms = (unsigned long*)(MC_BASE + MC_TMS(ch));
    if ( (GET_FIELD(*mc_csc, MC_CSC, MEMTYPE) == 0) &&
         (TEST_FLAG(*mc_csc, MC_CSC, EN) == 1     ) ) {
      mc_sdram_cs[ch].MS = GET_FIELD(*mc_csc, MC_CSC, MS);
      mc_sdram_cs[ch].BW = GET_FIELD(*mc_csc, MC_CSC, BW);
      mc_sdram_cs[ch].M  = GET_FIELD(*mc_csc, MC_CSC, SEL);
      mc_cs |= (1 << ch);
 
      printf("get_config(%d) : MS=0x%0lx, BW=0x%0lx, M=0x%0lx\n", ch,
             mc_sdram_cs[ch].MS,
             mc_sdram_cs[ch].BW,
             mc_sdram_cs[ch].M);
    }
  }
  printf("get_config() : cs=0x%0x\n", mc_cs);
  return 0;
}
 
int main()
{
    unsigned long ret;
    unsigned char ch;
 
    unsigned long j, i;
    unsigned long test;
    unsigned long gpio_pat = 0;
 
    unsigned long nRowSize = 0;
    unsigned long nRows    = 0;
    unsigned long nRowSh   = 0;
    unsigned long nRowGrp  = 0;
 
    unsigned long nAddress;
    unsigned long mc_sel;
    REGISTER mc_tms;
    REGISTER mc_csc;
 
    *rgpio_out = 0xFFFFFFFF;
 
    /* set configuration */
    randomin(7435);
    lpoc = *mc_poc;
 
#ifdef MC_READ_CONF
    if (get_config()) {
      printf("Error reading MC configuration\n");
      report(0x00000001);
      return(1);
    }
#else
    mc_cs = MC_SDRAM_CSMASK;
#endif
 
    for (ch=0; ch<8; ch++) {
        if (mc_cs & (0x01 << ch) ) {
            printf ("--- Begin Test on CS%d ---\n", ch);
 
            mc_csc = (unsigned long*)(MC_BASE + MC_CSC(ch));
            mc_tms = (unsigned long*)(MC_BASE + MC_TMS(ch));
            mc_sel = GET_FIELD(*mc_csc, MC_CSC, SEL);
 
            SET_FIELD(*mc_tms, MC_TMS_SDRAM, OM, 0); /*normal op*/
            SET_FIELD(*mc_tms, MC_TMS_SDRAM, CL, 3); /*CAS*/
 
            switch ( mc_sdram_cs[ch].BW + (3 * mc_sdram_cs[ch].MS) ) {
            case 0:
            case 4:
                nRowSize = MC_SDRAM_ROWSIZE_0;
                nRows    = MC_SDRAM_ROWS_0;
                nRowSh   = MC_SDRAM_ROWSH_0; break;
            case 1:
            case 5:
                nRowSize = MC_SDRAM_ROWSIZE_1;
                nRows    = MC_SDRAM_ROWS_1;
                nRowSh   = MC_SDRAM_ROWSH_1; break;
            case 2:
                nRowSize = MC_SDRAM_ROWSIZE_2;
                nRows    = MC_SDRAM_ROWS_2;
                nRowSh   = MC_SDRAM_ROWSH_2;  break;
            case 3:
                nRowSize = MC_SDRAM_ROWSIZE_3;
                nRows    = MC_SDRAM_ROWS_3;
                nRowSh   = MC_SDRAM_ROWSH_3; break;
            case 6:
                nRowSize = MC_SDRAM_ROWSIZE_6;
                nRows    = MC_SDRAM_ROWS_6;
                nRowSh   = MC_SDRAM_ROWSH_6; break;
            case 7:
                nRowSize = MC_SDRAM_ROWSIZE_7;
                nRows    = MC_SDRAM_ROWS_7;
                nRowSh   = MC_SDRAM_ROWSH_7; break;
            case 8:
                nRowSize = MC_SDRAM_ROWSIZE_8;
                nRows    = MC_SDRAM_ROWS_8;
                nRowSh   = MC_SDRAM_ROWSH_8; break;
            }
 
            printf ("CS configuration : CSC - 0x%08lX, TMS - 0x%08lX, rs = %lu, nr = %lu, sh = %lu, sel = %lu\n",
                    *mc_csc, *mc_tms, nRowSize, nRows, nRowSh, mc_sel);
 
            /*nRows -= MC_SDRAM_ROW_OFF;*/
            for (test=0; test<16; test++) {
                /* configure MC*/
                CLEAR_FLAG(*mc_csc, MC_CSC, PEN); /* no parity */
                CLEAR_FLAG(*mc_csc, MC_CSC, KRO); /* close row */
                CLEAR_FLAG(*mc_csc, MC_CSC, BAS); /* bank after column */
                CLEAR_FLAG(*mc_csc, MC_CSC, WP);  /* write enable */
                SET_FLAG(*mc_tms, MC_TMS_SDRAM, WBL); /* single loc access */
                CLEAR_FLAG(*mc_tms, MC_TMS_SDRAM, BT); /* sequential burst */
                SET_FIELD(*mc_tms, MC_TMS_SDRAM, BL, 0); /* 1 */
                switch (test) {
                case 0:
                    if ((MC_SDRAM_TESTS & MC_SDRAM_TEST0) != MC_SDRAM_TEST0)
                        continue;
                    break;
                case 1:
                    if ((MC_SDRAM_TESTS & MC_SDRAM_TEST1) != MC_SDRAM_TEST1)
                        continue;
                    SET_FLAG(*mc_csc, MC_CSC, PEN); /* parity */
                    break;
                case 2:
                    if ((MC_SDRAM_TESTS & MC_SDRAM_TEST2) != MC_SDRAM_TEST2)
                        continue;
                    SET_FLAG(*mc_csc, MC_CSC, KRO); /* keep row */
                    break;
                case 3:
                    if ((MC_SDRAM_TESTS & MC_SDRAM_TEST3) != MC_SDRAM_TEST3)
                        continue;
                    SET_FLAG(*mc_csc, MC_CSC, BAS); /* bank after row*/
                    break;
                case 4:
                    if ((MC_SDRAM_TESTS & MC_SDRAM_TEST4) != MC_SDRAM_TEST4)
                        continue;
                    SET_FLAG(*mc_csc, MC_CSC, WP);  /* RO */
                    break;
                case 5:
                    if ((MC_SDRAM_TESTS & MC_SDRAM_TEST5) != MC_SDRAM_TEST5)
                        continue;
                    CLEAR_FLAG(*mc_tms, MC_TMS_SDRAM, WBL); /* burst */
                    break;
                case 6:
                    if ((MC_SDRAM_TESTS & MC_SDRAM_TEST6) != MC_SDRAM_TEST6)
                        continue;
                    CLEAR_FLAG(*mc_tms, MC_TMS_SDRAM, WBL); /* burst */
                    SET_FIELD(*mc_tms, MC_TMS_SDRAM, BL, 1); /* 2 */
                    break;
                case 7:
                    if ((MC_SDRAM_TESTS & MC_SDRAM_TEST7) != MC_SDRAM_TEST7)
                        continue;
                    CLEAR_FLAG(*mc_tms, MC_TMS_SDRAM, WBL); /* burst */
                    SET_FIELD(*mc_tms, MC_TMS_SDRAM, BL, 2); /* 4 */
                    break;
                case 8:
                    if ((MC_SDRAM_TESTS & MC_SDRAM_TEST8) != MC_SDRAM_TEST8)
                        continue;
                    CLEAR_FLAG(*mc_tms, MC_TMS_SDRAM, WBL); /* burst */
                    SET_FIELD(*mc_tms, MC_TMS_SDRAM, BL, 3); /* 8 */
                    break;
                case 9:
                    if ((MC_SDRAM_TESTS & MC_SDRAM_TEST9) != MC_SDRAM_TEST9)
                        continue;
                    CLEAR_FLAG(*mc_tms, MC_TMS_SDRAM, WBL); /* burst */
                    SET_FIELD(*mc_tms, MC_TMS_SDRAM, BL, 7); /* full page */
                    break;
                case 10:
                    if ((MC_SDRAM_TESTS & MC_SDRAM_TEST10) != MC_SDRAM_TEST10)
                        continue;
                    CLEAR_FLAG(*mc_tms, MC_TMS_SDRAM, WBL); /* burst */
                    SET_FLAG(*mc_tms, MC_TMS_SDRAM, BT); /* interleaved burst */
                    break;
                case 11:
                    if ((MC_SDRAM_TESTS & MC_SDRAM_TEST11) != MC_SDRAM_TEST11)
                        continue;
                    CLEAR_FLAG(*mc_tms, MC_TMS_SDRAM, WBL); /* burst */
                    SET_FLAG(*mc_tms, MC_TMS_SDRAM, BT); /* interleaved burst */
                    SET_FIELD(*mc_tms, MC_TMS_SDRAM, BL, 1); /* 2 */
                    break;
                case 12:
                    if ((MC_SDRAM_TESTS & MC_SDRAM_TEST12) != MC_SDRAM_TEST12)
                        continue;
                    CLEAR_FLAG(*mc_tms, MC_TMS_SDRAM, WBL); /* burst */
                    SET_FLAG(*mc_tms, MC_TMS_SDRAM, BT); /* interleaved burst */
                    SET_FIELD(*mc_tms, MC_TMS_SDRAM, BL, 2); /* 4 */
                    break;
                case 13:
                    if ((MC_SDRAM_TESTS & MC_SDRAM_TEST13) != MC_SDRAM_TEST13)
                        continue;
                    CLEAR_FLAG(*mc_tms, MC_TMS_SDRAM, WBL); /* burst */
                    SET_FLAG(*mc_tms, MC_TMS_SDRAM, BT); /* interleaved burst */
                    SET_FIELD(*mc_tms, MC_TMS_SDRAM, BL, 3); /* 8 */
                    break;
                case 14:
                    if ((MC_SDRAM_TESTS & MC_SDRAM_TEST14) != MC_SDRAM_TEST14)
                        continue;
                    CLEAR_FLAG(*mc_tms, MC_TMS_SDRAM, WBL); /* burst */
                    SET_FLAG(*mc_tms, MC_TMS_SDRAM, BT); /* interleaved burst */
                    SET_FIELD(*mc_tms, MC_TMS_SDRAM, BL, 7); /* fullrow */
                    break;
                case 15:
                    if ((MC_SDRAM_TESTS & MC_SDRAM_TEST15) != MC_SDRAM_TEST15)
                        continue;
                    SET_FLAG(*mc_csc, MC_CSC, KRO);  /* keep row */
                    CLEAR_FLAG(*mc_tms, MC_TMS_SDRAM, WBL); /* burst */
                    SET_FLAG(*mc_tms, MC_TMS_SDRAM, BT); /* interleaved burst */
                    SET_FIELD(*mc_tms, MC_TMS_SDRAM, BL, 1); /* 2 */
                    break;
                } /*switch test*/
 
                printf ("Begin TEST %lu : CSC - 0x%08lX, TMS - 0x%08lX\n", test, *mc_csc, *mc_tms);
 
                if (MC_SDRAM_ACC & MC_SDRAM_SROW) {
                    /* perform sequential row access */
                    printf("Seuential Row\n");
                    for (j=0; j<T_ROWS; j++) {
                        nAddress  = mc_sel << 21;
                        nAddress |= MC_MEM_BASE;
                        nAddress += ( (j + T_ROW_OFF) << nRowSh);
 
                        gpio_pat ^= 0x00000008;
                        *rgpio_out = gpio_pat;
                        ret = mc_test_row(nAddress, nAddress + T_ROW_SIZE, MC_SDRAM_FLAGS);
 
                        printf("\trow - %lu: nAddress = 0x%08lX, ret = 0x%08lX\n", j, nAddress, ret);
 
                        if (ret) {
                            gpio_pat ^= 0x00000080;
                            *rgpio_out = gpio_pat;
                            report(ret);
                            return ret;
                        }
                    }
                }
 
                if (MC_SDRAM_ACC & MC_SDRAM_RROW) {
                    /* perform random row access */
                    printf("Random Row\n");
                    for (j=0; j<T_ROWS; j++) {
                        nAddress = mc_sel << 21;
                        nAddress |= MC_MEM_BASE;
                        nAddress += ( (T_ROW_OFF + random(nRows)) << nRowSh);
 
                        gpio_pat ^= 0x00000008;
                        *rgpio_out = gpio_pat;
                        ret = mc_test_row(nAddress, nAddress + T_ROW_SIZE, MC_SDRAM_FLAGS);
 
                        printf("\trow - %lu: nAddress = 0x%08lX, ret = 0x%08lX\n", j, nAddress, ret);
 
                        if (ret) {
                            gpio_pat ^= 0x00000080;
                            *rgpio_out = gpio_pat;
                            report(ret);
                            return ret;
                        }
                    }
                }
 
                if (MC_SDRAM_ACC & MC_SDRAM_SGRP) {
                    /* perform sequential row in group access */
                    printf("Sequential Group ");
 
                    printf("Group Size = %d\n", MC_SDRAM_GROUPSIZE);
                    for (i=0; i<T_GROUPS; i++) {
                        nRowGrp = random(nRows - MC_SDRAM_GROUPSIZE) + T_ROW_OFF;
                        for (j=0; j<MC_SDRAM_GROUPSIZE; j++) {
                            nAddress = mc_sel << 21;
                            nAddress |= MC_MEM_BASE;
                            nAddress += ((nRowGrp+j) << nRowSh);
 
                            gpio_pat ^= 0x00000008;
                            *rgpio_out = gpio_pat;
                            ret = mc_test_row(nAddress, nAddress + T_ROW_SIZE, MC_SDRAM_FLAGS);
 
                            printf("\trow - %lu: nAddress = 0x%08lX, ret = 0x%08lX\n", j, nAddress, ret);
 
                            if (ret) {
                                gpio_pat ^= 0x00000080;
                                *rgpio_out = gpio_pat;
                                report(ret);
                                return ret;
                            }
                        }
                    }
                }
 
                if (MC_SDRAM_ACC & MC_SDRAM_RGRP) {
                    /* perform random row in group access */
                    printf("Random Group ");
 
                    printf("Group Size = %d\n", MC_SDRAM_GROUPSIZE);
                    for (i=0; i<T_GROUPS; i++) {
                        nRowGrp = random(nRows - T_GROUPS) + T_ROW_OFF;
                        for (j=0; j<MC_SDRAM_GROUPSIZE; j++) {
                            nAddress = mc_sel << 21;
                            nAddress |= MC_MEM_BASE;
                            nAddress += ((nRowGrp + random(MC_SDRAM_GROUPSIZE)) << nRowSh);
 
                            gpio_pat ^= 0x00000008;
                            *rgpio_out = gpio_pat;
                            ret = mc_test_row(nAddress, nAddress + T_ROW_SIZE, MC_SDRAM_FLAGS);
 
                            printf("\trow - %lu: nAddress = 0x%08lX, ret = 0x%08lX\n", j, nAddress, ret);
 
                            if (ret) {
                                gpio_pat ^= 0x00000080;
                                *rgpio_out = gpio_pat;
                                report(ret);
                                return ret;
                            }
                        }
                    }
                } /*for groups*/
 
            } /*for test*/
        } /*if*/
    } /*for CS*/
    printf("--- End SDRAM tests ---\n");
    report(0xDEADDEAD);
 
    gpio_pat ^= 0x00000020;
    *rgpio_out = gpio_pat;
 
    return 0;
} /* main */

Line No.	Rev	Author	Line
1	454	ivang	`/* mc_dram.c - Memory Controller testbench dram test`
2			`Copyright (C) 2001 by Ivan Guzvinec, ivang@opencores.org`
3
4			`This file is part of OpenRISC 1000 Architectural Simulator.`
5
6			`This program is free software; you can redistribute it and/or modify`
7			`it under the terms of the GNU General Public License as published by`
8			`the Free Software Foundation; either version 2 of the License, or`
9			`(at your option) any later version.`
10
11			`This program is distributed in the hope that it will be useful,`
12			`but WITHOUT ANY WARRANTY; without even the implied warranty of`
13			`MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the`
14			`GNU General Public License for more details.`
15
16			`You should have received a copy of the GNU General Public License`
17			`along with this program; if not, write to the Free Software`
18			`Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.`
19			`*/`
20
21			`#include "support.h"`
22
23			`#include "mc_common.h"`
24			`#include "mc_dram.h"`
25			`#include "../peripheral/mc.h"`
26	544	ivang	`#include "../peripheral/gpio.h"`
27	454	ivang	`#include "../peripheral/fields.h"`
28
29	552	ivang	`#define T_ROW_SIZE 8`
30			`#define T_ROW_OFF 5`
31			`#define T_ROWS 25`
32			`#define T_GROUPS 3`
33
34	454	ivang	`typedef volatile unsigned long *REGISTER;`
35
36	552	ivang	`/*`
37	454	ivang	`unsigned long nRowSize = 0;`
38			`unsigned long nColumns = 0;`
39	552	ivang	`*/`
40	454	ivang	`REGISTER mc_poc = (unsigned long*)(MC_BASE + MC_POC);`
41			`REGISTER mc_csr = (unsigned long*)(MC_BASE + MC_CSR);`
42			`REGISTER mc_ba_mask = (unsigned long*)(MC_BASE + MC_BA_MASK);`
43
44	544	ivang	`REGISTER rgpio_out = (unsigned long*)(GPIO_BASE + RGPIO_OUT);`
45			`REGISTER rgpio_in = (unsigned long*)(GPIO_BASE + RGPIO_IN);`
46
47	454	ivang	`unsigned long lpoc;`
48	552	ivang	`unsigned char mc_cs;`
49	454	ivang
50			`unsigned long set_config()`
51			`{`
52			`REGISTER mc_csc;`
53			`unsigned char ch;`
54
55			`for (ch=0; ch<8; ch++) {`
56			`if (MC_SDRAM_CSMASK & (0x01 << ch) ) {`
57			`mc_csc = (unsigned long*)(MC_BASE + MC_CSC(ch));`
58			`SET_FIELD(*mc_csc, MC_CSC, MS, mc_sdram_cs[ch].MS);`
59			`SET_FIELD(*mc_csc, MC_CSC, BW, mc_sdram_cs[ch].BW);`
60			`SET_FIELD(*mc_csc, MC_CSC, SEL, mc_sdram_cs[ch].M);`
61			`SET_FLAG(*mc_csc, MC_CSC, EN);`
62	1024	simons	`printf ("Channel Config %d - CSC = 0x%08lX\n", ch, *mc_csc);`
63	454	ivang	`}`
64			`}`
65
66			`return 0;`
67			`}`
68
69	552	ivang	`unsigned long get_config()`
70			`{`
71			`REGISTER mc_csc;`
72			`REGISTER mc_tms;`
73			`unsigned char ch;`
74
75			`mc_cs = 0;`
76			`for (ch=0; ch<8; ch++) {`
77			`mc_csc = (unsigned long*)(MC_BASE + MC_CSC(ch));`
78			`mc_tms = (unsigned long*)(MC_BASE + MC_TMS(ch));`
79			`if ( (GET_FIELD(*mc_csc, MC_CSC, MEMTYPE) == 0) &&`
80			`(TEST_FLAG(*mc_csc, MC_CSC, EN) == 1 ) ) {`
81			`mc_sdram_cs[ch].MS = GET_FIELD(*mc_csc, MC_CSC, MS);`
82			`mc_sdram_cs[ch].BW = GET_FIELD(*mc_csc, MC_CSC, BW);`
83			`mc_sdram_cs[ch].M = GET_FIELD(*mc_csc, MC_CSC, SEL);`
84			`mc_cs \|= (1 << ch);`
85
86	1024	simons	`printf("get_config(%d) : MS=0x%0lx, BW=0x%0lx, M=0x%0lx\n", ch,`
87	552	ivang	`mc_sdram_cs[ch].MS,`
88			`mc_sdram_cs[ch].BW,`
89			`mc_sdram_cs[ch].M);`
90			`}`
91			`}`
92	1024	simons	`printf("get_config() : cs=0x%0x\n", mc_cs);`
93	552	ivang	`return 0;`
94			`}`
95
96	454	ivang	`int main()`
97			`{`
98			`unsigned long ret;`
99			`unsigned char ch;`
100
101			`unsigned long j, i;`
102			`unsigned long test;`
103	544	ivang	`unsigned long gpio_pat = 0;`
104	454	ivang
105			`unsigned long nRowSize = 0;`
106			`unsigned long nRows = 0;`
107			`unsigned long nRowSh = 0;`
108			`unsigned long nRowGrp = 0;`
109
110			`unsigned long nAddress;`
111			`unsigned long mc_sel;`
112			`REGISTER mc_tms;`
113	552	ivang	`REGISTER mc_csc;`
114	454	ivang
115	544	ivang	`*rgpio_out = 0xFFFFFFFF;`
116
117	454	ivang	`/* set configuration */`
118			`randomin(7435);`
119	544	ivang	`lpoc = *mc_poc;`
120	552	ivang
121			`#ifdef MC_READ_CONF`
122			`if (get_config()) {`
123	1024	simons	`printf("Error reading MC configuration\n");`
124	552	ivang	`report(0x00000001);`
125			`return(1);`
126	454	ivang	`}`
127	552	ivang	`#else`
128			`mc_cs = MC_SDRAM_CSMASK;`
129			`#endif`
130
131	454	ivang	`for (ch=0; ch<8; ch++) {`
132	552	ivang	`if (mc_cs & (0x01 << ch) ) {`
133	1024	simons	`printf ("--- Begin Test on CS%d ---\n", ch);`
134	454	ivang
135	552	ivang	`mc_csc = (unsigned long*)(MC_BASE + MC_CSC(ch));`
136	454	ivang	`mc_tms = (unsigned long*)(MC_BASE + MC_TMS(ch));`
137	552	ivang	`mc_sel = GET_FIELD(*mc_csc, MC_CSC, SEL);`
138	454	ivang
139			`SET_FIELD(mc_tms, MC_TMS_SDRAM, OM, 0); /normal op*/`
140			`SET_FIELD(mc_tms, MC_TMS_SDRAM, CL, 3); /CAS*/`
141
142			`switch ( mc_sdram_cs[ch].BW + (3 * mc_sdram_cs[ch].MS) ) {`
143			`case 0:`
144			`case 4:`
145			`nRowSize = MC_SDRAM_ROWSIZE_0;`
146			`nRows = MC_SDRAM_ROWS_0;`
147			`nRowSh = MC_SDRAM_ROWSH_0; break;`
148			`case 1:`
149			`case 5:`
150			`nRowSize = MC_SDRAM_ROWSIZE_1;`
151			`nRows = MC_SDRAM_ROWS_1;`
152			`nRowSh = MC_SDRAM_ROWSH_1; break;`
153			`case 2:`
154			`nRowSize = MC_SDRAM_ROWSIZE_2;`
155			`nRows = MC_SDRAM_ROWS_2;`
156			`nRowSh = MC_SDRAM_ROWSH_2; break;`
157			`case 3:`
158			`nRowSize = MC_SDRAM_ROWSIZE_3;`
159			`nRows = MC_SDRAM_ROWS_3;`
160			`nRowSh = MC_SDRAM_ROWSH_3; break;`
161			`case 6:`
162			`nRowSize = MC_SDRAM_ROWSIZE_6;`
163			`nRows = MC_SDRAM_ROWS_6;`
164			`nRowSh = MC_SDRAM_ROWSH_6; break;`
165			`case 7:`
166			`nRowSize = MC_SDRAM_ROWSIZE_7;`
167			`nRows = MC_SDRAM_ROWS_7;`
168			`nRowSh = MC_SDRAM_ROWSH_7; break;`
169			`case 8:`
170			`nRowSize = MC_SDRAM_ROWSIZE_8;`
171			`nRows = MC_SDRAM_ROWS_8;`
172			`nRowSh = MC_SDRAM_ROWSH_8; break;`
173			`}`
174
175	1024	simons	`printf ("CS configuration : CSC - 0x%08lX, TMS - 0x%08lX, rs = %lu, nr = %lu, sh = %lu, sel = %lu\n",`
176	552	ivang	`mc_csc, mc_tms, nRowSize, nRows, nRowSh, mc_sel);`
177	454	ivang
178	552	ivang	`/nRows -= MC_SDRAM_ROW_OFF;/`
179	454	ivang	`for (test=0; test<16; test++) {`
180			`/* configure MC*/`
181	552	ivang	`CLEAR_FLAG(mc_csc, MC_CSC, PEN); / no parity */`
182			`CLEAR_FLAG(mc_csc, MC_CSC, KRO); / close row */`
183			`CLEAR_FLAG(mc_csc, MC_CSC, BAS); / bank after column */`
184			`CLEAR_FLAG(mc_csc, MC_CSC, WP); / write enable */`
185	454	ivang	`SET_FLAG(mc_tms, MC_TMS_SDRAM, WBL); / single loc access */`
186			`CLEAR_FLAG(mc_tms, MC_TMS_SDRAM, BT); / sequential burst */`
187			`SET_FIELD(mc_tms, MC_TMS_SDRAM, BL, 0); / 1 */`
188			`switch (test) {`
189			`case 0:`
190			`if ((MC_SDRAM_TESTS & MC_SDRAM_TEST0) != MC_SDRAM_TEST0)`
191			`continue;`
192			`break;`
193			`case 1:`
194			`if ((MC_SDRAM_TESTS & MC_SDRAM_TEST1) != MC_SDRAM_TEST1)`
195			`continue;`
196	552	ivang	`SET_FLAG(mc_csc, MC_CSC, PEN); / parity */`
197	454	ivang	`break;`
198			`case 2:`
199			`if ((MC_SDRAM_TESTS & MC_SDRAM_TEST2) != MC_SDRAM_TEST2)`
200			`continue;`
201	552	ivang	`SET_FLAG(mc_csc, MC_CSC, KRO); / keep row */`
202	454	ivang	`break;`
203			`case 3:`
204			`if ((MC_SDRAM_TESTS & MC_SDRAM_TEST3) != MC_SDRAM_TEST3)`
205			`continue;`
206	552	ivang	`SET_FLAG(mc_csc, MC_CSC, BAS); / bank after row*/`
207	454	ivang	`break;`
208			`case 4:`
209			`if ((MC_SDRAM_TESTS & MC_SDRAM_TEST4) != MC_SDRAM_TEST4)`
210			`continue;`
211	552	ivang	`SET_FLAG(mc_csc, MC_CSC, WP); / RO */`
212	454	ivang	`break;`
213			`case 5:`
214			`if ((MC_SDRAM_TESTS & MC_SDRAM_TEST5) != MC_SDRAM_TEST5)`
215			`continue;`
216			`CLEAR_FLAG(mc_tms, MC_TMS_SDRAM, WBL); / burst */`
217			`break;`
218			`case 6:`
219			`if ((MC_SDRAM_TESTS & MC_SDRAM_TEST6) != MC_SDRAM_TEST6)`
220			`continue;`
221			`CLEAR_FLAG(mc_tms, MC_TMS_SDRAM, WBL); / burst */`
222			`SET_FIELD(mc_tms, MC_TMS_SDRAM, BL, 1); / 2 */`
223			`break;`
224			`case 7:`
225			`if ((MC_SDRAM_TESTS & MC_SDRAM_TEST7) != MC_SDRAM_TEST7)`
226			`continue;`
227			`CLEAR_FLAG(mc_tms, MC_TMS_SDRAM, WBL); / burst */`
228			`SET_FIELD(mc_tms, MC_TMS_SDRAM, BL, 2); / 4 */`
229			`break;`
230			`case 8:`
231			`if ((MC_SDRAM_TESTS & MC_SDRAM_TEST8) != MC_SDRAM_TEST8)`
232			`continue;`
233			`CLEAR_FLAG(mc_tms, MC_TMS_SDRAM, WBL); / burst */`
234			`SET_FIELD(mc_tms, MC_TMS_SDRAM, BL, 3); / 8 */`
235			`break;`
236			`case 9:`
237			`if ((MC_SDRAM_TESTS & MC_SDRAM_TEST9) != MC_SDRAM_TEST9)`
238			`continue;`
239			`CLEAR_FLAG(mc_tms, MC_TMS_SDRAM, WBL); / burst */`
240			`SET_FIELD(mc_tms, MC_TMS_SDRAM, BL, 7); / full page */`
241			`break;`
242			`case 10:`
243			`if ((MC_SDRAM_TESTS & MC_SDRAM_TEST10) != MC_SDRAM_TEST10)`
244			`continue;`
245			`CLEAR_FLAG(mc_tms, MC_TMS_SDRAM, WBL); / burst */`
246			`SET_FLAG(mc_tms, MC_TMS_SDRAM, BT); / interleaved burst */`
247			`break;`
248			`case 11:`
249			`if ((MC_SDRAM_TESTS & MC_SDRAM_TEST11) != MC_SDRAM_TEST11)`
250			`continue;`
251			`CLEAR_FLAG(mc_tms, MC_TMS_SDRAM, WBL); / burst */`
252			`SET_FLAG(mc_tms, MC_TMS_SDRAM, BT); / interleaved burst */`
253			`SET_FIELD(mc_tms, MC_TMS_SDRAM, BL, 1); / 2 */`
254			`break;`
255			`case 12:`
256			`if ((MC_SDRAM_TESTS & MC_SDRAM_TEST12) != MC_SDRAM_TEST12)`
257			`continue;`
258			`CLEAR_FLAG(mc_tms, MC_TMS_SDRAM, WBL); / burst */`
259			`SET_FLAG(mc_tms, MC_TMS_SDRAM, BT); / interleaved burst */`
260			`SET_FIELD(mc_tms, MC_TMS_SDRAM, BL, 2); / 4 */`
261			`break;`
262			`case 13:`
263			`if ((MC_SDRAM_TESTS & MC_SDRAM_TEST13) != MC_SDRAM_TEST13)`
264			`continue;`
265			`CLEAR_FLAG(mc_tms, MC_TMS_SDRAM, WBL); / burst */`
266			`SET_FLAG(mc_tms, MC_TMS_SDRAM, BT); / interleaved burst */`
267			`SET_FIELD(mc_tms, MC_TMS_SDRAM, BL, 3); / 8 */`
268			`break;`
269			`case 14:`
270			`if ((MC_SDRAM_TESTS & MC_SDRAM_TEST14) != MC_SDRAM_TEST14)`
271			`continue;`
272			`CLEAR_FLAG(mc_tms, MC_TMS_SDRAM, WBL); / burst */`
273			`SET_FLAG(mc_tms, MC_TMS_SDRAM, BT); / interleaved burst */`
274			`SET_FIELD(mc_tms, MC_TMS_SDRAM, BL, 7); / fullrow */`
275			`break;`
276			`case 15:`
277			`if ((MC_SDRAM_TESTS & MC_SDRAM_TEST15) != MC_SDRAM_TEST15)`
278			`continue;`
279	552	ivang	`SET_FLAG(mc_csc, MC_CSC, KRO); / keep row */`
280	454	ivang	`CLEAR_FLAG(mc_tms, MC_TMS_SDRAM, WBL); / burst */`
281			`SET_FLAG(mc_tms, MC_TMS_SDRAM, BT); / interleaved burst */`
282			`SET_FIELD(mc_tms, MC_TMS_SDRAM, BL, 1); / 2 */`
283			`break;`
284			`} /switch test/`
285
286	1024	simons	`printf ("Begin TEST %lu : CSC - 0x%08lX, TMS - 0x%08lX\n", test, mc_csc, mc_tms);`
287	454	ivang
288			`if (MC_SDRAM_ACC & MC_SDRAM_SROW) {`
289			`/* perform sequential row access */`
290	1024	simons	`printf("Seuential Row\n");`
291	552	ivang	`for (j=0; j<T_ROWS; j++) {`
292	454	ivang	`nAddress = mc_sel << 21;`
293			`nAddress \|= MC_MEM_BASE;`
294	552	ivang	`nAddress += ( (j + T_ROW_OFF) << nRowSh);`
295	544	ivang
296			`gpio_pat ^= 0x00000008;`
297			`*rgpio_out = gpio_pat;`
298	552	ivang	`ret = mc_test_row(nAddress, nAddress + T_ROW_SIZE, MC_SDRAM_FLAGS);`
299	454	ivang
300	1024	simons	`printf("\trow - %lu: nAddress = 0x%08lX, ret = 0x%08lX\n", j, nAddress, ret);`
301	544	ivang
302	454	ivang	`if (ret) {`
303	544	ivang	`gpio_pat ^= 0x00000080;`
304			`*rgpio_out = gpio_pat;`
305	454	ivang	`report(ret);`
306			`return ret;`
307			`}`
308			`}`
309			`}`
310
311			`if (MC_SDRAM_ACC & MC_SDRAM_RROW) {`
312			`/* perform random row access */`
313	1024	simons	`printf("Random Row\n");`
314	552	ivang	`for (j=0; j<T_ROWS; j++) {`
315			`nAddress = mc_sel << 21;`
316	454	ivang	`nAddress \|= MC_MEM_BASE;`
317	552	ivang	`nAddress += ( (T_ROW_OFF + random(nRows)) << nRowSh);`
318
319	544	ivang	`gpio_pat ^= 0x00000008;`
320			`*rgpio_out = gpio_pat;`
321	552	ivang	`ret = mc_test_row(nAddress, nAddress + T_ROW_SIZE, MC_SDRAM_FLAGS);`
322	454	ivang
323	1024	simons	`printf("\trow - %lu: nAddress = 0x%08lX, ret = 0x%08lX\n", j, nAddress, ret);`
324	544	ivang
325	454	ivang	`if (ret) {`
326	544	ivang	`gpio_pat ^= 0x00000080;`
327			`*rgpio_out = gpio_pat;`
328	552	ivang	`report(ret);`
329	454	ivang	`return ret;`
330			`}`
331			`}`
332			`}`
333
334			`if (MC_SDRAM_ACC & MC_SDRAM_SGRP) {`
335			`/* perform sequential row in group access */`
336	1024	simons	`printf("Sequential Group ");`
337	454	ivang
338	1024	simons	`printf("Group Size = %d\n", MC_SDRAM_GROUPSIZE);`
339	552	ivang	`for (i=0; i<T_GROUPS; i++) {`
340			`nRowGrp = random(nRows - MC_SDRAM_GROUPSIZE) + T_ROW_OFF;`
341			`for (j=0; j<MC_SDRAM_GROUPSIZE; j++) {`
342	454	ivang	`nAddress = mc_sel << 21;`
343			`nAddress \|= MC_MEM_BASE;`
344			`nAddress += ((nRowGrp+j) << nRowSh);`
345	544	ivang
346			`gpio_pat ^= 0x00000008;`
347			`*rgpio_out = gpio_pat;`
348	552	ivang	`ret = mc_test_row(nAddress, nAddress + T_ROW_SIZE, MC_SDRAM_FLAGS);`
349	454	ivang
350	1024	simons	`printf("\trow - %lu: nAddress = 0x%08lX, ret = 0x%08lX\n", j, nAddress, ret);`
351	544	ivang
352	454	ivang	`if (ret) {`
353	544	ivang	`gpio_pat ^= 0x00000080;`
354			`*rgpio_out = gpio_pat;`
355	454	ivang	`report(ret);`
356			`return ret;`
357			`}`
358			`}`
359			`}`
360			`}`
361
362			`if (MC_SDRAM_ACC & MC_SDRAM_RGRP) {`
363			`/* perform random row in group access */`
364	1024	simons	`printf("Random Group ");`
365	454	ivang
366	1024	simons	`printf("Group Size = %d\n", MC_SDRAM_GROUPSIZE);`
367	552	ivang	`for (i=0; i<T_GROUPS; i++) {`
368			`nRowGrp = random(nRows - T_GROUPS) + T_ROW_OFF;`
369			`for (j=0; j<MC_SDRAM_GROUPSIZE; j++) {`
370	454	ivang	`nAddress = mc_sel << 21;`
371			`nAddress \|= MC_MEM_BASE;`
372	552	ivang	`nAddress += ((nRowGrp + random(MC_SDRAM_GROUPSIZE)) << nRowSh);`
373	544	ivang
374			`gpio_pat ^= 0x00000008;`
375			`*rgpio_out = gpio_pat;`
376	552	ivang	`ret = mc_test_row(nAddress, nAddress + T_ROW_SIZE, MC_SDRAM_FLAGS);`
377	454	ivang
378	1024	simons	`printf("\trow - %lu: nAddress = 0x%08lX, ret = 0x%08lX\n", j, nAddress, ret);`
379	544	ivang
380	454	ivang	`if (ret) {`
381	544	ivang	`gpio_pat ^= 0x00000080;`
382			`*rgpio_out = gpio_pat;`
383	454	ivang	`report(ret);`
384			`return ret;`
385			`}`
386			`}`
387			`}`
388			`} /for groups/`
389
390			`} /for test/`
391			`} /if/`
392			`} /for CS/`
393	1024	simons	`printf("--- End SDRAM tests ---\n");`
394	454	ivang	`report(0xDEADDEAD);`
395	544	ivang
396			`gpio_pat ^= 0x00000020;`
397			`*rgpio_out = gpio_pat;`
398
399	454	ivang	`return 0;`
400			`} /* main */`

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